Abstract
Lichens are symbiotic associations resulting from interactions among fungi (primary and secondary mycobionts), algae and/or cyanobacteria (primary and secondary photobionts), and specific elements of the bacterial microbiome associated with the lichen thallus. The question of what is a species, both concerning the lichen as a whole and its main fungal component, the primary mycobiont, has faced many challenges throughout history and has reached new dimensions with the advent of molecular phylogenetics and phylogenomics. In this paper, we briefly revise the definition of lichens and the scientific and vernacular naming conventions, concluding that the scientific, Latinized name usually associated with lichens invariably refers to the primary mycobiont, whereas the vernacular name encompasses the entire lichen. Although the same lichen mycobiont may produce different phenotypes when associating with different photobionts or growing in axenic culture, this discrete variation does not warrant the application of different scientific names, but must follow the principle "one fungus = one name". Instead, broadly agreed informal designations should be used for such discrete morphologies, such as chloromorph and cyanomorph for lichens formed by the same mycobiont but with either green algae or cyanobacteria. The taxonomic recognition of species in lichen-forming fungi is not different from other fungi and conceptual and nomenclatural approaches follow the same principles. We identify a number of current challenges and provide recommendations to address these. Species delimitation in lichen-forming fungi should not be tailored to particular species concepts but instead be derived from empirical evidence, applying one or several of the following principles in what we call the LPR approach: lineage (L) coherence vs. divergence (phylogenetic component), phenotype (P) coherence vs. divergence (morphological component), and/or reproductive (R) compatibility vs. isolation (biological component). Species hypotheses can be established based on either L or P, then using either P or L (plus R) to corroborate them. The reliability of species hypotheses depends not only on the nature and number of characters but also on the context: the closer the relationship and/or similarity between species, the higher the number of characters and/or specimens that should be analyzed to provide reliable delimitations. Alpha taxonomy should follow scientific evidence and an evolutionary framework but should also offer alternative practical solutions, as long as these are scientifically defendable. Taxa that are delimited phylogenetically but not readily identifiable in the field, or are genuinely cryptic, should not be rejected due to the inaccessibility of proper tools. Instead, they can be provisionally treated as undifferentiated complexes for purposes that do not require precise determinations. The application of infraspecific (gamma) taxonomy should be restricted to cases where there is a biological rationale, i.e., lineages of a species complex that show limited phylogenetic divergence but no evidence of reproductive isolation. Gamma taxonomy should not be used to denote discrete phenotypical variation or ecotypes not warranting the distinction at species level. We revise the species pair concept in lichen-forming fungi, which recognizes sexually and asexually reproducing morphs with the same underlying phenotype as different species. We conclude that in most cases this concept does not hold, but the actual situation is complex and not necessarily correlated with reproductive strategy. In cases where no molecular data are available or where single or multi-marker approaches do not provide resolution, we recommend maintaining species pairs until molecular or phylogenomic data are available. This recommendation is based on the example of the species pair Usnea aurantiacoatra vs. U. antarctica, which can only be resolved with phylogenomic approaches, such as microsatellites or RADseq. Overall, we consider that species delimitation in lichen-forming fungi has advanced dramatically over the past three decades, resulting in a solid framework, but that empirical evidence is still missing for many taxa. Therefore, while phylogenomic approaches focusing on particular examples will be increasingly employed to resolve difficult species complexes, broad screening using single barcoding markers will aid in placing as many taxa as possible into a molecular matrix. We provide a practical protocol how to assess and formally treat taxonomic novelties. While this paper focuses on lichen fungi, many of the aspects discussed herein apply generally to fungal taxonomy. The new combination Arthonia minor (Lücking) Lücking comb. et stat. nov. (Bas.: Arthonia cyanea f. minor Lücking) is proposed.
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Table of contents
Introduction
What are lichens and how should they be named?
Species concepts and their application in lichenized fungi
The species pair concept and dual nomenclature in lichenized fungi
Cryptic speciation and the taxonomic value of phenotype characters
Species versus infraspecific ranks
A quick primer on common molecular complications
Data and taxon sampling
Conclusions: A protocol for consistent alpha (and gamma) taxonomy in lichen-forming fungi
Acknowledgements
Declarations
References
Introduction
Botanical nomenclature, and with it the nomenclature of fungi including lichen-formers, started with Linnaeus (1753). Only 80 lichens were accepted in that work, in a single genus Lichen, although some were also included in the algal genus Byssus (= Trentepohlia; for authorship and Index Fungorum/MycoBank registration numbers of names used in this paper, see Suppl. File S1). For comparison, while recognizing about the same number of fungi, Linnaeus classified these into ten genera. Prior to Linnaeus various workers had already elaborated more detailed classifications for lichens, regarding the number of species and/or genera. Michelius (1729), in his Nova Plantarum Genera, recognized nearly 300 species, in a single genus Lichen but classified into 38 groups ("ordo"). In Historia Muscorum, Dillenius (1742) also recognized close to 300 species, in several genera (e.g., Byssus, Conferva, Coralloides, Lichen, Lichenastrum, Lichenoides, Usnea), although it remains unclear whether some of these actually corresponded to lichens or to algae, bryophytes, or fungi. Thus, Linnaeus (1753) marked the first substantial change in species concepts in lichen fungi. It was not until Acharius (1798, 1803, 1810, 1814), the "father of lichenology" (Nylander 1858; Vitikainen 1976), when the classification of lichens got back on track and the diversity of this enigmatic group of organisms began to be unraveled.
Another angle on species concepts in lichens was provided by their initial treatment as organisms separate from plants and fungi, although similarities with bryophytes, algae and fungi (Fig. 1) were recognized early on. The separation between lichens and fungi was, however, not clear-cut: Acharius (1810) included some non-lichenized fungi, and Fries (1821) noted analogies between particular genera in his introduction to Systema Mycologicum—one of the key works sanctioning names of fungi. These analogies were, however, superficial and did not relate genera perceived as lichens to their closest fungal relatives (e.g., Verrucaria vs. Sphaeria = Hypoxylon; Graphis vs. Hysterium; Biatora vs. Peziza; Collema vs. Tremella). Just prior to the decade that led to the discovery of the lichen symbiosis (De Bary 1866; Schwendener in Anonymous 1867; Schwendener 1868), the Finnish lichenologist Nylander (1858) published a classification considering lichens an evolutionary link between algae and fungi. This was based on the idea that lichens were overall similar to fungi but contained an additional element not known from other fungi but similar to algae, the so-called "gonidia" (Körber 1939; Berkeley 1857). Thwaites (1849) established a close relationship of lichen "gonidia" with algae, such as Nostoc (in Collema, Leptogium and the species now known as Placynthium nigrum); Pleurococcus sensu lato (in most "lichens proper", including Biatora vernalis, referring to a variety of chlorococcoid photobionts nowadays classified in genera such as Trebouxia, Asterochloris, Coccomyxa, Myrmecia, and others); Coccochloris sensu lato (a rejected name in favour of Aphanothece, actually referring to the Gloeocapsa photobiont in what Thwaites called Synalissa vulgaris and which correctly refers to S. ramulosa); and Ulva sensu lato (the photobiont of Mastodia tessellata, subsequently identified as Prasiola crispa subsp. antarctica; see Pérez‐Ortega et al. 2010). Besides Sidney (1846), Thwaites (1849) was among the first to consider gonidia as an essential part of the lichen thallus, not merely a structure for reproduction. However, he did not draw the proper conclusions and instead considered lichens and the corresponding algae closely related, even suggesting that in some cases they should be placed in the same genus.
Prior to the recognition of the lichen as a symbiosis, names given to lichens encompassed the gonidia as specific structures of the thallus. The discovery of the lichen symbiosis made it necessary to not only reconsider the nature of lichens but also their nomenclature and classification. Shortly after the turn of the century, two schools had emerged: the largely Central European school, maintaining lichens as a separate group related to fungi (e.g., Reinke 1896; Zahlbruckner 1907, 1926), and the largely North American school, integrating lichen fungi into the overall fungal classifications (e.g., Lindau 1895; Clements 1897, 1909; Fink 1911; Clements and Shear 1931). In both cases, it was implied that the name given to lichens should refer to the fungal partner, but formally this issue was only resolved well into the twentieth century, when the Stockholm Code specified the scientific name as applying to the fungal component (Lanjouw et al. 1952; Santesson 1953). More than a decade prior, Thomas (1939) had proposed to name lichen fungi in culture differently, by adding the suffix "-myces". The subsequent approach by Ciferri and Tomaselli (1953a, b, 1954a, b, 1955, 1957; see Santesson 1954; Lücking and Hawksworth 2007) is often considered a last attempt at giving different names to lichen fungi whereas retaining the original name for the lichen as a whole. However, this is a misinterpretation of the original intention of these authors, who suggested to apply different names to the fungus in axenic culture vs. the lichen mycobiont in situ. Their approach was similar to dual nomenclature, which at the time was only allowed for so-called pleomorphic fungi, i.e., fungi with both sexual and asexual morphs.
Lichen-forming fungi continued to be regarded as a separate class from other Fungi, latinized as Lichenes (higher taxon names here placed in italics, following Thines et al. 2020), a practice followed in the appendices of conserved generic names in editions of the International Code of Botanical Nomenclature, right up to the Leningrad Code (Stafleu et al. 1978). This later changed to "Fungi (including lichen-forming fungi)" in the Sydney Code (Voss et al. 1983), and to "Fungi" in the Tokyo Code (Greuter et al. 1994). Alongside these changes, the second half of the twentieth century saw a full integration of lichen mycobionts into fungal classifications, fostered by initiatives such as Ainsworth & Bisby’s Dictionary of the Fungi (Ainsworth et al. 1971), the Index of Fungi (from 1970 onwards), and Systema Ascomycetum, from its inception in 1986 (Hawksworth and Eriksson 1994; Lücking et al. 2021a). Lichen fungi thus became part of regularly implemented updates of fungal classifications and this facilitated a seamless transition into the molecular era, with substantial changes in the higher classification of fungi including lichen-formers in the past three decades (Miądlikowska et al. 2006, 2014a; Nelsen et al. 2009, 2011, 2020; Lumbsch and Huhndorf 2010; Frisch et al. 2014; Chen et al. 2015; Lücking et al. 2017a; Kraichak et al. 2018; Pizarro et al. 2018; Widhelm et al. 2019). Molecular phylogenies were also employed early on to address species delimitation in lichen fungi, first using single-marker approaches focusing on the fungal ITS barcoding marker but also increasingly other approaches such as multi-marker coalescence or phylogenomics, including microsatellites, RADseq and target capture (Franc and Kärnefelt 1998; Lohtander et al. 1998; Thell et al. 2000; Kroken and Taylor 2001; Moncada et al. 2014; Lücking et al. 2017b; Magain et al. 2017; Grewe et al. 2018; Lagostina et al. 2018; LaGreca et al. 2020; Widhelm et al. 2021; Lücking et al. 2021b). These studies have also generated new interest in the application of theoretical species concepts to species-level taxonomy in lichen fungi (Grube and Kroken 2000; Buschbom and Mueller 2006; Crespo and Pérez-Ortega 2009; Crespo and Lumbsch 2010; Lumbsch and Leavitt 2011; Leavitt et al. 2016a, b; Jørgensen 2019).
Here, we provide a revised overview of the different aspects of species-level taxonomy in lichen fungi, focusing on conceptual and practical aspects and taking into account increasing evidence from phylogenetics and phylogenomics, with numerous examples and practical recommendations.
What are lichens and how should they be named?
After the discovery of the lichen symbiosis, the definition of what constitutes a lichen has varied considerably (Table 1). Some definitions are descriptive rather than diagnostic, e.g., that of Ahmadjan (1993). Rather than developing over time, definitions also followed particular views, such as Honegger (1991, 2001, 2012) using the symbiotic phenotype as core element, and Hawksworth and co-workers focusing on the notion of a stable, self-supporting association and the antagonism between the mycobiont as exhabitant and the photobiont as inhabitant (Hawksworth et al. 1983; Hawksworth and Hill 1984; Hawksworth 1988; Hawksworth and Honegger 1994).
There are certain challenges to the accurate and precise definition of a lichen. A merely functional definition, as a symbiosis between a heterotrophic fungus (or fungus-like organism) and a photosynthetic component, would be imprecise, as it would not discriminate between lichens one one hand and ecto- and endomycorrhiza, bryophilous fungi, mycophycosymbioses, and endosymbiotic associations, such as in Geosiphon pyriformis, all of which are not considered lichens (Hawksworth and Hill 1984; Hawksworth 1988). A taxonomic or phylogenetic definition, as a symbiosis between a fungus and an alga or cyanobacterium, would also be challenging, as fungi in the sense of the International Code of Nomenclature for algae, fungi and plants [ICNafp (Shenzen); Turland et al. 2018; May et al. 2018] are not a natural group, encompassing at least three kingdoms, and the known lichen photobionts represent two domains and three kingdoms (Friedl and Büdel 2008; Saini et al. 2019). Given extant lichens, one could specify the fungal component as a member of the kingdom Fungi, but what would a theoretical association involving a member of the Oomycota then constitute and how could one exclude that associations with other fungal-like organisms might exist or might have existed in the past? Associations with photosynthetic algae have also been formed by fungal-like bacteria (Actinomycetes) and by fungi otherwise not forming lichens, such as in the genus Aspergillus, under laboratory conditions (Lazo 1966; Lawrey 1984; Zvyagintsev et al. 2010; Lücking and Nelsen 2018; Krespach et al. 2020). Since photobionts of lichens represent two domains (including Bacteria) and three kingdoms, there would be no logical reason to restrict mycobionts to a single domain (excluding Bacteria) and kingdom. Additional complications arise from facultatively lichenized fungi, e.g., in the genera Schizoxylon and Stictis (Stictidaceae; Wedin et al. 2004; Muggia et al. 2011), from situations where it is unclear whether the fungus is actually lichenized, in species of genera such as Arthonia sensu lato, Arthopyrenia sensu lato, or Mycomicrothelia sensu lato (Hawksworth 2005; Lücking et al. 2017a; Grube and Wedin 2018; Thiyagaraja et al. 2020), and from lichenicolous lichens in which one fungus takes over the photobiont of another lichen, e.g. in Diploschistes muscorum (Friedl 1987).
Thus far, associations broadly accepted as lichens fulfil two criteria: (1) the mycobiont is a member of the kingdom Fungi; (2) the photobiont is algal-like, i.e., with an undifferentiated, unicellular to filamentous body plan not forming distinct organs (root, stem, leaves). If this is incorporated into the definition, two challenging cases remain that are currently not considered lichens: (1) so-called mycophycobioses, i.e., relationships between marine fungi and macroalgae with a differentiated body plan and in which the algae typically retain their form and sexual reproductive capacity, such as Mycophycias ascophylli in the seaweed genera Ascophyllum and Pelvetia (Kohlmeyer and Kohlmeyer 1972; Hawksworth 1988, 2000; Selosse and Le Tacon 1998; Gimmler 2001; Pérez-Ortega et al. 2018); and (2) relationships between certain mushrooms, such as in the genus Arrhenia, and moss protonemata, the latter being "algal-like" (Redhead 1984; Redhead and Kuyper 1987; Döbbeler 1997; Stenroos et al. 2010; Pressel et al. 2014).
Another issue is the biological nature of the symbiosis, which has been classified somewhere between mutualism and controlled parasitism (Ahmadjian 1993; Hawksworth 1988; Honegger 1991, 1998). The fungal partner actively seeks the relationship with a compatible photobiont and controls it, both in terms of morphology and physiology (Honegger 1991, 1998, 2001, 2012; Sanders 2001a, 2005, 2014; Sanders and Lücking 2002). Even some filamentous lichens, which give the impression that the thallus shape is driven by the photobiont, turned out to be remarkable cases of mycobiont-controlled photobiont morphogenesis (Nyati et al. 2007). Filamentous algae of the genus Trentepohlia also change their morphology in lichenization with Coenogonium (Uyenco 1965), even if the latter genus resembles non-lichenized algae (Fig. 1c). Essentially, the mycobiont builds a "greenhouse" for the photobiont, except for cases when the environmental conditions are favorable for the photobiont, such as in filamentous thalli of Coenogonium and Dictyonema in tropical regions (Thomas et al. 1997; Lakatos et al. 2006). For this reason, the definition of lichens being fungi that discovered agriculture has caught some momentum (Goward 1994; Lücking et al. 2009a, b, c; Lücking and Lumbsch 2014). Indeed, patterns of mycobiont and photobiont diversity and photobiont sharing between unrelated mycobionts show analogies to farming (Hyvärinen et al. 2002; Lücking et al. 2009a).
Up to the present, lichens have been defined as an association between a mycobiont and one or two photobionts (Table 1), as these are the elements generally visible under microscopic examination (Fig. 2). However, the frequent presence of lichenicolous fungi and the discovery of a diverse microbiome associated with the lichen thallus have challenged this view (Hawksworth and Grube 2020). Apart from the principal bionts, the lichen microbiome is constituted of at least four additional components: (1) lichenicolous fungi, (2) endolichenic fungi, (3) facultatively associated algae and/or cyanobacteria, and (4) bacteria. Lichenicolous fungi are the best studied group among these (Lawrey and Diederich 2003; Diederich et al. 2018). They can largely be divided into mycoparasites, which attack the lichen mycobiont and often cause substantial damage to the thallus, gall-formers, and often symptomless fungi that share the algal partner, sometimes called parasymbionts, although other strategies exist as well (Hawksworth 1988, 2003; Grube and Hafellner 1990; Grube and Lücking 2002). A remarkable case among the latter are the lichenicolous lineages nested within macrolichen clades in the family Parmeliaceae (Divakar et al. 2015). However, the division between lichenicolous fungi and lichen-formers is not clear-cut. New findings raise the question whether fungi other than the primary mycobiont, such basidiomycetous yeasts and other fungi inhabiting the cortex of lichen thalli, play a role in the symbiosis or are merely latent stages of lichenicolous gall formers (Spribille et al. 2016; Lücking and Moncada 2017; Černajová and Škaloud 2019; Lendemer et al. 2019; Tuovinen et al. 2019, 2021; Mark et al. 2020).
Endolichenic fungi are a more diffuse group usually detected with high throughput sequencing or culturing, in analogy to endophytic fungi (Arnold et al. 2009; Chagnon et al. 2015; Fernández-Mendoza et al. 2017; Tripathi and Joshi 2019). Endophytic fungi are generally latent saprotrophs or pathogens, but it remains unclear to what extent endolichenic fungi, other than lichenicolous taxa, actually have a latent presence within lichen thalli or whether they just represent spores or hyphae of widespread, weedy taxa accidentally trapped or otherwise associated with the latter. The role of fungi as saprotrophs on dead lichens remains unclear, although decomposition of lichen thalli has been widely studied (Guzman et al. 1990; Greenfield 1993; Biazrov 1994; McCune and Daly 1994; Caldiz et al. 2007; Campbell et al. 2010; Asplund and Wardle 2012; Berdugo et al. 2021). Given the diversity of mycoparasites in general and lichenicolous fungi attacking and damaging lichen mycobionts in particular, it seems feasible that certain fungi play a role in decomposing lichen thalli, although it has also been shown that certain lichen substances can prevent fungal attacks and this effect may persist in dead thalli (Lawrey 1995; Torzilli et al. 2002).
The bacterial microbiome of lichens is highly diverse and there is some indication of partial specificity and some functional role in the lichen symbiosis (Cardinale et al. 2012; Grube et al. 2012, 2015; Aschenbrenner et al. 2016; Hawksworth and Grube 2020; Grimm et al. 2021). However, when considering the microbiome in the definition of lichens, it should not be overlooked that microbiomes occur in practically all organisms, most notably in the gut of animals, such as insects or vertebrates including humans (Ohkuma 2008; Brune and Dietrich 2015; Heintz-Buschart and Wilmes 2018; Muñoz-Benavent et al. 2020; Scheelings et al. 2020). In none of these cases, the microbiome, even if highly specific, is included in the definition of the corresponding organism. Humans without their gut microbiome are still defined as humans. The case of lichens is, however, different, as lichens are not single organism but already constitute a symbiosis. Thus, while the definition of each of the principal components of a lichen, the mycobiont and the photobiont(s), is independent of the microbiome, the lichen as a whole may not exist without certain components of the latter. Even so, a definition should be diagnostic rather than descriptive, and hence not include every component potentially found in lichens but only those that are critical for their successful establishment. Therefore, we propose a modified definition, integrating aspects put forward by Ainsworth et al. (1971), Hawksworth (1988), Honegger (1991, 2012), Goward (1994), Kirk et al. (2008), and Hawksworth and Grube (2020).
A lichen is a stable, self-supporting association of a fungus or fungal-like organism, the primary mycobiont, and a morphologically undifferentiated, unicellular to filamentous alga and/or a cyanobacterium, the primary (and secondary) photobiont, along with obligately associated elements of the fungal and bacterial microbiome contained therein. The phenotype of the mycobiont in the lichenized state (the exhabitant) typically functions as a greenhouse around the photobiont (the inhabitant), the mechanical, physiological and evolutionary properties of the symbiosis thereby exhibiting analogies with agriculture.
The above considerations about the definition of lichens are of a purely biological and functional nature and primarily unrelated to taxonomic and nomenclatural considerations. It has, however, been argued that the lichen symbiosis is unique in that the mycobiont, in order to build the "greenhouse" for the photobiont, develops morphological structures neither known from other fungi nor from the mycobiont itself when grown in axenic culture (Honegger 1991, 2001, 2012). As a result, mycobionts in axenic culture have entirely different phenotypes compared to lichenized thalli, and the lichen architecture only exists in the presence of both bionts. Through this architecture, lichens acts in their environment as if they were single organisms, functionally and morphologically mimicking plants (Sanders 2001b). This morphological differentiation in the presence of a photobiont is particularly striking when considering cephalodia and so-called photosymbiodemes (Fig. 3a–b), in which the same fungus forms different structures or entirely different lichens when associating with either green algae or cyanobacteria (James and Henssen 1976; Armaleo and Clerc 1991; Green and Lange 1991; Purvis 2000; Sanders 2001c; Magain et al. 2012; Moncada et al. 2013a, b; Ranft et al. 2018). The notion that these instances form functionally distinct entities has sparked controversy as to whether they should be named differently (Goward 2008). This extends to the issue that the scientific name of the lichen mycobiont is often used as proxy for the lichen as a whole, in all its complexity, which is misleading at best and inappropriate at worst. In contrast, vernacular names encompass the entire lichen, as they are derived from the overall appearance of the thallus architecture, produced by both the mycobiont and the photobiont(s). Therefore, vernacular names do not precisely correspond to scientific names applied to lichens (Goward 2008). A comparison between the thallus of the yellow wall lichen, with the scientific name Xanthoria parietina for the mycobiont, and the axenic culture of the latter (Fig. 3c–d; see also Purvis 2000, p. 9), immediately demonstrates that the vernacular name cannot apply to the fungus in isolation.
While the above considerations seem to justify the need for a name to encompass the lichen as a whole, or to distinguish between different lichens formed by the same fungus, such as photosymbiodemes, it should be noted that analogous situations are common in the Tree of Life. Examples are rust fungi, red algae, and holometabolous insects. Rust fungi can form up to six morphologically different phases during their life-cycle, partly associated with different hosts (Aime 2006). Traditionally, these have been given different scientific names, especially when based on sexual vs. asexual reproduction, under the concept of dual nomenclature (Briquet et al. 1912). Thus, the phase of Puccinia graminis on Berberis was named Aecidium berberidis. However, during the past decade, this concept has been abandoned in favor of "one fungus = one name" (Taylor 2011; Hawksworth et al. 2011). A similar situation is found in red algae, where the so-called chantransia stages in the genus Batrachospermum sensu lato may have been classified in separate genera, such as Audouinella, Chantransia, Ptilothamnion, and others (Necchi and Zucchi 1997; Chiasson et al. 2005; Vis et al. 2006; Necchi et al. 2019). Vis et al. (2006) proposed to formally maintain the chantransia stages in the genus Chantransia, which is not allowed by the Code [ICNafp (Shenzen) Art. 52.1]. Holometabolous insects form strikingly different developmental stages, occupying quite different niches in ecosystems. These were rarely treated as separate taxa but from early on received informal names, such as larva, pupa, and imago (Johnson and Triplehorn 2005; Miller et al. 2005). The fact that the same species can form strikingly disparate morphs, triggered by environment, ontogeny, epigenetics, genotype, or other factors, is thus well-documented across the Tree of Life, and in modern nomenclature these are not treated separately. As a consequence, the appears to be no particular reason why the same fungus forming disparate phenotypes under different conditions should receive different scientific names. Rather, in such instances, the scientific name should be accompanied by a standardized, informal designation, in analogy to e.g., insect stages, such as chloromorph and cyanomorph in the case of photosymbiodemes (Goffinet and Bayer 1997).
This issue also relates to the effort initiated by Thomas (1939) and formally implemented by Ciferri and Tomaselli (1953a, b, 1954a, b, 1955, 1957) to generate separate scientific names for lichen mycobionts in axenic culture. While the latter authors recognized the newly implemented provision by the Code that the scientific name originally given to lichens applies to the mycobiont, they argued that the lichen fungus behaves strikingly different in the lichen symbiosis as compared to its axenic culture. In particular, they concluded that from the thousands of lichens recognized at the time, only a much smaller number of fungi could be isolated in culture. Thus, in their interpretation different lichens shared the same fungus, just as different lichens shared the same photobiont, and so the diversity of lichens was caused by variable combinations of a low number of fungi and algae or cyanobacteria. Their approach was thus ill-defined both scientifically and nomenclaturally (Lücking and Hawksworth 2007).
Species concepts and their application in lichenized fungi
Since Mayr (1944), the species has been widely recognized as the fundamental unit to classify organisms in biodiversity research (Wilson 1988; Mooers 2007; Freudenstein et al. 2017). This is also embedded in the Code, where the valid establishment of taxa above species (beta taxonomy) and below species level (gamma taxonomy) depend on the prior valid establishment of a species name [ICNafp (Shenzen) Art. 10.1, 10.9, 10.10, 24.1, 35.1]. However, the question what defines species remains complex and approaches to this problem have experienced continuous adjustments depending on conceptual and methodological advances. Numerous species concepts have been established over the past century (Mayden 1997; De Queiroz 2007; Wilkins 2009, 2018; Crous et al. 2015; Zachos 2016), but these can all be based on three basic components (Lücking et al. 2020a): lineage (L), phenotype (P), and reproduction (R). Species are branches in the lines of descent, i.e., segments of metapopulation lineages (De Queiroz 2007), typically expected to be reciprocally monophyletic. While reciprocal monophyly as an exclusivity criterion for species delimitation is intuitively appealing, metapopulation lineages may not be recovered as monophyletic of a number of reasons (Knowles and Carstens 2007), including incomplete lineage sorting in recently diverged species, introgression and hybridization (see below), porous or "semi-permeable" species boundaries, and other evolutionary scenarios (Joly et al. 2009; Steenkamp et al. 2018). Therefore, emerging lineages nested within a paraphyletic residual have been accepted as recently evolving species under certain circumstances (Wheeler and Nixon 1990; Crisp and Chandler 1996; Wheeler and Platnik 2000; Funk and Omland 2003; Freudenstein et al. 2017; Mercado-Díaz et al. 2020). It is further expected that diverging lineages also diverge in phenotype, including morphology, anatomy, chemistry, metabolism, and physiology, owing to either neutral mechanisms such as genetic drift, selective forces in diverging environments, selecting of sexual partners, or hybridization (Cohan and Hoffmann 1989; Harrington and Rizzo 1999; Grube and Kroken 2000; McGuigan et al. 2005; Pfennig et al. 2007; Mercader et al. 2009; Schoustra et al. 2012; Vigoder et al. 2015; Ament-Velásquez et al. 2020). The third component, at the heart of the biological species concept, is reproductive compatibility within vs. reproductive isolation between species. Ecological features can be considered an extension of phenotype, whereas distribution is independently assessed and may be used to evaluate reproductive isolation, e.g., in cases of sympatry.
In a best-case scenario, as so-called "gold standard", species should be defined through simultaneous assessment of lineages (coherence vs. divergence), phenotype (coherence vs. divergence), and reproductive biology (compatibility vs. isolation), in what we call the Lineage-Phenotype-Reproduction or LPR approach. However, one mostly has to rely on only one or at best two of these approaches. Indeed, species hypotheses can be established from any type of data, but their reliability depends on data quality and quantity. In addition, species can appear phenotypically cryptic or very recently diverged and hence phylogenetically unresolved, because the properties that are used for delimiting species, e.g., reciprocal monophyly or diagnostic phenotypic and ecological traits, may not manifest themselves at the same time or in a regular order (De Queiroz 1998). This also reflects emphasis on different properties among different biological subdisciplines. Ecologists expect to be able to accurately identify species in the field to understand niche differences and so will have difficulties to accept cryptic species. In contrast, phylogenetic properties, such as monophyly, are key for molecular systematists and population geneticists, even if they may not correlate with diagnostic phenotype characters.
Under the unified species concept, in which species represent segments of metapopulation lineages, any diagnostic property can be interpreted as evidence supporting the existence of a species (De Queiroz 2011). However, robustness arguments hold that hypotheses are more likely to be true when they are confirmed by multiple, diverse lines of evidence (Stegenga and Menon 2017). Thus, species hypotheses should be considered more robust with increasing corroboration from appropriately interpreted, independent data sources (i.e., phylogenetics, morphology, anatomy, chemistry, ecology, etc.), and integrating independent data for empirical species delimitation studies should be a major focus of species delimitation research in lichen fungi (Fujita et al. 2012; Lücking 2020; Lücking et al. 2020a). The paradigm of the unified species concept shifts the emphasis from traditional species criteria, focusing on "visual recognizability", towards utilizing operational criteria that incorporate new methods and quantitative data for species delimitation (Tobias et al. 2010; Camargo and Sites 2013). This may create the uncomfortable sentiment that a species is whatever the contemporary methodology determines it to be, rather than relying on the expertise of taxonomist and naturalists most familiar with the group (Raposo et al. 2020).
Recognizing that species are ontologically subjective entities, dictated by multiple ontological natures, taxonomist face the task of identifying and utilizing the most objective criteria for practical solutions to the potentially conflicting ontological nature of species, including lichen fungi (Laurin 2010). Therefore, phenotypic characters apparent to human observers may not consistently diagnose species. Evidence from molecular sequence data provides unprecedented insight into lineage status and is particularly relevant to species delimitation studies when analyzed within a rigorous statistical framework (Grewe et al. 2018). However, with genome-scale data practically every population will be diagnosable given enough resolution power (Zachos et al. 2013; Sukumaran and Knowles 2017; Widhelm et al. 2021), a problem that may also occur with fine-scaled behavioral, ecological and morphological traits. As a consequence, the potential to delimit this "fractal hierarchy of divergences" (Sukumaran and Knowles 2017) may result in infraspecific entities erroneously recognized as species (false positive or type I error, see below), resulting in inflated estimates of species diversity and "taxonomic anarchy" (Garnett and Christidis 2017; Raposo et al. 2020). While these least-inclusive entities may have importance in conservation strategies (Moritz 1994), their invariable recognition as species is taxonomically inaccurate and application of infraspecific categories may be more appropriate (see below). Ultimately, the limit between species (alpha) and infraspecies (gamma) taxonomy can only be determined by empirical or experimental evidence of reproductive compatibility vs. isolation (i.e., the biological component), although phenomena such as hybridization render this approach diffuse and in asexually reproducing lineages it is not readily applicable (Arnold et al. 1999; Schardl and Craven 2003; Wilkins 2009; Ament-Velásquez et al. 2020; Keuler et al. 2020). Indeed, assessment of potential hybridization defies the biological species concept as it may lead to circular reasoning: successful reproduction between two closely related lineages resulting in fertile offspring would imply that they represent a single species, with a proper classification at infraspecies level; however, their interpretation as distinct species, with interspecies hybridization leading to fertile offspring, is equally possible (Taylor 2009; Marchetti and Moyle 2010; Simon 2013). Disentangling such situations is a major challenge in alpha taxonomy, although in practical terms it has only been assessed in detail in few organisms, such as lion/tiger hybrids (ligers, tigons) or the Neanderthals and modern humans (Schillaci and Froehlich 2001; Clarke 2016).
A more immediate problem is that the assessment of reproductive compatibility and isolation is a challenge in fungi including lichen-formers and, as stated above, may not be applicable when lineages reproduce only asexually. Fungal model species, such as Neurospora crassa, have been used to test reproductive compatibility vs. isolation in the delimitation of species (Bistis 1981; Glass and Kuldau 1992; Dettman et al. 2003; Ni et al. 2011). However, this approach is not feasible as a routine component in the alpha taxonomy of fungi, particularly lichen-formers (Culberson et al. 1993; Magain et al. 2017) and has therefore only been employed in a few cases (e.g., Liu et al. 2016). Indeed, the mechanisms of sexual reproduction in lichen fungi are virtually unstudied in most species, although they can be hypothesized by comparison with related Ascomycota or Basidiomycota and their corresponding underlying structures, such as trichogynes, which have been demonstrated in lichen-formers (Henssen and Jahns 1973; Honegger 1984; Ahmadjan 1993; Jahns et al. 1995; Krishnamurthy and Upreti 2001; Keller and Scheidegger 2016). As a whole, the biological species concept in terms of direct testing of reproductive compatibility or isolation therefore has limited used in the alpha taxonomy of lichen fungi, although indirect evidence of past recombination or the lack thereof can be drawn from molecular data and is employed in coalescent approaches (Leavitt et al. 2011a, b, 2015; Wirtz et al. 2012; Onuţ‐Brännström et al. 2017; Boluda et al. 2019). As a consequence, modern alpha taxonomy largely aims at combining phylogenetic and phenotypic evidence in a polyphasic approach or integrative taxonomy (Dayrat 2005; Will et al. 2005; Padial et al. 2010; Crous et al. 2015; Goulding and Dayrat 2016; Lücking 2019; Vinarski 2020; Lücking et al. 2020a), and lichen-forming fungi are no exception.
Until the turn of the twentieth century, species of lichenized fungi were delimited based on phenotype, employing the principles of variational discontinuity, using a deviating phenotype as evidence for lineage separation. A thus defined species would exhibit a certain level of variation but also a variational gap compared to its most similar counterpart. Up to the early twentieth century, the concept of variation was either not well understood or the often sparse material did not allow the proper assessment of variation, which in many cases resulted in the description of the same species many times over. Currently, the proportion of accepted vs. described species-level names in lichen fungi oscillates around 50%, which means that on average, each species has presumably been described twice. However, even if taxa are well-documented, a problem of assessing variation based on phenotype alone is that it may stem from circular reasoning: without an independent criterion to define a group of related individuals, variation is essentially determined ad hoc, by deciding which individuals to include or exclude in a presumed species. One way to address this problem was the introduction of phenetics or numerical taxonomy, which implements quantitative analytical methods and hence unveils variational discontinuities independent of a priori groupings (Sneath and Sokal 1962, 1973; Kendrick and Proctor 1964; Sheard 1978; Park and Hong 1985; Sneath 2005). A main criticism of phenetics has been that it relies on overall similarity (or distance) and not on shared ancestry, but it is precisely the variational discontinuity that provides a first hypothesis on species delimitation, whereas shared ancestry focuses on relationships, not species delimitation. Therefore, methods originally established as part of phenetics, such as multidimensional ordination and statistical group comparisons, continue to be highly useful in integrative taxonomy and should be employed whenever possible (Tobias et al. 2010; Arup and Sandler-Berlin 2011; Zahradníková 2017; Lücking et al. 2020a).
While cladistics offered a new tool to establish classifications (Hennig 1950, 1966), it was initially of little use for the purpose of alpha taxonomy, since diagnostic characters at the species level are often morphometric and these are difficult to analyze in a cladistic context. For instance, three measures X, Y, and Z of the same underlying structure (e.g., thallus thickness) will be interpreted as three separate states of equal weight in a cladistic analysis, although they may represent different distances in character space, e.g., X being closer to Y than to Z. This problem can be remedied by transforming morphometric characters into a series of binary characters, e.g., X → 00, Y → 10, Z → 11, to the extent that similarity in a cladistic context reflects actual similarity. Another problem with cladistics is that a cladogram relates units to each other but does not separate them, i.e., it does not reflect variational discontinuities, unless phenetic distances are expressed through branch lengths by computing a phylogram instead of a cladogram. As stated, the notion that a phenotype-based cladogram or phylogram does not usually reflect actual relationships between taxa, due to the usually high level of homoplasy in phenotype data, is of little importance for alpha taxonomy and therefore not usually a limiting factor in the application of cladistics to phenotype data, because alpha taxonomy addresses the distinctiveness of species, not their underlying relationships. Even so, multivariate analytical tools remain overall superior to cladistic approaches when it comes to the analysis of phenotype data, as they are a better fit to the nature of such data, in particular morphometrics (Marhold 2011).
Molecular phylogenetics has provided an entirely new pathway to classify and delimit organisms, from the highest taxonomic levels down to infraspecies, particularly in Fungi and fungus-like organisms (Hibbett et al. 2007; Printzen 2010; Lumbsch and Leavitt 2011; Lücking et al. 2017a; Tedersoo et al. 2018; James et al. 2020; Li et al. 2021). Compared to phenotype data, molecular phylogenetics has four major advantages: (1) molecular data provide a conceptually independent framework to define clade-based units, as long as the employed markers are not causally correlated with diagnostic phenotype characters; (2) the number of characters that can be employed, i.e., sites in a multiple sequence alignment, exceeds phenotype matrices by one to several orders of magnitude (Table 2), providing far superior statistical power; (3) the proportion of putative homoplasies in DNA sequences is much lower than in phenotype characters, particularly in organisms with simple body plans, such as fungi including lichen-formers (Fig. 4); and (4) DNA sequences allow to implement evolutionary models based on the structure of the DNA and the mechanisms of DNA replication, e.g., by distinguishing between purine (A, G) and pyrimidine bases (C, T). As a consequence, molecular phylogenies are a priori more reliable than phenotype-based cladograms and thus provide a contextual framework within which to interpret phenotypic variation. However, conflicts often arise between molecular phylogenies and previously established phenotype-based taxonomies. In the overwhelming number of cases, these are resolved by assuming phenotypic homoplasy, rearranging the taxonomy in correspondence with the molecular phylogeny (Schmitt et al. 2005a; Crespo and Pérez-Ortega 2009; Parnmen et al. 2010; Lumbsch and Leavitt 2011; Rivas Plata and Lumbsch 2011; Leavitt et al. 2011a, b; Bendiksby and Timdal 2013; Fryday et al. 2017; Lücking et al. 2017c). Instances in which a supported phylogeny may be rejected in favor of a previously established taxonomy are rare and usually explained by problems in the molecular data, including unrecognized paralogs, introgression, unrecognized contaminants or sequence labeling errors, or chimeric data sets (Steinova et al. 2013; Lücking and Nelsen 2018; Vondrák et al. 2018; Llewellyn 2019; Keuler et al. 2020; Lücking et al. 2020b; Wilk et al. 2021), problems discussed in detail at the end of this paper.
With the parallel or combined application of phenotype- (P) and lineage-based (L) approaches, delimitation of species in lichen fungi currently follows two general strategies:
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Initially delimiting potential species based on phenotype, where possible using a quantitative approach. Such "species hypotheses" may subsequently be tested by molecular approaches. This "first P then L" approach is preferred when either molecular methods are not accessible or too resource-intensive or when the material is too old to allow for extraction of suitable DNA. By default, it applies to all names established in the pre-molecular era, although quantitative analytical methods were rarely applied in these cases.
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Initially delimiting potential species based on molecular phylogenies, using a phylogenetic species concept, i.e., a combination of branch support and branch length patterns, or in addition an assessment of coalescence between several markers. This principle is used in quantitative species delimitation methods. The thus delimited lineages are subsequently compared with phenotype features, ideally in a quantitative manner, in a "first L then P" approach.
A priori, neither one of the two approaches is superior to the other; rather, the quality of the outcome depends on the quality and resolution of the data and methods employed. Each approach is useful for establishing species hypotheses, even when using only a single phenotype character or a single marker. However, depending on the complexity of the underlying situation (i.e., the complexity of the "truth"), the P approach alone has a lower probability to be accurate: it may erroneously recognize species that do not represent distinct entities (false positive or type I error), by misinterpreting variational discontinuities or discrete variation, as in the aforementioned cases of photosymbiodemes, or it may erroneously overlooking species that underwent cryptic speciation or in which phenotypic variation is too broadly defined (false negative or type II error), such as in the collective species Cora glabrata and Cetraria aculeata (Lücking et al. 2014, 2017b; Pérez-Ortega et al. 2012; Lutsak et al. 2020). A type I error is much less likely with the L approach alone but may occur in cases of intragenomic variation such as gene duplication or introgression (Lücking et al. 2020a; see below). A type II error is also less likely with molecular data but depends on the markers employed, since the level of resolution differs between markers, as shown by the example (see below) of Usnea aurantiacoatra vs. U. antarctica (Wirtz et al. 2008, 2012; Grewe et al. 2018; Lagostina et al. 2018; Lücking et al. 2020b). The main difference between the P and L approaches, when used without the other, is that with the first, there is a likelihood of erroneously delimiting polyphyletic entities, whereas with the second, tha likelihood is close to zero. A striking example is the macrolichen Sticta fuliginosa. Traditionally delimited based on a set of correlated phenotype characters using a P approach, i.e., broad, sparsely branched lobes with laminal isidia, a pale underside and usually large, somewhat irregular cyphellae (Swinscow and Krog 1988; Brodo et al. 2001; Galloway 2007; Jørgensen and Tønsberg 2007; Smith et al. 2009), this taxon was resolved as highly polyphyletic (Moncada et al. 2014; Magain and Sérusiaux 2015). If the taxonomy of this complex had started by using the L approach, i.e., molecular data, the taxon would never have been established in its traditional sense in the first place.
In both the P and L approach, the inclusion of multiple independent characters increases reliability. In a molecular phylogenetic approach, a single marker already consists of multiple characters (sites), typically higher in number than an entire set of phenotype characters (Table 2). However, the individual sites in a molecular marker are not necessarily functionally independent: while replication errors causing the underlying variation are random and independent for each site, their fixation as alleles depends on their position and the relevance for the function of the gene, such as the three-dimensional structure of the transcribed RNA (e.g., ribosomal DNA) or the structural function of the translated amino acid sequence in a protein or enzyme. Thus, increasing the number of molecular markers distributed across the genome increases the statistical power of the analysis and enables the assessment of potential conflict between markers, which is often at a similar level as conflict between complexes of phenotype characters, e.g., in lichen fungi ascoma vs. thallus characters or morphology vs. chemistry (Culberson 1963, 1973; Santesson 2004; Lücking 2009, 2012; Messuti and Archer 2009; Aptroot and Lücking 2016). While single markers such as the fungal ITS barcoding locus may be sufficient to considerably improve the underlying taxonomy of particular genera, such as in ascolichens of the genus Sticta or basidiolichens of the genera Cora and Sulzbacheromyces (Moncada et al. 2014; Liu et al. 2017; Lücking et al. 2017b; Coca et al. 2018; Ranft et al. 2018), additional markers may either support the topology obtained from a single marker or increase resolution where a single marker such as the ITS is not sufficient. For this purpose, a combination of a small number of functionally and genomically distinct markers, in addition to the ITS also the mitochondrial small subunit (mtSSU), the nuclear large subunit (nuLSU), and one or several protein-coding markers (e.g., MCM7, RPB1, RPB2, TEF1, TUB2), usually provides sufficient resolution to assess species boundaries (e.g., Wirtz et al. 2008, 2012; Pino-Bodas et al. 2010a, b; Leavitt et al. 2011a, b, 2018; Rivas Plata et al. 2013; Frisch et al. 2014; Gerlach et al. 2017, 2019, 2020).
As mentioned above, an intrinsic problem with molecular phylogenies or cladistic approaches is that the resulting topology cannot be automatically translated into taxonomies, since the underlying philosophies, establishing relationships vs. establishing discrete categories, are different (Hibbett and Donoghue 1998; Franz 2005; Assis 2009; Lücking 2019). However, variational discontinuities in phylogenies can be assessed by employing quantitative species recognition methods, which assess branch length patterns within and between clades, such as the Generalized Mixed Yule Coalescent (GMYC) or the Poisson Tree Processes (PTP) approach (Fujisawa and Barraclough 2013; Zhang et al. 2013), and/or assess coalescence between markers, such as Bayesian species delimitation, the Bayesian Phylogenetics and Phylogeography (BPP) approach and the Accurate Species TRee ALgorithm or ASTRAL (Yang and Rannala 2010; Fujita et al. 2012; Mirarab et al. 2014; Yang 2015). These approaches go beyond the underlying phylogeny as they quantitatively delimit discrete, lineage-based entities. If the underlying study group is sampled with multiple individuals per entity, these methods serve to establish molecular and test morphological species hypotheses, although the taxonomic status of these entities depends on considerations such as distribution (see below). If sampling represents single individuals per entity, these methods can also be hijacked to define higher-level taxa (Humphreys and Barraclough, 2014; Barraclough and Humphreys, 2015; Lücking 2019). A problem with multimarker coalescent approaches is that some markers may result in artifactual topologies when representing paralogs, which may be the case with protein-coding markers (Keeling and Inagaki 2004; Hubka and Kolarik 2012; Zhao et al. 2014; Lücking et al. 2020a, b). This should be carefully assessed before translating coalescent-based species trees into formal taxonomies.
The barcoding gap has also been used as an approach to delimit species, including lichen-forming fungi (Del Prado et al. 2011; Puillandre et al. 2012; Xu et al. 2017). It is conceptually related to single-marker quantitative species delimitation such as GMYC, in that it assesses variational discontinuities in branch lengths. However, the difference is that the barcoding gap usually sets a threshold a priori, through pairwise comparison between species, whereas quantitative species delimitation provides an a posteriori assessment without a fixed threshold. Given that fixed thresholds to dot exist between species, but stem branch length depends on the time since divergence (Nilsson et al. 2008; Collins and Cruickshank 2013; Leavitt et al. 2016a; Lücking et al. 2020a), the barcoding gap approach is generally inferior to quantitative species delimitation methods. An additional disadvantage is that it assesses differences between all possible pairs of species, whereas only those between sister species or closely related species are actually relevant. Therefore, the barcoding gap approach should preferable be used in combination with a quantitative species delimitation method, to assess the usefulness of individual markers for subsequent species identification through molecular barcoding (Lücking et al. 2020a).
Whereas testing an existing alpha taxonomy with molecular methods (first P then L approach) provides some sort of integrative taxonomy by default, the advent of molecular methods initially challenged the usefulness of traditional taxonomy, not because of conflicting results but because it was soon believed that DNA sequence data alone could solve everything. It took some time to come to the conclusion that the integration of phenotype characters into molecular phylogenies was crucial to obtain sound and stable alpha taxonomies. As such, the approach of integrative taxonomy (i.e., L and P approach combined), has long been the aim of taxonomists, even if the term "integrative taxonomy" was only rather recently adopted in systematics (Dayrat 2005; Will et al. 2005). Integrative methods for species delimitation fall across a broad spectrum, ranging from verbal and qualitative assessments of data classes to quantitative methods that allow different data types to contribute to statistically assessed species delimitation. Any study linking at least two kinds of data (L, P and/or R) to support species hypotheses, including simple mapping morphological characters onto a molecular phylogeny, can be considered integrative. In practice, these data are not analysed simultaneously in a "total evidence" approach, but rather one kind of data is repeatedly tested with another in a refined manner, in an iterative, hypotheticodeductive framework (Yeates et al. 2011). As the most basic approach, comparing phenotypic characters to phylogenies is useful to identify the least inclusive monophyletic clade in the topology characterized by at least one unambiguously diagnostic phenotypic trait (e.g., Miralles and Vences 2013). In lichen fungi, previously unrecognized species-level clades with corresponding subtle, or overlooked, phenotypic characters have been commonly observed using this approach (e.g., Crespo and Pérez-Ortega 2009; Pino-Bodas et al. 2010a, b; Arup and Sandler-Berlin 2011; Leavitt et al. 2015; Altermann et al. 2016; Lücking et al. 2017c; Frolov et al. 2016; Orange 2018; Kistenich et al. 2019; Frisch et al. 2020).
Besides mapping of previously established taxonomies onto molecular phylogenies, an additional step is the assessment of type material of names to determine their placement in the revised phylogeny and hence the applicable nomenclature. Given that these steps are time consuming and require expertise far different from what is required to generate and analyse sequence data, linking inferences from integrative taxonomic approaches with formal taxonomic changes remains an often postponed task (Vinarski 2020). Molecularly delimited species-level lineages are frequently treated as "putative" or "candidate" species, using working names or alphanumeric clade designations, rather than providing formal descriptions. For instance, the seminal work by Kroken and Taylor (2001) on the genus Letharia, pioneering the multimarker coalescent approach in lichen fungi, established that the two traditionally distinguished taxa, L. columbiana (consistently apotheciate) and L. vulpina (always sorediate, rarely also with apothecia) represent between five and six distinct species. It took 15 years for four of these to be formally recognized, as L. columbiana s.str., L. gracilis, L. lupina, and L. vulpina s.str. (McCune and Altermann 2009; Altermann et al. 2016), while two entities still retain the provisional names L. "barbata" and L. "rugosa". Not rarely, such delays reflect the amount of time and resources necessary to provide an updated taxonomy, especially when large numbers of undescribed species are involved, such as in the genera Cora, Peltigera, and Sticta, where many taxonomically and phylogenetically recognized lineages still await formal description (Moncada 2012; Moncada et al. 2013a, b, 2014, 2015; Lücking et al. 2014, 2017b; Magain et al. 2017; Simon et al. 2018).
Effective approaches for encouraging formal taxonomic proposals with robust integrative species delimitations analyses should remedy this problem, such as "turbo-taxonomy" (Butcher et al. 2012; Riedel et al. 2013; Lücking et al. 2017b). However, "turbo" should not mean fast and sloppy, but instead effective while adhering to quality standards in terms of analyzing and documenting the data (Lendemer 2021; Aime et al. 2021). The study of type material and original literature is nowadays much easier through digital repositories such as JSTOR Global Plants [https://www.jstor.org] or the Biodiversity Heritage Library [https://www.biodiversitylibrary.org]. Taxonomic research using integrative approaches will not only result in a solid foundation for biodiversity and conservation studies but also tends to have higher "impact", including higher citation performance and broader readership, than non-integrative studies, due to the immediate appeal beyond taxonomy (Vinarski 2020). For instance, the recent "turbo-taxonomic" study of Cora, describing 70 new species based on a combination of molecular and phenotype data and with the generation of automated descriptions from a comprehensive data matrix (Lücking et al. 2017b), has been cited nearly 50 times in four years, including in non-taxonomic studies and studies unrelated to this genus. In contrast, an earlier work on the taxonomy of Cora and related genera, including a key to all species known at the time (Lücking et al. 2013), has been cited less than 40 times in eight years, almost exclusively in other taxonomic works. The comprehensive, exemplary inventory of lichens and associated fungi from Glacier Bay National Park, integrating expert field work and taxonomy with molecular assessments in a multi-authored study (Spribille et al. 2020) already generated around 20 citations since its publication last year, translating into a high impact factor. Indeed, the combination of taxonomic and other methodological expertise, reflected in multiple authorship, increases the impact of taxonomic papers (Lücking 2021). Data assembled for the purpose of integrative taxonomy can also be used to elaborate sophisticated studies on the evolution of the lichen symbiosis, as shown by the study on the Trapeliopsis-Placopsis clade by Schneider et al. (2016).
Beyond iterative approaches to species delimitation, other conceptual and methodological perspectives have been important to better understanding species boundaries and promote taxonomy in lichen fungi, e.g., population genetics and phylogenomics (Grewe et al. 2018; Muggia et al. 2020; Werth et al. 2021; Widhelm et al. 2021), phenotype-based phylogenetic binning (Lücking et al. 2015; Perlmutter et al. 2020), ecological modelling (Lendemer et al. 2015; Smith et al. 2016), or conservation assessments (Miądlikowska et al. 2014b; Lücking et al. 2020c). Other modern approaches, including machine learning and process-based approaches, have not yet been used for lichen fungi but hold tantalizing promise. Machine learning methods can accommodate various data types and are ideally suited for species delimitation (Derkarabetian et al. 2019). Processed-based analyses can evaluate demographic models consistent with a variety of modes of speciation, requiring researchers to use their expertise with the focal system to identify a reasonable model (Smith and Carstens 2020). The difference between machine-learning methods and other quantitative approaches, such as coalescence-based multi-marker phylogenies or quantitative character mapping, is that machine learning methods can be trained with well-established species-level taxa, integrating both molecular and phenotype data and even approaches such as distribution modeling. As a result, and depending on the quality and quantity of the training data, these methods provide a more flexible approach tailored to each group and are potentially able to reliably distinguish between species- and population-level lineages, potentially providing a quantitative framework to resolve between alpha and gamma taxonomy. However, this should not be misinterpreted as an approach to fully automate taxonomy, seemingly making taxonomic expertise superfluous. In reality, such methods require explicit predictions driven by familiarity with the target group, accurately identified training taxa, and proper connection of the thus delimited species to the evolutionary processes by which they were formed. One should also not misconceive the idea of taxonomic expertise as an undesired subjective approach to science. Good taxonomists do not just define species ad hoc or memorize large quantities of names; they able to perform effective pattern recognition and filtering of diagnostic characters upon visual inspection of a set of samples, processes for which non-taxonomists need the help of computerized tools.
The species pair concept and dual nomenclature in lichenized fungi
Due to their symbiotic nature, and in contrast to other fungi, lichens have three basic means of reproduction and dispersal: (1) sexually, via meiotic asco- or basidiospores, produced in asco- or basidiomata, usually after fertilization through hyphal fusion or mitotically produced spermatia (usually corresponding to microconidia); (2) asexually via mitotic conidia (usually corresponding to macroconidia), produced in conidiomata of various sorts, including campylidia, hyphophores, and sporodochia; and (3) asexually via structures containing both bionts, such as soredia, isidia, schizidia, and other thallus fragments. In reality, reproduction and dispersal in lichens is arguably much more complex, encompassing a variety of symbiotic and aposymbiotic propagules (Tripp and Lendemer 2018). Although various types of propagules may be produced in the same individual, frequently a lichen thallus exhibits only one reproductive strategy (Fig. 5). As a consequence, individuals may be identical in overall morphology except their means of reproduction and dispersal. Given that alpha taxonomy in lichens was initially based on external morphology, the different means of reproduction and dispersal were interpreted as taxonomically important characters and therefore the specimens displaying such differences assigned to different species. Notably, the potentially close relationship of these morphs was not recognized until early into the twentieth century (Du Rietz 1924). For instance, when establishing Physcia obscurata (now Heterodermia obscurata), Nylander (1863) compared it with P. speciosa (now Heterodermia speciosa), on account of the lip-shaped soralia, but not with Parmelia flabellata (now H. flabellata), its apotheciate counterpart (Fig. 5a–b).
Du Rietz (1924) was the first to establish the hypothesis that phenotypically identical morphs of lichens differing only in their reproductive mode are closely related, and he introduced the concept of so-called "species pairs" for these. Only much later, Poelt (1970, 1972a, b), formalized the species pair concept, calling the apotheciate morphs "primary species" and the asexually reproducing (usually sorediate) morphs "secondary species". Poelt thereby postulated that sexually reproducing morphs must be ancestral to those reproducing asexually, via an "unstable" (i.e., polymorphic) intermediate morphs that produces both ascomata and asexual propagules. Poelt (1970) considered such intermediate morphs rare, but species producing both functional ascomata and asexual propagules on the same thallus are actually quite frequent (Fig. 6). It is thus implied in Poelt's hypothesis that even extant species may represent polymorphic assemblies, depending on their evolutionary history and age. It also means that such polymorphic lineages, not the purely sexually reproducing lineages, are direct ancestors of "species pairs", applying the concept of ancestral polymorphism (Guerrero and Hahn 2017) to the phenotype (Wheeler and Platnik 2000).
Poelt (1970) claimed that species pairs only occur in lineages producing apothecia (i.e., ascomata with exposed discs), typically associated with sorediate (rarely isidiate) counterparts. Indeed, species pairs are rare in lichenized lineages with perithecioid ascomata, simply because soredia or isidia are rare in these groups. However, species pairs have been established in these cases as well, such as Porina imitatrix vs. P. distans, P. mirabilis vs. Phyllophiale alba (Fig. 5c–d), and P. fusca vs. Ph. fusca (Lücking 1991, 2008; Vězda 1994). Poelt (1970) further observed that, when apothecia are present in otherwise sorediate morphs, these are usually depauperate and non-functional. Again, this seems to depend on individual cases.
In his assessment, Poelt (1970) provided a list of 31 examples of presumed "species pairs", explicitly excluding large genera such as Heterodermia, Ramalina, Roccella, and Usnea, where he implied the existence of many additional cases. According to Poelt (1970, 1972a), species pairs should be considered separate taxa, under the assumption that the morph representing the secondary species only evolved once, leaving the primary species as paraphyletic residual. This was challenged by Tehler (1982), who postulated that morphs with asexual reproduction may have evolved multiple times within a lineage and so the entire complex could to be considered a single species with variable modes of reproduction.
Besides empirical data, there are several conceptual challenges to the "species pair" concept. The most obvious is that in many cases, there are two or more "secondary species", one producing soredia and the other isidia or other asexual propagules (e.g., phyllidia). Prominent examples include Coccocarpia erythroxyli (apotheciate) vs. C. palmicola (isidiate) vs. C. pellita (phyllidiate; Arvidsson 1982); Heterodermia flabellata (apotheciate) vs. H. obscurata (sorediate) vs. H. crocea (isidiate) vs. H. flavosquamosa (phyllidiate; Harris 1990); Pannaria rubiginosa (apotheciate) vs. P. conoplea (phyllidiate-sorediate) vs. P. tavaresii (isidiate; Jørgensen 2000); and the striking case of Hypotrachyna physcioides (apotheciate) vs. H. laevigata (sorediate) vs. H. imbricatula (isidiate) vs. H. steyermarkii (isidiate with cilia) vs. H. spinulosa (spinulose; Sipman et al. 2012). Since it is difficult to conceive that isidiate morphs evolved from sorediate ancestors or viceversa, one would theoretically have to expand the concept to postulate a polymorphic ancestor producing ascomata, soredia, and isidia simultaneously. However, the simultaneous production of two such distinct types of asexual propagules would make little sense from an evolutionary viewpoint and is rarely observed in nature, except in cases where species produce some sort of intermediate propagules, such as broadly isidiate clusters or pustules that break up into soredia or soredia growing into isidia or phyllidia, such as in the Pseudocyphellaria crocata complex (Lücking et al. 2017c). Therefore, the existence of both sorediate and isidiate counterparts of fertile morphs indicates that the evolutionary history of these morphs is more complicated than implied by a simplified species pair concept, perhaps better reflected by ancestral polymorphism in reproductive strategies in these lineages.
Another problem is that the "species pair" concept is only diffusely separated from the comparison of sexual and asexual (i.e., conidia-forming) or asexual and asexually reproducing morphs (e.g., Sundin and Tehler 1996). For instance, the putative species pair Umbilicaria antarctica and U. kappenii differs in the production of asexual thalloconidia vs. soredia or thallus fragments (Ott et al. 2004). The differential taxonomic and nomenclatural treatment of sexual and asexual morphs is well documented in non-lichenized fungi, under the now obsolete concept of "dual nomenclature" (see above). Under this concept, different names could be given to different morphs of the same species, with either sexual or one or more asexually reproducing morphs, which were then placed in separate genera. The name with priority was the one covering the sexual morph, with the exception of lichenized fungi in which priority applied irrespective of the morph. There are indeed numerous instances where lichenized morphs producing conidiomata were named differently from their counterparts producing ascomata, even when the connection was known. Thus, the name Ceratopycnidium citricola corresponds to the campyliiform (hooded) pycnidia of Byssoloma citricola, the name Pycnociliospora belluciae to the pycnidia of Strigula antillarum (Lücking et al. 1998, 2002), and the name Phyllophiale fusca to the disc-shaped isidia of Porina fusca (Lücking 1991). The conceptual difference between the "species pair" concept and "dual nomenclature" is that asexual (i.e., conidial) and sexual (e.g., ascoma-bearing) morphs were assumed to belong to the same species but assigned to separate (form-)genera, whereas "species pairs" were presumed to represent closely related, yet separate species in the same genus. However, the underlying biological mechanisms are not really different, since all three morphs (sexual, asexual via conidia, asexual via symbiotic thallus fragments) are means of reproduction and dispersal. Examples where the two concepts are intertwined include the apotheciate, sorediate, and pycnidiate morphs of Dirina massiliensis the sorediate morph called D. stenhammarii and the pycnidiate morph D. massiliensis f. aponina (Tehler et al. 2013).
A further challenge to the "species pair" concept is the level of actual similarity between morphs exhibiting different modes of reproduction. Theoretically, the species pair concept strictly applies only to cases where the underlying phenotype is otherwise identical. This is, however, often not the case. For instance, specimens of Heterodermia flabellata (apotheciate) typically differ in lobe configuration from those of H. obscurata (sorediate; Fig. 5a–b). Printzen (2014) argued that apotheciate vs. sorediate species of Biatora usually also differ in other characters and Lohtander et al. (1998) reported minor morphological differences between the apotheciate Dendrographa leucophaea and the sterile D. minor (now D. leucophaea f. minor). More obvious cases include Teloschistes exilis (apotheciate) vs. T. flavicans (sorediate), T. exilis typically forming smaller, more delicate and less brightly pigmented thalli (Almborn 1989, 1992). In addition to morphology, differences in ecology and distribution are often found between putative species pairs. Du Rietz (1924) already noted differences in distribution between Evernia esorediosa (apotheciate) and E. mesomorpha (sorediate), and Poelt (1970) elaborated on this phenomenon in detail. However, mere differences in the extension of distribution ranges cannot support the distinction of reproductive modes at the species level, as they may be a direct consequence of the latter, resulting in circular reasoning. In contrast, ecological differences, when present, are more striking. Thus, Physcia aipolia (apotheciate) typically grows on bark, whereas P. caesia (sorediate) is mostly found on rock, including human-made substrata (Myllys et al. 2001). This difference can neither be a cause nor a consequence of the mode of reproduction, as there is no reason why thalli derived from ascospores should only colonize bark and those originating from soredia only rock. Guttová et al. (2014) also reported subtle substrate differences for Solenopsora olivacea subsp. olivacea (apotheciate) vs. subsp. olviensis (sorediate), although in that case, the observed differences (shaded to open rock faces vs. shaded rock faces or crevices) may well be a trigger to switch the mode of dispersal.
A frequent misconception of asexually reproducing lichens is that these represent genetically identical clones or at least should have much lower genetic variation that sexually reproducing lineages (Poelt 1970; Tehler 1982; Huovinen 1985; Hammer 1997). It is thereby overlooked that the positional genetic variation used to reconstruct phylogenies and assess sequence variation consists of positional variation of presumably homologous nucleotides. This variation is caused by errors in DNA replication, which occurs during mitosis, and so affects cell divisions likewise. Thus, point variation in aligned sequences representing asexually reproducing individuals should not differ much from that of sexually reproducing individuals, which has been confirmed by empirical data (Mattson and Lumbsch 1989; Kroken and Taylor 2001; Buschbom and Mueller 2006; Nelsen and Gargas 2009; Altermann et al. 2016; Del Prado et al. 2016; Bellinchón et al. 2018). A major difference in sexual reproduction is mechanisms such as recombination, which does not result in point mutations but may be detected through coalescence-based methods when topologies between different markers affected by recombination are incongruent. Since asexually reproducing lineages can diverge in the same way as sexually reproducing lineages, by accumulating point mutations, these lineages do not represent evolutionary dead ends, as sometimes suggested (Poelt 1970; Tehler 1982; Tripp 2016).
Poelt (1970, p. 187) noted: "Flechten vermehren sich im allgemeinen, soweit überhaupt bei einer Gruppe neben der sicher ursprünglichen generativen auch vegetative Fortpflanzung vorkommt, nicht auf beide Weisen nebeneinander oder nacheinander im Leben eines Individuums, sondern in allen Individuen einer Sippe entweder generativ oder vegetativ." This is a central issue in the "species pair" concept that has been perpetuated in evolutionary considerations of sexual vs. asexual lineages, with the consequence that an apparent switch between sexually and asexually reproducing individuals or lineages in phylogenies has been interpreted as repeated loss and gain of either form of reproduction (Tehler et al. 2009; Tripp 2016). However, it is not actually possible to "regain" sexual reproduction; rather, one has to assume that the possibility to produce viable ascomata is generally present in the genome but that certain triggers determine their actual formation. Ascomycota produce ascomata typically after fertilization; if fertilization does not happen, an individual may switsch to an alternative mode of reproduction, similar to selfing in plants in the absence of pollination (Kalisz and Vogler 2003; Moeller 2006). An analogous strategy may apply to lichen fungi. As mentioned above, trichogynes have been repeatedly documented in lichen thalli. Population structure, not environmental conditions, would then be assumed to trigger the production of ascomata as a developmental switch. Heterothallism is widespread in lichen fungi, although homothallism occurs as well (Murtagh et al. 2000; Honegger et al. 2004; Seymour et al. 2005; Ludwig et al. 2017; Pizarro et al. 2019). Facultative homothallism in the absence of fertilization, so-called pseudo-homothallism (Grognet and Silar 2015), has been assumed to occur in some cases (Murtagh et al. 2000), but it is unclear whether absence of fertilization could alternatively cause a switch to asexual reproduction. Given that mixed populations are more likely to occur under favorable conditions (e.g., Walser et al. 2004), one would then predict that asexually reproducing thalli are more frequent under less favorable conditions. The ability of sexually reproducing thalli producing soredia and vice versa was experimentally shown in Knightiella splachnirima (Ludwig 2011, 2015; Molina et al. 2013). If this assumption is correct, the reconstruction of "ancestral reproduction modes" in a phylogenetic tree is actually misleading, since the reproductive mode observed in a terminal (individual) is just a snapshot of its actual condition, but does not reflect its genetic potential. This would affect studies like that of Buschbom and Mueller (2006), who entertained various hypothesis to explain complex patterns of sexually and asexually reproducing individuals in the putative species pair Porpidia flavocoerulescens (now P. flavicunda) (apotheciate) and P. melinodes (sorediate) and postulated a selective sweep in a single species with complex phylogeny.
Overall, the advent of molecular phylogeny has permitted the testing of the species pair concept in numerous examples (Table 3). While putative species pairs have been explicitly examined in various studies, an increasing amount of molecular data is becoming available for many more instances, although these data, in particular the fungal ITS barcoding marker, are rarely analyzed in a context revealing the underlying patterns for presumed species pairs (e.g., Stenroos et al. 2019: Cladonia; Lücking et al. 2020b: Usnea). For instance, the available ITS data (Carlsen et al. 2012; Ekman et al. 2014; Marthinsen et al. 2019) for the species pair Fuscopannaria protensa (apotheciate) vs. F. ahlneri (sorediate) (Jørgensen 2000) suggest that two distinct lineages are involved, one apotheciate-sorediate and the other sorediate only. However, no phylogenetic analysis seems to have included these data simultaneously: the study by Carlsen et al. (2012) reported two specimens which correspond to the sorediate lineage, whereas the work by Ekman et al. (2014) includes two other samples, representing the apotheciate-sorediate lineage, giving the impression that apotheciate and sorediate morphs in this species pair are genetically uniform.
While species pairs were first analyzed prior to the turn of the millenium (Lohtander et al. 1998), the work by Kroken and Taylor (2001) on Letharia columbiana (apotheciate and usually with isidia) vs. L. vulpina (sorediate and rarely with few apothecia) can be considered a model study, as it employed a multimarker coalescence approach, demonstrating that putative species pairs may neither represent two distinct taxa nor a single, variable species, but a complex of multiple lineages not strictly correlated with mode of reproduction. Combining ITS and nuSSU data and up to ten anonymous protein-coding markers, the authors distinguished up to six entities. The sorediate L. vulpina was thereby split into two species, L. vulpina s.str. and the subsequently validated L. lupina (Altermann et al. 2016). The primarily apotheciate L. columbiana was divided into four entities: L. gracilis (McCune and Altermann 2009), L. "barbata", L. "lucida", and L. "rugosa", all except L. "lucida" producing isidia in addition to apothecia. Kroken and Taylor (2001) did not associate already available names with these latter entities, as it was unclear at the time which would correspond to L. columbiana s.str. or to its synonym, L. californica. Altermann et al. (2016) subsequently associated L. columbiana s.str. with the L. "lucida" clade. The apotheciate L. "rugosa", on the other hand, formed a paraphyletic grade relative to L. vulpina s.str., offering the possibility to recognize a single species, L. vulpina, producing either sexually or asexually. The resulting six (or five) entities were supported by subtle morphological and chemical characters, as well as distribution, with L. vulpina s.str. being the only species also widespread in Europe (Kroken and Taylor 2001).
Molecular studies on numerous putative species pairs suggest that multiple (semi-)cryptic speciation, as exemplified by the genus Letharia, is the rule rather than the exception: in over 60 examples analyzed, nearly two third (61%) appear to be species complexes, consisting of various lineages reproducing either sexually, asexually, or both (Table 3). Besides Letharia, the best documented case among these is Usnea florida vs. U. subfloridana (Articus et al. 2002; Mark et al. 2016; Degtjarenko et al. 2020; Lücking et al. 2020b). In only 11 cases (18%), the separation of an apotheciate and a sorediate or isidiate species was supported, although there were mostly few available data. Among the most convincing cases are Hypogymnia lophyrea vs. H. hultenii and H. minilobata vs. H. mollis (Miądlikowska et al. 2011). Nine cases (15%) exhibit genetic uniformity relative to the studied markers or did not show structured resolution, but the available data in these cases were often limited, e.g., in Evernia esorediosa vs. E. mesomorpha (Miądlikowska et al. 2014a). Considering examples such as Fuscopannaria protensa vs. F. ahlneri, Pectenia plumbea vs. P. atlantica, and the Roccella belangeriana vs. R. montagnei species pair (Prashanth et al. 2008; Tehler et al. 2010; Carlsen et al. 2012; Otálora et al. 2013; Ekman et al. 2014; Marthinsen et al. 2019), we predict that in cases were limited molecular data initially indicate conspecifity or would support the species pair concept, additional data will in most cases reveal more complex patterns. In ten cases (16%), the putative species pairs were, at least in part, not directly related and in one case, Caloplaca aurantiaca (= Blastenia ferruginea) vs. C. chrysophthalma (≡ Solitaria chrysophthalma), even ended up in different genera (Arup et al. 2013; Vondrák et al. 2020).
Even with the availability of molecular data to test species pairs, two challenges arise. One is the selection of markers. While the ITS has been chosen as the standard barcoding marker for fungi (Schoch et al. 2012), employed in almost all studies including presumed species pairs (Table 3), it may present limited resolution when lineages diverged recently (Lücking et al. 2020a). A striking case is the putative species pair Usnea aurantiacoatra (apotheciate) vs. U. antarctica (sorediate). Being the most frequently sequenced species pair in Usnea, with over 250 accessions, the ITS and the RPB1 markers are remarkably uniform in this case, suggesting a single species (Wirtz et al. 2008, 2012; Lücking et al. 2020b). However, both RADseq and microsatellite markers support the presence of two lineages (Grewe et al. 2018; Lagostina et al. 2018). In the case of Usnea florida vs. U. subfloridana, on the other hand, microsatellite markers did not clearly resolve the two morphs (Degtjarenko et al. 2020). The other challenge is the application of formal taxonomic classifications to phylogenetically defined lineages. One case is Dirina massiliensis, which exhibits phylogenetic structure, but a rather broad concept was applied to this case, subsuming the various apotheciate and/or sorediate lineages within a single species (Tehler et al. 2013). These different approaches are conflicting, as it seems unlikely that in one case, a single species can diverge strongly in the ITS and other markes, whereas in another case, a species pair with almost no variation in the ITS is recognized as separate species based on highly resolving markers such as RADseq and microsatellites.
The diverse patterns detected in putative species pairs show that there is no consistent pattern, and each case has to be considered individually (Mattson and Lumbsch 1989). Tehler et al. (2009) therefore suggested that the species pair concept should be abandoned. Molecular data largely support this view. However, where conclusive data are not available, species pairs should continue to be recognized as separate taxa.
Cryptic speciation and the taxonomic value of phenotype characters
Traditional taxonomy assumes that taxa should differ in phenotype. However, there is no law in nature that would require phylogenetically diverging sister taxa to also diverge in phenotype by default. Rather, phenotypic similarity within a species is caused by coherence, so one would assume that the absence of coherence should lead to phenotypic divergence. Ultimately, this is the case, but phenotypic divergence may be delayed relative to phylogenetic divergence, which may then lead to cryptic speciation, for a variety of reasons. For one, species may have diverged too recently to have also diverged in phenotype. On the other hand, there might be selective forces at work relative to a particular phenotype, thus preventing phenotypes from diverging. Finally, fungi including lichen-formers exhibit simple body plans which may offer little evidence for phenotypic divergence except for difficult to perceive ultrastructural or physiological features (Lumbsch and Leavitt 2011; Schneider et al. 2016; Lücking 2019). Indeed, cryptic speciation is a matter of perception, and often there are subtle (or simply overlooked) characters that eventually separate phylogenetically distinct lineages (Molina et al. 2011; Nuñez-Zapata et al. 2011; Frolov et al. 2016; Santos et al. 2019). Sometimes, such characters may be difficult to discern or are only unveiled as statistically supported differences in morphometrics, not useful in the field or in keys (Altermann et al. 2014, 2016; Schneider et al. 2016; Zahradníková et al. 2018; Zakeri et al. 2019). For such cases, "near-cryptic" may be a better term. In contrast, Vondrák et al. (2009) redefined the term "semi-cryptic", previously employed in plant- and algal-taxonomic papers in the sense of near-cryptic, for species that cannot be distinguished by their phenotype but through their distribution and/or ecology (e.g., Lendemer 2011; Hodkinson and Lendemer 2011; Cornejo and Scheidegger 2015).
Cryptic or near-cryptic (including semi-cryptic) speciation is rather well-documented in lichen fungi (Table 4), with an increasing number of examples, particularly in the Parmeliaceae (Feuerer and Thell 2002; Molina et al. 2004, 2011; Argüello et al. 2007; Hodkinson and Lendemer 2011; Altermann et al. 2016; Leavitt et al. 2016b; Haugan and Timdal 2019; Boluda et al. 2019; Corsie et al. 2019; Crespo et al. 2020), but also in other families, such as Graphidaceae (Kraichak et al. 2015; Zhao et al. 2017), Icmadophilaceae (Onuţ‐Brännström et al. 2017, 2018; Jørgensen 2019), Lepidostromataceae (Coca et al. 2018), Peltigeraceae (now including Lobariaceae; Lendemer and O'Brien 2011; Miądlikowska et al. 2014b; Cornejo and Scheidegger 2015), Stereocaulaceae (Lendemer 2011), Trapeliaceae (Resl et al. 2015; Orange 2018), and such unique forms such as the lichenized hypomycete Dictyocatenulata alba (An et al. 2012), although often not reflected in formalized revised taxonomies.
An important argument against the acceptance of phenotypically (near-)cryptic species, identifiable through molecular markers only, is the requirement for advanced technical equipment for their identification and the difficulty to reliable identify such species in the field. While this argument is understandable, it could be logically extended to any technical tool. Thus, one could reject the validity of secondary chemistry because thin-layer chromatography is not accessible, or one could even challenge the need of a microscope to discern anatomical characters such as ascospores. Particularly in crustose lichens, e.g., in the highly diverse families Graphidaceae, Pyrenulaceae, and Trypetheliaceae, species can often only be identified through their ascospores, besides other anatomical characters that cannot be assessed without a microscope, such as hymenial inspersion (Lücking 2009; Lücking et al. 2009a, b, c; Aptroot 2012; Aptroot and Lücking 2016). So-called sporomorphs (Wirth and Hale 1978; Lücking 2009), i.e., species with identical external morphology and even anatomy but differing in ascospore septation and size, are common (Fig. 7). Indeed, whenever technical advancements were introduced historically, there was some initial opposition against their broad application (Ainsworth 1976). We therefore anticipate that the current reluctance against the acceptance of phenotypically cryptic species will diminish, especially as molecular tools become more easily available. Having said that, cryptic species should be well-documented phylogenetically, to exclude the possibility of type I errors. The other issue, elaborated in detail below, is the assessment whether phylogenetically distinct lineages are always to be recognized at species level or whether the application of infraspecific ranks is preferrable in an evolutionary framework in certain cases.
Throughout history, alpha taxonomy has faced challenges due to misunderstood variation of characters and conflict between character complexes in the delimitation of species. Prior to the advent of molecular phylogenetic approaches, variation and conflict have been addressed through ad hoc solutions, involving circular reasoning and subjectively defined taxa. Almost two centuries ago, Watson (1843) labeled thus defined species "book species", a concept taken up in McCabe's (2021) Descent and Logic in Biosystematics. Essentially, there is no difference between book species and the modern term "species hypothesis", other than the framework to establish species hypotheses having greatly improved over time. McCabe's (2021) rationale for the term "Linneon" also essentially corresponds to our current understanding of species hypothesis, although in its original sense, Lotsy (1916, 1925) defined Linneon as morphologically defined species complexes likely to contain a number of distinct lineages, i.e., cryptic speciation. In our LPR approach (see above), a Linneon in a modern sense would correspond to a species hypothesis based on phenotype characters, although McCabe (2021) extends this concept to species defined by DNA characters.
The assessment of the taxonomic value of characters is closely tied to technological advances in biodiversity research. While early fungal taxonomy was characterized by evaluation of external morphologies, four major advances shaped further developments in this field until today (Ainsworth 1976; Jørgensen 2017): (1) the use of the microscope to assess anatomical characters, in particular ascospores but later on also ultrastructure (Körber 1853; Roux et al. 1986); (2) the assessment of the ontogeny as a taxonomically important character (Letrouit-Galinou 1968; Henssen and Jahns 1973; Eriksson 1982; Honegger 1993; Letrouit-Galinou et al. 1994; Döring and Lumbsch 1998); (3) the study of secondary chemical compounds eventually using chromatographic methods (Zopf 1903; Culberson and Kristinsson 1970; Huneck and Yoshimura 1996); and (4) the advent of molecular phylogeny.
Perhaps the best-documented example for conflicting taxonomies arising from new technological approaches is the application of chemotaxonomy (Duvigneaud 1939; Lamb 1951; Culberson 1960, 1969, 1970; Hale 1955, 1968; Krog 1969; Hawksworth 1976; Brodo 1986; Rogers 1989; Lumbsch 1998). While secondary chemistry has long been accepted as an important tool in taxonomy, forms only differing in their chemical compounds but agreeing in morphology, so-called chemomorphs, were often not accepted at species level, unless the differences were considered substantial. For instance, the presence or absence of pigments or certain cortical substances, such as atranorin and usnic acid, have usually been considered of higher value than differences in medullary chemistry or the presence or absence of lichexanthone (Culberson 1970; Tehler 1983, 1993; Harris 1995). Thus, Parmeliopsis ambigua (cortical usnic acid and atranorin) and P. hyperopta (cortical atranorin only) have mostly been considered distinct species, a concept confirmed by molecular evidence (Tehler and Kallersjö 2001). Harris (1995) accepted the presence of lichexanthone as a characteristic feature at species level for many taxa, including Caliciaceae (Pyxine), Graphidaceae, Parmeliaceae, Pertusariaceae, and Pyrenulaceae, but suggested to abandon lichexanthone as a taxonomic character in Trypetheliaceae, e.g., in the genera Astrothelium sensu lato (A. variolosum aggr.), Polymeridium, and Trypethelium sensu lato, and perhaps also in Monoblastiaceae (Anisomeridium). In most cases, this was based on the absence of other correlated characters.
A priori, there appears to be no reason for considering discrete chemomorphs as species in some cases and infraspecific variation in others, and independent evidence is required to assess each case individually or derive general patterns where these exist (Robinson 1975; Lumbsch 1998). However, even this can be misleading. Thus, quantitative analysis of the morphology, chemistry, distribution, and ecology, of variants in the Ramalina siliquosa complex led to the distinction of a variable number of taxa (Culberson and Culberson 1967; Culberson 1969; Sheard 1978; Culberson et al. 1993). In contrast, molecular phylogenetic analysis revealed only two species-level lineages, each with variable chemistry (LaGreca et al. 2020). In the genus Thamnolia (see below), the different chemotypes were usually considered to represent species, whereas discrete morphodemes, e.g., hollow vs. solid thalli, were treated as subspecies (Culberson 1973; Santesson 2004). Molecular phylogeny rejected either as useful taxonomic characters, some lineages being morphologically and chemically uniform and others variable (see below). Molecular phylogeny of the Parmotrema perforatum group, in which species have traditionally been separated by medullary chemistry and reproductive mode (Culberson 1973; Culberson and Culberson 1973), revealed a complex picture: one lineage (P. subrigidum/P. louisianae) chemically and genetically uniform, one lineage (P. perforatum/P. hypotropum s.str.) chemically uniform but divided into two sublineages not corresponding to the two species, and one lineage (P. preperforatum/P. hypoleucinum) chemically variable (including samples with P. hypotropum chemistry) and genetically complex (Widhelm et al. 2016), with a correlation between chemotypes and ecology (Lendemer et al. 2015). In some cases, differences in chemical compounds have been used to support the separation of morphologically cryptic species, such as in Parmelia mayi vs. P. saxatilis (Molina et al. 2011). In the Trypetheliaceae, chemically and morphologically distinct forms that have been proposed to be lumped into a single, highly variable species, A. variolosum (Harris 1995), are not only phylogenetically distinct but also contain multiple, often unrelated lineages (Fig. 8; Lücking et al. 2016).
In contrast to discrete chemomorphs, so-called sporomorphs, morphologically identical species that differ in ascospore type (e.g., transversely septate vs. muriform ascospores), have generally been accepted as separate species. These cases are particularly common in crustose lichens, e.g., the families Gomphillaceae, Graphidaceae (Fig. 7), Porinaceae, Pyrenulaceae, and Trypetheliaceae (Wirth and Hale 1978; Lücking 2009; Aptroot 2012; Aptroot and Lücking 2016). Another type of chemical variation is that of so-called inspersomorphs, in which species with the same morphology and ascospore type differ only in the presence or absence of hymenial inspersion with oil droplets, a phenomenon also common in Graphidaceae and Trypetheliaceae (Lücking 2009; Aptroot and Lücking 2016). A unique form of discrete morphological differences are single vs. compound ascomata in perithecioid taxa of the families Pyrenulaceae and Trypetheliaceae (Harris 1995; Aptroot 2012; Aptroot and Lücking 2016). Whereas Harris (1995) suggested to lump these into a single species in some cases, e.g., in the Astrothelium variolosum complex, molecular data suggest that these forms represent not only discrete entities but may not even be closely related (Fig. 8; Lücking et al. 2016).
Historically, thallus morphology was less scrutinized than other character complexes, such as ascospores or secondary chemistry, in relation to its taxonomic value, likely because it is more difficult to quantify and assess in an objective manner. Thus, while in the early period of lichen taxonomy, minor differences in thallus characters often led to the establishment of new species or infraspecific taxa, especially during the second half of the twentieth century, differences in thallus characters were usually ascribed to variation induced by habitat or other factors, even if the variation was discrete (Anderson and Rudolph 1956; Wirth and Hale 1978; Larcher and Vareschi 1988). This approach was based on circular reasoning, because the assessment of variation was affected by the underlying decision of assigning individuals to a particular species, based on the same characters used to assess their variation. Molecular data now show that such broadly defined taxa are often composed of several to numerous, even unrelated lineages, demonstrating that thallus variation is much more limited than previously assumed (Moncada et al. 2014; Lücking et al. 2017b, c). As a consequence, even in the absence of molecular data, species are now much more narrowly defined (Lücking 2014). On the other hand, molecular data have also shown that previously separated taxa may indeed represent discrete variation of a single species (Fryday et al. 2017; Boluda et al. 2019; LaGreca et al. 2020).
Species versus infraspecific ranks
As mentioned above, taxonomy can be divided into three levels: alpha taxonomy, the delimitation and recognition of species, beta taxonomy, which refers to higher taxa, and gamma taxonomy, which deals with infraspecific levels (Mayr 1968; Winston 1999; Disney 2000; Tahseen 2014). Lichenologists and other mycologists have made ample use of gamma taxonomy, particularly in historical times (Fig. 9a). Compared to nearly 370,000 fungal species names established between 1753 and 2020, over 61,000 infraspecific names were established during the same time period, resulting in a ratio of about 6:1. Of these, over 29,000 (nearly half) correspond to lichen-formers, although overall, species names of lichen-formers make less than 10% of all fungal species names (see above). Thus, infraspecific names established for lichenized fungi are strongly overrepresented compared to all fungi.
In absolute numbers, the introduction of infraspecific fungal names (including lichen-formers) peaked between 1860 and 1940 (Fig. 9a), during which more than half of all infraspecific names were established. The relative proportion of lichen-formers among these thereby oscillated between less than 10% and over 80%, with the lowest proportions in the past two decades and in the two decades leading up to 1800 and the highest in the decade up to 1770 and again between 1840 and 1870 (Fig. 9b). Relative to overall species-level names, the highest proportion of infraspecific names in fungi was published between 1800 and 1870, whereas in lichens, three peaks occurred between 1800 and 1820, between 1830 and 1850, and between 1900 and 1910 (Fig. 9c). Overall, the proportion of infraspecific taxa relative to species never exceeded 50% in all fungi, but during the peak periods, newly established infraspecific names were approximately twice the number of species names in lichenized fungi. These three peaks fell in the Acharius period (1801–1820), the Montagne period (1831–1850), and the Zahlbruckner period (1901–1910). During these periods, most of the infraspecific names were established by A. B. Boistel (953), in his Nouvelle Flore des Lichens (Boistel 1903), E. Acharius (818), and L. E. Schaerer (659), but a considerably number also by J.-B. Lamarck (470), largely in Encyclopédie Méthodique Botanique (Lamarck and Poiret 1813), J. von Flotow (302), H. Olivier (298), E. Fries (275), K. F. W. Wallroth (242), E. A. Vainio (221), G. L. Rabenhorst (206), J. Harmand (185), M. Bouly de Lesdain (134), A. Zahlbruckner (129), and G. Torssell (122), in his Enumeratio Lichenum et Byssacearum Scandinaviae (Torssell 1843).
In the past three decades, which mark the period of molecular taxonomy and systematics, the absolute number and particularly the relative proportion of new infraspecific names has dropped substantially, to distinctly under 10% up to 2010 and under 5% up to 2020, comparing to post-Linnean levels leading up to 1800. This indicates a dramatic shift in the theoretical concept and practical application of infraspecific names, likely a consequence of much improved insight into the phylogenetic structure of presumed infraspecific variation and its taxonomic value.
The use of infraspecific names (gamma taxonomy) has been highly inconsistent throughout history, but has largely followed two main concepts (Du Rietz 1930; Davis and Heywood 1963; Hawksworth 1974; Hamilton and Reichard 1992; McDade 1995; Lücking 2008). The evolutionary concept assigns intraspecific names to diverging lineages within a species that are considered to be reproductively compatible but exhibit some sort of non-biological reproductive isolation, which can be either geographical (allopatric or peripatric) or ecological, e.g., through seasonal or diurnal differentiation of sexual reproductive structures (sympatric). In contrast, the typological concept assigns infraspecific names to phenotypic variation that is deemed worthy of taxonomic recognition but not sufficient to distinguish species. The recognition of taxa at any rank should have some biological or evolutionary meaning, but the typological concept rarely takes the principle of reproductive isolation into account and hence generally violates modern taxonomic principles. Because of these issues, some workers have dismissed the use of infraspecific taxa, also because the species rank values more in the non-scientific communication with stakeholders in policies regarding biodiversity and conservation (O'Brien and Mayr 1991; De Queiroz 2007; Patten 2015). Moritz (1994) brought to attention the concept of Evolutionary Significant Units (ESUs), but implicitly equated these to species rather than infraspecies.
Notably, in addition to his pioneering work on species pairs, nearly a century ago Du Rietz (1930) also published a seminal account on the nature of taxonomic units, discussing in detail the principal infraspecific ranks offered by the Code (form, variety, subspecies) and their inconsistent application in the taxonomy of lichen-formers and other organisms, especially regarding the rank forma. He defined the latter rank as corresponding to discrete morphological variation unrelated to distribution, population structure, or lineage descent, thus essentially of polyphyletic origin. In contrast, the rank variety and subspecies applied to natural entities with differing degree of range extension (local vs. regional). While these definitions seem straightforward and partially agree with what is being set forth below, Du Rietz (1930) noted that, particularly in botanical (including mycological) nomenclature, the corresponding ranks had rarely been applied following this concept. This is especially true of the ranks variety and form, as applied in the 19th and early twentieth century, but also including more recent cases; for instance, Thamnolia taurica has been variably recognized at the rank of species, subspecies, variety, and form (see below). There also appears to have been a temporal change in concept, particularly when using variety vs. subspecies. Thus, in lichen fungi, the rank subspecies was not only much less popular than variety (606 vs. 16,811 instances), but also less frequently used in the 19th compared to the 20th century (142 vs. 464 instances). Furthermore, the two peak periods for the use of the subspecies rank (1861–1890: 113 instances; 1971–2000: 225 instances) do not correlate with the overall peaks for infraspecific taxonomy. In general, both in mycology and botany, the rank subspecies appears to have a more clearly defined geographical component, while the rank form is often used typologically and the rank variety may favor one or the other component, in contrast to the more strict definition of variety by Du Rietz (1930).
The proper application of infraspecific ranks requires a thorough understanding of the mechanisms of spatiotemporal reproductive isolation. Fungi, including lichen-formers, generally lack specific, vector-based fertilization mechanisms that would allow ecological divergence, and hence spatiotemporal separation, in sympatry. Such mechanisms are often found in related plant species, including seasonally or diurnally different flowering periods associated with different pollination vectors (e.g., Schlueter et al. 2009). On the other hand, selfing, another mechanism proposed to facilitate sympatric evolution in plants (e.g., Wendt et al. 2002; Matallana et al. 2010) is found in homothallic fungi (Honegger et al. 2004; Lin and Heitmann 2007; Ni et al. 2011). However, as long as an underlying biological mechanism supporting spatiotemporal reproductive isolation in sympatry has not been demonstrated, infraspecific taxa in fungi including lichen-formers are expected to exhibit spatiotemporal reproductive isolation primarily through geographic differentiation, in form of allopatry or peripatry or at least limited overlap. Therefore, the application of infraspecific names to widely distributed entities that largely or fully overlap with the typical (nominal) infraspecies, or other infraspecific taxa within the same species, is ill-defined. As a consequence, the bulk of infraspecific names historically established in fungi, including lichen-formers, has been either subsumed into synonymy under particular species or these taxa have been raised to species level.
An additional conceptual issue in traditional botanical and mycological nomenclature is the notion that the three principal infraspecific ranks, subspecies, variety, and form, should theoretically follow a hierarchy, similar to supraspecific ranks [ICNafp (Shenzen) Art. 4, 24]. Thus, in a strict sense, variety should correspond to the subdivision of a subspecies and form to the subdivision of a variety. Historically, infraspecific ranks have mostly be applied to subdivisions of species, independent of rank, and often in a simplified sense, especially with respect to form vs. variety, i.e., the smaller the perceived deviation, the lower the applied rank. In a biological sense, a situation where hierarchical infraspecific ranking would be applicable at the infraspecies level can be theoretically conceived, e.g., a geographically isolated population that, while not yet reproductively isolated from the mother population, already undergoes further geographic isolation. On the other hand, one could argue that infraspecific ranks reflect the temporal dynamics of speciation, i.e., when a new lineage emerges, the differences towards its ancestor become gradually more distinct, and so a new lineage would gradually pass through taxonomic recognition at different infraspecific levels and ultimately at specific level, and the proper rank would then reflect the inferred stage and not a nested taxonomic structure. A third approach would be to invariably treat infraspecific lineages at the level of subspecies, independent of the degree of deviation. Zoological and prokaryote nomenclature have long adopted this practice and abandoned the use of infraspecific ranks below subspecies, recognizing all infraspecific ranks by default as subspecies, even if originally designated otherwise, e.g., as variety or form [ICZN Art. 45.5, 45.6 (Ride et al. 1999); ICNP Rule 5c, 14a (Parker et al. 2019)]. Here, we consider that the rank of subspecies should be the default when the distribution ranges are not nested, i.e., cases of allo-, para- or peripatry, whereas variety should be applied when a narrow range is nested within a broader range, always assuming that the underlying phylogeny allows for such an interpretation (Fig. 10). Variety should also be used when indeed a hierarchically nested pattern can be demonstrated (see below). The rank forma should, however, be abandoned.
Within a modern taxonomic framework, based on the findings from molecular phylogenetic studies, the use of infraspecific taxa in fungi including lichen-formers has decreased considerably and, where continued to be employed, has been based on a more solid evolutionary rationale, although not necessarily in all instances. In a modern context, infraspecific (gamma) taxonomy offers the possibility to deal with structured infraspecific variation, providing a tool to mediate between splitting and lumping of species. In theory, the decision whether lineages should be considered species or infraspecific taxa is reproductive isolation (species) vs. compatibility (infraspecies) in sympatry, either in nature or experimental. While sympatry in nature can be assessed from distribution data, experimental approaches pose challenges in terms of practicability and hence have only rarely been used in fungal taxonomy (Dettman et al. 2003; Liu et al. 2016; Lücking et al. 2020a). In lichen-formers, an experimental approach to reproductive isolation vs. compatibility is even more difficult, but indirect evidence through mating genes and molecular patterns of past recombination and gene flow have been employed (Leavitt et al. 2011a, b, 2015; Wirtz et al. 2012; Ludwig et al. 2017).
As detailed approaches to reconstruct the reproductive biology of lichenized fungi are rare, so far there has been no widespread and consequent implementation of infraspecific taxonomy in a modern, evolutionary sense, such as practiced in zoology (Wilson and Brown 1953; Mallet 2007; Patten 2015). On the contrary, competing solutions are often applied to such cases. A recent example is the genus Thamnolia. Between 1850 and 2020, 67 names were established in this genus, 22 of which correspond to unrelated genera in other lineages and 45 to Thamnolia sensu stricto, representing 30 heterotypic entities (Table 5). Of these, 19 were only recognized at infraspecific level. Taxa in this genus have traditionally been distinguished based on few phenotype characters: a hollow vs. solid, cylindral to flattened thallus, branching pattern, and secondary chemistry, with individuals producing either thamnolic (and decarboxythamnolic) acid (UV–) or squamatic and baeomycesic (UV + yellow) acids (Culberson 1963; Santesson 2004; Jørgensen 2019). Given the lack of correlation between morphology and secondary chemistry, the taxonomy in this genus has been disputed and concepts varied between recognizing a single, variable species or various taxa with emphasis on either morphology or chemistry, or both, at species or infraspecific rank (Culberson 1963; Santesson 2004; Jørgensen 2019). A recent molecular phylogenetic study based on six markers (Onuţ‐Brännström et al. 2017, 2018) resolved three main, supported lineages, one widespread, one subarctic, and one restricted to the Alps. In the widespread lineage, there was little or no correlation with morphological or chemical features. The authors recognized the three lineages as three species, the widespread lineage under the name T. subuliformis, the subarctic lineage as new species, T. tundrae, and the alpine lineage as T. vermicularis s.str. Jørgensen (2019) subsequently corrected an apparent error in typification, so that the widespread lineage would carry the name vermicularis and the alpine lineage the name taurica; however, he recognized the three lineages only at the subspecies level, as T. vermicularis subsp. vermicularis (syn.: T. subuliformis), T. vermicularis subsp. taurica, and T. vermicularis subsp. tundrae.
Given that the underlying phylogeny is known, the correct application of alpha and/or gamma taxonomy in this case can be assessed. The topological patterns, in particular the long stem branches and the somewhat structured internal variation in the widespread lineage (Onuţ‐Brännström et al. 2017, 2018) support the recognition of each lineage at the species level, reflecting the separate evolutionary history of each lineage. The allopatric distribution of the subarctic (tundrae) vs. the alpine lineage (taurica) allow the application of infraspecific taxonomy, if both were sister groups and showed little phylogenetic divergence. Whereas the ITS marker resolved both as sister clades (Onuţ‐Brännström et al. 2018), the six-marker phylogeny did not resolve the relationships between the three lineages but suggested that the subarctic and the alpine lineage split more recently (0.6–4.1 Mya) from each other than either from the widespread lineage (1.5–6.6 Mya; Onuţ‐Brännström et al. 2017). The widespread lineage (vermicularis) is present in the range of both taurica and tundrae, so the latter two fully overlap with vermicularis within their corresponding range. Therefore, it appears that in the overlapping ranges, taurica and tundrae are reproductively isolated from vermicularis, because otherwise one would expect them to interbreed. This consideration is of course complicated by the notion that extant sexual reproduction in Thamnolia is not known, making the application of the biological species concept difficult. The molecular data show signs of past recombination within but not between lineages (Nelsen and Gargas 2009; Onuţ‐Brännström et al. 2017), supporting their distinction at species level and also indicating that sexual reproduction happened in the past. The data also suggest that taurica and tundrae are relict species with a broader ancestral distribution, whereas vermicularis shows signatures of a recent expansion. Given this evidence, the proposal by Jørgensen (2019) is not in accordance with the evolutionary history of these lineages and they are better recognized as species, with the revised names T. vermicularis for the widespread lineage (= T. subuliformis sensu Onuţ‐Brännström et al. 2018), T. tundrae for the subarctic lineage, and T. taurica for the lineage in the Alps.
Unfortunately, few cases offer the amount of data available as in Thamnolia to assess the feasibility of infraspecific taxonomy in species complexes. Another example is Ramalina celastri subsp. ovalis, now recognized as a separate species, R. ovalis (Hayward et al. 2014). Therefore, great care should be applied when opting for infraspecific taxonomy and the reasoning for such an approach should always include an evolutionary component, even if only inferred from indirect evidence. For instance, Lücking and Lücking (1995) established Arthonia cyanea var. cocosensis for an isolated population on the oceanic Cocos Island in the eastern Pacific that slightly deviates from other material of the widespread A. cyanea var. cyanea in the ascospores becoming 3–4-septate and greyish-brown (2–3-septate and colourless in A. cyanea var. cyanea). Subsequently, Lücking (2008) divided the latter into f. minor Lücking (ascospores predominantly 2-septate) and f. cyanea (ascospores predominantly 3-septate). The phylogenetic relationships between these phenotypes are unknown and the current taxonomic concept is therefore an untested hypothesis. However, given that f. minor, although comparatively rare, is widespread in the Neotropics (Lücking 2008; van den Boom and Sipman 2016), it cannot be separated from the widespread f. cyanea based on non-biological reproductive isolation. Therefore, f. minor should either be merged into A. cyanea as a single taxon or, given that intermediate forms have not yet been reported, better recognized at the species level: Arthonia minor (Lücking) Lücking comb. et stat. nov. [Bas.: Arthonia cyanea f. minor Lücking, Fl. Neotrop. Monogr. 103: 132 (2008); MycoBank 840275].
Ahti (2000) applied infraspecific taxonomy in various cases of species classified at the time in the genus Cladina, now subsumed within Cladonia, for instance in Cladonia arbuscula, with subsp. boliviana, subsp. imshaugii, and subsp. pachyderma. Two of these had originally been established at the species level, viz. C. boliviana and C. imshaugii. The subspecies within C. arbuscula were based on a combination of chemical and morphological characteristics and, in part, distribution range, although two subspecies were given as chemically variable. Thus, subsp. arbuscula is characterized by usnic and fumarprotocetraric acids, a robust habit with combed apical branchlets, and a compact ectal layer; it is widespread in temperate regions in both hemispheres. In contrast, subsp. boliviana is principally Andean, with a more slender habit, the apical branchlets not conspicuously combed, and a fibrose extal layer; it has four chemotypes, one corresponding to that of subsp. arbuscula and the others with usnic acid only or additionally with stictic acid (Ahti 2000). The other two subspecies, subsp. imshaugii and subsp. pachyderma, share with subsp. arbuscula the robust habit with combed apical branchlets and compact extal layer, but differ in the mainly dichotomous branching and in other morphological details; both have narrow distribution ranges in Hispaniola (subsp. imshaugii) and the Venezuelan Andes (subsp. pachyderma). In addition, populations in Western North America, eastern Asia and Australasia have been separated as subsp. beringiana and subsp. squarrosa, and C. mitis has also been considered a subspecies of C. arbuscula (Ahti 2000; Myllys et al. 2003; Piercey-Normore et al. 2010). Data of the ITS marker are available for subsp. arbuscula, subsp. beringiana, subsp. boliviana, subsp. mitis, and subsp. squarrosa, indicating that subsp. boliviana is nested on a long, strongly supported branch within a paraphyletic residual formed by intermingled samples of subsp. arbuscula, subsp. beringiana, and subsp. squarrosa; this residual is otherwise nested within subsp. mitis or, depending on sampling and markers, subsp. mitis is nested within subsp. arbuscula or both are reciprocally monophyletic (Myllys et al. 2003; Piercey-Normore et al. 2010; Stenroos et al. 2019; Moncada et al., unpubl. data). The nested topology, together with the largely allopatric distribution and the morpho-anatomical differences, would justify the recognition of subsp. boliviana at precisely that level, comparable to the case of Cora dewisanti (Fig. 10). In contrast, subsp. arbuscula, subsp. beringiana and subsp. squarrosa are not resolved into coherent entities and hence should not be formally recognized, although they show some degree of phenotypic differentiation (Fig. 10). On the other hand, C. mitis and C. arbuscula have nearly the same broad distribution ranges and hence cannot be recognized at infraspecific level; based on the underlying topology (Piercey-Normore et al. 2010; Stenroos et al. 2019; Moncada et al., unpubl. data), C. mitis should be recognized as a separate species, similar to the situation in Pseudocyphellaria biliana vs. P. pomaikaiana (Fig. 10).
Clerc (1987) distinguished two varieties in Usnea fragilescens, var. fragilescens and var. mollis. Both show minor morphological and evological divergence and both exhibit broadly overlapping ranges across the Northern Hemisphere (Lücking et al. 2020b). No molecular data are currently available for var. mollis, but the distribution ranges suggest that the distinction is merely typological and hence both should either be merged or separated at the species level (Moncada et al. 2020a).
The subspecies level was applied to recently discovered new taxa in the genera Cora, Peltigera, and Sticta. In the cases of C. dewisanti subsp. mexicana vs. subsp. dewisanti and S. scabrosa subsp. hawaiiensis vs. subsp. scabrosa (Moncada et al. 2019, 2021a, b), the subspecies exhibit peripatry relative to the typical subspecies: C. dewisanti subsp. mexicana in Mexico vs. subsp. dewisanti in South America, and S. scabrosa subsp. hawaiiensis in Hawaii vs. subsp. scabrosa in the Neotropics. In both cases, the two subspecies showed only minor phenotypic differentiation, close to being cryptic. Besides this, the main aspect for their classification as subspecies was their nested placement within the typical subspecies in the underlying phylogeny, on short branches. For such cases, the evolutionary history best justifies the status of subspecies (Fig. 10). A different pattern was found for Peltigera polydactylon subsp. udeghe (Magain et al. 2016), which was resolved as reciprocally monophyletic compared to subsp. polydactylon, differing morphologically in the phyllidiate thallus, and with an allopatric distribution pattern. This would in our view justify the distinction at species level, comparable to the case of Cora palaeotropica vs. C. bovei (Fig. 10).
In contrast, Solenopsora olivacea subsp. olivacea and S. olivacea subsp. olbiensis form a species pair with either sexual or asexual reproduction (see above). The limited molecular data (only three specimens in total sequenced) indicate that both are closely related but potentially reciprocally monophyletic, and both have broadly overlapping ranges in the Mediterranean (Guttová et al. 2014). Their separation at infraspecific level is therefore purely typological and subsp. olbiensis should either be subsumed under S. olivacea or recognized at the species level, depending on additional molecular data.
A quick primer on common molecular complications
While molecular data are overall superior to phenotype data in establishing evolutionary relationships and delimiting species, they are not free of potential complications, which may lead to type I errors (false positives), i.e., the erroneous establishment of novel taxa. The six most common ones are (1) contaminant sequences, (2) laboratory mixups, (3) chimeric sequences, (4) incomplete lineage sorting, (5) introgression, and (6) gene duplication (Loeffler et al. 1999; Stojanovic et al. 2002; Hugenholtz and Huber 2003; Maddison and Knowles 2006; Joly et al. 2009; Naciri and Linder 2015; Sheik et al. 2018; Lücking et al. 2020a; Aime et al. 2021). As a consequence, molecular phylogenies used to test existing taxonomies should be carefully assessed for such errors, before proposing formal changes or describing new species. To that end, we provide precise definitions and guidelines.
Contaminant sequences are defined as sequences generated from a sample that do not represent the target organism, in this case the primary mycobiont. Frequently, these are attributed to environmental laboratory contaminants accidentally entering the sample, but in reality, such contaminants are much less common than contaminants originating from the sample itself or from DNA contamination of stock solutions (which can be tested by using sample-free controls). Sample contaminants may not only be fungi developing on the sample a posteriori, such as molds, but also lichenicolous, endolichenic, or other fungi occurring as natural components of the sample, although not necessarily growing in the lichen thallus (see above). Contaminants can usually be recognized by blasting the resulting sequence, as it should give results unrelated to the target mycobiont. Surprisingly, such contaminant sequences are not rarely submitted to public repositories, such as GenBank, under the name of the target mycobiont (Sheik et al. 2018); for instance, an ITS sequence labeled Strigula orbicularis (GenBank accession KU509981) represents a contaminant in the genus Aspergillus. This happened more frequently in the earlier days of DNA sequencing, as the lack of proper reference sequences made it more difficult to assess whether a given sequence represented the target fungus or a contaminant, e.g., a dothidealean contaminant mtSSU sequence of Lasallia pennsylvanica (AF356664) leading to an artifactual topology, with Eurotiomycetes nested within Lecanoromycetes (Lutzoni et al. 2001; Lücking and Nelsen 2018). Not rarely, the same sample and DNA extract may provide the desired target sequences for a given set of markers but contaminant sequences for other markers, depending on the affinity of the primers to the target mycobiont vs. any contaminant fungus present in the sample. A recent example is the presence of basidiomycetous fungi in the thalli of certain Verrucariaceae, in which the mtSSU primers consistently recovered the primary mycobiont (Verrucariaceae), whereas the ITS primers generally sequenced the basidiomycetous component (Corticiaceae; Lücking and Moncada 2017). A particular challenge arises when the contaminant sequence represents a (closely) related taxon, which can happen in diffusely delimited lichen phenotypes that may contain small pieces of other lichens (see below; "extraneous mycobiont DNA"). Such cases will not be immediately obvious but should be considered when phylogenetic placement of a set of sequences generated from the same sample results in unexpected placements. The only conclusive way to test for close-relative contamination is to make another DNA extract from the underlying sample.
An often overlooked problem is the decoupling of the underlying specimen from the different steps in the workflow of generating the molecular data, i.e., DNA extract, PCR aliquots, PCR cleaning product, or the actual sequence data file. The underlying connection is ensured by a unique identifier (DNA extract number, tissue sample barcode, etc.); however, errors of mislabeling easily and inadvertently happen, particularly in the last sequencing step, including reverse positioning of the sequencing plate. Apart from attempting to avoid such errors by working carefully and with attention to detail, or using software pipelines to track potential mixups (e.g., Stojanovic et al. 2002), a way to avoid unrecognized mixups is to combine distantly related samples in a single work set and, if resulting sequences from a sequencing plate appear odd, test whether reverse order of the plate labels provide the expected match. If there is evidence for a mixup, the safest way to obtain reliable data is repeating the PCR and sequencing steps, rather than trying to make sense of the existing data. Kondratyuk et al. (2019) recently reported "extraneous mycobiont DNA", i.e., unexpected sequences corresponding to a particular lichen mycobiont presumably detected in the thallus of other lichens, e.g., of Biatora longispora (Ramalinaceae) in the thallus of Agonimia pacifica (Verrucariaceae). It is unclear whether these are the result of a laboratory mixup or of natural contamination of the underlying lichen thalli. Proposing a special term ("extraneous mycobiont DNA") and postulating that this may play "… an important role in [the] formation of lichen associations …" or "… help to understand better [the] taxonomy of some lichen groups …" (Kondratyuk et al. 2019: 294) is not only fanciful but also far-fetched.
Chimeric sequences are a known problem in next generation sequencing (NGS) techniques (Nilsson et al. 2015). Sanger sequencing does not usually result in chimeras, unless the primer pair shows differential downstream and upstream affinities to fungal lineages. When trying to assemble such sequences, the mismatch is usually immediately detected, unless there is little overlap between forward and reverse sequences in a conserved region. Given that such chimeric contig sequences should contain more or less equally large forward and reverse parts, they are rather easily detectable either by blasting and inspecting the alignment patterns, or in a phylogenetic analysis, by causing the including clade to have a rather long, yet unsupported stem branch. Besides chimeric sequences, chimeric data sets, i.e., concatenating clean sequences that represent different target organisms, have been reported to lead to erroneously established taxa (Vondrák et al. 2018; Llewellyn 2019; Wilk et al. 2021).
Incomplete lineage sorting is a commonly occurring, natural problem in recently emerging species (Maddison and Knowles 2006; Joly et al. 2009; Alexander et al. 2017). It is caused by a temporary shift in the divergence of different genes, usually located in different portions of the genome. When a lineage L0 diverges into two lineages L1 and L2, gene A may diverge first, then represented by alleles A1 and A2, subsequently followed by gene B, with alleles B1 and B2. The ancestral lineage is then characterized by the combination A0-B0, whereas the two descendant lineages will eventually exhibit the combinations A1-B1 vs. A2-B2, after sufficient "sorting" time has passed. During the emergence of the two lineages, individuals may show various combinations, including also A1-B2 or A2-B1, leading to conflict when different markers are comparatively analysed. Such incomplete lineage sorting can be recognized when the visible conflict is restricted to closely related sister lineages and when some markers appear to have more resolution than others, i.e., when there is an underlying pattern regarding the timeline of individual gene trees, although in practice this can be difficult to discern with typical sampling sizes.
Introgression occurs after interspecies hybridization, when hybrids backcross with one or both parent lineages (Alexander et al. 2017; Ament-Velásquez et al. 2020; Keuler et al. 2020). If this happens between recently diverged sister species, patterns resulting from introgression are difficult to distinguish from those caused by incomplete lineage sorting (Alexander et al. 2017), although statistical tests have been developed to aid in such cases (Joly et al. 2009). If introgression happened between more distantly related species, the conflict should be visible in that conflicting markers from the same sample cluster in different clades representing other parent species. Again, sampling size, both in terms of individuals and markers (e.g., phylogenomics; Ament-Velásquez et al. 2020; Keuler et al. 2020) is critical to properly assess this issue.
Gene duplication denotes the divergence of a given gene into two (or more) copies within the same genome. Once this happens, the different copies (original ortholog and duplicated paralogs) are bound to evolve independently through random DNA replicating errors, unless a mechanism of concerted evolution is in place. Such sequence evolution is independent of lineage evolution, exploring new phylospace, meaning that, contrary to introgression, paralogous sequences do not have exact matches in the genome of other species (Lücking et al. 2020b). However, as in the case of incomplete lineage sorting vs. introgression, this depends on the time passed since the divergence. Also, given that gene duplication is clade-based, the resulting conflicting topologies may resemble those obtained from introgression (Lücking et al. 2020b). The differentiation is further complicated when paralogs remain functional and do not evolve freely, especially, when a functional paralog replaces the original ortholog in the genome, so that the genome contains one copy of the gene (Linder and Rieseberg 2004). In such cases, the absence of more than one copy in genome sequencing approaches does not mean that the gene is not a paralog.
Data and taxon sampling
An often overlooked issue in taxonomic works is improper or insufficient data and taxon sampling, which can lead to type I errors (false positives) and taxonomic inflation (Leavitt et al. 2011b; Bernstein et al. 2021), rarely also to type II errors (false negatives). Common errors include improper taxon and specimen sampling, improper comparison of different data types, and omitting the search for potentially available names in historic or obscure literature.
When establishing a new species, it should by default be compared to both the most similar and the most closely related species. Most similar species are those deviating in only few characters, for instance with the same morphology but a different chemistry or ascospore type, or with the same (particularly if unusual) chemistry but differing in other features. Most closely related are those species forming part of the same clade, in particular the immediate sister species. Assessing close relationship is often non-intuitive when molecular data are not available, as closely related species may be phenotypically disparate (Lücking et al. 2017b; Esslinger et al. 2020). When a comprehensive taxonomy, such as a global revision or monograph (e.g., Arvidsson 1982; Aptroot and Lücking 2016) and/or a more or less complete set of molecular data, such as for the genera Cora or Melanelixia (Arup and Sandler-Berlin 2011; Leavitt et al. 2016b; Lücking et al. 2017b) exist for a higher taxon, taxon selection for proper comparison is rather straightforward. However, more often than not this is not the case. Therefore, the distinctiveness of a clade in a molecular phylogeny alone is not evidence for a novel species, unless all species in this group have been sequenced. Even in groups for which a large amount of sequence data is available, such as the genus Usnea, with currently over 1750 ITS accessions, the proportion of sequenced vs. known species is generally low, in the case of Usnea little over 25% (Lücking et al. 2020b). Thus, before introducing taxonomic novelties based on a molecular phylogeny, similar but non-sequenced species in the group in question should be carefully examined and this should be documented in the discussion of the new taxon (Lendemer 2021).
In groups where the majority of the species have already been described and where a large proportion of established names are currently treated as synonyms, such as in vascular plants or reptiles (Joppa et al. 2011; Bernstein et al. 2021), the likelihood for an unfamiliar lineage to already have a name, and hence for the establishment of another, superfluous name, is rather high. In lichen-forming fungi, about half of the established species-level names are currently considered synonyms (see above), whereas the number of undescribed species is estimated to surpass the number of currently accepted species by about fifty percent (Lücking et al. 2009b). Thus, an unfamiliar lineage is about twice more likely to already have a name than to be undescribed. As a result, issues of unrecognized diversity and taxonomic inflation may go hand in hand (Leavitt et al. 2011b; Bradshaw et al. 2020). In fungi overall, the number of available species-level names is about twice the number of currently accepted species, whereas the number of estimated species is about twenty times as high (Hawksworth and Lücking 2018), and so it is statistically ten times more likely to detect an undescribed species than an unfamiliar, yet previously described species. However, this does not release the taxonomist from the responsibility to always carefully check old names and historic or obscure publications, including in foreign languages, that way developing a thorough familiarity with the focal group to appropriately recognizing non-fitting samples. Nomenclatural repositories such as Index Fungorum and MycoBank, with extensive synonymies and often with direct links to protologues, greatly facilitate this task.
In multi-marker phylogenies it is not rare that lineages are only represented by a subset of markers. For instance, in a three-marker phylogeny comprised of mtSSU, nuLSU, and RPB2, any given lineage may be represented by all three, two, or just one of these markers. Problems then arise particularly for terminals (species), when the markers do not overlap. For instance, one species may be represented by a combination of two markers (e.g., mtSSU, RPB2) and another by a single marker only (e.g., nuLSU), which will lead to "phylogenetic orphans" or false polyphyly (e.g., Rivas Plata et al. 2013). For broader phylogenies, e.g., attempting to resolve genera within a family, this is of no concern, as long as each genus-level clade has at least some marker overlap between the lineages contained therein. However, individual species can appear polyphyletic if there is no marker overlap between different samples representing the same species (Rivas Plata et al. 2013). It is therefore conceivable that absence of marker overlap can lead to erroneous recognition of presumably novel taxa, when the marker(s) sequenced for such material do not overlap with the already existing markers sequenced for other specimens of the same taxon. Such problems are fortunately often recognized at the submission stage of manuscripts.
A third problem is the generation of sequence data for presumably widespread species when sequence data for the metapopulation including the type locality are not available. For instance, a species may have originally been described from the Caribbean (e.g., Teloschistes flavicans), but sequence data were first generated from geographically distant regions, such as South Africa, Australia, and Hawaii (Fedorenko et al. 2009). The assumption that such sequence data really represent the species in question, and hence demonstrate its wide distribution, is ill-defined and can lead to potential type II errors, i.e. false negatives. Fortunately, such cases are easily discerned when molecular data become available for material from the region encompassing the type locality, although complicated cases where even the type locality may harbor more than one species of a species complex are known, e.g. S. fuliginosa vs. S. fuliginoides (Moncada et al. 2014; Magain and Sérusiaux 2015). In any case, drawing deeper conclusions from cases where presumably widespread species are first sequenced outside their type region should be avoided.
Conclusions: a protocol for consistent alpha (and gamma) taxonomy in lichen-forming fungi
In conclusion, we present a protocol for a consistent alpha (and gamma) taxonomy in lichen-forming fungi, including practical solutions for different purposes. The underlying logic is in part loosely based on McCabe (2021) but has been placed into a more practical framework and adjusted to modern terminology.
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1.
Detect a phenotypically or phylogenetically non-fitting sample (individual or group of individuals) within the framework of a previously established taxonomy.
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2.
Determine the degree of non-fittingness, preferably using a quantitative approach. For phenotype characters, apply a statistical approach when the differences are morphometric (e.g., ascospore size) and not immediately obvious, demonstrating that the non-fitting sample is outside the variation range of already known taxa. For instance, differences in ascospore sizes of 10–20 × 6–8 μm (non-fitting sample) vs. 20–30 × 8–10 μm (most similar known taxon) should be quantified using a statistical group comparison or a multivariate ordination graph. Qualitative phenotype characters (e.g., presence/absence of particular chemical compounds) should be assessed in comparison to the known variation in related, well-established taxa defined with the aid of molecular data, taking into account the underlying nature of the character (e.g., chemosyndromes of related substances vs. different substance classes). For example, norstictic vs. stictic acid (both 1'-6'-OH depsidones) is more likely to represent variation compared to norstictic vs. psoromic (6'-COOH depsidone) or lecanoric acid (depside). If there is no evidence for qualitative variation (discrete phenodemes) in the established taxonomic framework of a genus, always consider a non-fitting sample a separate entity instead of assuming discrete variation ad hoc, unless the qualitative character corresponds to a known discrete variation (e.g., photomorphs associated with different photobionts, reproductive mode). Always check for correlation between at least two functionally uncorrelated characters. For instance, statisticaly correlated differences in ascospore size and chemistry are likely evidence for distinct taxa, whereas statistically correlated differences in ascospore size and numbers of ascospores per ascus (i.e., ascospores are larger in asci with fewer ascospores) may represent a taxonomically meaningless, functional correlation.
For a phylogenetically non-fitting sample, assess the underlying topology (reciprocally monophyletic vs. nested within a paraphyletic residual), as well as branch length and support patterns. Assess congruence between different markers if available (coalescence). Reciprocal monophyly combined with long, strongly supported stem branches (significantly longer than internal branches) in congruence between various markers is strong evidence for separate entities, whereas a nested clade with s short, unsupported stem branch within another clade is not.
Generally, the more pronounced the difference of the non-fitting sample relative to all known taxa, the lower the number of characters needed to establish a species hypothesis. Even single characters may suffice if the difference is immediately convincing (e.g., transversely septate vs. richly muriform ascospores or linear vs. broadly rounded lobes). Similarly, pronounced differences in single-locus phylogenetic trees can be sufficient for establishing a robust species hypothesis, although not for inferring evolutionary relationships with confidence.
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3.
If the sample has been assessed phenotypically, where possible test the non-fittingness by generating molecular data. Note that this approach is only valid when molecular data exist for the most similar known taxa to which the non-fitting sample is compared. If the molecular data result in topological polyphyly of the non-fitting sample, the initial species hypothesis is likely to be rejected. If the phylogeny of the non-fitting sample vs. known taxa is unresolved (i.e., all forming a single lineage), but the phenotypic deviation cannot be explained by known patterns of variation, consider the possibility that the molecular marker(s) employed may not provide sufficient resolution. Testing phenotypic non-fittingness with molecular data is not a requirement (and may not be possible when the underlying material is of a certain age), but the importance of the latter increases when phenotypic non-fittingness is low and particularly when well-established taxonomic concepts are being challenged (Lendemer 2021).
If phylogenetic non-fittingness has been detected first, compare the phenotypes of the underlying individuals. If there are no immediately obvious differences, perform a quantitative analysis of a phenotype character matrix mapped onto the phylogeny. If there are no discernable phenotypic differences but the underlying phylogeny shows distinct clades (i.e., reciprocal monophyly combined with long, strongly supported stem branches), consider cryptic speciation.
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4.
If the degree of non-fittingness of the sample is deemed sufficient to consider a novelty, it should be made sure that all historically described names have been assessed to rule out there is no fitting name. In particular, heterotypic synonyms of similar and/or closely related taxa should be thoroughly checked. For synonyms, consult taxonomic treatments of the genus in question. For the assessment of type material, JSTOR Global Plants [https://plants.jstor.org] is an excellent source. When considering potentially applicable names, always take into account the geographic origin but consider known broad disjunctions, such as western North American vs. Central Asia (Weber 2003; Melton et al. 2020)
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5.
If the degree of non-fittingness of the sample is deemed sufficient to consider a novelty and no applicable name appears to exist, the sample should be formally described. Names should not be published "ad interim" or as "nom. provis." or using informal working names, unless their formal description using the same name is immediate. If there is reason for hesitation, the proper solution would be to use the name of the most similar or most closely related taxon, in combination with the prefix "aff.", to denote a non-fitting sample. This latter strategy avoids the propagation of invalid names and ensures tracking down such non-fitters a posteriori, once enough data become available for a formal description. Non-fitters should not simply be subsumed within known taxa, as these will be impossible to trace a posteriori.
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6.
If the degree of non-fittingness of the sample is deemed sufficient to consider a novelty and it has been decided to describe it formally, the proper taxonomic level needs to be assessed, i.e., whether describing the sample as new species or as new infraspecific taxon of a known species. By default, assume the sample represents a new species. Apply infraspecific (gamma) taxonomy only if the following criteria apply: (a) the phenotypic differences are minor or cryptic; (b) the non-fitting sample and its most similar known counterpart or closest known relative exhibit allopatric or peripatric distribution; (c) the phylogeny shows a shallow topology (i.e., reciprocal monophyly with short stem branches not significantly longer than internal branches) or a nested relationship within a paraphyletic residual. If an infraspecific category appears to be the proper solution, always opt for the subspecies (subspecies, subsp.) category, unless the data support the category of variety (varietas, var.). Do not use the category of form (forma, f.).
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7.
When formally establishing a new species, follow the rules and guidelines (best practices) for valid publication and proper circumscription (Lendemer 2021; Aime et al. 2021).
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8.
When phenotypic identification of a novel taxon is challenging, e.g., in ecological studies or monitoring protocols, apply standardized taxonomic designations for less resolved identifications, e.g., aggregate for a monophyletic, cryptic species complex, such as the Bryoria fuscescens aggregate (Boluda et al. 2019) or Thamnolia vermicularis aggregate, or morphodeme for a polyphyletic assembly of phenotypically similar species, such as the Sticta fuliginosa or S. weigelii morphodeme. However, the degree of precision should always be adjusted to the objectives of the study, and lack of time and resources alone should never be an argument to reject more precise species concepts. Merging species not readily identifiable in the field or with standard approaches such as light microscopy or chemical spot tests into aggregates or morphodemes is only permissible when their underlying ecology and/or distribution does not generate conflicts with the aims of the study.
Data availability
No new data were generated for this review and other data sources are cited.
Code availability
No new code was generated for this review.
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Acknowledgements
Paul Kirk is thanked for placing data from Index Fungorum at our disposal and for fruitful discussions on individual cases. Bibiana Moncada kindly provided the field image of Lichenomphalia lobata, Rosemarie Honegger (via David Hawksworth) the SEM image of Xanthoria parietina, and Zakieh Zakeri the photograph of a culture of Xanthoria parietina.
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RL wrote the first draft for most of this manuscript and SDL wrote the first draft for the portion on species concepts. DLH contributed information on various historical aspects and perspectives for the initial draft. After integrating the drafts, all authors provided modifications to all parts of the manuscript in three subsequent rounds of revision.
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Lücking, R., Leavitt, S.D. & Hawksworth, D.L. Species in lichen-forming fungi: balancing between conceptual and practical considerations, and between phenotype and phylogenomics. Fungal Diversity 109, 99–154 (2021). https://doi.org/10.1007/s13225-021-00477-7
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DOI: https://doi.org/10.1007/s13225-021-00477-7