Abstract
Harmonia axyridis (Pallas, 1773), also known as the harlequin ladybird, is an invasive non-native species intentionally introduced to many countries as a biological control agent of agricultural pests. In Greece, H. axyridis was first introduced as a biological control agent in 1994, with releases taking place between 1994 and 2000. For many years there was no evidence to indicate that H. axyridis had established self-sustaining populations. In 2008, a citizen science campaign was initiated aimed at raising awareness regarding the invasive status of H. axyridis to farmers and agronomists. The campaign did not yield results, and it was discontinued in 2011. During this study, the distribution, phenology, and presence of H. axyridis in different habitat types and protected areas in Greece are investigated, using both citizen science data and literature records. Records from iΝaturalist, the Alientoma database and social media examined herein demonstrate that H. axyridis has been established in Greece since 2010. Harmonia axyridis is currently present in 13 administrative districts of Greece, most of them at a considerable distance from the initial release sites. The harlequin ladybird is present in urban and agricultural habitats as well as seventeen NATURA 2000 sites. The adverse socioeconomic and environmental impacts of H. axyridis are briefly discussed alongside suggestions for management activities. Based on our findings, we propose the establishment of a national monitoring scheme for H. axyridis and native ladybirds that will also encourage public participation in recording ladybird observations and provide information on the distribution, spread and impact of this invasive non-native species.
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Introduction
The harlequin ladybird, Harmonia axyridis (Pallas, 1773) has been released as part of biological control programmes globally against aphids and scale insects. This species was considered a suitable biological control agent as it is easy to rear (Adriaens et al. 2007; Roy et al. 2016; Kulijer 2017), it can track prey in space and time (Koch 2003), and it has voracious feeding habits (Sloggett et al. 2011). However, there is also evidence that H. axyridis has adverse impacts on biodiversity and it is considered an invasive non-native species (hereafter invasive species) (Roy et al. 2012, 2016; Skuhrovec et al. 2021).
Harmonia axyridis has attracted the interest of researchers and the public because of its dramatic spread and adverse impacts on nature and people (Roy et al. 2016; Kulijer 2017; Honek et al. 2018; Haelewaters et al. 2020; Skuhrovec et al. 2021). In the invaded habitats, there is evidence that H. axyridis preys upon many native arthropods and has displaced native natural enemies (Koch 2003; Roy et al. 2016). It is also considered a household nuisance in some contexts because of the large numbers that aggregate in buildings particularly through the winter months and a pest of fruit production (Koch and Galvan 2007; Honek et al. 2017). Furthermore, H. axyridis can affect human health, by causing urticaria and allergic reactions (such as rhino-conjunctivitis and asthma) or bite induced injuries (Goetz 2007; Roy et al. 2016; Roques et al. 2018).
Harmonia axyridis has rapidly spread over Europe and the Balkan Peninsula over the last few decades (Brown et al. 2007). However, there is very limited information regarding its phenology and distribution in Greece (Katsoyannos et al. 1997; Kontodimas et al. 2008a, b). Harmonia axyridis was first released in four citrus growing areas of Greece in 1994 (Marathon-Attica, Campos-Chios, Leonidion-Arcadia, and Chania-Crete) (Katsoyannos et al. 1997). Initially, it was considered to be an effective biological control agent against aphids in two of the locations of initial release but subsequent introductions in 1995 were not successful in any orchards. In 1995–1999, more than 100 000 insectary-reared adults of H. axyridis were released in various cultivations (i.e., citrus, vegetables, beans, maize) and urban areas of central and southern Greece as well as the islands of Chios, Evoia and Crete. During this period, field surveys were conducted every spring, just before the releases, to determine if H. axyridis had overwintered in the field. A month after each release field surveys were also conducted in order to estimate the population size of the ladybird shortly after the release (Kontodimas et al. 2008a). Subsequent surveys conducted every spring from 2000 to 2007, yielded no records of H. axyridis in any of the locations where the predator had been released (Kontodimas et al. 2008b). In earlier studies by Kontodimas et al. (2008a, b) H. axyridis was reported as having failed to establish’ but the authors at the time stated that ‘absence of evidence is not necessarily evidence of absence’. Given the time lag between the releases of H. axyridis and its establishment the authors stated the need for on-going surveillance (Kontodimas et al. 2008a, b).
Citizen or community science is a valuable tool for recording invasive non-native species at wide geographical scales and for engaging non-professionals in scientific research (Dickinson et al. 2012; Roy et al. 2018; Johnson et al. 2020; Lepczyk et al. 2020; Pataki et al. 2021). Community science in entomology can give valuable information regarding the distribution of insect species and their role in ecological networks (Gardiner and Roy 2022; Groom et al. 2021; Skuhrovec et al. 2021). In an effort to collect data from the general public and farmers, in 2008, Martinou and Kontodimas published a popular science article in Greek in a farmer’s magazine, describing the life-forms and other attributes of H. axyridis asking the readers to send photos or specimens to the Benaki Phytopathological Institute. However, that effort yielded no records. The first published records in the literature of established populations of H. axyridis were documented in June 2017 in three localities in Northern Greece (Promachonas, Charopo and Asprovalta) by Ceryngier and Romanowski (2017), no other records exist in the literature. The aim of our study was to provide information on the establishment and spread of H. axyridis in Greece by reviewing the literature and examining the records on the iNaturalist platform, the Alientoma database and social media. Citizen science records and records from the scientific literature were used to map the distribution of H. axyridis in Greece. These records were also used in order to identify the colour pattern polymorphism of adult individuals of the species in the country as well as the presence of the entomopathogenic fungus He. virescens. A literature search was also performed in order to identify the feeding habits of H. axyridis and its impacts on native biodiversity.
Material and methods
Distribution of Harmonia axyridis in Greece
Records of H. axyridis in Greece were obtained from citizen science observations made through the iNaturalist platform (iNaturalist 2021), the Alientoma database for non-native insects in Greece (Kalaentzis et al. 2021) and data mining from the social media (i.e., Facebook). Citizen science observations were downloaded from iNaturalist and the Alientoma database up to September the 8th 2021. These data were supplemented by observations from the authors and published literature records by Ceryngier and Romanowski (2017). The localities of the initial releases were also catalogued and georeferenced (Katsoyannos et al. 1997; Kontodimas et al. 2008a). Each record represented a unique sighting of H. axyridis on a given date and location reported by one person.
Distributional patterns in respect to land cover and the NATURA 2000 network sites
Citizen science data were used to investigate the occurrence of H. axyridis including in NATURA 2000 sites. A total of 191 records were collected from iNaturalist (164) and Alientoma (27); only georeferenced records which had more than two decimal places were used for accuracy reasons [accuracy of 100 m, to coincide with the Corine Land Cover (CLC) mapping width of 100 m]. We used CLC datasets (CLC 2018—Copernicus Land Monitoring Service). CLC data provides information on the biophysical properties of the Earth’s surface. The CLC datasets used have a common nomenclature with 44 classes in a hierarchical 3-level CLC nomenclature downloaded from the Copernicus Land Monitoring Service. The version used, covers the year 2018 with a minimum mapping width of 100 m. The projection used was EPSG: 3035-ETRS89-extended/LAEA Europe was used as assigned coordinate reference system (CRS). In addition, we identified the sites that are part of the NATURA 2000 European network (under Council Directive 92/43/EEC). These layers were then joined with the citizen science records (in total, 191 records) in order to explore the occurrence of H. axyridis in Natura 2000 sites and the land use classes in Greece. Finally, the administrative regions of Greece (Kallikratis Plan 2010—Law 3852/2010) were used to compare the distributional patterns of H. axyridis amongst areas of initial introductions and those where the species was not released.
Phenology, colour pattern polymorphism and parasitism by Hesperomyces virescens
Observations depicting more than one individual of different colour forms (melanic and non-melanic morphs; f. spectabilis, f. conspicua, f. axyridis and f. succinea) or life stage (i.e., larva, pupae or adult) were catalogued accordingly. All observations were verified from photographs submitted alongside each record, to confirm the species identification and study the colour pattern polymorphism of adult individuals. In addition, the presence of the entomopathogenic fungus He. virescens was assessed by examining citizen science observations of H. axyridis for signs of parasitism by the fungus.
Feeding habits
To assess the feeding habits and adverse impacts of H. axyridis on native biodiversity, a literature search was performed with the Scholar Google search engine, which, apart from peer-reviewed articles, included technical reports, etc. Eligibility criteria included any document with the following keywords anywhere in the article: < Harmonia axyridis > or < harlequin ladybird > AND “trophic preferences” AND “prey” AND “alternative food”. Publications related to H. axyridis presence, establishment and status in Greece were deemed to be of the highest relevance according to our scope, while references of each individual article were thoroughly searched for additional bibliography.
Statistical analysis
Plots were created in RSTUDIO Version 1.2.5042 (R Studio Team 2021), by using the ggplot2 package (Wickham 2016), while maps were created using QGIS 3.18.2.
Results
Distribution of Harmonia axyridis in Greece
A total of 191 observations were reported by citizen scientists (164 observations iNaturalist and 27 observations Alientoma), in thirteen of the fourteen administrative regions of Greece (with the exception of the Monastic Republic of Mount Athos). The number of records per year has increased from three in 2010 to 57 records in 2021 (Fig. 1B). More than half (51.83%) of the individuals observed by citizen scientists were recorded in the years 2020 and 2021. Most citizen science observations were recorded in continental Greece from Thessaly (53), Central Macedonia (45) and West Macedonia (32), accounting for 69% of all observations made by the public (Fig. 2). In addition, data that were collected through a literature review were used for mapping the introductions, the spread and the distribution of the species. Our results showed that H. axyridis is present throughout Greece and not only at the locations of initial introductions (Kontodimas et al. 2008a), or the locations studied by Ceryngier and Romanowski (2017) in northern Greece (Fig. 1A). However, it is not possible to know the exact year of H. axyridis establishment, as the records of iNaturalist for H. axyridis in Greece began in 2010.
Distributional patterns in respect to land cover and the NATURA 2000 network sites
Harmonia axyridis was observed in 18 different types of CLC (Fig. 4), with most records (35%, 63 observations) within urban areas with transport networks, bare ground and vegetated land classified as discontinuous urban fabric (CLC 112), followed by land principally occupied by agriculture (CLC 243) (24%, 44 observations). The administrative divisions “West Macedonia”, “Central Macedonia”, “Thessaly” had most observations and the rest of administrative divisions were grouped due to the small number of records (the “rest of Greece”). Within these four categories, more than 50% of H. axyridis individuals were recorded in urban areas of West, Central Macedonia and the rest of Greece, mainly in continuous or discontinuous urban fabric (CLC 112) as well as sport and leisure facilities, industrial or commercial units etc. In Thessaly a major agricultural production area, 66% of the records (33 observations) fell within land principally occupied by agriculture (CLC 243) followed by urban habitat types (35%, 18 observations) (Fig. 4).
Despite the large percentage of observations corresponding to urban habitats, this study showed that harlequin ladybirds are present also in protected NATURA 2000 areas. That means that the spatial distribution of the species is not necessarily related to man-made habitats and areas with high anthropogenic pressures. Regarding the presence of H. axyridis within the NATURA 2000 network, the species was recorded in 17 sites, located in eight administrative divisions (Table 1). The highest number of observations (5 records) was recorded from lakes Volvi and Lagkada (Limnes Volvi and Lagkada, GR1220001), in Central Macedonia, followed by two records from the wider area of Ioannina (Evryteri Periochi Polis Ioanninon, GR2130012) in Epirus (Table 1).
Phenology, colour pattern polymorphism and parasitism by Hesperomyces virescens
The vast majority of citizen science records were of adult individuals (87%, 189 photographic observations), followed by larvae (11%, 25 observations) and just four observations of pupae (2%) (Fig. 3C). Citizen scientists observed H. axyridis individuals throughout the year, except January (Fig. 3A, B). The species was mostly encountered from April to September although approximately ten living individuals per month were spotted from October to December (Fig. 3A). The highest frequency of individuals was recorded in May when all three developmental stages of H. axyridis were observed. During August, no larvae or pupae were detected, although adults were detected in the highest numbers (Fig. 3A). Copulating adults were recorded in April, June, August and September (Fig. 3B).
Similar to Ceryngier and Romanowski (2017), three main colour forms of adult H. axyridis have been recorded in Greece by citizen scientists. These are f. succinea that constituted 81.4% of observations, followed by f. spectabilis (almost 12.4%) and f. conspicua (almost 5%). Only two individuals of forma axyridis have been recorded, both from Magnesia, Liri (Thessaly). In addition, our study showed that melanic morphs were more frequent in the northern part of the country (i.e., Eastern Macedonia and Thrace and Thessaly); however only a few observations of the melanic morphs were recorded.
Concerning the parasitic entomopathogenic fungus He. virescens, this species was first recorded in Greece in 2001 on two native ladybird species (Castaldo et al. 2004) and later it was found on H. axyridis from three Northern Greek localities, namely Asprovalta, Charopo and Promachonas (Ceryngier and Romanowski 2017). Citizen science observations of infected H. axyridis were detected in Psili Ammos, Serifos Island and Servia Kozanis (Fig. 4). Thus, citizen science can provide very useful data in recording parasitic infections and the distribution of parasitic fungus on H. axyridis in Greece.
Feeding habits
The literature survey on the feeding habits of H. axyridis in Greece revealed various aphids as prey of the harlequin ladybird, i.e., Acyrthosiphonpisum (Harris, 1776), Aphis fabae (Scopoli, 1763), A. gossypii (Glover, 1877), A. spiraecola (Patch, 1914), Hyalopteruspruni (Geoffroy 1762), Macrosiphumrosae (Linnaeus, 1758), Myzus persicae (Sulzer, 1776), Nasonoviaribis-nigri (Mosley, 1841), Rhopalosiphumpadi (Linnaeus, 1758) and Toxopteraaurantii (Boyer de Fonscolombe, 1841) (Katsoyannos et al. 1997; Kontodimas et al. 2008a). On the side, citizen science records revealed an additional prey species, A. nerii (Boyer de Fonscolombe, 1841), observed in Magnesia, Liri (Fig. 4).
Discussion
Citizen science data mainly from the iNaturalist platform show that the harlequin ladybird is widely distributed in Greece, inhabiting multiple islands and continental regions, most of them remote to the initial sites where it was introduced as a biological control agent (Figs. 1A, 2). Early research on the distribution of H. axyridis up to 2007 implied that the ladybird had failed to establish in the areas where it was released as a biological control agent (Kontodimas et al. 2008b) and an effort for a citizen science recording scheme for this particular species in 2008 yielded no records (Martinou and Kontodimas 2008). However, citizen science records from as early as 2010 show that H. axyridis has been present in three distant geographical areas at least since that year (Fig. 1B). In particular, H. axyridis was observed from Sivota Thesprotias (G. Kakiopoulos pers. comm.), Florina, Cheimatitida lake (G. Kakiopoulos pers. comm.) and Magnesia, Liri. In the following two years only one individual was recorded, while in 2013 observations steeply increased reaching 13% of total observations (26 sightings). Up to 2018, data were scarce, but a rapid increase over the following years was evident with three quarters (144 observations) of all records attributed to 2018–2021. The increasing interest in biodiversity monitoring by citizen scientists in recent years using new technologies such as GPS and smartphones, may account for this increase (Johnson et al. 2020).
Records of H. axyridis in the administrative units of the initial introductions were scarce, with most records coming from Northern Greece. Most of the citizen science observations were from Thessaly, Central and West Macedonia (Fig. 2). Particularly, Central Macedonia (including Thessaloniki, the second largest city in Greece, with more than a third of a million residents; World Population Review 2021) and Thessaly which is mainly agricultural land; the large number of cultivated areas could explain the increased number of observations (Fig. 4). The high number of records from these regions may also have been a consequence of biases inherent with citizen science methods such as increased recording intensity in regions of high human population density (Isaac et al. 2014). A large percentage of observations correspond to urban habitats (54%), suggesting a recording bias towards human settlements and anthropogenic habitats. However, human population density does not seem to explain completely the spatiotemporal biases in the observed patterns (Isaac and Pocock 2015) as the number of observations in Attica, which is populated by more than half a million people (World Population Review 2021), was low. In addition, our study shows the increased engagement of people, at high latitudes where population densities are low. Nevertheless, the presence of the species in Northern Greece since 2010 (Fig. 1B) and the climatic suitability of the region, and the country in general (Grez et al. 2016), in combination with the highly invasive behaviour of H. axyridis, suggest that the species is widely established in Thessaly, Central and West Macedonia. Similar to previous studies (Dickinson et al. 2012; Roy et al. 2016; Grez et al. 2016; Werenkraut et al. 2020), this study demonstrates that citizen science is a valuable tool for understanding the spatial distribution of invasive non-native species.
The citizen science records also show that H. axyridis is active for a long period of time throughout the year (Fig. 3). Previous semi-field trials using outdoor cages showed that H. axyridis can have four annual generations in Greece (Katsoyannos et al. 1997). Although citizen science data cannot adequately determine the number of generations per year for H. axyridis, it is evident that the species is active for a long period of time, with living adult individuals being observed even during the winter months (December–February) (Fig. 3A, B). These findings are in accordance with earlier studies stating that H. axyridis can overwinter in Greece, but the phenomenon was rare, and populations were rather small (Kontodimas et al. 2008a, b). The vast majority of observations were of adult individuals (Fig. 3C). Noting the difficulties in identifying ladybird larvae, resources including simple identification guides for the immature stages of H. axyridis could be developed to promote recording across all life stages. Ladybirds are attractive and charismatic (Gardiner et al. 2021; Gardiner and Roy 2022), this is encouraging as people could be invited to contribute records that could help scientists understand the future range expansion, phenology, and impacts of H. axyridis on ecological networks (Groom et al. 2021). Training the citizen scientists on ladybird identification and ecology, could improve the degree of confidence. Existing recording applications could be promoted to citizen scientists in Greece for example the European Ladybird app (Skuhrovec et al. 2021).
Our study shows that more observations on the geographical and seasonal variation of melanic and non-melanic morphs of H. axyridis are needed to elucidate its seasonal patterns. In general, the non-melanic morphs exist at low temperatures. Temperature determines the size and number of black spots and affects the size of red spots in melanic morphs (Honek et al. 2020). Across the native range of H. axyridis non-melanic morph, succinea is found most often in hot, arid regions and melanic morphs being more frequent in cooler, more humid ones (Roy et al. 2016). Our study showed that melanic morphs were more frequent in the northern part of the country (i.e., Eastern Macedonia and Thrace and Thessaly). However, the number of observations of the species in southern Greece was much smaller compared to northern Greece (Fig. 1). In addition, only a few observations of melanic morphs were recorded; thus, the small size of observations might cause less accurate results regarding the melanic and non-melanic morphs and the factors that affect their distribution in Greece.
The involvement of citizens in monitoring H. axyridis in Greece has provided valuable data and this is the case in many other countries (Gardiner et al. 2012; Grez et al. 2016; Werenkraut et al. 2020). Most of the records were reported in urban areas and land principally occupied by agriculture. It seems that high human activity might be facilitating the invasion of the species (Hufbauer et al. 2012; Grez et al. 2016; Werenkraut et al. 2020) (Fig. 4). However, the observations could be biased towards these habitat types. The presence of the species in 17 NATURA 2000 sites is concerning, considering the large number of endemic taxa and rich biodiversity that Greece holds (Sfenthourakis and Legakis 2001; Spiliopoulou et al. 2021). The NATURA 2000 network covers 27.3% of the terrestrial area in the country (Spiliopoulou et al. 2021). There is a large number of non-native insects established in Greece (Anagnou-Veronikiet al. 2008; Avtzis et al. 2017; Demetriou et al. 2021) and monitoring the spread of these, particularly in protected sites, could underpin strategic action. Monitoring H. axyridis in Greece is important because the harlequin ladybird could have adverse impacts on native species and ecosystem function. However, several years of monitoring would be required before the long-term impacts can be reliably assessed (Kenis et al. 2010). The present work documents the distribution and phenology of the species in Greece and it is the first step towards improving our general understanding of the ecology of the species. In the future studying the impact of H. axyridis on native biodiversity and ecosystem services in Greece should be a priority.
Regarding the predation of aphids by H. axyridis, aphid prey can be easily overlooked or misidentified due to their small size. Thus, citizen science efforts could be taxonomically biased. Such biases could be minimised through structured surveys (Kelling et al. 2019). Nevertheless, the discovery of A. nerii as an additional prey species for H. axyridis from citizen science records highlights the importance of citizen science towards the study of ecological networks of alien species (Groom et al. 2021). Future studies could incorporate citizen-science approaches in the monitoring of alien species and their ecology in addition to the monitoring undertaken by expert entomologists. Assessing the level of infections via parasitism can also be observed and recorded by citizen scientists, providing data that are essential to ecological research.
Management implications
This study highlights the importance of public participation in recording ladybirds showing that citizen science schemes can provide valuable information on invasive non-native species in Greece. The current distribution and spread of H. axyridis in Greece at a multitude of remote localities where no releases had been made in the past and in protected areas, calls for action. National and regional monitoring schemes by experts in combination with efforts by citizen scientists are essential in order to gain a better understanding of the spread and the hotspots of activity of the invasive H. axyridis. Monitoring efforts could guide management plans, including control efforts where possible. Studies of the interactions of the harlequin ladybirds with native ladybirds and other beneficial species will enable us to gain a better understanding of the impacts of the harlequin ladybird on the native biodiversity.
Data availability
The datasets analysed during the current study are available from the corresponding authors on reasonable request.
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Acknowledgements
We are thankful to all citizen scientists for data provision. Special thanks towards the Greek naturalist communities of Alientoma, in “Insects of Greece and Cyprus Facebook group” and iNaturalist Citizen Science Platform. We also thank Kamil Erguler for his feedback on the methodology. This work is based on a Virtual Mobility (VM) Grant that Ms Angelidou obtained from COST Action CA17122—Alien CSI, supported by COST. Article publication fees were covered by COST Action CA17122—Alien CSI, supported by COST (European Cooperation in Science and Technology), www.cost.eu and EMME CARE project, the European Union’s Horizon 2020 research and innovation programme under Grant Agreement No. 856612 and the Cyprus Government. Helen Roy is partly supported through Natural Environment Research Council award number NE/R016429/1 as part of the UK-SCAPE programme delivering National Capability. Finally, we would like to thank Darwin Plus initiative, for funding Ioanna Angelidou and Jakovos Demetriou (DPLUS101 and DPLUS124).
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Conceptualisation (IA, JD, HER, AFM), Methodology (IA, JD, MC, HER, AFM), Software (IA, JD, MC, EK, CK, KK), Formal analysis (IA, JD, MC), Investigation (IA, JD, MC, EK, CK, PG, KK, DCK, QG, HER, AFM), Resources, Data Curation (IA, JD, MC, EK, CK, PG, KK, DCK, QG, HER, AFM), Writing—Original draft (IA, JD, MC), Writing—Review and Editing (IA, JD, MC, EK, CK, PG, KK, DCK, QG, HER, AFM), Visualisation (IA, JD, MC, EK, CK, KK), Supervision (DCK, HER, AFM), Project Administration (DCK, HER, AFM), Funding Acquisition (HER).
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Angelidou, Ι., Demetriou, J., Christou, M. et al. Establishment and spread of the invasive ladybird Harmonia axyridis (Coleoptera: Coccinellidae) in Greece: based on contributions from citizen scientists. Biol Invasions 25, 889–900 (2023). https://doi.org/10.1007/s10530-022-02955-8
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DOI: https://doi.org/10.1007/s10530-022-02955-8