Abstract
Plastic waste has a negative impact on marine ecosystems and the quantity of this source of anthropogenic pollution continues to increase. Several studies have investigated plastic biodegradation using various microorganisms. In this study, we isolated fungi from polyethylene terephthalate (PET) waste on Korean seacoasts and evaluated their ability to degrade plastic by comparing the diameters of the clear zones they formed on polycaprolactone (PCL) agar. We isolated 262 strains from 47 plastic waste sources and identified 108 fungal species via molecular methods. The PCL agar assay revealed that 87 species presented with varying degrees of PCL degradation capacity. Among them, certain fungal species were strong PCL degraders. The present study demonstrated the possibility that some fungi inhabiting plastic could potentially degrade it in the marine environment. We believe that the discoveries made herein lay theoretical and practical foundations for the development of novel bioremediation systems for marine plastispheres and help mitigate the environmental pollution issues related to plastic wastes.
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Introduction
Plastic products are extensively and widely used, and the plastic polymer compositions vary depending on the intended applications of the products they are used to fabricate. Common plastics include high-density polyethylene (HDPE), low-density polyethylene (LDPE), and polyethylene terephthalate (PET) (Plastics Europe, 2021). As of 2020, approximately 367 million tonnes of plastic products were produced. The plastic production volume has substantially increased since the 1990s (Plastics Europe, 2021). However, only about 9% of all plastic waste is recycled, and as much as 60% of it is buried in a landfill or discarded as litter in terrestrial environments (Geyer et al. 2017). Most marine plastic waste consists of improperly disposed terrestrial plastic waste that has entered the oceans via rivers, wastewater outflows, wind, and tides. In 2010, 4–12 million tonnes of marine plastic waste originated from land (Jambeck et al. 2015). Additionally, about 1.15–2.41 million tonnes of marine plastic waste originated from river (Lebreton et al. 2017).
Plastic waste accumulation has had a direct and indirect negative impact on marine ecosystems. Plastic pieces are ingested by marine animals and damage their internal organs (Ahrendt et al. 2020; Wright et al. 2013). Furthermore, wave action, weathering, and other processes break down plastic pieces into microplastics which are the plastic wastes that were degraded into smaller fragments and fibers (Thompson et al. 2004), causing other more hazards. Microplastics float on ocean surfaces and contain Persistent Organic Pollutants (POPs), which are endocrine disruptors that hinder the survival rate of marine organisms (Rios et al. 2007). Microplastics also transport microbial pathogens and alien species, hazardous to marine ecosystems in other regions (Arias-Andres et al. 2018; Beloe et al. 2022; Bowley et al. 2021). Thus, plastic in marine ecosystems has become a serious environmental issue. However, there are no policies or solutions in place that effectively mitigate the plastic waste problem. Recent studies have explored chemical degradation, recycling, and biodegradation as potential marine plastic waste remediation measures.
Much research attention has been directed toward plastic waste degradation by microorganisms. Plastic waste has persisted in natural environments for decades. Plastic debris that is inhabited and partially decomposed by the microbial community is now referred to as the “plastisphere” (Zettler et al. 2013) and numerous different microorganisms are found in it (Hirota et al. 2021; Amaral-Zettler et al. 2020). Some of them were reported to degrade plastic by various kinds of tests (Badahit et al. 2018; Sangeetha Devi et al. 2019; Hou et al. 2022; Kumari et al. 2019; Muhonja et al. 2018; Yamada-Onodera et al. 2001): and enzymatic activities involved in plastic degradation have been investigated extensively (Temporiti et al. 2022). Nevertheless, prior research has focused mainly on plastic-decomposing bacteria. Fungi comprise only about 3% of all eukaryotic organisms in the plastisphere, although they play a vital role as decomposers in the environment (Rogers et al., 2020). Numerous plastic-degrading fungi have been detected and identified in the landfill (terrestrial) plastisphere including Aspergillus spp. (Cosgrove et al. 2007; Muhonja et al. 2018; Zahra et al. 2010), Fusarium spp. (Kanelli et al. 2015; Zahra et al. 2010), and Penicillium simplissimum (Yamada-Onodera et al. 2001). Previous studies on plastic-degrading fungi in marine environments concentrated primarily on several specific taxa such as Aspergillus sp. (Sarkhel et al. 2020) and Zalerion maritimum (Paço et al. 2017).
Previously, we isolated different fungi from various substrates in marine environments such as sailfin eggs (Park et al. 2018) and microalgae (Lee et al. 2019; Park et al. 2016). Many of these fungi had high enzymatic activity (Lee et al., 2019; Park et al. 2015a, 2019). Since these studies detected the fungal ability to degrade complex organic matter, it was expected that plastic-isolated fungi could decompose plastic substrates. A metabarcoding analysis revealed that a wide array of fungi survived on plastics collected from seawater (Lacerda et al. 2020, Davidov et al. 2020) and the sea floor (De Tender et al. 2017). We hypothesized that different fungi can inhabit plastic waste and most of them actively participate in plastic degradation. In the present study, therefore, we investigated fungal diversity in PET waste collected from seacoasts and used a polycaprolactone (PCL) degradation assay to evaluate their capacity to degrade plastic. PCL is a biopolymer that has been extensively used in biodegradation research as a surrogate for non-degradable polymers. Its usage in fungal incubation varies from film/sheet form (Benedict et al. 1983; Fukushima et al. 2010), or agar from as emulsified substance (Lee et al. 2021).
Materials and methods
Sampling
Forty-seven PET wastes such as PET bottles and PET cups were collected from 15 sites along the western and southern sea coast of the Republic of Korea in April, 2018 (Fig. 1). We collected PET bottles and PET cups with intact shape to prevent wrong sample collection. The PET surfaces were cleansed of debris by washing with artificial seawater (ASW). Each PET waste sample was cut with sterilized scissors into 27 pieces each 1 cm2 in area. To isolate the fungi, nine pieces per sample were placed in dichloran rose bengal chloramphenicol agar (DRBC; Difco, Sparks, MD, USA), glycerol yeast extract agar (GYA; 1 g L−1 glucose, 0.1 g L−1 yeast extract, 0.5 g L−1 peptone, and 15 g L−1 agar), and potato dextrose agar (PDA; Difco, Sparks, MD, USA) supplemented with ASW (purified from seawater in South Korea; salinity = 32.0%). The plates were incubated at 25 °C for 7–14 d. Pure fungal colonies were then transferred to new PDA + ASW plates. Pure fungal strains were stored in 20% (v/v) glycerol at –80 °C and deposited in the Seoul National University Fungus Collection (SFC).
Molecular identification
The fungal isolates on PDA were grouped according to their morphological characteristics such as texture, color, colony size, and sporulation. At least one strain was selected from each group for molecular identification. Genomic DNA was extracted by a modified cetyltrimethylammonium bromide (CTAB) method (Rogers and Bendich 1994). PCR amplification of the internal transcribed spacer (ITS) region was performed using ITS1F/ITS4 primers (Gardes and Bruns 1993; White et al. 1990) and AccuPower PCR Master Premix (Bioneer Co., Daejeon, Republic of Korea). All representative strains were identified down to the genus level based on their ITS sequences. The strains within certain genera were identified to the species level using various protein-coding gene analyses and different primer sets. Actin (act) was amplified using ACT-512F/ACT-783R (Carbone and Kohn 1999) or ACT1Fd/ACT1Rd (Aveskamp et al. 2009; Groenewald et al. 2013) whilst β-tubulin (BenA) was amplified using Bt2a/Bt2b (Glass and Donaldson 1995). PCR was performed in a C1000 Thermal Cycler (Bio-Rad Laboratories, Hercules, CA, USA) under previously described conditions (Park et al. 2015b). PCR amplicons were checked with 1% agarose gel and purified with an Expin™ PCR Purification Kit (GeneAll Biotechnology, Seoul, Korea) according to the manufacturer's instructions. DNA was sequenced at Macrogen (Seoul, Republic of Korea) in an ABI PRISM 3700 Genetic Analyzer (Life Technologies, Gaithersburg, MD, USA).
All sequences were proofread and edited with MEGA7 (Kumar et al. 2016) and deposited in GenBank (Supplementary Table 2). For the phylogenetic analysis, the type sequences of the reference species were retrieved from GenBank (Supplementary Table 3) and aligned with the sample sequences for each locus with MAFFT v. 7 (Katoh and Standley 2013) using the default parameters. Maximum likelihood phylogenetic analyses were performed on each gene (ITS, act, BenA) using RAxML (Stamatakis 2006), the GTRGAMMA evolution model, and 1,000 bootstrap replicates.
PCL degradation test on agar plate
The PET-degrading ability was determined for one to nine representative strains of each fungal species (Table 1) by measuring the clear zones formed in polycaprolactone (PCL) media. The PCL agar was prepared according to a previously reported method (Lee et al. 2021) and consisted of a 1% (w/v) emulsified PCL suspension (pellet form, 3 mm in diameter; Sigma-Aldrich., St. Louis, MO, USA) in acetone plus distilled water (10% of acetone volume). The PCL suspension was added to an autoclaved medium comprising a 0.8% (w/v) yeast nitrogen base (Difco-Becton Dickinson, Broken Bow, NE, USA), 1.5% (w/v) agar, and distilled water, then poured into 90 mm-Petri dishes.
Representative strains of each fungal species identified were inoculated with a 4-mm hole punch at the center of each agar plate. Clear zone formation was evaluated by measuring the distance between the margin of the clear (transparent) zone and that of the colony after 7 d incubation at 25 °C. All clear zones were measured in triplicate and averaged. PCL degradation by each species was determined from the averages of the clear zone lengths of all representative strains of the same species. For species with multiple tested strains, the standard deviations of the average clear zone lengths of all strains within the same species were also calculated.
Results
Identification and diversity analysis
A total of 262 fungal strains were isolated from 47 PET wastes. Multiple strains of the same species derived from a single PET waste were treated as a single strain. One to nineteen fungal strains were isolated per PET. Depending on the isolation medium used (DRBC, GYA, or PDA), different numbers of fungal strains were isolated from the same PET waste (Fig. 1, Supplementary Table S1). All fungal strains were grouped into 108 taxa based on their morphological features and ITS sequencing results (Fig. 2). Forty-seven taxa were identified to the species level based on their protein-coding genes. The actin gene was used to identify Cladosporium species whilst the β-tubulin gene was used to identify Aspergillus, Diaporthe, Didymella, Epicoccum, Juxtiphoma, Neodidymelliopsis, Nothophoma, Penicillium, Pestalotiopsis, Remotididymella, and Talaromyces species (Table 1, Supplementary Figure S1). Based on the ITS sequences alone, 47 taxa were confirmed to the species level whilst 14 others were identified to the genus, family, and order levels.
All 108 species detected belonged to the Ascomycota and were classified into 15 orders and 46 genera (Table 1, Fig. 2). Pleosporales was the dominant order and included 44 species. It was followed by Cladosporiales and Eurotiales with 13 species each (Fig. 3A). Cladosporiales only included the genus Cladosporium whereas Eurotiales comprised the genera Penicillium, Aspergillus, and Talaromyces. The latter two included three and one species, respectively, and nine Penicillium species were identified (Fig. 3B, Table 1). Eleven different species were isolated from at least five PET wastes (Fig. 3C). Alternaria alternata was isolated from 21 different PET waste sources followed by Cladosporium ramotenellum (16 PET wastes) and Paradendryphiella arenariae (14 PET wastes).
Fungal PCL degradation activity
A PCL degradation test was performed on 146 representative strains of 108 species (Supplementary Table S3). The clear zone lengths of the fungal strains were in the range of 0–13.96 mm. Based on the average clear zone lengths, fungal PCL degradation ability was categorized into four levels, namely, no degradation (0 mm: 0), weak (0 < ( +) ≤ 5 mm), moderate (5 < (+ +) ≤ 10 mm), and strong (10 < (+ + +) ≤ 15 mm) (Fig. 4). Five species exhibited strong PCL degradation, 18 species showed moderate PCL degradation, 64 species presented with weak PCL degradation, and 21 species did not degrade PCL at all (Table 1). There was also intraspecies variation. The PCL degradation capacities of eight Alternaria alternata strains ranged from 12.88 mm (NP321) to 3.32 mm (NP044). In most cases, however, all tested strains of the same species were similar in terms of their PCL degradation ability.
Phaeophleospora eucalypticola had the strongest PCL degradation ability (clear zone length = 13.96 mm). Four Cladosporium species also showed strong PCL degradation activity. Cladosporium allicinum had the widest clear zone (13.92 mm) followed by C. xanthochromaticum (11.37 mm), C. rectoides (10.34 mm), and C. tenuissimum (10.21 mm). Seventeen species of moderate PCL-degrading fungi were classified into ten genera including two Alternaria spp., two Aureobasidium spp., two Phaeosphaeria spp., five Cladosporium spp., and each one species of Cytospora, Epicoccum, Neodevriesia, Nothophoma, Sarocladium, Sphaeropsis (Table 1). Cladosporium species showed relatively high PCL degradation activity among the moderate PCL degraders.
Weak PCL-degrading fungi included 64 species. They were classified as 30 genera (Table 1). Didymella, Epicoccum, and Remotiodidymella (Didymellaceae) showed relatively weak PCL degradation as no strain produced a clear zone wider than 5 mm. The species in the Eurotiales exhibited very weak PCL degradation ability. None of the Penicillium strains produced clear zones wider than 1 mm (Fig. 4, Table 1). Aspergillus and Talaromyces showed higher PCL-degrading activity than Penicillium. The lengths of the average clear zones produced by Aspergillus and Talaromyces were 2.30 and 3.31 mm on average, respectively. Most species in the Order Amphisphaeriales were weak PCL degraders (Table 1).
Whereas most fungi could degrade PCL, certain species isolated from 27 PET waste sources failed to form clear zones on PCL agar. Most of them were isolated along with other PCL-degrading fungi (Fig. 5). Weak and moderate PCL-degrading fungi were detected in most samples. Weakly PCL-degrading fungi were particularly abundant in PET samples Nos. 20, 36, 37, 43, and 44. By contrast, strong PCL degrading fungi did not predominate in any PET samples and always co-occurred either with weak or moderate PCL-degrading fungi or with those that did not degrade PCL at all.
Discussion
We isolated fungi from marine PET wastes and tested PCL degradation to discover competent plastic-degrading fungi in the marine plastisphere and determined whether they could degrade PET. Numerous fungi were isolated despite the limited number of PET wastes examined here. They resembled that reported in a previous study on fungal diversity in the marine environment (Jones et al. 2015; Kwon et al. 2021). Acremonium fuci was isolated from seaweed in Europe and North America (Zuccaro et al. 2004), and several Cladosporium species, such as C. perangustum, C. tenuissimum, and C. xanthochromaticum were found in marine sediments (Luo et al., 2020). Paradendryphiellla arenariae were reported from various microalgae in Europe (Dela Cruz et al. 2006), and a number of other fungal species including Fusarium equiseti, Nigrospora oryzae, Penicillium oxalicum, and Trichoderma harzianum were found in sea sand, mudflats, and seaweeds (Heo et al. 2019; Park et al. 2019). The fungal species detected in this research were also similar to those in other marine and terrestrial plastisphere. Many species in Pleosporales were detected in plastisphere of the Antarctic Ocean (Lacerda et al. 2020) and the North Sea (De Tender et al. 2017). The Aspergillus, Chaetomium, Epicoccum, Fusarium, and Trichoderma species were identified in the terrestrial plastisphere (Kemona and Piotrowska 2016; Ye et al., 2021).
Several putative plastic-degrading fungi were identified by the PCL agar degradation test. Approximately 81% of all identified species formed clear zones and were, therefore, potential plastic biodegraders. PET degradation-associated enzyme activity was detected in PCL-degrading fungus (Nyyssölä et al. 2013). Hence, the species identified here could conceivably decompose PET and other plastics as well. Cladosporium included 13 PCL-degrading species of which four and nine had strong and moderate PCL-degrading activity, respectively. Prior research confirmed that several Cladosporium strains effectively degraded other substrates, such as polyurethane (Bonhomme et al. 2003; Brunner et al. 2018; Srikanth et al. 2022). Therefore, Cladosporium species could degrade plastic wastes in the marine environment. Aureobasidium pullulans, which displayed relatively good polyurethane degradation were also reported previously (Crabbe et al. 1994). Phaeophleospora eucalypticola showed the strongest PCL-degrading activity, but this species has not been given much attention to its degrading abilities. Further research on P. eucalypticola may reveal its full potential for the degradation of plastics. It is reported that various enzymes, such as cutinase, laccase, and esterase from fungi were used in degradation of PET (Anbalagan et al. 2021; Khan et al. 2022), and this may explain the high biodiversity in relatively small number of plastic samples.
In this study, most of the highly abundant species showed low levels of PCL degradation ability. Paradendryphiella arenariae, Pleosporales sp.1, and Acremonium cf. fuci were very abundant but relatively weak PCL degraders. In contrast, the fungi with the strongest degradation ability were far less abundant. Phaeophleospora eucalypticola and C. xanthochromaticum showed strong PCL degradation capacity, but only two strains were isolated from 47 plastic wastes. Each PET waste had many fungal species with low level of PCL degradation but generally possessed only one fungal species that was highly effective. This result allowed us to infer that varying fungal species on plastic waste performed different roles. The abundant weak plastic degraders may grow on plastic wastes to utilize materials primarily degraded by mechanical or biological process. The initial breakdown mechanism of plastics may include polymer oxidation, which increases the hydrophilicity of plastics, weakens their bonds and mechanical structures, and facilitates secondary colonizer access (Oberbeckmann and Labrenz 2020). Microorganisms also gradually degrade other complex molecules such as lignin (Janusz et al. 2017) and anthropogenic (synthetic) polymers (Chen et al. 2020). Hence, the colonizing mechanisms of various microbes strongly influence fungal diversity on plastic wastes. Species with weak or no PCL-degrading ability may have been isolated from the primary colonizers as fungicolous fungi. The inhabitation of fungal species on other plastic-colonizing microorganisms has previously been reported (Webb et al. 2000). Some Hypocreales and Pleosporales species are known to obtain their nutrients either commensally or parasitically from other fungi (Sun et al. 2019). Most species in Hypocreales and Pleosporales showed low PCL degradation ability, proving that they get their nutrients from alternative sources.
In conclusion, the present study showed that numerous fungi inhabit PET wastes in the marine environment. Certain fungal taxa including Phaeophleospora eucalypticola, Alternaria spp., Aureobasidium spp., and Cladosporium spp. have strong PCL degrading activity. Fungi with low level of PCL degrading ability were abundant and co-occurred with one of strong PCL degrader. The wide diversity and ranges of abundance, and plastic-degrading capacity of fungi even on small quantities of PET suggest that the various fungal taxa play different roles in marine plastic waste decomposition. In future research, we will aim to clarify the functions of each of these fungal taxa in order to develop a strategy for effective and efficient plastic waste degradation in the marine environment.
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This research was supported by the National Marine Biodiversity Institute of Korea (2022M01100).
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Sung Hyun Kim performed the experiment and overall manuscript writing, Jun Won Lee, Ji Seon Kim, and Wonjun Lee participated in writing the manuscript, Myung Soo Park supported the experiment design, and Young Woon Lim conducted the process and reviewed the manuscript.
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Supplementary file 1 Table S1: Collected PET wastes and isolated fungal species. Representative strains and cultures whence fungal species were isolated are also indicated. Table S2: Strains and their GenBank accession numbers used for phylogenetic analyses in this study. Table S3: Clear zone data for all tested fungal strains. The degradation abilities are categorized into four level
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Kim, S.H., Lee, J.W., Kim, J.S. et al. Plastic-inhabiting fungi in marine environments and PCL degradation activity. Antonie van Leeuwenhoek 115, 1379–1392 (2022). https://doi.org/10.1007/s10482-022-01782-0
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DOI: https://doi.org/10.1007/s10482-022-01782-0