Introduction
Bjerkandera is a common white-rot fungus found worldwide [16]. The genus Bjerkandera, erected by Karsten in 1876, is characterized by soft, pileate basidiocarps. The type species, B. adusta, exhibits a gray to black tube layer, which contrasts with a white context [22]. The two species in this genus, B. adusta and B. fumosa, are both distributed in North America, Europe, and Asia [9, 17, 22]. In Korea, B. adusta was first reported in 1936 as Polyporus adustus [29], and B. fumosa was officially recorded in 1994 as part of an exhaustive list of Korean wood-rooting fungi [12]. Systematic taxonomic descriptions of both species were documented in 2010 [15].
Bjerkandera plays an ecologically important role in the global carbon cycle by growing on and decomposing dead hardwood trees [6], but also has negative impacts, such as causing timber damage and interfering with the cultivation of culinary mushrooms [1]. Additional to its effectiveness in decaying lignin, Bjerkandera can degrade common anthropogenic pollutants, such as various polycyclic aromatic hydrocarbons [10]. Such notable enzymatic activities led scientists to explore the industrial application of Bjerkandera; B. adusta has demonstrated an ability to decolorize synthetic dyes, which can be applied to bioremediation [4]. The interest in Bjerkandera has been recently renewed, as the whole genome of B. adusta has been sequenced by the Joint Genome Institute (JGI) as part of the 1,000 Fungal Genomes project [2].
Superficially, B. adusta and B. fumosa are similar and are easily confused for each other, especially when basidiocarps are immature, but morphological characters have been identified to distinguish these two species: fruiting body shape, pore size, context and tube thickness, and basidia and spore size [22]. The ease of misidentification is of greater concern for industrially important B. adusta strains that are currently preserved as cultures and/or dried specimen fragments; species identification cannot be checked, as distinguishing morphological characters are no longer present. If the specimens were misidentified, subsequent data, such as DNA sequences, would be incorrectly identified and this problem maintained in public databases and the scientific literature.
DNA barcoding is a useful tool to help classify species and identify cryptic diversity [11] that depends on comparison to public databases. When species identifications in public databases are incorrect, additional samples will be misidentified and the problem perpetuated. In fact, about 20% of species identifications of DNA sequences in public database were estimated to be incorrect or questionable [3, 18].
In this study, we used the genus Bjerkandera as an example to quantify, characterize, and correct species misidentifications in GenBank. We chose Bjerkandera because (i) there are only two species, (ii) the two species are highly similar and easily misidentified by non-specialists despite distinguishing morphological characters, and (iii) the results have implications to genomic and biotechnological research. To complete these goals, we first identified true B. adusta and B. fumosa samples through rigorous morphological observation, followed by DNA sequencing to build a framework for comparison. Two molecular markers, the internal transcribed spacer (ITS) and the 28S nuclear ribosomal large subunit (LSU), were sequenced since they are the two most common genes used in fungal systematics [5, 23, 24]. Lastly, all ITS and LSU sequences in GenBank, which have been identified as or show high sequence similarity to Bjerkandera, were evaluated against correctly identified B. adusta and B. fumosa sequences.
Materials and Methods
Specimens and Microscopic Observation
All specimens used in this study were collected throughout the Korean Peninsula between 1989 and 2013, dried, and deposited in the Seoul National University Fungal Collection (SFC) (Table 1). Specimens labeled as Bjerkandera were rigorously reexamined based on distinguishing morphological characters to determine their true species identification. Microscopic features were observed using an Eclipse 80i light microscope (Nikon, Japan). After specimen identification was confirmed using DNA sequence analyses (methods below), the macro- and microscopic features of the specimens were characterized in detail.
Table 1.Specimens identified by morphological observations, but not sequenced: B. adusta: SFC19891015-20, SFC19900807-21, SFC19950511-07, SFC20010221-25, SFC20011114-06, SFC20030612-01, SFC20030612-04 B. fumosa: SFC19891017-96, SFC19990422-27
DNA Extraction, PCR Amplification, and Sequencing
A small piece of fungal tissue from each dried specimen was placed in a 1.5 ml tube containing 2× CTAB buffer and ground with a plastic pestle. Genomic DNA was extracted with a modified CTAB extraction protocol [20]. The ITS region was amplified using the primers ITS1-F and ITS4-B [8], and the LSU region was amplified using the primers ITS3 and LR5 [30, 31]. The amplification was performed in a C1000 thermal cycler (Bio-Rad, USA) using the AccuPower PCR premix (Bioneer Co., Korea) in a final volume of 20 μl containing 10 pmol of each primer and 1 μl of genomic DNA. Thermal cycler conditions for PCR followed Park et al. [19]. After verification via gel electrophorese on a 1% agarose gel and the PCR product purified using the Expin PCR Purification Kit (GeneAll Biotechnology, Korea), DNA sequencing was performed with an ABI3700 automated DNA sequencer (Applied Biosystems, USA) at Macrogen (Seoul, Korea).
Sequence Analysis
For all molecular analyses, alignments were performed using MAFFT [13], and manually adjusted in MEGA5 [26]. For the ITS and LSU datasets, neighbor-joining (NJ) analyses were performed using MEGA5, and maximum likelihood (ML) analyses were performed using RAxML ver. 8.0.2 [25]. NJ analyses were performed using p-distances, substitutions including transitions and transversions, pairwise deletion of missing data, and 1,000 bootstrap replicates. ML was performed using the combined rapid bootstrap and search for the best-scoring ML tree analysis, the GTRGAMMA model of sequence evolution, and 1,000 bootstrap replicates. Both rooted and unrooted analyses were performed on the datasets to enhance our ability to identify distantly related species that were mislabeled as Bjerkandera. Based on a previous phylogenetic study, Phanerochaete chrysosporium was selected as the outgroup for rooted phylogenetic analyses [14]. Intra- and interspecific pairwise distances were calculated in MEGA5 using the p-distance model, substitutions including transitions and transversions, and pairwise deletion of gaps.
Our analysis had three steps. First, phylogenetic trees for ITS and LSU were built using only specimens of B. adusta and B. fumosa which identities were verified using morphology. Both species were reciprocally monophyletic for both ITS and LSU, with low intraspecific and high interspecific variation, validating the morphological identification. These sequence data and the phylogenetic tree served as the framework to which we determined whether GenBank sequences are misidentified.
Second, we downloaded all sequences resulting from the search query “Bjerkandera” for GenBank. We also included ITS and LSU data from the single JGI specimen used in the genome sequencing project. Sequences with over 90% coverage of the ITS region (500-600 bp) and 5’ partial LSU region (including D1 and D2 regions, 580-650 bp) were retained for further analyses. NJ and ML analyses were performed on the ITS and LSU alignments to classify the sequences; if sequences fell within the clades of B. adusta or B. fumosa, they were classified as such. In the phylogenetic tree, sequences that fell outside clades of the two Bjerkandera species were considered misclassified. Through this process, we validated the authenticity of sequences annotated as Bjerkandera in GenBank.
Third, we used BLAST to identify sequences highly similar to sequences identified as B. adusta and B. fumosa from the previous step. This set of sequences represents ones that are unidentified or mislabeled as different genera. We selected sequences based on similarity and coverage. Based on intraspecific p-distances of B. adusta and B. fumosa from step two (ITS: ˂6%; LSU: ˂3%), to be conservative, we downloaded all sequences that had a p-distance of ˂8% (92% similarity) for ITS and ˂5% (95% similarity) for LSU. To exclude short sequences, we removed those that had coverage of ˂80%. As in the previous step, NJ and ML analyses were performed on the two alignments to classify sequences. All work with GenBank was performed on April 2, 2014.
We performed an additional phylogenetic analysis to investigate the relationship between Thanatephorus cucumeris (or anamorphic name Rhizoctonia solani) and Bjerkandera adusta . BLAST search resulted in a substantial number of ITS sequences in GenBank annotated as T. cucumeris that were highly similar to B. adusta. We downloaded all ITS sequences labeled as T. cucumeris or R. solani and determined their phylogenetic relationship with Bjerkandera using NJ analysis as described above. For this analysis, Waitea circinata (or anamorphic name Rhizoctonia zeae) was used as the outgroup [27].
Results
Morphological and Molecular Analyses of Korean Bjerkandera Specimens
All 25 SFC specimens identified as Bjerkandera were used in the preliminary portion of this study. Initial identification of specimens was 18 B. adusta and 7 B. fumosa (Fig. 2A). Each specimen was reexamined based on distinguishing morphological characters between the two species and compared with published data (Table 2). Clear differences between the two species were observed (Fig. 1). The final identification recognized 18 B. adusta and 6 B. fumosa. One specimen of B. fumosa proved not to be Bjerkandera and was excluded from the study.
Table 2.aNorth American data from Gilbertson and Ryvarden [9] and European data from Ryvarden and Gilbertson [22].
Fig. 1.Morphology of (A) Bjerkandera adusta and (B) B. fumosa. (a) Upper surface of basidiocarps, (b) pore surface, and (c) microscopic features. Microscopic features of basidiospores, basidia, and generative hyphae with clamp connection are arranged from top to bottom. Scale bar = 1 cm (a, b), 10 μm (c).
Fig. 2.Summary of methodology and misidentifications. (A) Specimens of Bjerkandera at SFC. (B) Summary of “Bjerkandera” sequences in GenBank (and JGI). Names inside the dashed boxes indicate original names in GenBank. (C) Summary of all B. adusta and B. fumosa sequences identified in this study. Names inside the dashed boxes indicate the original identifications in GenBank.
Owing to the old age of many specimens, DNA was not successfully sequenced for all samples. The ITS and LSU regions were successfully amplified and sequenced for 11 B. adusta and 4 B. fumosa. Phylogenetic relationships inferred from the ITS and LSU, using both NJ and ML methods, were similar and exhibited a clear distinction between the two species (Figs. S1-S5). For ITS, the intraspecific variation of Korean B. adusta and B. fumosa was 0.0–0.55% and 0.0%, respectively, whereas the interspecific variation was 5.15–5.89%. For LSU, the intraspecific variation of Korean B. adusta and B. fumosa was 0.0–0.16% for both species, and the interspecific variation was 1.44–1.78%.
Validity of Bjerkandera Sequences in GenBank
The query for ITS and LSU sequences labeled as Bjerkandera in GenBank (including JGI sequences) recovered 95 and 29 sequences, respectively. Of the 95 Bjerkandera ITS sequences, 75 were labeled as B. adusta, 4 as B. fumosa, and 16 as Bjerkandera sp. For the B. adusta records, one sequence used an old name (B. adustus), and one was misspelled (B. adjusta). Based on the phylogenetic analyses, 10.5% (10/95) of the sequences were shown to be misidentified (Fig. 2B). Five of these misidentified sequences (B. adusta: JN861758, JN628105; Bjerkandera sp.: HQ596906, KF578081, KJ174457) fell outside the clades of B. adusta and B. fumosa, so we removed them from subsequent analyses (Figs. S2-S3). Of the Bjerkandera sp. sequences, 12 and 1 were identified as B. adusta and B. fumosa, respectively. The intraspecific variation of ITS for B. adusta and B. fumosa was 0.0–5.48% and 0.0–1.86%, respectively, and the interspecific variation was 3.53–7.85%.
Of the 29 Bjerkandera LSU sequences, 26 were initially identified as B. adusta, zero as B. fumosa, and 3 as Bjerkandera sp. Based on phylogenetic analyses, 13.8% (4/29) of the sequences were shown to be misidentified (Fig. 2B). Two sequences (B. adusta: AJ406530; Bjerkandera sp.: KF578081) were inferred to be unrelated to Bjerkandera and removed from subsequent analyses (Figs. S4-S5). The intraspecific variation of LSU for B. adusta and B. fumosa was 0.0–2.45% and 0.0–0.55%, respectively, whereas the interspecific variation was 1.14–2.38%.
Misidentified and Unidentified Sequences in GenBank
Based on our search criteria (see Materials and Methods section), a total of 121 unique ITS and 15 unique LSU sequences were identified to be highly similar to B. adusta and B. fumosa and included in the final phylogenetic analyses. For ITS, 90 sequences were shown to be B. adusta and 1 B. fumosa (boldface in Fig. 2C). The remaining 30 sequences were not Bjerkandera. For B. adusta, 30 sequences were previously identified as T. cucumeris (or anamorphic name R. solani), 2 Trichaptum abietinum (FJ768676, U63474), 1 Entrophospora sp. (AY035664), 1 Ceratobasidium stevensii (AJ427405), 1 Ganoderma lobatum (JQ520165), and 55 unidentified sequences. For B. fumosa, one sequence was an unidentified species (FJ820598). For LSU, two sequences were misidentified and shown to be B. adusta: Antrodia malicola (AY333836) and an unidentified fungal species (JQ249221). The remaining 13 sequences were not closely related to Bjerkandera. All GenBank sequences used in this study (retrieved on April 2, 2014), their database identification, and corrected species information are listed in the Table S1.
Discussion
The genus Bjerkandera can be easily recognized by a blackish to brown tube layer contrasting with a white context [22], whereas the two species B. adusta and B. fumosa can be distinguished by pore size, thickness of context and tube layer, and size of basidia (Table 2). Despite the presence of distinguishing morphological characters for B. adusta and B. fumosa, misidentification is common, especially for those not specializing in taxonomic classification of fungi. This problem of misidentification is made worse since both species are sympatric and have a global distribution [9, 17, 22]. In this study, we have rigorously reexamined Bjerkandera specimens from Korea and verified the distinguishing morphological characters separating these two species (Fig. 1, Table 2). We also found that DNA data are useful to distinguish between B. adusta and B. fumosa, as phylogenetic analyses of ITS and LSU both recovered reciprocally monophyletic groups; thus molecular identification based on either of these two DNA markers is sufficient to distinguish Bjerkandera species.
DNA data are a powerful tool to aid in species identification. An approach such as DNA barcoding has become popular for species identification because it is easy and straightforward for a non-specialist to use [11]. However, the efficacy of DNA barcoding depends on public databases having satisfactory taxonomic sampling and sequences that are correctly identified [18]. We found that the number of misidentified sequences of Bjerkandera in GenBank is substantial. More ITS sequences (95 sequences) were present in GenBank compared with LSU (29 sequences), and as such, the problem of misidentification was more evident for ITS sequences. Our discussion of misidentification herein focuses on ITS.
The results revealed that B. fumosa was more commonly misidentified as B. adusta (n = 4) as opposed to the opposite case (n = 1) (Fig. 2B). This is likely due to B. adusta being more common in the environment compared with B. fumosa [22], and B. adusta being the focus of more academic and industrial research. In addition to misidentified sequences, there were many unidentified sequences that, through the phylogenetic analyses, were shown to be B. adusta or B. fumosa. Recognition of these previously misidentified and unidentified sequences of B. adusta (90 sequences) and B. fumosa (1 sequence) nearly doubles the number of Bjerkandera ITS sequences in GenBank.
Of the misidentifications between genera, some sequences originally identified as T. cucumeris (or anamorphic name R. solani) were later re-identified as B. adusta. Morphologically, these two species are different in culture morphology, with B. adusta possessing hyaline hyphae with conidia, and T. cucumeris having brownish hyphae without conidia [21]. The problem of identification was raised in studies exploring fungal diversity from air, soil, and industrial wastes. Several authors explicitly described the difficulty distinguishing between Bjerkandera and Thanatephorous using DNA data, due to the highly similar sequences of the two different species uploaded in GenBank [e.g., 7, 21]. Other previous studies also raise the problem of identification using environmental DNA data and BLAST for identification [28]. To clarify the issue, we performed a phylogenetic analysis of our Bjerkandera ITS data, adding data from T. cucumeris. We found that 1,024 sequences of T. cucumeris formed a distinct group with high bootstrap support from the 30 sequences re-identified as B. adusta (Fig. S6). These results indicate that T. cucumeris and B. adusta are distinguishable with molecular data, and the problem was due to misidentified sequences.
For a small subset of sequences, Bjerkandera species were found to be misidentified as different wood decay fungi genera (Antrodia, Ganoderma, Trichaptum). Although the basidiocarps of Bjerkandera are morphologically distinct from these wood decay fungi, such misidentification may occur in the absence of fungal taxonomic expertise or apparent morphological distinctions (e.g., working with cultures, immature basidiocarps, or environmental samples).
These scenarios exemplify the importance of thorough morphological observation and correct identification of specimens/cultures before uploading associated DNA data to GenBank. Misidentification in groups such as Bjerkandera can have important implications to biotechnological research. Considering the interest Bjerkandera has attracted for various industrial applications, it is necessary that Bjerkandera cultures and stocks are molecularly verified for potential misidentification. For accurate comprehension of the evolution and mechanisms underlying enzymatic activities and optimum application of strains, precise taxonomy is paramount. This problem of misidentification perpetuated through public databases and future studies are not confined to Bjerkandera or wood-rotting fungi. We hope that researchers understand the responsibility of using a public database, and are prudent in accurate species identification and annotation before submitting sequence data for public use.
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