https://orcid.org/0009-0007-2981-8526
Figures
Abstract
This study aimed to characterize zoonotic yeasts from zebra dove (Geopelia striata) droppings in small farms in Songkhla province, Thailand. Four out of thirty-one isolates were found with morphology and biochemical test results like those of Cryptococcus spp. (12.9%) but they exhibited different results from the positive control in nested polymerase chain reaction (PCR); the first step with ITS1-ITS4 primers was negative, but the nested PCR step with CN4-CN5 was positive. All isolates were subjected to antifungal susceptibility testing. Only the Tip11 isolate showed high resistance to itraconazole and ketoconazole, with minimum inhibitory concentrations of >32.0 and 32.0 µg/mL, respectively, corresponding to high levels of minimum fungicidal concentrations for both drugs (>32 µg/mL). Consequently, Tip11 was selected as a representative of the contaminated isolates and subjected to whole-genome sequencing analysis. The results identified the Tip11 isolate as Hyphopichia burtonii (99.30% identity), with a genome length of 12,360,159 bp, a GC content of 35.16%, and 2,146 protein groups closely related to the Saccharomycetaceae family. It showed 43 candidates resistance genes of antifungal drugs mostly in azole and itraconazole group which related to the antifungal susceptibility testing. This is the first report of H. burtonii in zebra doves in Thailand. This yeast has been previously identified as a cause of human infection leading to peritonitis in Thailand, and its resistance to antifungal drugs may pose a public health risk. Therefore, the application of biosecurity measures on farms, such as regular removal of droppings and cage sanitization, should be implemented according to good agricultural practices.
Citation: Indoung S, Chumtong S, Prachantasena S, Wiriyaprom R, Surachat K, Pomwised R, et al. (2025) Whole-genome sequencing of Hyphopichia burtonii from isolated yeast recovered from zebra dove droppings in Thailand. PLoS One 20(6): e0315067. https://doi.org/10.1371/journal.pone.0315067
Editor: Hamida Hamdi Mohammed Ismail, Cairo University, Faculty of Science, EGYPT
Received: November 20, 2024; Accepted: May 28, 2025; Published: June 13, 2025
Copyright: © 2025 Indoung et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: Funding from Faculty of Veterinary Science, Prince of Songkla University Grant no. VET6604128S The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing of interests.
Introduction
The zebra dove (Geopelia striata) is renowned for its soft, staccato cooing calls, particularly in southern Thailand. These birds are popular as pets, especially for cooing competitions, making the breeding of zebra doves a thriving industry focused on producing birds with desirable vocal qualities. Many farmers rear zebra doves for sale and export to countries such as Indonesia, Malaysia, and Brunei. In Songkhla province, particularly in the Chana district, there are more than 170 zebra dove farms. The are large, moderate and small farms 30, 40, and 100, respectively. Collectively, approximately 40,000–50,000 zebra dove in the area [1]. From observation, individuals who raise zebra doves maintain close contact with the birds because the cages are often located inside or near their homes. Champion birds are usually kept as close to their owners as possible.
Various yeasts can infect pet birds, including Candida albicans, Aspergillus spp., Cryptococcus neoformans, and Trichomonas gallinae [2–4]. Avian gastric yeast (Macrorhabdus ornithogaster), the causative agent of proventriculitis in birds, is also found in these settings. Clinical signs of yeast infection can range from acute symptoms, resulting in sudden death, to chronic symptoms such as wasting, diarrhoea, or enteritis [5]. In psittacines, pathogenic yeasts have been isolated from faecal or cloacal samples in passeriformes, columbiformes, and falconiformes [6,7]. In one study, Candida catenulata and Candida albicans were the most frequently isolated species from cloacal swabs, faeces, and eggs of laying hens [8].
Birds harbour potentially pathogenic yeasts and can easily spread them into the environment via their faeces. Examples of zoonotic yeasts associated with bird droppings include Candida kefyr, Cryptococcus neoformans, and Cryptococcus gattii [9,10]. However, yeasts in the genus Hyphopichia have not been previously reported in zebra doves. Even rare cases have been documented in humans, but it is considered as a zoonotic yeast. This study was performed to analyze the assembly sequence of H. burtonii yeast obtained from whole-genome sequencing (WGS). The results may enhance understanding and raise awareness regarding this yeast.
Materials and methods
Fungal isolation
Four contaminated isolates, initially suspected to be zoonotic yeast (Cryptococcus spp.) were recovered from zebra dove droppings by Indoung et al [3]. The isolates were stored at −80°C in glycerol stock tubes and sub-cultured onto Sabouraud dextrose agar (SDA) (Oxoid, UK). Staining with India ink and crystal violet was performed to identify capsules and yeast budding. Candida albicans ATCC 90028 was used for quality control. The inoculum was prepared from 48-hour-old cultures suspended in 0.85% normal saline to a concentration of 0.5 McFarland (1–5 × 106 CFU/mL) using a spectrophotometer (absorbance = 530 nm) and diluted to 0.5–2.5 × 103 CFU/mL in RPMI 1640 broth medium [11].
Yeast DNA extraction
Genomic DNA was prepared for nested polymerase chain reaction (PCR) and WGS. The cryopreserved cells in 20% (v/v) glycerol were streaked onto SDA (HiMedia, India) and incubated at 37°C for 24 hours. Single fungal colonies were then cultured on SDA at 37°C for 48 hours. Genomic DNA was extracted from all single fungal colonies using the Presto™ Mini gDNA Yeast Kit (Geneaid Biotech, Taiwan) in accordance with the manufacturer’s instructions. The genomic DNA was analysed using 1% agarose gel electrophoresis, with quality and quantity measured to have an A260/280 ratio of 1.8–2.0 and a concentration of at least 50 ng/µL, determined by a NanoDrop™ 2000 spectrophotometer (Thermo Fisher Scientific, USA).
Nested PCR targeting Cryptococcus spp
To rule out Cryptococcus spp., pure DNA was subjected to modified nested PCR as previously reported by Mitchell [12]. In the first step of amplification, the primers ITS-1 (5′-TCCGTAGGTGAACCTGCGG-3′) and ITS-4 (5′-TCCTCCGCTTATTGATATGC-3′) were used, resulting in an amplicon of approximately 500–600 bp. The 12-µL PCR mixture contained 10 µL of KAPA PCR Ready Mix (Kapa Biosystems, Japan), 0.5 µL of 10 µM of each primer, and 1 µL of DNA template. The amplification conditions were as follows: heating at 94°C for 5 minutes, followed by 35 cycles of denaturation at 94°C for 30 seconds, annealing at 55°C for 45 seconds, and DNA extension at 72°C for 1 minute, with a final heating at 72°C for 7 minutes in a Bio-Rad Thermal Cycler (Bio-Rad Laboratories Inc., USA). The second reaction was prepared similarly to the first round, using the amplicon product from the first round as the template, with the primers CN-4 (5′-ATCACCTTCCCACTATT CACACATT-3′) and CN-5 (5′-GAAGGGCATGCCTGTTT GAGAG-3′), producing an amplicon of 136 bp. The reaction conditions were the same as those used in the first round.
Drug susceptibility
Testing was performed using the broth microdilution method, following the guidelines in Clinical and Laboratory Standards Institute (CLSI) document M27-A3 [11] with some modifications. RPMI 1640 medium, containing glutamine and lacking bicarbonate (Gibco, USA), was buffered to a pH of 7.0 using 0.165 mol/L 3-(N-morpholino) propanesulfonic acid (MOPS; Sigma, USA) and supplemented with 2% glucose. The medium was filter-sterilised by passing it through a 0.22-µm-pore filter before use in susceptibility tests. Stock solutions of the antifungal powder amphotericin B (PanReac, Spain) and itraconazole (Sigma, USA) were prepared in dimethyl sulfoxide (Amresco Inc, USA), while stock solutions of fluconazole (Sigma, USA) were prepared in water. The antifungal drugs amphotericin B, fluconazole, ketoconazole, and itraconazole were tested at final concentrations of 0.0625–32.00, 0.0125–64.00, 0.0625–32.00, and 0.0625–32.00 μg/mL, respectively. Each well was filled with 100 µL of each antifungal dose, followed by 100 µL of the yeast inoculum. For controls, 100 µL of RPMI 1640 broth medium without antifungal was used as the medium control, and 100 µL of RPMI 1640 broth medium with yeast inoculum was used as the growth control. The test was carried out in duplicate. Plates were incubated at 35°C ± 2°C for 48 hours, after which 0.01% resazurin was added and the plates were re-incubated for 3 hours to measure viable cells [13]. The minimum inhibitory concentration (MIC) was visually determined by the change in colour from pink/red to blue after 72 hours of incubation. MIC endpoints were read according to NCCLS criteria (previous name of CLSI) [14]. Wells showing no visible growth were subsequently cultured on SDA and incubated at 35°C ± 2°C for 24 hours to determine the minimum fungicidal concentration (MFC).
WGS genome assembly and genome annotation
Genomic DNA was subjected to short-read WGS using the MGISEQ-2000 platform (MGI, China) with 150-bp paired-end reads. The raw reads (FASTQ format) were de novo assembled with the sequencing data available at NCBI BioProject ID PRJNA1047299 and BioSample ID SAMN38529121 by using SPAdes version 3.12 to generate genome contigs and scaffolds [15]. The complete assembled sequences (FASTA format) were verified using the BUSCO version of Galaxy 5.5.0 + galaxy0 (https://shorturl.at/wdpvm) and annotated using the Augustus program version of + galaxy 11.12 (https://shorturl.at/nolNl). Protein analysis was conducted by using BUSCO program version of Galaxy version 5.5.0 + galaxy0 (https://shorturl.at/wdpvm) and online OrthoDB database (https://www.orthodb.org/). Both statistics of assembled and annotated sequences were computed by QUAST v.5.0.2 [16].
Pairwise average nucleotide identity (ANI) and phylogenetic analyses
The 24 published genomes were isolated from 2 geniuses from Cryptococcus sp (n = 11). and Hyphopichia sp (n = 13). These genomes were available at the National Center for Biotechnology Information (NCBI) under Submitted GenBank assembly number GCA_001661395.1, GCA_003856795.1, GCA_018343885.1, GCA_030573595.1, GCA_037044105.1, GCA_003856775.1, GCA_001599095.1, GCA_030444945.1, GCA_030578475.1, GCA_030569195.1, GCA_030556945.1, GCA_030560785.1, GCA_030569855.1, GCA_001720195.2, GCA_000836335.2, GCA_036417295.1, GCA_002954075.1, GCA_000091045.1, GCA_000185945.1, GCA_000835755.2, GCA_001720205.1, GCA_001720155.1, GCA_000149245.3 and GCA_000149385.1. All previously published Cryptococcus sp and Hyphopichia sp genomes from NCBI and one of Hyphopichia sp. of this study were used Augustus program for annotation by Galaxy version 3.4.0 + galaxy 11.12 (https://shorturl.at/nolNl). Then, the annotated sequences (FASTA format) of protein were constructed phylogenetic trees to compare with all annotated protein sequences by OrthoFider version 2.5.5 [17] and using geneious tree builder of Geneious Prime program with Neighbor-joining (1,000 bootstrap). A total of 24 From all the assembled sequences (FASTA format) from NCBI database and one of assembled sequences of this study. All FASTA files (n = 25) were comparative pairwise average nucleotide identity (ANI). The ANI was evaluated using FastANI v1.32 [18].
Results
Four contaminated isolates, initially presumed to be Cryptococcus spp. based on their morphology and the results of biochemical tests by Indoung [3], were recovered on SDA for 3 days at 35°C. Colonies appeared as round cells with elevated and raised surfaces. The margins of the colonies were smooth but irregular and exhibited an opaque, creamy-white colour but not mucoid like colony of Cryptococcus spp. Staining the colonies with India ink and Gram stain revealed yeast capsules and budding like those seen in Cryptococcus spp. (Fig 1). Similarity to Cryptococcus species, the results of the biochemical tests revealed that the urease test was positive, assimilation of glucose, maltose, raffinose and sucrose were all positive whereas lactose negative. The isolates were then subjected to nested PCR to confirm or rule out Cryptococcus spp. All isolates yielded different results from the positive Cryptococcus spp. controls, showing negative results in the first step and positive results in the second step of nested PCR (Fig 2).
Capsule stained with India ink (yellow arrow) and Budding yeast stained with Gram stain (red arrow).
Antifungal susceptibility testing demonstrated the MIC and MFC values of amphotericin B, fluconazole, itraconazole, and ketoconazole for the four isolates. A low MIC value for amphotericin B was observed in all isolates (0.0625–0.25 µg/mL). By contrast, all isolates exhibited high MIC values for fluconazole (4–8 µg/mL). The MIC value of ketoconazole for Tip1, Tip10, and Park4 was low (0.0625 µg/mL), but for Tip11, it was high (32 µg/mL). The MFC values of all isolates were high for fluconazole (32–64 µg/mL), itraconazole (4.0–32.0 µg/mL), and ketoconazole (4.0–32.0 µg/mL), while the MFC values for amphotericin B ranged from 0.25 to 1.0 µg/mL (Table 1).
Based on the results of morphology, biochemical tests, nested PCR, and antifungal susceptibility testing, Tip11 was selected for WGS. The quality assessment results for WGS using the raw reads (FASTQ format) with the BUSCO program showed completeness. After de novo assembly, the quality of the assembled genomes (FASTA format) indicated >90% completeness using the BUSCO program. The genome length of H. burtonii was 12.3 Mb, with a GC content of 35.16%. The number of contigs in this genome was 191, with L50 and N50 values of 9 and 439,709 bp, respectively (Table 2).
The genomes annotation statistics by QUAST of H. burtonii was shown with a total length is 6.8 Mb, GC content is 36.47% and 4,564 contigs. The L50 was 1124 and N50 is 1,875 bp. The high quality of annotated genome allowed the prediction of protein-coding genes for H. burtonii strain by using OrthoDB database. A total of 2,137 genes and proteins were predicted in the analysis, with most proteins related to yeasts in the Saccharomycetaceae family (S1 File). The Complete BUSCOs (C) has 75.5% (n = 1614), 5.2% (n = 111) of Fragmented BUSCOs (F) and 19.3% of Missing BUSCOs (M) remained unannotated (Table 3).
The function category has divided to 24 categories including RNA processing and modification, Chromatin structure and dynamics, Energy production and conversion, Cell cycle control, cell division, chromosome partitioning, Amino acid transport and metabolism, Nucleotide transport and metabolism, Carbohydrate transport and metabolism, Coenzyme transport and metabolism, Lipid transport and metabolism, Translation, ribosomal structure and biogenesis, Transcription, Replication, recombination and repair, Cell wall/membrane/envelope biogenesis, Cell motility, Posttranslational modification, protein turnover, chaperones, Inorganic ion transport and metabolism, Secondary metabolites biosynthesis, transport and catabolism, Signal transduction mechanisms, Intracellular trafficking, secretion, and vesicular transport, Defense mechanisms, Extracellular structures, Mobilome: prophages, transposons, Cytoskeleton and Function category not found (Fig 3).
(C), Fragmented BUSCOs (F) and Missing BUSCOs (M) proteins of H. burtonii annotated sequences and function category has divided to 24 categories.
Proteins of H. burtonii represented similarity to Pichiaceae family protein. Among the identified proteins, midasin, heat shock 70 family proteins, and Csf1 were of particular interest (Fig 4). In the defense mechanisms (V) group, RFT1 was specially considered. Phylogenetic annotated protein sequences and 14 Hyphopichia sp. annotated protein sequences showed complete identity to H. burtonii makgeolli (Fig 5). Total 43 canditate resistance genes of H. burtonii was shown in Fig 6. Briefly, the highest number of resistance genes were found in azole (11) followed by itraconazole (10) vericonazole (8), fluconazole (4), casprofungin (4), micafungin (4), and 5-fluorocystosine (2), respectively. In the Azole group, ATP binding cassette (ABC) transporters superfamily (SNQ2, MDL1, MDL2 and ADP1) was the most finding. While in itraconazole found cytochrome P450 family including ERG11, ERG5, HAP5 and COX10.
(A) Midasin (B) Csf1 (C) Heat shock protein 70.
Discussion
The morphology of H. burtonii observed in this study was consistent with previous descriptions by Burgain [19]. As previously noted, the cells are short, ellipsoidal, or elongate, with pseudohyphae and true hyphae sometimes forming. Colonies are tannish-white, and their texture ranges from butyrous to hyphal [20]. H. burtonii, historically referred to as ‘chalky mould’, is known to cause food spoilage by fragmenting hyphae into short lengths [21]. Despite its role as a spoilage organism, it has also been used in bread and dairy production and is part of the flora of cured meats. To date, it has only been reported as the cause of cutaneous mycosis in a bat [22].
The results of the drug susceptibility test showed that H. burtonii isolate was highly susceptible to amphotericin B, exhibited intermediate resistance to fluconazole, and was highly resistant to itraconazole and ketoconazole. Relatively with the finding of candidate resistance genes by HDMM analysis (Fig 6), which were high in azole and itraconazole. The most finding resistance genes in azole group were ABC transporters superfamily that are responsible for drug resistance and a low bioavailability of drugs by pumping a variety of drugs out cells at the expense of ATP hydrolysis [23]. ATP-binding cassette (ABC) transporters play a role in active efflux of a broad range of xenobiotics which is one of the common mechanisms of multidrug resistance in eukaryotic cells [24]. Azole antifungal drugs inhibit cytochrome P450-dependent enzymes, particularly 14-demethylase, which is crucial for the biosynthesis of ergosterol—a key component of fungal cell membrane structure and function [25]. Resistance to azoles often involves alterations in genes encoding the azole drug target 14-α-demethylase (ERG11) in yeast [26]. ERG11 gene was identified in the H. burtonii isolate possess ergosterol biosynthesis genes might contribute to its resistance to ketoconazole.
These findings differ significantly from reports of H. burtonii causing sterile peritonitis in humans, where the yeast was highly susceptible to amphotericin B, voriconazole, fluconazole, itraconazole, and caspofungin [27]. The observed MIC levels of ketoconazole in this yeast are like those reported for C. neoformans var. neoformans and C. neoformans var. gattii (16–64 µg/mL) [28]. However, this finding showed similar with the recent study that reported C. gattii VGIII was less susceptible to fluconazole and itraconazole [29].
The genome of this H. burtonii isolate contains the Pichiaceae family protein midasin (Fig 4A), which is involved in coenzyme transport and metabolism, intracellular trafficking, secretion, and vesicular transport. Previous studies have suggested that midasin may function as a nuclear chaperone and be involved in the assembly/disassembly of macromolecular complexes within the nucleus of yeast [30]. Interestingly, H. burtonii also possesses the Csf1 gene (Fig 4B), which plays a critical role in protein uptake at low temperatures, like the Hsf1 protein in Saccharomycetes [31]. Additionally, the heat shock protein 70 family (Fig 4C) was identified in this yeast, which is known to participate in both the heat shock response and adaptation to oxidative stress and glucose starvation [32]. These characteristics may explain why H. burtonii is a yeast species commonly found in nature and highly competitive under harsh environmental conditions, such as low water availability (0.85 aw) [19] and exhibited strong exhibit strong halotolerance [33]. Moreover, it is a potent producer of amylases that support mite digestion in stored products such as cereals and grains [34]. Interestingly, RFT1 gene in categories of defense mechanisms was identified in H. burtonii genome. RFT1 catalyzes the translocation of M5GN2-PP-Dol across the lipid bilayer and acts as the M5GN2-PP-Dol ER flippase [35]. Yeast RFT1 is homologous to human RFT1 and SEC61A1 and has been used to study congenital disorder of glycosylation type I and cancer [36].
However, infections in animals and humans caused by H. burtonii are rarely reported. There have been cases in which H. burtonii caused dermatitis in Barbastella bats [22]. The yeast has also been isolated from fish feed (tambatinga fish) and marine environments, including fish and fishponds [37,38]. The presence of this yeast may depend on the composition of the feed [38]. Laying hens might harbour potentially pathogenic H. burtonii yeasts in their gastrointestinal tracts and spread them through faeces and eggs [8]. Human cases of secondary peritonitis involving H. burtonii have also been documented [27,39].
Conclusion
This study is the first report of H. burtonii recovered form zebra dove droppings in Thailand with the novel knowledge on the resistance genes. The azole drugs (Itraconazole and ketoconazole) resistance were observed in this yeast suggest that infections originating from zebra dove droppings could pose significant public health risks, especially in immunocompromised individuals, like other pathogenic yeasts where treatment options are limited. Therefore, further characterization and functional studies of H. burtonii are necessary. Additionally, implementing biosecurity measures in zebra dove farms is crucial to mitigate potential risks.
Supporting information
S1 File. The lineage dataset of proteins in H. burtonii.
The most proteins of H. burtonii related to yeasts in the Saccharomycetaceae family
https://doi.org/10.1371/journal.pone.0315067.s001
(CSV)
Acknowledgments
This research sincerely thank to the Faculty of Veterinary Science, Prince of Songkla University supported for the equipments. We are grateful to the zebra dove farmers who granted us permission to enter their farms and collect samples.
References
- 1. Zebra dove trading business in Songkhla is booming (in Thai) (internet) Prachachat Business, 2017. [Cite 2025 Feb 25]. Available from: https://today.line.me.
- 2. Boseret G, Losson B, Mainil JG, Thiry E, Saegerman C. Zoonoses in pet birds: review and perspectives. Vet Res. 2013;44(1):36. pmid:23687940
- 3. Indoung S, Prachantasena S, Wiriyaprom R, Laksana K, Ruengphodchanapruek K, Aleediman W, et al. Detection of zoonotic Cryptococcus neoformans in zebra dove (Geopelia striata) dropping by nested PCR. Southeast Asian J Trop Med Public Health. 2021;54:780–9.
- 4. Talazadeh F, Ghorbanpoor M, Shahriyari A. Candidiasis in birds (Galliformes, Anseriformes, Psittaciformes, Passeriformes, and Columbiformes): a focus on antifungal susceptibility pattern of candida albicans and non-albicans isolates in avian clinical specimens. Top Companion Anim Med. 2022;46:100598. pmid:34700027
- 5.
Sharman MH. Mycotic diseases of pet birds. MSD Veterinary Manual. 2021. Online available at https://www.msdvetmanual.com/. Accessed 26 August 2024.
- 6. Cafarchia C, Camarda A, Romito D, Campolo M, Quaglia NC, Tullio D, et al. Occurrence of yeasts in cloacae of migratory birds. Mycopathologia. 2006;161(4):229–34. pmid:16552486
- 7. Criseo G, Bolignano MS, De Leo F, Staib F. Evidence of canary droppings as an important reservoir of Cryptococcus neoformans. Zentralblatt fur Bakteriol. 282(3):244–54.
- 8. Cafarchia C, Iatta R, Danesi P, Camarda A, Capelli G, Otranto D. Yeasts isolated from cloacal swabs, feces, and eggs of laying hens. Med Mycol. 2019;57(3):340–5. pmid:29762763
- 9.
Kramer M. Zoonotic diseases of birds, reptiles, and fish. In: World Small Animal Veterinary Association World Congress Proceedings, Miami, FL, USA, 2105.
- 10. Simi WB, Leite-Jr DP, Paula CR, Hoffmann-Santos HD, Takahara DT, Hahn RC. Yeasts and filamentous fungi in psittacidae and birds of prey droppings in midwest region of Brazil: a potential hazard to human health. Braz J Biol. 2019;79(3):414–22. pmid:30304251
- 11.
CLSI. Reference method for broth dilution antifungal susceptibility testing of yeasts, 4th edn. CLSI standard M27. CLSI, Wayne, PA, USA. 2008.
- 12. Mitchell TG, Freedman EZ, White TJ, Taylor JW. Unique oligonucleotide primers in PCR for identification of Cryptococcus neoformans. J Clin Microbiol. 1994;32(1):253–5. pmid:8126194
- 13. de Vasconcelos LC, Sampaio FC, Albuquerque A de J dos R, Vasconcelos LC de S. Cell viability of Candida albicans against the antifungal activity of thymol. Braz Dent J. 2014;25(4):277–81. pmid:25250489
- 14.
Galgiani JN, Bartlett MS, Espinel-Ingroff A et al. Reference method for broth dilution antifungal susceptibility testing of yeasts; proposed standard. NCCLS publication M27P. National Committee for Clinical Laboratory Standards, Villanova, PA, USA. 1992.
- 15. Nurk S, Bankevich A, Antipov D, Gurevich AA, Korobeynikov A, Lapidus A, et al. Assembling single-cell genomes and mini-metagenomes from chimeric MDA products. J Comput Biol. 2013;20(10):714–37.
- 16. Mikheenko A, Prjibelski A, Saveliev V, Antipov D, Gurevich A. Versatile genome assembly evaluation with QUAST-LG. Bioinformatics. 2018;34(13):i142–i50.
- 17. Emms DM, Kelly S. OrthoFinder2: fast and accurate phylogenomic orthology analysis from gene sequences. bioRxiv, 2018;466201.
- 18. Jain C, Rodriguez-R LM, Phillippy AM, Konstantinidis KT, Aluru S. High throughput ANI analysis of 90K prokaryotic genomes reveals clear species boundaries. Nat Commun. 2018;9(1):5114. pmid:30504855
- 19. Burgain A, Bensoussan M, Dantigny P. Validation of a predictive model for the growth of chalk yeasts on bread. Int J Food Microbiol. 2015;204:47–54. pmid:25847185
- 20.
Kurtzman CP, Fell JW, Boekhout T. The yeasts: a taxonomic study, 5th edn. Elsevier, Amsterdam, 2021. pp. 223–77.
- 21. Deschuyffeleer N, Audenaert K, Samapundo S, Ameye S, Eeckhout M, Devlieghere F. Identification and characterization of yeasts causing chalk mould defects on par-baked bread. Food Microbiol. 2011;28(5):1019–27. pmid:21569947
- 22. Simpson VR, Borman AM, Fox RI, Mathews F. Cutaneous mycosis in a Barbastelle bat (Barbastella barbastellus) caused by Hyphopichia burtonii. J Vet Diagn Invest. 2013;25(4):551–4. pmid:23794016
- 23. Choi C-H. ABC transporters as multidrug resistance mechanisms and the development of chemosensitizers for their reversal. Cancer Cell Int. 2005;5:30. pmid:16202168
- 24. Piecuch A, Obłąk E. Yeast ABC proteins involved in multidrug resistance. Cell Mol Biol Lett. 2014;19(1):1–22. pmid:24297686
- 25.
Dixon DM, Walsh TJ. Antifungal agents. In: Baron S (ed) Medical microbiology, 4th edn. University of Texas Medical Branch at Galveston, Galveston, TX, Chapter 76. 1996. Available from: https://www.ncbi.nlm.nih.gov/books/NBK8263/
- 26. Lee Y, Robbins N, Cowen LE. Molecular mechanisms governing antifungal drug resistance. NPJ Antimicrob Resist. 2023;1(1):5. pmid:38686214
- 27. Chamroensakchai T, Kanjanabuch T, Saikong W, Panya W, Thaweekote S, Eiam-Ong S, et al. The first human report of Hyphopichia burtonii, initially misdiagnosed as sterile peritonitis in a patient on peritoneal dialysis. Med Mycol Case Rep. 2021;33:26–9. pmid:34377633
- 28. Dongmo W, Kechia F, Tchuenguem R, Nangwat C, Yves I, Kuiate J-R, et al. In vitro antifungal susceptibility of environmental isolates of cryptococcus spp. from the west region of Cameroon. Ethiop J Health Sci. 2016;26(6):555–60. pmid:28450771
- 29. Taha M, Tartor YH, Elaziz RMA. et al. Genetic diversity and antifungal susceptibilities of environmental Cryptococcus neoformans and Cryptococcus gattii species complexes. IMA Fungus. 2024; 15, 21.
- 30. Garbarino JE, Gibbons IR. Expression and genomic analysis of midasin, a novel and highly conserved AAA protein distantly related to dynein. BMC Genomics. 2002;3:18. pmid:12102729
- 31. Tokai M, Kawasaki H, Kikuchi Y, Ouchi K. Cloning and characterization of the CSF1 gene of Saccharomyces cerevisiae, which is required for nutrient uptake at low temperature. J Bacteriol. 2000;182(10):2865–8. pmid:10781556
- 32. Castells-Roca L, García-Martínez J, Moreno J, Herrero E, Bellí G, Pérez-Ortín JE. Heat shock response in yeast involves changes in both transcription rates and mRNA stabilities. PLoS One. 2011;6(2):e17272. pmid:21364882
- 33. Lee DW, Hong CP, Thak EJ, Park S-G, Lee CH, Lim JY, et al. Integrated genomic and transcriptomic analysis reveals unique mechanisms for high osmotolerance and halotolerance in Hyphopichia yeast. Environ Microbiol. 2021;23(7):3499–522. pmid:33830651
- 34. Takeuchi A, Shimizu-Ibuka A, Nishiyama Y, Mura K, Okada S, Tokue C, et al. Purification and characterization of an α-amylase of pichia burtonii isolated from the traditional starter “Murcha” in Nepal. Biosci Biotechnol Biochem. 2006;70(12):3019–24.
- 35. Chen S, Pei C-X, Xu S, Li H, Liu Y-S, Wang Y, et al. Rft1 catalyzes lipid-linked oligosaccharide translocation across the ER membrane. Nat Commun. 2024;15(1):5157. pmid:38886340
- 36. Koerte A, Chong T, Li X, Wahane K, Cai M. Suppression of the yeast mutation rft1-1 by human p53. J Biol Chem. 1995;270(38):22556–64. pmid:7673248
- 37. Gadanho M, Sampaio JP. Occurrence and diversity of yeasts in the mid-atlantic ridge hydrothermal fields near the Azores Archipelago. Microb Ecol. 2005;50(3):408–17. pmid:16328655
- 38. Pinheiro R, Rodrigues A, Teixeira de O. Santos J, Costa J, Pereyra C, Torres A, et al. Occurrence and diversity of yeast species isolated from fish feed and tambatinga gut. Lat Am J Aquat Res. 2018;46(4):837–42.
- 39. Feldman E, Bellinghausen A, Vodkin I, Abeles S, Kamdar B. Hyphopichia burtonii: a novel pathogen in secondary peritonitis. Chest. 2020;158(4):A1001.