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Abstract Anaerobic gut fungi (AGF,Neocallimastigomycota) represent a phylum of zoospore-producing fungi inhabiting the gastrointestinal tracts of herbivores. Twenty mammalian-affiliated genera (M-AGF) and two tortoise-affiliated genera (T-AGF) have been described so far. Here, we report on three additional novel T-AGF isolates obtained from Texas and sulcata tortoises. Phylogenetic analysis using the D1-D2 regions of the large ribosomal RNA subunit (D1-D2 LSU), RNA polymerase II large subunit (RPB1), internal transcribed spacer-1 region (ITS1), and transcriptomics-enabled phylogenomic analysis clustered these strains into three distinct, deep-branching clades, closely related to previously described T-AGF genusTestudinimyces. All isolates displayed filamentous rhizoidal growth patterns and produced monoflagellated zoospores. Unique morphological characteristics included the production of elongated, thick, nucleated structures in GX isolates, the formation of thin hair-like projections on sporangial walls in SR isolates, and irregularly shaped sporangia in TM isolates. All strains grew optimally at 32-35 °C and showed distinct substrate utilization capacity (e.g., growth on pectin, chitin, galactose). LSU analyses revealed GX isolates as the first cultured representatives of tortoise-affiliated but previously uncultured lineage NY56, while SR and TM strains have not been encountered in prior culture-independent AGF surveys. We propose to accommodate these isolates in three new genera and species –Gopheromyces tardescens(GXA2),Gigasporangiomyces pilosus(SR0.6), andKelyphomyces adhaerens(TM0.3). Further, based on the ecological, physiological, and phylogenetic distinctions between T-AGF and M-AGF, we propose to establish a new family (Testudinimycetaceae) to accommodate the generaTestudinimyces, Gopheromyces,Gigasporangiomyces,andKelyphomyces, within a new order (Testudinimycetales), and amend the description ofNeocallimastigalesto circumscribe M-AGF genera only.
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Evaluating the impact of redox potential on the growth capacity of anaerobic gut fungi
Abstract Anaerobic gut fungi (AGF, Neocallimastigomycota) inhabit the alimentary tract of herbivores. Although strict anaerobes, studies have suggested their capacity to retain viability after various durations of air exposure. It is currently unclear whether AGF can actively grow, and not merely survive, in redox potentials (Eh) higher than those encountered in the herbivorous gut. We evaluated the growth of two AGF strains (Orpinomyces joyonii and Testudinimyces gracilis) at various Eh levels, achieved by manipulating the concentrations of reductant (cysteine hydrochloride) in culture media. Both strains exhibited robust and sustainable growth at negative Eh (−50 mV or below). However, growth in the absence of cysteine hydrochloride (Eh value around +50 mV) was possible only for O. joyonii and only for one subcultivation. The capacity to grow at +50 mV was further confirmed in four additional taxa (Pecoramyces ruminatium, Anaeromyces mucronatus, Aklioshbmyces papillarum, and Piromyces communis), while two (Aestipascuomyces dupliciliberans and Capellomyces foraminis) failed to grow under these conditions. Our results establish the ability of AGF to grow at redox potential values higher than those encountered in their natural habitats. Such capability could contribute to efficient AGF dispersal and horizontal transmission between hosts, and could have important implications for industrial applications of AGF.
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- Award ID(s):
- 2029478
- PAR ID:
- 10555653
- Publisher / Repository:
- Oxford University Press
- Date Published:
- Journal Name:
- FEMS Microbes
- Volume:
- 5
- ISSN:
- 2633-6685
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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