Genome-scale phylogeny and contrasting modes of genome evolution in the fungal phylum Ascomycota

Shen, Xing‐Xing; Steenwyk, Jacob L.; LaBella, Abigail L.; Opulente, Dana A.; Zhou, Xin; Kominek, Jacek; Li, Yuanning; Groenewald, Marizeth; Hittinger, Chris Todd; Rokas, Antonis

doi:10.1126/sciadv.abd0079

Cited by 102 publications

(115 citation statements)

References 70 publications

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“…2c; Supplementary Fig. 1), with a separation of Pneumocystis and Schizosaccharomyces genera around 512 mya (CI: 822-203 mya), which is consistent with independent estimates of the origin of Taphrinomycota crown group at 530 mya 21 . The Pneumocystis genus thereafter divided into two main clades, P1 consisting of P. jirovecii, P. macacae, P. oryctolagi, and P. canis, and P2 consisting of species infecting rodents (P. carinii, P. wakefieldiae, and P. murina) (Fig.…”

Section: Genomic Differences Amongsupporting

confidence: 85%

Genomic insights into the host specific adaptation of the Pneumocystis genus

Cissé

Dekker

et al. 2021

Commun Biol

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Pneumocystis jirovecii, the fungal agent of human Pneumocystis pneumonia, is closely related to macaque Pneumocystis. Little is known about other Pneumocystis species in distantly related mammals, none of which are capable of establishing infection in humans. The molecular basis of host specificity in Pneumocystis remains unknown as experiments are limited due to an inability to culture any species in vitro. To explore Pneumocystis evolutionary adaptations, we have sequenced the genomes of species infecting macaques, rabbits, dogs and rats and compared them to available genomes of species infecting humans, mice and rats. Complete whole genome sequence data enables analysis and robust phylogeny, identification of important genetic features of the host adaptation, and estimation of speciation timing relative to the rise of their mammalian hosts. Our data reveals insights into the evolution of P. jirovecii, the sole member of the genus able to infect humans.

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Section: Genomic Differences Amongsupporting

confidence: 85%

Genomic insights into the host specific adaptation of the Pneumocystis genus

Cissé

Dekker

et al. 2021

Commun Biol

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“…Branches are colored by subphylum; budding yeasts / Saccharomycotina (n = 332 species) are in red, fission yeasts / Taphrinomycotina (n = 14 species) are in purple, and filamentous fungi / Pezizomycotina (n = 761 species) are in green. Taxon names have been omitted from the phylogeny for visualization purposes; the phylogenetic tree with taxon names can be found in Figure S1 and Shen et al (2020). The inset phylogenetic tree shows the HLT (in blue) and LLT (in black), with the blue box beneath highlighting them.…”

Section: Fig 2 Conservation Of Mismatch Repair (Mmr) Pathway Genes Across the Fungal Phylummentioning

confidence: 99%

“…Although DNA repair genes are generally highly conserved, certain fungal lineages have been reported to have a more limited repertoire of DNA repair genes, particularly within the phylum Ascomycota. For example, budding yeasts (subphylum Saccharomycotina) and fission yeasts (Taphrinomycotina) have fewer DNA repair genes than filamentous fungi (Pezizomycotina) (Milo et al 2019;Shen et al 2020). Furthermore, DNA repair genes that were lost from budding yeasts and fission yeasts are more likely to also be lost in filamentous fungi (Milo et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Examination of gene loss in the DNA mismatch repair pathway and its mutational consequences in a fungal phylum

Phillips

Steenwyk

Shen

et al. 2021

Preprint

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The DNA mismatch repair (MMR) pathway corrects mismatched bases produced during DNA replication and is highly conserved across the tree of life, reflecting its fundamental importance for genome integrity. Loss of function in one or a few MMR genes can lead to increased mutation rates and microsatellite instability, as seen in some human cancers. While loss of MMR genes has been documented in the context of human disease and in hypermutant strains of pathogens, examples of entire species and species lineages that have experienced substantial MMR gene loss are lacking. We examined the genomes of 1,107 species in the fungal phylum Ascomycota for the presence of 52 genes known to be involved in the MMR pathway of fungi. We found that the median ascomycete genome contained 49 / 52 MMR genes. In contrast, four closely related species of obligate plant parasites from the powdery mildew genera Erysiphe and Blumeria, have lost between 6 and 22 MMR genes, including MLH3, EXO1, and DPB11. The lost genes span MMR functions, include genes that are conserved in all other ascomycetes, and loss of function of any of these genes alone has been previously linked to increased mutation rate. Consistent with the hypothesis that loss of these genes impairs MMR pathway function, we found that powdery mildew genomes with high levels of MMR gene loss exhibit increased numbers of monomer repeats, longer microsatellites, accelerated sequence evolution, elevated mutational bias in the A|T direction, and decreased GC content. These results identify a striking example of macroevolutionary loss of multiple MMR pathway genes in a eukaryotic lineage, even though the mutational outcomes of these losses appear to resemble those associated with detrimental MMR dysfunction in other organisms.

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“…According to single locus or multigene phylogenetic analyses, the fungi assigned to Taphrinomycotina form either mono- or paraphyletic groups depending on the taxon sampling, the analysed phylogenetic markers, and the applied algorithm [ 3 ]. However, phylogenomic analyses support the monophyly of the taxa of Taphrinomycotina involved in the analyses (e.g., [ 8 , 9 , 10 , 11 , 12 ]).…”

Section: Introductionmentioning

confidence: 94%

Novakomyces olei sp. nov., the First Member of a Novel Taphrinomycotina Lineage

et al. 2021

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Taphrinomycotina is the smallest subphylum of the phylum Ascomycota. It is an assemblage of distantly related early diverging lineages of the phylum, comprising organisms with divergent morphology and ecology; however, phylogenomic analyses support its monophyly. In this study, we report the isolation of a yeast strain, which could not be assigned to any of the currently recognised five classes of Taphrinomycotina. The strain of the novel budding species was recovered from extra virgin olive oil and characterised phenotypically by standard methods. The ultrastructure of the cell wall was investigated by transmission electron microscopy. Comparisons of barcoding DNA sequences indicated that the investigated strain is not closely related to any known organism. Tentative phylogenetic placement was achieved by maximum-likelihood analysis of the D1/D2 domain of the nuclear LSU rRNA gene. The genome of the investigated strain was sequenced, assembled, and annotated. Phylogenomic analyses placed it next to the fission Schizosaccharomyces species. To accommodate the novel species, Novakomyces olei, a novel genus Novakomyces, a novel family Novakomycetaceae, a novel order Novakomycetales, and a novel class Novakomycetes is proposed as well. Functional analysis of genes missing in N. olei in comparison to Schizosaccharomyces pombe revealed that they are biased towards biosynthesis of complex organic molecules, regulation of mRNA, and the electron transport chain. Correlating the genome content and physiology among species of Taphrinomycotina revealed some discordance between pheno- and genotype. N. olei produced ascospores in axenic culture preceded by conjugation between two cells. We confirmed that N. olei is a primary homothallic species lacking genes for different mating types.

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Genome-scale phylogeny and contrasting modes of genome evolution in the fungal phylum Ascomycota

Cited by 102 publications

References 70 publications

Genomic insights into the host specific adaptation of the Pneumocystis genus

Genomic insights into the host specific adaptation of the Pneumocystis genus

Examination of gene loss in the DNA mismatch repair pathway and its mutational consequences in a fungal phylum

Novakomyces olei sp. nov., the First Member of a Novel Taphrinomycotina Lineage

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