The mitochondrial view of Blastocladiella emersonii

The second complete mitochondrial genome of Capillidium rhysosporum within the family Capillidiaceae, Entomophthorales

The complete mitochondrial genome of the entomophthoroid fungus Capillidium rhysosporum (strain no.: ATCC 12588) was sequenced using next-generation sequencing technology. The assembled circular genome has a length of 46,756 base pairs with a GC content of 27.06%. Gene prediction identified 15 core protein-coding genes (PCGs), two rRNA genes, and 27 tRNA genes. Phylogenetic analysis confirmed that C. rhysosporum belongs to the Zoopagomycota clade and is closely related to C. heterosporum. This study presents the second complete mitochondrial genome within the family Capillidiaceae, contributing to the mitochondrial DNA database of entomophthoroid fungi.

A Genome Sequence Assembly of the Phototactic and Optogenetic Model Fungus Blastocladiella emersonii Reveals a Diversified Nucleotide-Cyclase Repertoire

The chytrid fungus Blastocladiella emersonii produces spores with swimming tails (zoospores); these cells can sense and swim toward light. Interest in this species stems from ongoing efforts to develop B. emersonii as a model for understanding the evolution of phototaxis and the molecular cell biology of the associated optogenetic circuits. Here, we report a highly contiguous genome assembly and gene annotation of the B. emersonii American Type Culture Collection 22665 strain. We integrate a PacBio long-read library with an Illumina paired-end genomic sequence survey leading to an assembly of 21 contigs totaling 34.27 Mb. Using these data, we assess the diversity of sensory system encoding genes. These analyses identify a rich complement of G-protein-coupled receptors, ion transporters, and nucleotide cyclases, all of which have been diversified by domain recombination and tandem duplication. In many cases, these domain combinations have led to the fusion of a protein domain to a transmembrane domain, tying a putative signaling function to the cell membrane. This pattern is consistent with the diversification of the B. emersonii sensory-signaling systems, which likely plays a varied role in the complex life cycle of this fungus.

The complete mitochondrial genome of Linnemannia amoeboidea (W. Gams) Vandepol & Bonito (Mortierellales: Mortierellaceae)

The complete mitochondrial genome of Linnemannia amoeboidea (W. Gams) Vandepol & Bonito 2020 (Strain no.: CBS 889.72) was sequenced under the next-generation sequencing platform. It was the second one in the family Mortierellaceae Luerss. 1877. The circular genome was 49,702 bp in size, with a GC content of 20.86%. Gene prediction revealed 15 PCGs, two rRNA genes, 26 tRNA genes, one rnpB gene and seven ORFs. Phylogenetic analyses showed that L. amoeboidea was closely related to Podila verticillate (Linnem.) Vandepol & Bonito 2020.

Comparative mitogenome analysis of two ectomycorrhizal fungi (Paxillus) reveals gene rearrangement, intron dynamics, and phylogeny of basidiomycetes

In this study, the mitogenomes of two Paxillus species were assembled, annotated and compared. The two mitogenomes of Paxillus involutus and P. rubicundulus comprised circular DNA molecules, with the size of 39,109 bp and 41,061 bp, respectively. Evolutionary analysis revealed that the nad4L gene had undergone strong positive selection in the two Paxillus species. In addition, 10.64 and 36.50% of the repetitive sequences were detected in the mitogenomes of P. involutus and P. rubicundulus, respectively, which might transfer between mitochondrial and nuclear genomes. Large-scale gene rearrangements and frequent intron gain/loss events were detected in 61 basidiomycete species, which revealed large variations in mitochondrial organization and size in Basidiomycota. In addition, the insertion sites of the basidiomycete introns were found to have a base preference. Phylogenetic analysis of the combined mitochondrial gene set gave identical and well-supported tree topologies, indicating that mitochondrial genes were reliable molecular markers for analyzing the phylogenetic relationships of Basidiomycota. This study is the first report on the mitogenomes of Paxillus, which will promote a better understanding of their contrasted ecological strategies, molecular evolution and phylogeny of these important ectomycorrhizal fungi and related basidiomycete species.

Small heat shock protein genes are developmentally regulated during stress and non-stress conditions in Blastocladiella emersonii

Small heat shock proteins (sHsps) are molecular chaperones of low molecular weight involved in an early association with misfolded proteins. In response to heat shock, B. emersonii induces the synthesis of a number of proteins. As sHsps are still poorly studied in B. emersonii and in fungi overall, the aim of this work was to carry out a in-depth characterization of sHsps during B. emersonni life cycle, as well as in response to thermal stress. We verified a strong induction of the hsp17 gene in cells exposed to heat shock both in germination and sporulation stages, and that Hsp17 protein levels show the same pattern of variation of its mRNA. Unlike hsp17 and hsp30, hsp16 gene is not significantly induced during heat shock, in germination or sporulation cells. However, at normal temperatures, the hsp16 gene presents high mRNA levels in sporulation cells, whereas the hsp30 gene presents high mRNA levels in germination cells. Interestingly, heat shock mRNA levels for hsp17 and hsp30 genes are 10 times higher in germination cells than in sporulation cells. Thus, our data show that the expression of these sHsp genes is quite distinct, both under normal temperature as during heat shock.

Conserved novel ORFs in the mitochondrial genome of the ctenophore Beroe forskalii

To date, five ctenophore species' mitochondrial genomes have been sequenced, and each contains open reading frames (ORFs) that if translated have no identifiable orthologs. ORFs with no identifiable orthologs are called unidentified reading frames (URFs). If truly protein-coding, ctenophore mitochondrial URFs represent a little understood path in early-diverging metazoan mitochondrial evolution and metabolism. We sequenced and annotated the mitochondrial genomes of three individuals of the beroid ctenophore Beroe forskalii and found that in addition to sharing the same canonical mitochondrial genes as other ctenophores, the B. forskalii mitochondrial genome contains two URFs. These URFs are conserved among the three individuals but not found in other sequenced species. We developed computational tools called pauvre and cuttlery to determine the likelihood that URFs are protein coding. There is evidence that the two URFs are under negative selection, and a novel Bayesian hypothesis test of trinucleotide frequency shows that the URFs are more similar to known coding genes than noncoding intergenic sequence. Protein structure and function prediction of all ctenophore URFs suggests that they all code for transmembrane transport proteins. These findings, along with the presence of URFs in other sequenced ctenophore mitochondrial genomes, suggest that ctenophores may have uncharacterized transmembrane proteins present in their mitochondria.

Mitochondrial genome characterization and phylogenetic analysis of Blastocladiella sp. (Blastocladiales: Blastocladiaceae)

In the present study, the complete mitochondrial genome of an early diverging fungus Blastocladiella sp. was assembled by the next-generation sequencing. The complete mitochondrial genome of Blastocladiella sp. is 33, 800 bp in length and consists of 11,620 (34.38%) adenine, 5,047 (14.93%) cytosine, 6,025 (17.83%) guanosine and 11,108 (32.86%) thymine. The genome contains 19 protein-coding genes, 24 tRNA genes and 2 rRNA genes. Phylogenetic analysis based on the combined mitochondrial gene set showed that Blastocladiella sp. has a close relationship with Allomyces macrogynus and Blastocladiella emersonii.

Mitochondrial alternative oxidase is determinant for growth and sporulation in the early diverging fungus Blastocladiella emersonii

Blastocladiella emersonii is an early diverging fungus of the phylum Blastocladiomycota. During the life cycle of the fungus, mitochondrial morphology changes significantly, from a fragmented form in sessile vegetative cells to a fused network in motile zoospores. In this study, we visualize these morphological changes using a mitochondrial fluorescent probe and show that the respiratory capacity in zoospores is much higher than in vegetative cells, suggesting that mitochondrial morphology could be related to the differences in oxygen consumption. While studying the respiratory chain of the fungus, we observed an antimycin A and cyanide-insensitive, salicylhydroxamic (SHAM)-sensitive respiratory activity, indicative of a mitochondrial alternative oxidase (AOX) activity. The presence of AOX was confirmed by the finding of a B. emersonii cDNA encoding a putative AOX, and by detection of AOX protein in immunoblots. Inhibition of AOX activity by SHAM was found to significantly alter the capacity of the fungus to grow and sporulate, indicating that AOX participates in life cycle control in B. emersonii.

Transcriptional response to hypoxia in the aquatic fungus Blastocladiella emersonii

Global gene expression analysis was carried out with Blastocladiella emersonii cells subjected to oxygen deprivation (hypoxia) using cDNA microarrays. In experiments of gradual hypoxia (gradual decrease in dissolved oxygen) and direct hypoxia (direct decrease in dissolved oxygen), about 650 differentially expressed genes were observed. A total of 534 genes were affected directly or indirectly by oxygen availability, as they showed recovery to normal expression levels or a tendency to recover when cells were reoxygenated. In addition to modulating many genes with no putative assigned function, B. emersonii cells respond to hypoxia by readjusting the expression levels of genes responsible for energy production and consumption. At least transcriptionally, this fungus seems to favor anaerobic metabolism through the upregulation of genes encoding glycolytic enzymes and lactate dehydrogenase and the downregulation of most genes coding for tricarboxylic acid (TCA) cycle enzymes. Furthermore, genes involved in energy-costly processes, like protein synthesis, amino acid biosynthesis, protein folding, and transport, had their expression profiles predominantly downregulated during oxygen deprivation, indicating an energy-saving effort. Data also revealed similarities between the transcriptional profiles of cells under hypoxia and under iron(II) deprivation, suggesting that Fe(2+) ion could have a role in oxygen sensing and/or response to hypoxia in B. emersonii. Additionally, treatment of fungal cells prior to hypoxia with the antibiotic geldanamycin, which negatively affects the stability of mammalian hypoxia transcription factor HIF-1alpha, caused a significant decrease in the levels of certain upregulated hypoxic genes.