Shed Light in the DaRk LineagES of the Fungal Tree of Life—STRES

The polyphyletic group of black fungi within the Ascomycota (Arthoniomycetes, Dothideomycetes, and Eurotiomycetes) is ubiquitous in natural and anthropogenic habitats. Partly because of their dark, melanin-based pigmentation, black fungi are resistant to stresses including UV- and ionizing-radiation, heat and desiccation, toxic metals, and organic pollutants. Consequently, they are amongst the most stunning extremophiles and poly-extreme-tolerant organisms on Earth. Even though ca. 60 black fungal genomes have been sequenced to date, [mostly in the family Herpotrichiellaceae (Eurotiomycetes)], the class Dothideomycetes that hosts the largest majority of extremophiles has only been sparsely sampled. By sequencing up to 92 species that will become reference genomes, the “Shed light in The daRk lineagES of the fungal tree of life” (STRES) project will cover a broad collection of black fungal diversity spread throughout the Fungal Tree of Life. Interestingly, the STRES project will focus on mostly unsampled genera that display different ecologies and life-styles (e.g., ant- and lichen-associated fungi, rock-inhabiting fungi, etc.). With a resequencing strategy of 10- to 15-fold depth coverage of up to ~550 strains, numerous new reference genomes will be established. To identify metabolites and functional processes, these new genomic resources will be enriched with metabolomics analyses coupled with transcriptomics experiments on selected species under various stress conditions (salinity, dryness, UV radiation, oligotrophy). The data acquired will serve as a reference and foundation for establishing an encyclopedic database for fungal metagenomics as well as the biology, evolution, and ecology of the fungi in extreme environments.

Toward a Fully Resolved Fungal Tree of Life

In this review, we discuss the current status and future challenges for fully elucidating the fungal tree of life. In the last 15 years, advances in genomic technologies have revolutionized fungal systematics, ushering the field into the phylogenomic era. This has made the unthinkable possible, namely access to the entire genetic record of all known extant taxa. We first review the current status of the fungal tree and highlight areas where additional effort will be required. We then review the analytical challenges imposed by the volume of data and discuss methods to recover the most accurate species tree given the sea of gene trees. Highly resolved and deeply sampled trees are being leveraged in novel ways to study fungal radiations, species delimitation, and metabolic evolution. Finally, we discuss the critical issue of incorporating the unnamed and uncultured dark matter taxa that represent the vast majority of fungal diversity.

The enigmatic Mixia osmundae revisited: a systematic review including new distributional data and recent advances in its phylogeny and phylogenomics

The enigmatic basidiomycete genus Mixia includes intracellular parasites of Osmunda and Osmundastrum ferns. Here, the authors review the systematic and phylogenetic history of M. osmundae, originally known as Taphrina osmundae, and provide new data from investigations of specimens of Osmunda japonica collected in Yunnan Province, China, which we determine to be conspecific with M. osmundae. In addition, Taphrina higginsii, a parasite on fronds of Osmundastrum cinnamomeum described from Georgia, USA, was confirmed to be phenotypically identical with M. osmundae. The name T. higginsii is lectotypified with a Mix specimen. Collections examined to date document four localities for M. osmundae: Japan (Honshu and Kyushu), Taiwan (Taichung), USA (Georgia), and China (Yunnan), and host-parasite relationships with the old extant ferns Osmunda japonica and its relatives and with Osmundastrum cinnamomeum. The phylogenetic placement of M. osmundae on the fungal tree of life, its evolutionary implications, and recent advances in the phylogenomics of this fungus are briefly reviewed and discussed.

Complex multicellularity in fungi: evolutionary convergence, single origin, or both?

Complex multicellularity comprises the most advanced level of organization evolved on Earth. It has evolved only a few times in metazoans, green plants, brown and red algae and fungi. Compared to other lineages, the evolution of multicellularity in fungi follows different principles; both simple and complex multicellularity evolved via unique mechanisms not seen in other lineages. In this article we review ecological, paleontological, developmental and genomic aspects of complex multicellularity in fungi and discuss the general principles of the evolution of complex multicellularity in light of its fungal manifestations. Fungi represent the only lineage in which complex multicellularity shows signatures of convergent evolution: it appears 8-12 distinct fungal lineages, which show a patchy phylogenetic distribution, yet share some of the genetic mechanisms underlying complex multicellular development. To mechanistically explain the patchy distribution of complex multicellularity across the fungal tree of life we identify four key observations that need to be considered: the large number of apparently independent complex multicellular clades; the lack of documented phenotypic homology between these; the universal conservation of gene circuits regulating the onset of complex multicellular development; and the existence of clades in which the evolution of complex multicellularity is coupled with limited gene family diversification. We discuss how these patterns and known genetic aspects of fungal development can be reconciled with the genetic theory of convergent evolution to explain its pervasive occurrence in across the fungal tree of life.