• Xing-Xing Shen
  • Dana A. Opulente
  • Jacek Kominek
  • Xiaofan Zhou
  • Jacob L. Steenwyk
  • Kelly V. Buh
  • Max A.B. Haase
  • Jennifer H. Wisecaver
  • Mingshuang Wang
  • Drew T. Doering
  • James T. Boudouris
  • Rachel M. Schneider
  • Quinn K. Langdon
  • Moriya Ohkuma
  • Rikiya Endoh
  • Masako Takashima
  • Ri-ichiroh Manabe
  • Neža Čadež
  • Diego Libkind
  • Carlos A. Rosa
  • Jeremy DeVirgilio
  • Amanda Beth Hulfachor
  • Cletus P. Kurtzman
  • Chris Todd Hittinger
  • Antonis Rokas
Budding yeasts (subphylum Saccharomycotina) are found in every biome and are as genetically diverse as plants or animals. To understand budding yeast evolution, we analyzed the genomes of 332 yeast species, including 220 newly sequenced ones, which represent nearly one-third of all known budding yeast diversity. Here, we establish a robust genus-level phylogeny comprising 12 major clades, infer the timescale of diversification from the Devonian period to the present, quantify horizontal gene transfer (HGT), and reconstruct the evolution of 45 metabolic traits and the metabolic toolkit of the budding yeast common ancestor (BYCA). We infer that BYCA was metabolically complex and chronicle the tempo and mode of genomic and phenotypic evolution across the subphylum, which is characterized by very low HGT levels and widespread losses of traits and the genes that control them. More generally, our results argue that reductive evolution is a major mode of evolutionary diversification.
Original languageEnglish
Pages (from-to)1533 - 1545.e20
JournalCell
Volume175
Issue number6
DOI
Publication statusPublished - 08 Nov 2018

    Research areas

  • Ascomycota, Saccharomycotina, high-throughput sequencing, genomics, phylogenetics, phylogenomics, molecular dating, horizontal gene transfer, metabolic traits, reductive evolution

ID: 9389071