Abstract
In most eukaryotes, including the majority of fungi, expression of sterol biosynthesis genes is regulated by Sterol-Regulatory Element Binding Proteins (SREBPs), which are basic helix-loop-helix transcription activators. However, in yeasts such as Saccharomyces cerevisiae and Candida albicans sterol synthesis is instead regulated by Upc2, an unrelated transcription factor with a Gal4-type zinc finger. The SREBPs in S. cerevisiae (Hms1) and C. albicans (Cph2) have lost a domain, are not major regulators of sterol synthesis, and instead regulate filamentous growth. We report here that rewiring of the sterol regulon, with Upc2 taking over from SREBP, likely occurred in the common ancestor of all Saccharomycotina. Yarrowia lipolytica, a deep-branching species, is the only genome known to contain intact and full-length orthologs of both SREBP (Sre1) and Upc2. Deleting YlUPC2, but not YlSRE1, confers susceptibility to azole drugs. Sterol levels are significantly reduced in the YlUPC2 deletion. RNA-seq analysis shows that hypoxic regulation of sterol synthesis genes in Y. lipolytica is predominantly mediated by Upc2. However, YlSre1 still retains a role in hypoxic regulation; growth of Y. lipolytica in hypoxic conditions is reduced in a Ylupc2 deletion and is abolished in a Ylsre1/Ylupc2 double deletion, and YlSre1 regulates sterol gene expression during hypoxia adaptation. We show that YlSRE1, and to a lesser extent YlUPC2, are required for switching from yeast to filamentous growth in hypoxia. Sre1 appears to have an ancestral role in the regulation of filamentation, which became decoupled from its role in sterol gene regulation by the arrival of Upc2 in the Saccharomycotina.
Highlights
Changes in gene regulatory networks are an important mechanism of evolutionary adaptation
The DUF2014 domain appears to have been acquired by the Sterol-Regulatory Element Binding Proteins (SREBPs) in the ancestor of the Ascomycota, as it is not found in Sre1 of C. neoformans and other Basidiomycetes
Upc2 regulates sterol synthesis in the Saccharomycotina Sterols are essential for maintaining membrane structure and function, and synthesis in fungi and other eukaryotes is very carefully regulated at several levels [66]
Summary
Changes in gene regulatory networks are an important mechanism of evolutionary adaptation. Transcriptional rewiring can result from gene loss, gene duplication, alterations in transcription factor binding sites, or changes in protein modularity that affect the interaction of transcription factors with other regulators [1,2,3,4,5]. Other examples include substitution of the transcription factor Cph with Gal for regulation of galactose metabolism genes in the Saccharomyces clade [7], and changes in telomere binding proteins [8]. Most reported evolutionary changes involve the connection or disconnection of a group of target genes from a particular transcription factor, while the cellular function of the factor remains the same [9]
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