Isabelle Gagnon‐Arsenault scite author profile

Recent functional, proteomic and ribosome profiling studies in eukaryotes have concurrently demonstrated the translation of alternative open-reading frames (altORFs) in addition to annotated protein coding sequences (CDSs). We show that a large number of small proteins could in fact be coded by these altORFs. The putative alternative proteins translated from altORFs have orthologs in many species and contain functional domains. Evolutionary analyses indicate that altORFs often show more extreme conservation patterns than their CDSs. Thousands of alternative proteins are detected in proteomic datasets by reanalysis using a database containing predicted alternative proteins. This is illustrated with specific examples, including altMiD51, a 70 amino acid mitochondrial fission-promoting protein encoded in MiD51/Mief1/SMCR7L, a gene encoding an annotated protein promoting mitochondrial fission. Our results suggest that many genes are multicoding genes and code for a large protein and one or several small proteins.

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Gene duplication can impart fragility, not robustness, in the yeast protein interaction network

Diss¹,

Gagnon‐Arsenault²,

Dion-Côté³

et al. 2017

Science

104

109

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Robustness of protein networks It is thought that gene duplication helps cells maintain genetic robustness, but this seems not to be the whole story. Diss et al. investigated the fate of protein-protein interactions among duplicated genes in yeast. Some interacting duplicates evolved mutual dependence, resulting in a more fragile system. This finding helps us understand the evolutionary trajectories of gene duplications and how seemingly redundant genes can increase the complexity of protein interaction networks. Science , this issue p. 630

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Fungal yapsins and cell wall: a unique family of aspartic peptidases for a distinctive cellular function

Gagnon‐Arsenault

Tremblay

Bourbonnais

2006

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A novel class of aspartic peptidases known as fungal yapsins, whose first member ScYps1p was identified more than a decade ago in Saccharomyces cerevisiae, is characteristically modified by the addition of a glycophosphatidylinositol moiety and has a preference for cleaving substrates C-terminally to mono- and paired-basic residues. Over the years, several other members, first in S. cerevisiae and then in other fungi, have been identified. The implication of fungal yapsins in cell-wall assembly and/or remodelling had been suspected for many years. However, it is only very recently that studies performed on S. cerevisae and Candida albicans have confirmed their importance for cell-wall integrity. Here, we review 16 years of research, covering all fundamental aspects of these unique enzymes, in an effort to track their functional significance. We also propose a nomenclature for fungal yapsins based on their sequence identity with the founding members of this family, the S. cerevisiae yapsins.

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Activation mechanism, functional role and shedding of glycosylphosphatidylinositol‐anchored Yps1p at the Saccharomyces cerevisiae cell surface

Gagnon‐Arsenault

Parisé

Tremblay

et al. 2008

Molecular Microbiology

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SummaryYeast cell wall assembly is a highly regulated and dynamic process. A class of cell surface aspartic peptidases anchored by a glycosylphosphatidylinositol (GPI) group, collectively known as yapsins, was proposed to be involved in cell wall construction. The Saccharomyces cerevisiae Yps1p, the prototypal yapsin, is processed internally within a loop region to produce an a/b two-subunit enzyme. Here we investigated the activation mechanism of GPI-anchored Yps1p and identified some of its substrates. We report that all activation steps of GPI-Yps1p take place at the cell surface and are regulated by the environmental pH. GPI-Yps1p is active in vivo at pH 6.0 and pH 3.0 and functions as a sheddase for a subset of GPI-anchored enzymes, including itself and the Gas1 glucanosyltransferase. Importantly, while native GPI-Yps1p weakly suppresses many phenotypes associated with the yeast kex2D mutant, loop mutants that interfere with conversion into the two-subunit enzyme restore the kex2D phenotypes to near wild type level. We propose that cleavage of this internal loop region plays an important regulatory function through stimulating its shedding activity. Collectively, our data provide a direct link between the pH regulation of yeast cell wall assembly and the activity of a yapsin.

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