Vivian L. MacKay scite author profile

In nearly every organism studied, reduced caloric intake extends life span. In yeast, span extension from dietary restriction is thought to be mediated by the highly conserved, nutrient-responsive target of rapamycin (TOR), protein kinase A (PKA), and Sch9 kinases. These kinases coordinately regulate various cellular processes including stress responses, protein turnover, cell growth, and ribosome biogenesis. Here we show that a specific reduction of 60S ribosomal subunit levels slows aging in yeast. Deletion of genes encoding 60S subunit proteins or processing factors or treatment with a small molecule, which all inhibit 60S subunit biogenesis, are each sufficient to significantly increase replicative life span. One mechanism by which reduced 60S subunit levels leads to life span extension is through induction of Gcn4, a nutrient-responsive transcription factor. Genetic epistasis analyses suggest that dietary restriction, reduced 60S subunit abundance, and Gcn4 activation extend yeast life span by similar mechanisms.

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The STE4 and STE18 genes of yeast encode potential β and γ subunits of the mating factor receptor-coupled G protein

Whiteway

Hougan

Dignard

et al. 1989

Cell

496

307

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Rapamycin Reverses Elevated mTORC1 Signaling in Lamin A/C–Deficient Mice, Rescues Cardiac and Skeletal Muscle Function, and Extends Survival

et al. 2012

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Mutations in LMNA, the gene that encodes A-type lamins, cause multiple diseases including dystrophies of the skeletal muscle and fat, dilated cardiomyopathy, and progeria-like syndromes (collectively termed laminopathies). Reduced A-type lamin function, however, is most commonly associated with skeletal muscle dystrophy and dilated cardiomyopathy rather than lipodystrophy or progeria. The mechanisms underlying these diseases are only beginning to be unraveled. We report that mice deficient in Lmna, which corresponds to the human gene LMNA, have enhanced mTORC1 (mammalian target of rapamycin complex 1) signaling specifically in tissues linked to pathology, namely, cardiac and skeletal muscle. Pharmacologic reversal of elevated mTORC1 signaling by rapamycin improves cardiac and skeletal muscle function and enhances survival in mice lacking A-type lamins. At the cellular level, rapamycin decreases the number of myocytes with abnormal desmin accumulation and decreases the amount of desmin in both muscle and cardiac tissue of Lmna–/– mice. In addition, inhibition of mTORC1 signaling with rapamycin improves defective autophagic-mediated degradation in Lmna–/– mice. Together, these findings point to aberrant mTORC1 signaling as a mechanistic component of laminopathies associated with reduced A-type lamin function and offer a potential therapeutic approach, namely, the use of rapamycin-related mTORC1 inhibitors.

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Gene Expression Analyzed by High-resolution State Array Analysis and Quantitative Proteomics

MacKay

Flory

et al. 2004

Molecular & Cellular Proteomics

192

230

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The transcriptome provides the database from which a cell assembles its collection of proteins. Translation of individual mRNA species into their encoded proteins is regulated, producing discrepancies between mRNA and protein levels. Using a new modeling approach to data analysis, a striking diversity is revealed in association of the transcriptome with the translational machinery. Each mRNA has its own pattern of ribosome loading, a circumstance that provides an extraordinary dynamic range of regulation, above and beyond actual transcript levels. Using this approach together with quantitative proteomics, we explored the immediate changes in gene expression in response to activation of a mitogen-activated protein kinase pathway in yeast by mating pheromone. Interestingly, in 26% of those transcripts where the predicted protein synthesis rate changed by at least 3-fold, more than half of these changes resulted from altered translational efficiencies. These observations underscore that analysis of transcript level, albeit extremely important, is insufficient by itself to describe completely the phenotypes of cells under different conditions. Molecular & Cellular Proteomics 3:478 -489, 2004.

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Ribosome Deficiency Protects Against ER Stress in Saccharomyces cerevisiae

et al. 2012

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In Saccharomyces cerevisiae, 59 of the 78 ribosomal proteins are encoded by duplicated genes that, in most cases, encode identical or very similar protein products. However, different sets of ribosomal protein genes have been identified in screens for various phenotypes, including life span, budding pattern, and drug sensitivities. Due to potential suppressors of growth rate defects among this set of strains in the ORF deletion collection, we regenerated the entire set of haploid ribosomal protein gene deletion strains in a clean genetic background. The new strains were used to create double deletions lacking both paralogs, allowing us to define a set of 14 nonessential ribosomal proteins. Replicative life-span analysis of new strains corresponding to ORF deletion collection strains that likely carried suppressors of growth defects identified 11 new yeast replicative aging genes. Treatment of the collection of ribosomal protein gene deletion strains with tunicamycin revealed a significant correlation between slow growth and resistance to ER stress that was recapitulated by reducing translation of wild-type yeast with cycloheximide. Interestingly, enhanced tunicamycin resistance in ribosomal protein gene deletion mutants was independent of the unfolded protein response transcription factor Hac1. These data support a model in which reduced translation is protective against ER stress by a mechanism distinct from the canonical ER stress response pathway and further add to the diverse yet specific phenotypes associated with ribosomal protein gene deletions.T HE yeast ribosome consists of two subunits, the 40S (small) and 60S (large), which together contain four discrete rRNA species and 78 ribosomal proteins (RPs). In Saccharomyces cerevisiae, 59 of the 78 ribosomal proteins are encoded by a pair of paralogous genes, most of which arose through a genome-wide duplication event roughly 100 million years ago (Wolfe and Shields 1997). Only 12% of the duplicated genome remains, and of the paralogous gene pairs present, a majority of ribosomal proteins genes (RPGs) are in a class that exhibits little or even decelerated evolution (Kellis et al. 2004). Remarkably, 21 of the 59 RPG pairs encode identical proteins, and the others are highly similar (Supporting Information, Table S1). The prevalence of synthetic lethality among RPG paralogs indicates that the two protein products are generally redundant for at least one essential function (Dean et al. 2008).Despite the significant similarity among RPG paralogs, many reports have described differential effects of deleting only one, and such instances have been observed even in cases where the encoded protein product is identical (Briones et al. 1998). One explanation for this is that the two genes contribute different amounts of protein, and neither is alone sufficient to support wild-type growth. In the case of Rpl16, for example, expression of either RPL16A or RPL16B can rescue the growth defect of cells lacking RPL16B (Rotenberg et al. 1988). Consistently, the RPL16...

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Vivian L. MacKay

Yeast Life Span Extension by Depletion of 60S Ribosomal Subunits Is Mediated by Gcn4

The STE4 and STE18 genes of yeast encode potential β and γ subunits of the mating factor receptor-coupled G protein

Rapamycin Reverses Elevated mTORC1 Signaling in Lamin A/C–Deficient Mice, Rescues Cardiac and Skeletal Muscle Function, and Extends Survival

Gene Expression Analyzed by High-resolution State Array Analysis and Quantitative Proteomics

Ribosome Deficiency Protects Against ER Stress in Saccharomyces cerevisiae

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