Suppressor analysis points to the subtle role of the LAG1 ceramide synthase gene in determining yeast longevity

Autor:	James C. Jiang, Paul A. Kirchman, S. Michal Jazwinski, Meghan Allen
Rok vydání:	2004
Předmět:	Aging Ceramide Cell signaling Saccharomyces cerevisiae Proteins media_common.quotation_subject Molecular Sequence Data Saccharomyces cerevisiae Biology Biochemistry chemistry.chemical_compound Endocrinology Gene Expression Regulation Fungal Genetics Amino Acid Sequence Molecular Biology Ceramide synthase Gene media_common Regulation of gene expression Dose-Response Relationship Drug Longevity Galactose Membrane Proteins Cell Biology Sphingolipid Yeast Cell biology chemistry Oxidoreductases Sequence Alignment Gene Deletion Plasmids
Zdroj:	Experimental Gerontology. 39:999-1009
ISSN:	0531-5565
DOI:	10.1016/j.exger.2004.03.026
Popis:	Individual yeast cells display a finite replicative capacity. LAG1 was identified as a gene that is differentially expressed during the yeast replicative life span and was shown to play a role in determining yeast longevity. This gene is not essential, but simultaneous deletion of LAG1 and its close homologue LAC1 is lethal. Lag1p and Lac1p have been found to be an essential component of ceramide synthase. In this study, multicopy suppressors of the lethality of a lag1delta lac1delta double mutant were isolated to help clarify the role of LAG1 in yeast longevity. The two multicopy suppressors YBR183w (YPC1) and YPL087w (YDC1) encode ceramidases unrelated to Lag1p and Lac1p, which were previously found to support the reverse reaction of ceramide synthesis. Multiple copies of YPC1 were much more efficient than YDC1 in rescuing cell growth. They were also much more effective in rescuing the life span of a lag1delta lac1delta double mutant, sustaining a life span approaching that obtained by the restoration of LAG1 expression. Neither deletion of LAC1 nor overexpression of YPC1 had a detectable effect on wild-type life span. However, the overexpression of LAG1 had a bimodal effect on longevity, with moderate expression resulting in increased longevity and with higher expression curtailing life span. These results suggest that subtle changes in ceramide/sphingolipid metabolism are important in determining yeast longevity. They also indicate that Lag1p plays a special role in this relationship. Homologues of Lag1p have been identified in higher eukaryotes, including human, raising the possibility that ceramide and other sphingolipid metabolites play a wider role in biological aging.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::bdc29c52bc0b4f7eb6c775c75cd7e329 https://doi.org/10.1016/j.exger.2004.03.026 Zobrazit plný text záznamu Full Text from ScienceDirect