Yeast

About: Yeast is a research topic. Over the lifetime, 31777 publications have been published within this topic receiving 868967 citations. The topic is also known as: yeasts.

Functional complementation of yeast ste6 by a mammalian multidrug resistance mdr gene.

Abstract: Multidrug resistance in mammalian tumor cells is associated with the overexpression of mdr genes encoding P-glycoproteins, which function as drug efflux pumps. A yeast homolog of mdr, STE6, mediates export of a-factor mating peptide. Yeast MATa cells carrying a ste6 deletion produce no extracellular a-factor and therefore are defective in mating. Expression of a complementary DNA for the mouse mdr3 gene in a yeast ste6 deletion strain restored ability to export a-factor and to mate. A mutation (a serine to phenylalanine substitution at amino acid 939) known to affect the activity of the mdr3 gene product abolished its ability to complement the yeast ste6 deletion. Thus, functions of P-glycoproteins in normal mammalian cells may include the transmembrane export of endogenous peptides.

Characterization of Alcohol-induced Filamentous Growth in Saccharomyces cerevisiae

Abstract: Diploid cells of the budding yeast Saccharomyces cerevisiae starved for nitrogen differentiate into a filamentous growth form. Poor carbon sources such as starches can also stimulate filamentation, whereas haploid cells undergo a similar invasive growth response in rich medium. Previous work has demonstrated a role for various alcohols, by-products of amino acid metabolism, in altering cellular morphology. We found that several alcohols, notably isoamyl alcohol and 1-butanol, stimulate filamentous growth in haploid cells in which this differentiation is normally repressed. Butanol also induces cell elongation and changes in budding pattern, leading to a pseudohyphal morphology, even in liquid medium. The filamentous colony morphology and cell elongation require elements of the pheromone-responsive MAPK cascade and TEC1, whereas components of the nutrient-sensing machinery, such as MEP2, GPA2, and GPR1, do not affect this phenomenon. A screen for 1-butanol–insensitive mutants identified additional proteins that regulate polarized growth (BUD8, BEM1, BEM4, and FIG1), mitochondrial function (MSM1, MRP21, and HMI1), and a transcriptional regulator (CHD1). Furthermore, we have also found that ethanol stimulates hyperfilamentation in diploid cells, again in a MAPK-dependent manner. Together, these results suggest that yeast may sense a combination of nutrient limitation and metabolic by-products to regulate differentiation.

Transition Metal Transport in Yeast

Abstract: All eukaryotes and most prokaryotes require transition metals. In recent years there has been an enormous advance in our understanding of how these metals are transported across the plasma membrane. Much of this understanding has resulted from studies on the budding yeast Saccharomyces cerevisiae. A variety of genetic and biochemical approaches have led to a detailed understanding of how transition metals such as iron, copper, manganese, and zinc are acquired by cells. The regulation of metal transport has been defined at both the transcriptional and posttranslational levels. Results from studies on S. cerevisiae have been used to understand metal transport in other species of yeast as well as in higher eukaryotes.