Genetic analysis of pleiotropic effects of pho85 mutations in yeast Saccharomyces cerevisiae

The cyclin-dependent phosphoprotein kinase Pho85p is involved in the regulation of metabolism and cell cycle in the yeast Saccharomyces cerevisiae. It is known that mutations in the PHO85 gene lead to constitutive synthesis of Pho5p acidic phosphatase, a delay in cell growth on media containing nonfermentable carbon sources, sensitivity to high temperature, and other phenotypic effects. A lack of growth at 37 degrees C and on a medium with alcohol as the carbon source was shown to be associated with the rapid accumulation of nuclear ts and mitochondrial [rho-] mutations occurring in the background of gene PHO85 inactivation. Thus, Pho85p seems to play an important role in the maintenance of yeast genome stability.     

Genetic analysis of spontaneous suppressors of the pho85 mutation in the yeast Saccharomyces cerevisiae

Chaperones are known to play an important role in complexation of cyclin-dependent kinases with cyclins. In yeast cells growing in the presence of phosphate, cyclin-dependent kinase Pho85p and cyclin Pho80p form a complex and phosphorylate activator Pho4p. As a result, Pho4p is exported from the nucleus, and the PHO5 gene is not transcribed. The mutations suppressing the pho85 mutation were analyzed in order to identify genes which code for chaperones involved in the formation of the Pho80p-Pho85p complex in the presence of environmental phosphate. Dominant mutations DSP1, DSP2, and DSP4-6 were found. It is shown that the DSP1 gene is 2.1 cM away from the PHO85 gene on chromosome XVI and probably coincides with the EGD1 gene coding for a chaperone.     

Genetic Analysis of Pleiotropic Effects of pho85 Mutations in Yeast Saccharomyces cerevisiae

The cyclin-dependent phosphoprotein kinase Pho85p is involved in the regulation of metabolism and cell cycle in the yeast Saccharomyces cerevisiae. It is known that mutations in the PHO85gene lead to constitutive synthesis of Pho5p acidic phosphatase, a delay in cell growth on media containing nonfermentable carbon sources, sensitivity to high temperature, and other phenotypic effects. A lack of growth at 37°C and on a medium with alcohol as the carbon source was shown to be associated with the rapid accumulation of nuclear ts and mitochondrial [rho ^– ] mutations occurring in the background of gene PHO85 inactivation. Thus, Pho85p seems to play an important role in the maintenance of yeast genome stability.     

Biochemical Genetics in St. Petersburg University: From the gene-enzyme model to medical biotechnology

The history of biochemical genetics research in St. Petersburg (Leningrad) State University is described. The main research projects and achievements of the Laboratory of Biochemical Genetics in studies on the mechanisms of gene expression control, coordinated regulation of metabolism, and the relationship of the physiological state of yeast cells with the maintenance of genetic stability are discussed. The fundamental importance of studies on the acid phosphatase model for the formation and development of medical biotechnology in St. Petersburg University is demonstrated.     

The absence of cyclin-dependent protein kinase Pho85 affects stability of mitochondrial DNA in yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

The cyclin-dependent protein kinase Pho85 is involved in the regulation of phosphate metabolism in yeast Saccharomyces cerevisiae. Mutations in the PHO85 gene lead to constitutive synthesis of Pho5 acid phosphatase, a delay in cell growth on media containing nonfermentable carbon sources, and other pleiotropic effects. In this work, it was shown that the accumulation of respiratory incompetent cells occurs with high frequency in strains carrying pho85 mutations as early as during the first cell divisions, and the number of these cells at the early logarithmic growth phase of the culture promptly reaches virtually 100%. Cytological analysis revealed a high accumulation rate of [rho⁰] cells in the background of gene pho85 that may be related to disturbances in the distribution of mitochondrial nucleoids rather than to changes in morphology of mitochondria and a delay in their transport into the bud. Genetic analysis revealed that secondary mutations pho4, pho81, pho84, and pho87 stabilize nucleoids and prevent the loss of mitochondrial DNA caused by pho85. These results provide an evidence for the influence of intracellular phosphate concentration on the inheritance of mitochondrial nucleoids, but do not exclude the possibility that the occurrence of mutation pho4 in the background of gene pho85 may change the expression level of other genes required for the stabilization of mitochondrial functions.     

Biochemical genetics in St. Petersburg university: from the gene-enzyme model to medical biotechnology

The history of biochemical genetic research in St. Petersburg (Leningrad) State University is described. The main research projects and achievements of the Laboratory of Biochemical Genetics in studies on the mechanisms of gene expression control, coordinated regulation of metabolism, and the relationship of the physiological state of yeast cells with the maintenance of genetic stability are discussed. The fundamental importance of studies on the acid phosphatase model for the formation and development of medical biotechnology in St. Petersburg University is demonstrated.     

Prospects for the Application of Yeast Display in Biotechnology and Cell Biology (Review)

The technology of the yeast cell surface display, which appeared 20 years ago and was based on the displaying of target proteins on the cell surface via fusion to an abundant cell wall protein finds broad application in basic and applied research. The main advantage of the cell surface display on the basis of eukaryotic microorganisms—yeast—is the opportunity for correct modification of mammalian proteins. The cell surface display is an important tool for the analysis and understanding of protein function and protein–protein interactions and for the screening of novel clones from peptide and protein libraries. This technology makes it possible to obtain cells with novel abilities, such as catalytic functions and affinity binding to valuable ligands, including rare and heavy metals. It provides the chance to use yeast in biotechnology and in bioremediation and biomonitoring of the environment. The review considers the methods of obtaining a cell surface display on the basis of the yeasts Saccharomyces cerevisiae, Pichia pastoris, and Yarrowia lipolytica, the properties of anchor proteins, and the main fields of yeast display technology.     

Genetic mapping of genes regulating synthesis of acid phosphatases in the yeast Saccharomyces cerevisiae of the Peterhoff yeast collection

Genetic mapping of yeast genes ACP5, acp83 and ACP82 was performed. According to the results obtained, ACP5 and acp83 are located in the chromosome VI and ACP82--in the chromosome XVI. Based on identity of chromosome location and phenotypes of mutations arising, it was proposed that ACP5 and acp83 are homologous to PHO4 and pho82 genes, respectively, and ACP82--to PHO85 in the yeasts of the same line.