Induction and genetics of two alpha-galactosidase activities in Saccharomyces cerevisiae

Summary The induction of -galactosidase of Saccharomyces cerevisiae was investigated. We have demonstrated the existence of inducible internal and external -galactosidase activities and have studied the relationship between the two -galactosidases by examining a mutant strain which lacks both the internal and external activities. The mutant possesses a mutation in a single locus (mel 1-1) which does not affect the synthesis of the other galactose pathway enzymes or the ability of the yeast to grow on media containing only galactose as the carbon source. Genetic studies of the mutant indicate that mel 1-1 is recessive and allelic to the wild type allele for melibiose fermentation Mel 1.This investigation was supported in part by Grant No. AM15325 from the National Institutes of Arthritis, Metabolism and Digestive Diseases, and a grant from the Office of Research Administration, University of Hawaii. R.G. Buckholz was a National Science Foundation Pre-Doctoral Fellow during part of this study     

Molecular analysis of alpha-galactosidase MEL genes from Saccharomyces sensu stricto

To infer the molecular evolution of yeast Saccharomyces sensu stricto from analysis of the alpha-galactosidase MEL gene family, two new genes were cloned and sequenced from S. bayanus var. bayanus and S. pastorianus. Nucleotide sequence homology of the MEL genes of S. bayanus var. bayanus (MELb), S. pastorianus (MELpt), S. bayanus var. uvarum (MELu), and S. carlsbergensis (MELx) was rather high (94.1-99.3%), comparable with interspecific homology (94.8-100%) of S. cerevisiae MEL1-MEL11. Homology of the MEL genes of sibling species S. cerevisiae (MEL1), S. bayanus (MELb), S. paradoxus (MELp), and S. mikatae (MELj) was 76.2-81.7%, suggesting certain species specificity. On this evidence, the alpha-galactosidase gene of hybrid yeast S. pastorianus (S. carlsbergensis) was assumed to originate from S. bayanus rather than from S. cerevisiae.     

Eliminating gene conversion improves high-throughput genetics in Saccharomyces cerevisiae

Synthetic genetic analysis was improved by eliminating leaky expression of the HIS3 reporter and gene conversion between the HIS3 reporter and his3Delta1. Leaky expression was eliminated using 3-aminotriazole and gene conversion was eliminated by using the Schizosaccharomyces pombe his5+ gene, resulting in a 5- to 10-fold improvement in the efficiency of SGA.     

Physiological studies in aerobic batch cultivations of Saccharomyces cerevisiae strains harboring the MEL1 gene

Physiological studies of Saccharomyces cerevisiae strains harboring the MEL1 gene were carried out in aerobic batch cultivations on glucose-galactose mixtures and on the disaccharide melibiose, which is hydrolyzed by the enzyme melibiase (Mel1, EC 3.2.1.22) into a glucose and a galactose moiety. The strains examined (T200, T256, M24, and TH1) were all derived from the bakers' and distillers' strain of S. cerevisiae, DGI 342. All the strains showed a significant higher ethanol yield when growing on glucose, and half the biomass yield, compared with growth on galactose. The maximum specific uptake rates were 2.5-3.3-fold higher on glucose than on galactose for all the strains examined, and hence, ethanol production was pronounced on glucose due to respiro-fermentative metabolism. The T256 strain and the T200 strain having the MEL1 gene inserted in the HXK2 locus and the LEU2 locus, respectively, hydrolyzed melibiose with low specific hydrolysis rates of 0.03 C-mol/g/h and 0.04 C-mol/g/h, respectively. This resulted in high biomass yields on melibiose in the order of 10 g/C-mol compared with 3.7 g/C-mol for M24 and 1.6 g/C-mol for TH1. The M24 strain, constructed by classical breeding, and the mig1/gal80 disrupted and melibiase-producing strain TH1, were superior in their ability to hydrolyze melibiose into glucose and galactose showing specific melibiose hydrolysis rates of 0.17 C-mol/g/h and 0.24 C-mol/g/h, respectively. Hence, high ethanol yields on melibiose were obtained with these two strains. Growth on the glucose-galactose mixtures showed a reduction of glucose control successfully obtained in the M24 strain and the TH1 strain.     

Ascospore Formation in the Yeast Saccharomyces cerevisiae

Sporulation of the baker's yeast Saccharomyces cerevisiae is a response to nutrient depletion that allows a single diploid cell to give rise to four stress-resistant haploid spores. The formation of these spores requires a coordinated reorganization of cellular architecture. The construction of the spores can be broadly divided into two phases. The first is the generation of new membrane compartments within the cell cytoplasm that ultimately give rise to the spore plasma membranes. Proper assembly and growth of these membranes require modification of aspects of the constitutive secretory pathway and cytoskeleton by sporulation-specific functions. In the second phase, each immature spore becomes surrounded by a multilaminar spore wall that provides resistance to environmental stresses. This review focuses on our current understanding of the cellular rearrangements and the genes required in each of these phases to give rise to a wild-type spore.     

A new transformation system of Saccharomyces cerevisiae with blasticidin S deaminase gene

A new method for transformation of Saccharomyces cerevisiae that allows selection was developed. As the frequency of spontaneous blasticidin S resistant mutants from diploid type yeast strain (X-2180AB) was 5.2×10^–6, which was a thousandfold less than that from haploid type yeast strain (X-2180B), it was considered that the mechanism of spontaneous blasticidin S resistant mutations was related to recessive gene. Industrial yeasts, which were diploid, were transformed with blasticidin S deaminase gene from Aspergillus terreus to blasticidin S resistance. Expression of blasticidin S deaminase gene allowed selection of transformants from industrial yeasts.     

Specificity and genetics of S-adenosylmethionine transport in Saccharomyces cerevisiae.

The specificity of a transport system for S-adenosylmethionine was determined through the use of structurally related derivatives. Of the compounds tested, the analogues S-adenosylethionine and S-inosylmethionine and the naturally occurring compounds S-adenosyl-(5')-3-methylthiopropylamine and S-adenosylhomocysteine competitively inhibited uptake of the sulfonium compound. Ki values for these compounds indicate that the order of affinity for the transport protein is S-adenosylmethionine congruent to S-adenosyl-(5')-3-methyl-thiopropylamine greater than S-adenosylethionine greater than S-inosylmethionine greater than S-adenosylhomocysteins. S-adenosyl-(2-hydroxy-4-methylthio)butyric acid exerted inhibition of a mixed type. S-insoyl-(2-hydroxy-4-methylthio)butyric acid, S-inosylhomocysteine, and S-ribosylhomocysteine were without effect. On the basis of the inhibition data, the methionine-amino, adenine-amino, and methyl groups were identified as group important in the binding of S-adenosylmethionine to the transport protein. Comparison is made with the specificities of various transmethylating enzymes utilizing S-adenosylmethionine. In addition, a number of conventional and temperature-sensitive S-adenosylmethionine transport mutants were isolated and analyzed in an attempt to identify the structural character of the specific transport protein(s). The data obtained suggest that only a single gene (a single polypeptide) is involved in specific S-adenosylmethionine transport. Apparent interallelic complementation supports the assumption that the functional form of the protein is composed of two or more copies of a monomer.     

Atg9 Trafficking in Yeast Saccharomyces cerevisiae

Autophagy can be divided into selective and non-selective modes. This process is considered selective when a precise cargo is specifically and exclusively incorporated into autophagosomes, the double-membrane vesicles that are the hallmark of autophagy. In contrast, during nonselective, bulk autophagy, cytoplasmic components are randomly enwrapped into autophagosomes. To date, approximately 30 autophagy-related genes called ATG have been identified. Sixteen of them compose the general basic machinery catalyzing the formation of double-membrane vesicles in all eukaryotic cells. The rest of them are often not conserved between species and cooperate with the basic Atg proteins during either selective or nonselective autophagy. Atg9 is the only integral membrane component of the conserved Atg machinery and appears to be a crucial organizational element.5 Recent studies in the S. cerevisiae have shown that Atg9 transport is differentially regulated depending on the autophagy mode. In this addendum, we will review and discuss what has recently been unveiled about yeast S. cerevisiae Atg9 trafficking, its modulators and its potential role in double-membrane vesicle biogenesis.

Addendum to:

Atg9 Sorting from Mitochondria is Impaired in Early Secretion and VFT Complex Mutants in Saccharomyces cerevisiae

F. Reggiori and D.J. Klionsky

J Cell Sci 2006: 119:2903-11     

A Fine-Structure Map of Spontaneous Mitotic Crossovers in the Yeast Saccharomyces cerevisiae

Homologous recombination is an important mechanism for the repair of DNA damage in mitotically dividing cells. Mitotic crossovers between homologues with heterozygous alleles can produce two homozygous daughter cells (loss of heterozygosity), whereas crossovers between repeated genes on non-homologous chromosomes can result in translocations. Using a genetic system that allows selection of daughter cells that contain the reciprocal products of mitotic crossing over, we mapped crossovers and gene conversion events at a resolution of about 4 kb in a 120-kb region of chromosome V of Saccharomyces cerevisiae. The gene conversion tracts associated with mitotic crossovers are much longer (averaging about 12 kb) than the conversion tracts associated with meiotic recombination and are non-randomly distributed along the chromosome. In addition, about 40% of the conversion events have patterns of marker segregation that are most simply explained as reflecting the repair of a chromosome that was broken in G1 of the cell cycle.     

A second transport ATPase gene in Saccharomyces cerevisiae

A second transport ATPase gene from Saccharomyces cerevisiae has been identified by hybridization to a PMA1 probe and sequenced. The gene called PMA2 encodes a polypeptide of Mr = 102,157, which, with the exception of the 144 amino-terminal residues, is highly homologous to the structural gene PMA1 for the H+-ATPase. It is localized on the chromosome XVI at 16.7 centimorgan from gal4 and is not essential for haploid growth. Comparison between the upstream, noncoding DNA regions of PMA1 and PMA2 indicates that the two genes are controlled differently. The extensive amino acid sequence homology with the fungal H+-ATPases described so far indicates that the PMA2-encoded protein is also able to function as a H+ pump. This is supported by the observation that in pma1 mutants with reduced plasma membrane ATPase activity, disruption of the PMA2 gene confers the ability to grow under alkaline pH conditions. Slower development of diploids is also observed on normal minimal medium after bilateral disruption of PMA2 in the two parents.     

A new RAS mutation that suppresses the CDC25 gene requirement for growth of Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, the activation of adenylate cyclase requires the products of the RAS genes and of CDC25. We isolated several dominant extragenic suppressors of the yeast cdc25 mutation. They did not suppress a thermosensitive allele of the adenylate cyclase gene (CDC35). One of these suppressors was a mutated RAS2 gene in which the transition C/G----T/A at position 455 resulted in replacement of threonine 152 by isoleucine in the protein. The same mutation in a v-Ha-ras gene reduces the affinity of p21 for guanine nucleotides (L.A. Feig, B. Pan, T.M. Roberts, and G.M. Cooper, Proc. Natl. Acad. Sci. USA 83:4607-4611, 1986). These results support a model in which the CDC25 gene product is the GDP-GTP exchange factor regulating the activity of the RAS gene product.     

De novo origination of a new protein-coding gene in Saccharomyces cerevisiae

Origination of new genes is an important mechanism generating genetic novelties during the evolution of an organism. Processes of creating new genes using preexisting genes as the raw materials are well characterized, such as exon shuffling, gene duplication, retroposition, gene fusion, and fission. However, the process of how a new gene is de novo created from noncoding sequence is largely unknown. On the basis of genome comparison among yeast species, we have identified a new de novo protein-coding gene, BSC4 in Saccharomyces cerevisiae. The BSC4 gene has an open reading frame (ORF) encoding a 132-amino-acid-long peptide, while there is no homologous ORF in all the sequenced genomes of other fungal species, including its closely related species such as S. paradoxus and S. mikatae. The functional protein-coding feature of the BSC4 gene in S. cerevisiae is supported by population genetics, expression, proteomics, and synthetic lethal data. The evidence suggests that BSC4 may be involved in the DNA repair pathway during the stationary phase of S. cerevisiae and contribute to the robustness of S. cerevisiae, when shifted to a nutrient-poor environment. Because the corresponding noncoding sequences in S. paradoxus, S. mikatae, and S. bayanus also transcribe, we propose that a new de novo protein-coding gene may have evolved from a previously expressed noncoding sequence.