Identification of protein kinase disruptions as suppressors of the calcium sensitivity of S. cerevisiae Δptp2 Δmsg5 protein phosphatase double disruptant

The double disruptant of the S. cerevisiae protein phosphatase (PPase) genes, PTP2 (phosphotyrosine-specific PPase) and MSG5 (phosphotyrosine and phosphothreonine/serine-PPase) causes calcium-sensitive growth (Ca^s). Previous study using Fluorescent-activated cell sorting (FACS) analysis showed that this growth defect with calcium occurs at G1–S transition in the cell cycle. We discovered that six non-essential protein kinase (PKase) disruptions (Δbck1, Δmkk1, Δslt2/Δmpk1, Δmck1, Δssk2 and Δyak1) suppressed the Ca^s-phenotype of the Δptp2 Δmsg5 double disruptant. Bck1p, Mkk1p and Slt2p are components of the mitogen-activated protein kinase (MAPK) cascade of cell wall integrity pathway (Slt2 pathway), and Mck1p is its down regulator. Ssk2p is the MAPK kinase kinase of the high-osmolarity glycerol (HOG) pathway, while Yak1p is a negative regulator for the cAMP-dependent PKA pathway. FACS analysis revealed that only the disruption of Δssk2 and Δyak1 but not Δbck1, Δmkk1, Δslt2 and Δmck1 was able to suppress the delayed G1–S transition, suggesting that suppression of the growth defect is not always accompanied by suppression of the G1–S transition delay. The discovery of these PKases as suppressors revealed that in addition to the previously anticipated Slt2 pathway, HOG, Yak1p and Mck1p regulatory pathways may also be involved in the calcium sensitivity of the Δptp2 Δmsg5 double disruptant.     

Genome-wide mapping of unexplored essential regions in the Saccharomyces cerevisiae genome: evidence for hidden synthetic lethal combinations in a genetic interaction network

Despite systematic approaches to mapping networks of genetic interactions in Saccharomyces cerevisiae, exploration of genetic interactions on a genome-wide scale has been limited. The S. cerevisiae haploid genome has 110 regions that are longer than 10 kb but harbor only non-essential genes. Here, we attempted to delete these regions by PCR-mediated chromosomal deletion technology (PCD), which enables chromosomal segments to be deleted by a one-step transformation. Thirty-three of the 110 regions could be deleted, but the remaining 77 regions could not. To determine whether the 77 undeletable regions are essential, we successfully converted 67 of them to mini-chromosomes marked with URA3 using PCR-mediated chromosome splitting technology and conducted a mitotic loss assay of the mini-chromosomes. Fifty-six of the 67 regions were found to be essential for cell growth, and 49 of these carried co-lethal gene pair(s) that were not previously been detected by synthetic genetic array analysis. This result implies that regions harboring only non-essential genes contain unidentified synthetic lethal combinations at an unexpectedly high frequency, revealing a novel landscape of genetic interactions in the S. cerevisiae genome. Furthermore, this study indicates that segmental deletion might be exploited for not only revealing genome function but also breeding stress-tolerant strains.     

Prolonged copulation and spermatophore size ejaculated in the sulfur butterfly,Colias erate (lepidoptera: pieridae) under selective harassments of mated pairs by conspecific lone males

Uninterrupted copula durations between virgin male and virgin female in the sulfur butterflyColias erate successfully lasted about 45 min in the greenhouse. Without harassment, the copula duration of virgin females with wild young males was similar to that in the greenhouse. The male structured a spermatophore about 40 min after copula initiation. Young males ejaculated bigger spermatophores than old males, while age did not influence copula duration. The mating behaviors of the wild males and the tethered females were observed and the copula duration was recorded. All copulating pairs were harassed by single males in the field, and the copula duration was increased, though there was no difference in spermatophore size. Single males harassed pairs with old males significantly longer duration than pairs with young males. Severe harassment elicited no particular response by the pairs. There was a successful mating takeover by a single male. Females tended to be more likely to re-mate when they had fewer spermatophores in the bursa copulatrix. The females that accepted re-mating retained smaller ejaculates in the bursa copulatrix than those that refused re-mating. Lone males seemed to be able to discriminate old and young males in copula. The harassment of pair with old males might be advantageous for single males to increase mating success.     

Advances in molecular methods to alter chromosomes and genome in the yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

A fundamental issue in biotechnology is how to breed useful strains of microorganisms for efficient production of valuable biomaterials. On-going and more recent developments in gene manipulation technologies and chromosomal and genomic modifications in particular have facilitated important contributions in this area. “Chromosome manipulation technology” as an outgrowth of “gene manipulation technology” may provide opportunities for creating novel strains of organisms with a variety of genomic constitutions. A simple and rapid chromosome splitting technology called “PCR-mediated chromosome splitting” (PCS) that we recently developed has made it possible to manipulate chromosomes and genomes on a large scale in an industrially important microorganism, Saccharomyces cerevisiae. This paper focuses on recent advances in molecular methods for altering chromosomes and genome in S. cerevisiae featuring chromosome splitting technology. These advances in introducing large-scale genomic modifications are expected to accelerate the breeding of novel strains for biotechnological purposes, and to reveal functions of presently uncharacterized chromosomal regions in S. cerevisiae and other organisms.     

Large scale deletions in the <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> genome create strains with altered regulation of carbon metabolism

Saccharomyces cerevisiae, for centuries the yeast that has been the workhorse for the fermentative production of ethanol, is now also a model system for biological research. The recent development of chromosome-splitting techniques has enabled the manipulation of the yeast genome on a large scale, and this has allowed us to explore questions with both biological and industrial relevance, the number of genes required for growth and the genome organization responsible for the ethanol production. To approach these questions, we successively deleted portions of the yeast genome and constructed a mutant that had lost about 5% of the genome and that gave an increased yield of ethanol and glycerol while showing levels of resistance to various stresses nearly equivalent to those of the parental strain. Further systematic deletion could lead to the formation of a eukaryotic cell with a minimum set of genes exhibiting appropriately altered regulation for enhanced metabolite production. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

CDC19 encoding pyruvate kinase is important for high-temperature tolerance in Saccharomyces cerevisiae

Use of thermotolerant strains is a promising way to reduce the cost of maintaining optimum temperatures in the fermentation process. Here we investigated genetically a Saccharomyces cerevisiae strain showing a high-temperature (41°C) growth (Htg(+)) phenotype and the result suggested that the Htg(+) phenotype of this Htg(+) strain is dominant and under the control of most probably six genes, designated HTG1 to HTG6. As compared with a Htg(-) strain, the Htg(+) strain showed a higher survival rate after exposure to heat shock at 48°C. Moreover, the Htg(+) strain exhibited a significantly high content of trehalose when cultured at high temperature and stronger resistance to Congo Red, an agent that interferes with cell wall construction. These results suggest that a strengthened cell wall in combination with increased trehalose accumulation can support growth at high temperature. The gene CDC19, encoding pyruvate kinase, was cloned as the HTG2 gene. The CDC19 allele from the Htg(+) strain possessed five base changes in its upstream region, and two base changes resulting in silent mutations in its coding region. Interestingly, the latter base changes are probably responsible for the increased pyruvate kinase activity of the Htg(+) strain. The possible mechanism leading to this increased activity and to the Htg(+) phenotype, which may lead to the activation of energy metabolism to maintain cellular homeostasis, is discussed.     

Chromosome-shuffling technique for selected chromosomal segments in Saccharomyces cerevisiae

We describe a novel chromosome engineering technique for shuffling selected regions of chromosomes from two strains in Saccharomyces cerevisiae: The technique starts with the construction of MAT a and MATα strains in which a particular chromosome is split at exactly the same site in both strains such that the split chromosomes generated are marked with different markers. The two strains are then crossed, and the resultant diploid is cultivated in nutrient medium to induce loss of the split chromosome originating from either of the strains. We predicted that some of these clones that are hemizygous for the split chromosome would spontaneously restore a homozygous configuration of the split chromosome during cultivation. We verified this prediction by tetrad analysis and quantitative Southern hybridization analysis, indicating that it is possible to create diploid hybrids in which a selected region of a chromosome from one strain is replaced by the corresponding chromosomal region from another strain. We also found that some chromosomal segments maintain a hemizygous state. This novel technique, which we call ‘chromosome shuffling’, could provide a new tool to analyze phenotypic alterations caused by the replacement or hemizygosity of a selected chromosomal region in not only laboratory but also industrial strains of S. cerevisiae.