Francisco Estruch

Hyperphosphorylation of Msn2p and Msn4p in response to heat shock and the diauxic shift is inhibited by cAMP in Saccharomyces cerevisiae.

In response to various stresses, as well as during the diauxic transition, the Msn2p and Msn4p transcription factors of Saccharomyces cerevisiae are activated and induce a large set of genes. This activation is inhibited by the Ras/cAMP/PKA (cAMP-dependent protein kinase) pathway. Here we show by immunoblotting experiments that Msn2p and Msn4p are phosphorylated in vivo during growth on glucose, and become hyperphosphorylated at the diauxic transition and upon heat shock. This hyperphosphorylation is correlated with activation of Msn2/4p-dependent transcription. An increased level of cAMP prevents and reverses these hyperphosphorylations, indicating that kinases other than PKA are involved. These results suggest that PKA and stress-activated kinases control Msn2/4p activity by antagonistic phosphorylation. It was also noted that Msn4p is transiently increased at the diauxic transition. Msn2p and Msn4p present different hyperphosphorylation patterns in response to different stresses.

Baker’s yeast: challenges and future prospects

In the past few years, recombinant DNA technology has led to the apparition of new baker’s yeast strains, which have optimized or novel properties, and in the near future, it is expected that this tool will produce a huge spectrum of specialized yeasts of high added value. Their introduction in the manufacturing market will produce a dramatic change in formulation, ingredients, or processing conditions currently used in the baking practice and will provide new products with enhanced flavour, textures, or extended shelf life. As the potential of recombinant gene expression and metabolic engineering is more understood, this technology could be further addressed to attend to public and consumer demands of environmentally sound processes and healthy and convenient products. This chapter reviews the most important advances in the genetic improvement of baker’s yeast, puts emphasis on fundamental and applied aspects, and discusses perspectives and outlooks in this field.

DNase I sensitivity of the chromatin of the yeast SUC2 gene for invertase.

SummaryThe DNase I sensitivity of chromatin of the yeast SUC2 gene, which encodes two forms of invertase, has been studied both in the genome and in a multicopy plasmid carrying the gene and its flanking sequences. Whereas little if any difference in the DNase I sensitivity of the flanking regions was found between the repressed and the derepressed states, derepression of the gene was accompanied by a large increase in the sensitivity of the transcribed region. A well-defined DNase I hypersensitive site was found centered at ∼ 120 bp downstream from the end of the coding region. This site seems to be flanked in the 3′ non-coding region by strictly positioned nucleosomes, and the structure of this region changes upon derepression. In the 5′ non-conding region two DNase I hypersensitive sites have been found flanking the TATA box and a set of three closely spaced hypersensitive sites occurs in an upstream regulatory sequence. The structure of these latter sites depends on the on-off state of transcription.

A genetic screen in Saccharomyces cerevisiae identifies new genes that interact with mex67-5, a temperature-sensitive allele of the gene encoding the mRNA export receptor

The Mex67p protein, together with Mtr2p, functions as the mRNA export receptor in Saccharomyces cerevisiae by interacting with both mRNA and nuclear pore complexes. To identify genes that interact functionally with MEX67, we used transposon insertion to search for mutations that suppressed the temperature-sensitive mex67-5 allele. Four suppressors are described here. The screen revealed that mutant Mex67-5p, but not wild-type Mex67p, is a target of the nuclear protein quality control mediated by San1p, a ubiquitin-protein ligase that participates in degradation of aberrant chromatin-associated proteins. Our finding that overexpression of the SPT6 gene alleviates the growth defects of the mex67-5 strain, together with the impairment of poly(A)+ RNA export caused by depletion of Spt6p or the related protein Iws1p/Spn1p, supports the mechanism proposed in mammalian cells for Spt6-mediated co-transcriptional loading of mRNA export factors during transcription elongation. Finally, our results also uncovered genetic connections between Mex67p and the poly(A) nuclease complex and with components of chromatin boundary elements.

The Yeast RNA Polymerase II-associated Factor Iwr1p Is Involved in the Basal and Regulated Transcription of Specific Genes

RNA polymerase II (RNA pol II) is a multisubunit enzyme that requires many auxiliary factors for its activity. Over the years, these factors have been identified using both biochemical and genetic approaches. Recently, the systematic characterization of protein complexes by tandem affinity purification and mass spectroscopy has allowed the identification of new components of well established complexes, including the RNA pol II holoenzyme. Using this approach, a novel and highly conserved factor, Iwr1p, that physically interacts with most of the RNA pol II subunits has been described in yeast. Here we show that Iwr1p genetically interacts with components of the basal transcription machinery and plays a role in both basal and regulated transcription. We report that mutation of the IWR1 gene is able to bypass the otherwise essential requirement for the transcriptional regulator negative cofactor 2, which occurs with different components of the basal transcription machinery, including TFIIA and subunits of the mediator complex. Deletion of the IWR1 gene leads to an altered expression of specific genes, including phosphate-responsive genes and SUC2. Our results show that Iwr1p is a nucleocytoplasmic shuttling protein and suggest that Iwr1p acts early in the formation of the pre-initiation complex by mediating the interaction of certain activators with the basal transcription apparatus.

Specific defects in different transcription complexes compensate for the requirement of the negative cofactor 2 repressor in Saccharomyces cerevisiae.

Negative cofactor 2 (NC2) has been described as an essential and evolutionarily conserved transcriptional repressor, although in vitro and in vivo experiments suggest that it can function as both a positive and a negative effector of transcription. NC2 operates by interacting with the core promoter and components of the basal transcription machinery, like the TATA-binding protein (TBP). In this work, we have isolated mutants that suppress the growth defect caused by the depletion of NC2. We have identified mutations affecting components of three different complexes involved in the control of basal transcription: the mediator, TFIIH, and RNA pol II itself. Mutations in RNA pol II include both overexpression of truncated forms of the two largest subunits (Rpb1 and Rpb2) and reduced levels of these proteins. Suppression of NC2 depletion was also observed by reducing the amounts of the mediator essential components Nut2 and Med7, as well as by deleting any of the nonessential mediator components, except Med2, Med3, and Gal11 subunits. Interestingly, the Med2/Med3/Gal11 triad forms a submodule within the mediator tail. Our results support the existence of different components within the basic transcription complexes that antagonistically interact with the NC2 repressor and suggest that the correct balance between the activities of specific positive and negative components is essential for cell growth.

Chromatin structure of the 5' flanking region of the yeast LEU2 gene.

SummaryThe chromatin structure of theLEU2 gene and its flanks has been studied by means of nuclease digestion, both with micrococcal nuclease and DNase I. The gene is organized in an array of positioned nucleosomes. Within the promoter region, the nucleosome positioning places the regulatory sequences, putative TATA box and upstream activator sequence outside the nucleosomal cores. The tRNA3Leu gene possesses a characteristic structure and is protected against nucleases. Most of the 5′ flank is sensitive to DNase I digestion, although no clear hypersensitive sites were found. The chromatin structure is independent of either the transcriptional state of the gene or the chromosomal or episomal location. Finally, in the plasmid pJDB207, which lacks most of the promoter, we have found that the chromatin structure of the coding region is similar to that of the wild-type allele.

Construction of a Trp- commercial baker's yeast strain by using food-safe-grade dominant drug resistance cassettes.

We have designed a food-safe-grade module for gene disruptions in commercial bakers yeast strains, which contains the G418 resistance cassette, KanMX4, flanked by direct repeats from the MEL1 gene of Saccharomyces cerevisiae. This module was used to obtain a Trp(-) auxotrophic mutant of the polyploid HY strain by successive targeting to the TRP1 locus and later in vivo excision of the kan(r) marker. Southern blot analysis indicated that HY contains five copies of the TRP1 gene. However, after four disruption rounds, a strain named HYtrpM(4), unable to grow in the absence of tryptophan, was selected. Southern and Northern analysis of HYtrpM(4) cells showed that a remaining functional wild-type copy was still present, suggesting that the level of phosphoribosylanthranylate isomerase activity, resulting from a single copy of TRP1, is too low to sustain growth. Accordingly, a high reversion frequency of the Trp(-) phenotype, through gene conversion, was found in cells of the mutant strain. Nevertheless, this was not a drawback for its use as a recipient strain of heterologous genes. Indeed, YEpACT-X24 transformants were stable after 25 generations and expressed and secreted high levels of active recombinant xylanase. These data indicate that the new Trp(-) strain can be used to generate a stable recombinant yeast that fulfils all the requirements and market criteria for commercial utilisation.

Rtp1p Is a Karyopherin-Like Protein Required for RNA Polymerase II Biogenesis

ABSTRACT The assembly and nuclear transport of RNA polymerase II (RNA pol II) are processes that require the participation of many auxiliary factors. In a yeast genetic screen, we identified a previously uncharacterized gene, YMR185w (renamed RTP1), which encodes a protein required for the nuclear import of RNA pol II. Using protein affinity purification coupled to mass spectrometry, we identified interactions between Rtp1p and members of the R2TP complex. Rtp1p also interacts, to a different extent, with several RNA pol II subunits. The pattern of interactions is compatible with a role for Rtp1p as an assembly factor that participates in the formation of the Rpb2/Rpb3 subassembly complex and its binding to the Rpb1p-containing subcomplex. Besides, Rtp1p has a molecular architecture characteristic of karyopherins, composed of HEAT repeats, and is able to interact with phenylalanine-glycine-containing nucleoporins. Our results define Rtp1p as a new component of the RNA pol II biogenesis machinery that plays roles in subunit assembly and likely in transport through the nuclear pore complex.

Functional analysis of 12 ORFs from Saccharomyces cerevisiae chromosome II

Twelve different ORFs have been deleted from the right arm of Saccharomyces cerevisiae chromosome II; namely YBR193c, YBR194w, YBR197c, YBR198c, YBR201w, YBR203w, YBR207w, YBR209w, YBR210w, YBR211c, YBR217w and YBR228w. Tetrad analysis of heterozygous deletant strains revealed that YBR193c, YBR198c and YBR211c are essential genes for vegetative growth. No effects were detected in any of the haploid deletion mutants for the rest of the ORFs with respect to growth, gross morphology or mating. Copyright