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607 results on '"Yeast fungi -- Genetic aspects"'

2. A yeast living ancestor reveals the origin of genomic introgressions

Author

D'Angiolo, Melania, De Chiara, Matteo, Yue, Jia-Xing, Irizar, Agurtzane, Stenberg, Simon, Persson, Karl, and Llored, Agnès

Subjects
Yeast fungi -- Genetic aspects, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Genome introgressions drive evolution across the animal.sup.1, plant.sup.2 and fungal.sup.3 kingdoms. Introgressions initiate from archaic admixtures followed by repeated backcrossing to one parental species. However, how introgressions arise in reproductively isolated species, such as yeast.sup.4, has remained unclear. Here we identify a clonal descendant of the ancestral yeast hybrid that founded the extant Saccharomyces cerevisiae Alpechin lineage.sup.5, which carries abundant Saccharomyces paradoxus introgressions. We show that this clonal descendant, hereafter defined as a 'living ancestor', retained the ancestral genome structure of the first-generation hybrid with contiguous S. cerevisiae and S. paradoxus subgenomes. The ancestral first-generation hybrid underwent catastrophic genomic instability through more than a hundred mitotic recombination events, mainly manifesting as homozygous genome blocks generated by loss of heterozygosity. These homozygous sequence blocks rescue hybrid fertility by restoring meiotic recombination and are the direct origins of the introgressions present in the Alpechin lineage. We suggest a plausible route for introgression evolution through the reconstruction of extinct stages and propose that genome instability allows hybrids to overcome reproductive isolation and enables introgressions to emerge. A yeast clonal descendant of an ancient hybridization event is identified and sheds light on the early evolution of the Saccharomyces cerevisiae Alpechin lineage and its abundant Saccharomyces paradoxus introgressions., Author(s): Melania D'Angiolo [sup.1] , Matteo De Chiara [sup.1] , Jia-Xing Yue [sup.1] , Agurtzane Irizar [sup.1] , Simon Stenberg [sup.2] [sup.3] , Karl Persson [sup.3] , Agnès Llored [sup.1] [...]

Published
2020
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3. Synthetic biology circuits can respond within seconds

Subjects
Yeast fungi -- Genetic aspects, Proteins -- Genetic aspects, Synthetic biology -- Evaluation, Aerospace and defense industries, Astronomy, High technology industry, Telecommunications industry
Abstract

Boston MA (SPX) Jul 02, 2021 Synthetic biology offers a way to engineer cells to perform novel functions, such as glowing with fluorescent light when they detect a certain chemical. [...]

Published
2021

5. Research from Nanjing Agricultural University Has Provided New Data on Molecular Science (Five Post-Translational Modification Residues of CmPT2 Play Key Roles in Yeast and Rice)

Subjects
Yeast fungi -- Genetic aspects, Post-translational modification -- Physiological aspects, Rice -- Genetic aspects, Health, Science and technology
Abstract

2023 MAR 3 (NewsRx) -- By a News Reporter-Staff News Editor at Science Letter -- Current study results on molecular science have been published. According to news reporting from Nanjing, [...]

Published
2023

6. Spatial scale, genetic structure, and speciation of Hawaiian endemic yeasts

Author

Lachance, Marc-Andre, Collens, Julie D., Peng, Xiao Feng, Wardlaw, Alison M., Bishop, Lucie, Hou, Lily Y., and Starmer, William T.

Subjects
Yeast fungi -- Genetic aspects, Earth sciences, Science and technology
Abstract

Abstract: Two Hawaiian endemic yeast species, Metschnikowia hawaiiensis and Metschnikowia hamakuensis, were examined by means of multilocus characterization. In spite of their narrow range of distribution, restricted to the island [...]

Published
2016
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8. Research from National Center for Biotechnology Information in the Area of Genetics Described (No evidence for widespread positive selection on double substitutions within codons in primates and yeasts)

Subjects
Yeast fungi -- Genetic aspects, Codon -- Physiological aspects, Primates -- Genetic aspects, Biological sciences, Health
Abstract

2022 SEP 27 (NewsRx) -- By a News Reporter-Staff News Editor at Life Science Weekly -- New study results on genetics have been published. According to news originating from Bethesda, [...]

Published
2022

9. Research Study Findings from Duke University School of Medicine Update Understanding of Biology (Mutational Analyses of the Cysteine-Rich Domain of Yvh1, a Protein Required for Translational Competency in Yeast)

Subjects
Yeast fungi -- Genetic aspects, Ribosomes -- Research, Microbiological research, Biological sciences, Health
Abstract

2022 SEP 13 (NewsRx) -- By a News Reporter-Staff News Editor at Life Science Weekly -- Data detailed on biology have been presented. According to news reporting out of Durham, [...]

Published
2022

10. Genetics of single-cell protein abundance variation in large yeast populations

Author

Albert, Frank W., Treusch, Sebastian, Shockley, Arthur H., Bloom, Joshua S., and Kruglyak, Leonid

Subjects
Yeast fungi -- Genetic aspects, Genetic research, Unicellular organisms -- Genetic aspects, Genetic variation -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Variation among individuals arises in part from differences in DNA sequences, but the genetic basis for variation in most traits, including common diseases, remains only partly understood. Many DNA variants influence phenotypes by altering the expression level of one or several genes. The effects of such variants can be detected as expression quantitative trait loci (eQTL) (1). Traditional eQTL mapping requires large-scale genotype and gene expression data for each individual in the study sample, which limits sample sizes to hundreds of individuals in both humans and model organisms and reduces statistical power (2-6). Consequently, many eQTL are probably missed, especially those with smaller effects (7). Furthermore, most studies use messenger RNA rather than protein abundance as the measure of gene expression. Studies that have used mass-spectrometry proteomics (8-13) reported unexpected differences between eQTL and protein QTL (pQTL) for the same genes (9,10), but these studies have been even more limited in scope. Here we introduce a powerful method for identifying genetic loci that influence protein expression in the yeast Saccharomyces cerevisiae. We measure single-cell protein abundance through the use of green fluorescent protein tags in very large populations of genetically variable cells, and use pooled sequencing to compare allele frequencies across the genome in thousands of individuals with high versus low protein abundance. We applied this method to 160 genes and detected many more loci per gene than previous studies. We also observed closer correspondence between loci that influence protein abundance and loci that influence mRNA abundance of a given gene. Most loci that we detected were clustered in 'hotspots' that influence multiple proteins, and some hotspots were found to influence more than half of the proteins that we examined. The variants that underlie these hotspots have profound effects on the gene regulatory network and provide insights into genetic variation in cell physiology between yeast strains., We developed a method for detecting genetic influences on protein levels in large populations of genetically distinct individual yeast cells (Extended Data Fig. 1). The method leverages extreme QTL mapping [...]

Published
2014

11. Pervasive genetic hitchhiking and clonal interference in forty evolving yeast populations

Author

Lang, Gregory I., Rice, Daniel P., Hickman, Mark J., Sodergren, Erica, Weinstock, George M., and Desai, Michael M.

Subjects
Yeast fungi -- Genetic aspects, Genomics -- Research, Adaptation (Biology) -- Research, Mutation (Biology) -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

The dynamics of adaptation determine which mutations fix in a population, and hence how reproducible evolution will be. This is central to understanding the spectra of mutations recovered in the [...]

Published
2013

12. A complete mass-spectrometric map of the yeast proteome applied to quantitative trait analysis

Author

Picotti, Paola, Clement-Ziza, Mathieu, Lam, Henry, Campbell, David S., Schmidt, Alexander, Deutsch, Eric W., Rost, Hannes, Sun, Zhi, Rinner, Oliver, Reiter, Lukas, Shen, Qin, Michaelson, Jacob J., Frei, Andreas, Alberti, Simon, Kusebauch, Ulrike, Wollscheid, Bernd, Moritz, Robert L., Beyer, Andreas, and Aebersold, Ruedi

Subjects
Yeast fungi -- Genetic aspects, Proteomics -- Research, Mass spectrometry -- Observations, Chromosome mapping -- Observations, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Experience from different fields of life sciences suggests that accessible, complete reference maps of the components of the system under study are highly beneficial research tools. Examples of such maps include libraries of the spectroscopic properties of molecules, or databases of drug structures in analytical or forensic chemistry. Such maps, and methods to navigate them, constitute reliable assays to probe any sample for the presence and amount of molecules contained in the map. So far, attempts to generate such maps for any proteome have failed to reach complete proteome coverage (1-3). Here we use a strategy based on high-throughput peptide synthesis and mass spectrometry to generate an almost complete reference map (97% of the genome-predicted proteins) of the Saccharomyces cerevisiaeproteome. We generated two versions of this mass-spectrometric map, one supporting discovery-driven (shotgun) (3,4) and the other supporting hypothesis-driven (targeted) (5,6) proteomic measurements. Together, the two versions of the map constitute a complete set of proteomic assays to support most studies performed with contemporary proteomic technologies. To show the utility of the maps, we applied them to a protein quantitative trait locus (QTL) analysis (7), which requires precise measurement of the same set of peptides over a large number of samples. Protein measurements over 78 S. cerevisiaestrains revealed a complex relationship between independent genetic loci, influencing the levels of related proteins. Our results suggest that selective pressure favours the acquisition of sets of polymorphisms that adapt protein levels but also maintain the stoichiometry of functionally related pathway members., In proteomics, the generation of reference maps covering a complete proteome has been attempted in two ways. The first is based on the development of immunoassays to detect target proteins [...]

Published
2013

13. Synthetic chromosome arms function in yeast and generate phenotypic diversity by design

Author

Dymond, Jessica S., Richardson, Sarah M., Coombes, Candice E., Babatz, Timothy, Muller, Heloise, Annaluru, Narayana, Blake, William J., Schwerzmann, Joy W., Dai, Junbiao, Lindstrom, Derek L., Boeke, Annabel C., Gottschling, Daniel E., Chandrasegaran, Srinivasan, Bader, Joel S., and Boeke, Jef D.

Subjects
Yeast fungi -- Genetic aspects, DNA synthesis -- Research, Genomes -- Research, Chromosomes -- Research, Phenotype -- Research, Synthetic biology -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Recent advances in DNA synthesis technology have enabled the construction of novel genetic pathways and genomic elements, furthering our understanding of system-level phenomena (1-7). The ability to synthesize large segments of DNA allows the engineering of pathways and genomes according to arbitrary sets of design principles. Here we describe a synthetic yeast genome project, Sc2.0, and the first partially synthetic eukaryotic chromosomes, Saccharomyces cerevisiae chromosome synIXR, and semi-synVIL. We defined three design principles for a synthetic genome as follows: first, it should result in a (near) wild-type phenotype and fitness; second, it should lack destabilizing elements such as tRNA genes or transposons (8,9); and third, it should have genetic flexibility to facilitate future studies. The synthetic genome features several systemic modifications complying with the design principles, including an inducible evolution system, SCRaMbLE (synthetic chromosome rearrangement and modification by loxP-mediated evolution). We show the utility of SCRaMbLE as a novel method of combinatorial mutagenesis, capable of generating complex genotypes and a broad variety of phenotypes. When complete, the fully synthetic genome will allow massive restructuring of the yeast genome, and may open the door to a new type of combinatorial genetics based entirely on variations in gene content and copy number., The first phase of any genome engineering project is design (Supplementary Text 1). We designed the right arm of chromosome IX (IXR) according to the three principles outlined above and [...]

Published
2011
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14. Data from Huazhong University of Science and Technology Advance Knowledge in Molecular Science (T1121G Point Mutation in the Mitochondrial Gene * * COX1* * Suppresses a Null Mutation in * * ATP23* * Required for the Assembly of Yeast ...)

Subjects
Gene mutations -- Research, Yeast fungi -- Genetic aspects, Genetic research, ATP synthases -- Research, Health, Science and technology
Abstract

2022 MAR 18 (NewsRx) -- By a News Reporter-Staff News Editor at Science Letter -- Researchers detail new data in molecular science. According to news reporting originating from Wuhan, People's [...]

Published
2022

15. Study Findings from Federal University Piaui Broaden Understanding of Cryptogamic Plant Research (Molecular Identification and Phylogenetic Analysis of Trichoderma Isolates Obtained From Woody Plants of the Semi-arid of Northeast Brazil)

Subjects
Yeast fungi -- Genetic aspects, Biological sciences, Health
Abstract

2022 MAR 15 (NewsRx) -- By a News Reporter-Staff News Editor at Life Science Weekly -- Current study results on Life Science Research - Cryptogamic Plant Research have been published. [...]

Published
2022

19. A phosphorylation-regulated amphipathic helix controls the membrane translocation and function of the yeast phosphatidate phosphatase

Author

Karanasios, Eleftherios, Han, Gil-Soo, Xu, Zhi, Carman, George M., and Siniossoglou, Symeon

Subjects
Phosphatases -- Chemical properties, Phosphorylation -- Methods, Membranes (Biology) -- Chemical properties, Yeast fungi -- Chemical properties, Yeast fungi -- Genetic aspects, Science and technology
Abstract

Regulation of membrane lipid composition is crucial for many aspects of cell growth and development. Lipins, a novel family of phosphatidate (PA) phosphatases that generate diacylglycerol (DAG) from PA, are emerging as essential regulators of fat metabolism, adipogenesis, and organelle biogenesis. The mechanisms that govern lipin translocation onto membranes are largely unknown. Here we show that recruitment of the yeast lipin (Pah1p) is regulated by PA levels onto the nuclear/endoplasmic reticulum (ER) membrane. Recruitment requires the transmembrane protein phosphatase complex Nem1p-Spo7p. Once dephosphorylated, Pah1p can bind to the nuclear/ER membrane independently of Nem1p-Spo7p via a short amino-terminal amphipathic helix. Dephosphorylation enhances the activity of Pah1p, both in vitro and in vivo, but only in the presence of a functional helix. The helix is required for both phospholipid and triacylglycerol biosynthesis. Our data suggest that dephosphorylation of Pah1p by the Nem1pSpo7p complex enables the amphipathic helix to anchor Pah1p onto the nuclear/ER membrane allowing the production of DAG for lipid biosynthesis. doi/ 10.1073/pnas.1007974107

Published
2010

20. Ribosome recycling step in yeast cytoplasmic protein synthesis is catalyzed by eEF3 and ATP

Author

Kurata, Shinya, Nielsen, Klaus H., Mitchell, Sarah F., Lorsch, Jon R., Kaji, Akira, and Kaji, Hideko

Subjects
Protein biosynthesis -- Research, Yeast fungi -- Genetic aspects, Cytoplasm -- Properties, Translation elongation factors -- Properties, Adenosine triphosphate -- Properties, Science and technology
Abstract

After each round of protein biosynthesis, the posttermination complex (PoTC) consisting of a ribosome, mRNA, and tRNA must be disassembled into its components for a new round of translation. Here, we show that a Saccharomyces cerevisiae model PoTC was disassembled by ATP and eukaryotic elongation factor 3 (eEF3). GTP or ITP functioned with less efficiency and adenosine 5[gamma]'- ([beta],[gamma]-imido)triphosphate did not function at all. The [k.sub.cat] of eEF3 was 1.12 [min.sup.-1], which is comparable to that of the in vitro initiation step. The disassembly reaction was inhibited by aminoglycosides and cycloheximide. The subunits formed from the yeast model PoTC remained separated under ionic conditions close to those existing in vivo, suggesting that they are ready to enter the initiation process. Based on our experimental techniques used in this paper, the release of mRNA and tRNA and ribosome dissociation took place simultaneously. No 40S*mRNA complex was observed, indicating that eEF3 action promotes ribosome recycling, not reinitiation. yeast cytoplasm | ribosome recycling factor | ribosomal subunits | kinetics | antibiotics doi/ 10.1073/pnas.1006247107

Published
2010
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21. Conversion of a yeast prion protein to an infectious form in bacteria

Author

Garrity, Sean J., Sivanathan, Viknesh, Dong, Jijun, Lindquist, Susan, and Hochschild, Ann

Subjects
Escherichia coli -- Physiological aspects, Escherichia coli -- Genetic aspects, Escherichia coli -- Research, Prions -- Physiological aspects, Prions -- Genetic aspects, Prions -- Research, Yeast fungi -- Physiological aspects, Yeast fungi -- Genetic aspects, Science and technology
Abstract

Prions are infectious, self-propagating protein aggregates that have been identified in evolutionarily divergent members of the eukaryotic domain of life. Nevertheless, it is not yet known whether prokaryotes can support the formation of prion aggregates. Here we demonstrate that the yeast prion protein Sup35 can access an infectious conformation in Escherichia coli cells and that formation of this material is greatly stimulated by the presence of a transplanted [[PSI.sup.+]] inducibility factor, a distinct prion that is required for Sup35 to undergo spontaneous conversion to the prion form in yeast. Our results establish that the bacterial cytoplasm can support the formation of infectious prion aggregates, providing a heterologous system in which to study prion biology. Sup35 | [[PSI.sup.*]] inducibility factor I amyloid doi/ 10.1073/pnas.0913280107

Published
2010

22. Non-Mendelian determinant [[ISP.sup.+]] in yeast is a nuclear-residing prion form of the global transcriptional regulator Sfp1

Author

Rogoza, Tatyana, Goginashvili, Alexander, Rodionova, Sofia, Ivanov, Maxim, Viktorovskaya, Olga, Rubel, Alexander, Volkov, Kirill, and Mironova, Ludmila

Subjects
Prions -- Properties, Yeast fungi -- Genetic aspects, Transcriptional coactivators -- Properties, Science and technology
Abstract

Four protein-based genetic determinants or prions--[[SWI.sup.*]], [MCA], [[OCT.sup.+]], and [[MOT3.sup.+]]--are recent additions to the list of well-known Saccharomyces cerevisiae prions, [[PSI.sup.+]], [URE3], and [[PIN.sup.+]]. A rapid expansion of this list may indicate that many yeast proteins can convert into heritable prion forms and underscores a problem of prion input into cellular physiology. Here, we prove that the global transcriptional regulator Sfp1 can become a prion corresponding to the prion-like determinant [[ISP.sup.+]] described earlier. We show that SFP1 deletion causes an irreversible [[ISP.sup.+]] loss, whereas increased SFP1 expression induces [[ISP.sup.+]] appearance. Cells that display the [[ISP.sup.+]] phenotype contain the aggregated form of Sfp1. Indeed, these aggregates demonstrate a nuclear location. We also show that the phenotypic manifestation of Sfp1 prionization differs from the manifestation of SFP1 deletion. These properties and others distinguish [[ISP.sup.+]] from yeast prions described to date. protein inheritance | nonsense suppression doi/ 10.1073/pnas.1005949107

Published
2010

23. A role for tetrahydrofolates in the metabolism of iron-sulfur clusters in all domains of life

Author

Waller, Jeffrey C., Alvarez, Sophie, Naponelli, Valeria, Lara-Nunez, Aurora, Blaby, Ian K., Silva, Vanessa Da, Ziemak, Michael J., Vickers, Tim J., Beverley, Stephen M., Edison, Arthur S., Rocca, James R., Gregory, Jesse F., III, de Crecy-Lagard, Valerie, and Hanson, Andrew D.

Subjects
Yeast fungi -- Physiological aspects, Yeast fungi -- Genetic aspects, Enzyme activation -- Research, Folic acid -- Genetic aspects, Folic acid -- Physiological aspects, Science and technology
Abstract

Iron-sulfur (Fe/S) cluster enzymes are crucial to life. Their assembly requires a suite of proteins, some of which are specific for particular subsets of Fe/S enzymes. One such protein is yeast Iba57p, which aconitase and certain radical S-adenosylmethionine enzymes require for activity. Iba57p homologs occur in all domains of life; they belong to the COG0354 protein family and are structurally similar to various folate-dependent enzymes. We therefore investigated the possible relationship between folates and Fe/S cluster enzymes using the Escherichia coil Iba57p homolog, YgfZ. NMR analysis confirmed that purified YgfZ showed stereoselective folate binding. Inactivating ygfZ reduced the activities of the Fe/S tRNA modification enzyme MiaB and certain other Fe/S enzymes, although not aconitase. When successive steps in folate biosynthesis were ablated, [DELTA]folE (lacking pterins and folates) and [DELTA]folP (lacking folates) mutants mimicked the [DELTA]ygfZ mutant in having low MiaB activities, whereas [DELTA]folE [DELTA]thyA mutants supplemented with 5-formyltetrahydrofolate (lacking pterins and depleted in dihydrofolate) and [DELTA]gcvP [DELTA]glyA mutants (lacking one-carbon tetrahydrofolates) had intermediate MiaB activities. These data indicate that YgfZ requires a folate, most probably tetrahydrofolate. Importantly, the [DELTA]ygfZ mutant was hypersensitive to oxidative stress and grew poorly on minimal media. COG0354 genes of bacterial, archaeal, fungal, protistan, animal, or plant origin complemented one or both of these growth phenotypes as well as the MiaB activity phenotype. Comparative genomic analysis indicated widespread functional associations between COG0354 proteins and Fe/S cluster metabolism. Thus COG0354 proteins have an ancient, conserved, folate-dependent function in the activity of certain Fe/S cluster enzymes. comparative genornics | oxidative stress | YgfZ protein | Iba57 | COG0354 doi/ 10.1073/pnas.0911586107

Published
2010

24. A global protein kinase and phosphatase interaction network in yeast

Author

Breitkreutz, Ashton, Choi, Hyungwon, Sharom, Jeffrey R., Boucher, Lorrie, Neduva, Victor, Larsen, Brett, Lin, Zhen-Yuan, Breitkreutz, Bobby-Joe, Stark, Chris, Liu, Guomin, Ahn, Jessica, Dewar-Darch, Danielle, Reguly, Teresa, Tang, Xiaojing, Almeida, Ricardo, Qin, Zhaohui Steve, Pawson, Tony, Gingras, Anne-Claude, Nesvizhskii, Alexey I., and Tyers, Mike

Subjects
Phosphatases -- Physiological aspects, Phosphatases -- Research, Protein kinases -- Physiological aspects, Protein kinases -- Research, Yeast fungi -- Physiological aspects, Yeast fungi -- Research, Yeast fungi -- Genetic aspects, Science and technology
Abstract

The interactions of protein kinases and phosphatases with their regulatory subunits and substrates underpin cellular regulation. We identified a kinase and phosphatase interaction (KPI) network of 1844 interactions in budding yeast by mass spectrometric analysis of protein complexes. The KPI network contained many dense local regions of interactions that suggested new functions. Notab|y, the cell cycle phosphatase Cdc14 associated with muttiple kinases that revealed roles for Cdc14 in mitogen-activated protein kinase signaling, the DNA damage response, and metabolism, whereas interactions of the target of rapamycin comptex 1 (TORCl) uncovered new effector kinases in nitrogen and carbon metabolism. An extensive backbone of kinase-kinase interactions cross-connects the proteome and may serve to coordinate diverse cellular responses. doi: 10.1126/science.1176495

Published
2010
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26. Conservation of recombination hotspots in yeast

Author

Tsai, Isheng J., Burt, Austin, and Koufopanou, Vassiliki

Subjects
Genetic recombination -- Research, Yeast fungi -- Genetic aspects, Science and technology
Abstract

Meiotic recombination does not occur randomly along a chromosome, but instead tends to be concentrated in small regions, known as 'recombination hotspots.' Recombination hotspots are thought to be short-lived in evolutionary time due to their self-destructive nature, as gene conversion favors recombination-suppressing alleles over recombination-promoting alleles during double-strand repair. Consistent with this expectation, hotspots in humans are highly dynamic, with little correspondence in location between humans and chimpanzees. Here, we identify recombination hotspots in two lineages of the yeast Saccharomyces paradoxus, and compare their locations to those found previously in Saccharomyces cerevisiae. Surprisingly, we find considerable overlap between the two species, despite the fact that they are at least 10 times more divergent than humans and chimpanzees. We attribute this unexpected result to the low frequency of sex and outcrossing in these yeasts, acting to reduce the population genetic effect of biased gene conversion. Traces from two other signatures of recombination, namely high mutagenicity and GC-biased gene conversion, are consistent with this interpretation. Thus, recombination hotspots are not inevitably short-lived, but rather their persistence through evolutionary time will be determined by the frequency of outcrossing events in the life cycle. base composition | frequency of outcrossing | hotspot degeneration | Saccharomyces | biased gene conversion doi/ 10.1073/pnas.0908774107

Published
2010

27. Genetic analysis of variation in transcription factor binding in yeast

Author

Zheng, Wei, Zhao, Hongyu, Mancera, Eugenio, Steinmetz, Lars M., and Snyder, Michael

Subjects
Yeast fungi -- Genetic aspects, Gene expression -- Physiological aspects, Genetic variation -- Identification and classification, Transcription factors -- Properties, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Variation in transcriptional regulation is thought to be a major cause of phenotypic diversity (12). Although widespread differences in gene expression among individuals of a species have been observed (3-8), studies to examine the variability of transcription factor binding on a global scale have not been performed, and thus the extent and underlying genetic basis of transcription factor binding diversity is unknown. By mapping differences in transcription factor binding among individuals, here we present the genetic basis of such variation on a genome-wide scale. Whole-genome Ste12-binding profiles were determined using chromatin immunoprecipitation coupled with DNA sequencing in pheromone-treated cells of 43 segregants of a cross between two highly diverged yeast strains and their parental lines. We identified extensive Ste12-binding variation among individuals, and mapped underlying cis- and trans-acting loci responsible for such variation. We showed that most transcription factor binding variation is cis-linked, and that many variations are associated with polymorphisms residing in the binding motifs of Ste12 as well as those of several proposed Ste12 cofactors. We also identified two transfactors, AMN1 and FLO8, that modulate Ste12 binding to promoters of more than ten genes under a-factor treatment. Neither of these two genes was previously known to regulate Ste12, and we suggest that they may be mediators of gene activity and phenotypic diversity. Ste12 binding strongly correlates with gene expression for more than 200 genes, indicating that binding variation is functional. Many of the variable-bound genes are involved in cell wall organization and biogenesis. Overall, these studies identified genetic regulators of molecular diversity among individuals and provide new insights into mechanisms of gene regulation., Many, and possibly most, phenotypic differences among individuals maybe elicited by alterations in gene expression and the underlying transcriptional regulation (1,2). Differences in gene expression have been observed among individuals [...]

Published
2010
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28. Metabolic cycling in single yeast cells from unsynchronized steady-state populations limited on glucose or phosphate

Author

Silverman, Sanford J., Petti, Allegra A., Slavov, Nikolai, Parsons, Lance, Briehof, Ryan, Thiberge, Stephan Y., Zenklusen, Daniel, Gandhi, Saumil J., Larson, Daniel R., Singer, Robert H., and Botstein, David

Subjects
Dextrose -- Physiological aspects, Glucose -- Physiological aspects, Phosphates -- Physiological aspects, Yeast fungi -- Physiological aspects, Yeast fungi -- Genetic aspects, Cell cycle -- Research, Science and technology
Abstract

Oscillations in patterns of expression of a large fraction of yeast genes are associated with the 'metabolic cycle,' usually seen only in prestarved, continuous cultures of yeast. We used FISH of mRNA in individual cells to test the hypothesis that these oscillations happen m single cells drawn from unsynchronized cultures growing exponentially in chemostats. Gene-expression data from synchronized cultures were used to predict coincident appearance of mRNAs from pairs of genes in the unsynchronized cells. Quantitative analysis of the FISH results shows that individual unsynchronized cells growing slowly because of glucose limitation or phosphate limitation show the predicted oscillations. We conclude that the yeast metabolic cycle is an intrinsic property of yeast metabolism and does not depend on either synchronization or external limitation of growth by the carbon source. chemostat | fluorescence in situ hybridization | mRNA | single cells doi/ 10.1073/pnas.1002422107

Published
2010

31. Gene duplication and the evolution of ribosomal protein gene regulation in yeast

Author

Wapinski, Ilan, Pfiffner, Jenna, French, Courtney, Socha, Amanda, Thompson, Dawn Anne, and Regev, Aviv

Subjects
Genetic regulation -- Research, Ribosomal proteins -- Genetic aspects, Yeast fungi -- Genetic aspects, Yeast fungi -- Physiological aspects, Science and technology
Abstract

Coexpression of genes within a functional module can be conserved at great evolutionary distances, whereas the associated regulatory mechanisms can substantially diverge. For example, ribosomal protein (RP) genes are tightly coexpressed in Saccharomyces cerevisiae, but the cis and trans factors associated with them are surprisingly diverged across Ascomycota fungi. Little is known, however, about the functional impact of such changes on actual expression levels or about the selective pressures that affect them. Here, we address this question in the context of the evolution of the regulation of RP gene expression by using a comparative genomics approach together with cross-species functional assays. We show that an activator (Ifh1) and a repressor (Crf1) that control RP gene regulation in normal and stress conditions in S. cerevisiae are derived from the duplication and subsequent specialization of a single ancestral protein. We provide evidence that this regulatory innovation coincides with the duplication of RP genes in a whole-genome duplication (WGD) event and may have been important for tighter control of higher levels of RP transcripts. We find that subsequent loss of the derived repressor led to the loss of a stress-dependent repression of RPs in the fungal pathogen Candida glabrata. Our comparative computational and experimental approach shows how gene duplication can constrain and drive regulatory evolution and provides a general strategy for reconstructing the evolutionary trajectory of gene regulation across species. stress response | comparative functional genomics | regulatory modules | expression profiling www.pnas.org/cgi/doi/10.1073/pnas.0911905107

Published
2010

32. Yeast Tdp1 regulates the fidelity of nonhomologous end joining

Author

Bahmed, Karim, Nitiss, Karin C., and Nitiss, John L.

Subjects
Yeast fungi -- Physiological aspects, Yeast fungi -- Genetic aspects, Genetic regulation -- Physiological aspects, Phosphodiesterases -- Genetic aspects, Phosphodiesterases -- Physiological aspects, Science and technology
Abstract

Tyrosyl-DNA-phosphodiesterase 1 (Tdp1)can disjoin peptides covalently bound to DNA. We assessed the role of Tdp1 in nonhomologous end joining (NHEJ) and found that linear DNA molecules with 5' extensions showed a high frequency of misrepair in [DELTA]tdp1 cells. The joining errors in [DELTA]tdp1 cells were predominantly 2-4 nucleotide insertions. Ends with 3' extensions or blunt ends did not show enhanced frequencies of errors, although [DELTA]tdp1 cells repaired blunt DNA ends with greater efficiency than WT cells. We found that insertions required Ku80 and DNA ligase IV, as well as polymerase IV. Our results show that yeast Tdp1 is a component of the NHEJ pathway. We suggest that Tdp1p 3' nucleosidase activity regulates the processing of DNA ends by generating a 3' phosphate, thereby restricting the ability of polymerases and other enzymes from acting at DNA ends. In support of this model, we found that overexpression of Tpp1, a yeast DNA 3' phosphatase, also leads to a higher frequency of insertions, suggesting that the generation of a 3' phosphate is a key step in Tdp1-mediated error prevention during NHEJ. Tpp1 | nucleosidase | repair accuracy | break repair doi/10.1073/pnas.0909917107

Published
2010

33. Synergistic roles of the proteasome and autophagy for mitochondrial maintenance and chronological lifespan in fission yeast

Author

Takeda, Kojiro, Yoshida, Tomoko, Kikuchi, Sakura, Nagao, Koji, Kokubu, Aya, Pluskal, Tomas, Villao-Briones, Alejandro, Nakamura, Takahiro, and Yanagida, Mitsuhiro

Subjects
Mitochondrial DNA -- Properties, Ubiquitin-proteasome system -- Properties, Autophagy (Cytology) -- Research, Yeast fungi -- Properties, Yeast fungi -- Genetic aspects, Science and technology
Abstract

Regulations of proliferation and quiescence in response to nutritional cues are important for medicine and basic biology. The fission yeast Schizosaccharomyces pombe serves as a model, owing to the shift of proliferating cells to the metabolically active quiescence (designate GO phase hereafter) by responding to low nitrogen source. S. pombe GO phase cells keep alive for months without growth and division. Nitrogen replenishment reinstates vegetative proliferation phase (designate VEG). Some 40 genes required for GO maintenance were identified, but many more remain to be identified. We here show, using mutants, that the proteasome is required for maintaining GO quiescence. Functional outcomes of proteasome in GO and VEG phases appear to be distinct. Upon proteasome dysfunction, a number of antioxidant proteins and compounds responsive to ROS (reactive oxygen species) are produced. In addition, autophagy-mediated destruction of mitochondria occurs, which suppresses the loss of viability by eliminating ROS-generating mitochondria. These defensive responses are found in GO but not in VEG, suggesting that the main function of proteasome in GO phase homeostasis is to minimize ROS. Proteasome and autophagy are thus collaborative to support the lifespan of S. pombe GO phase. cell cycle | cellular quiescence | proteolysis | mitochondria doi/10.1073/pnas.0911055107

Published
2010

34. Chromosome arm length and nuclear constraints determine the dynamic relationship of yeast subtelomeres

Author

Therizols, Pierre, Duong, Tarn, Dujon, Bernard, Zimmer, Christophe, and Fabre, Emmanuelle

Subjects
Gene expression -- Research, Diagnostic imaging -- Methods, Telomeres -- Identification and classification, Yeast fungi -- Genetic aspects, Science and technology
Abstract

Physical interactions between distinct chromosomal genomic loci are important for genomic functions including recombination and gene expression, but the mechanisms by which these interactions occur remain obscure. Using telomeric association as a model system, we analyzed here the in vivo organization of chromosome ends of haploid yeast cells during interphase. We separately labeled most of the 32 subtelomeres and analyzed their positions both in nuclear space and relative to three representative reference subtelomeres by high-throughput 3D microscopy and image processing. We show that subtelomeres are positioned nonrandomly at the nuclear periphery, depending on the genomic size of their chromosome arm, centromere attachment to the microtubule organizing center (spindle pole body, SPB), and the volume of the nucleolus. The distance of subtelomeres to the SPB increases consistently with chromosome arm length up to [approximately equal to]300 kb; for larger arms the influence of chromosome arm length is weaker, but the effect of the nucleolar volume is stronger. Distances between pairs of subtelomeres also exhibit arm-length dependence and suggest, together with dynamic tracking experiments, that potential associations between subtelomeres are unexpectedly infrequent and transient. Our results suggest that interactions between subtelomeres are nonspecific and instead governed by physical constraints, including chromosome structure, attachment to the SPB, and nuclear crowding. genome organization | telomeric foci | image analysis doi/10.1073/pnas.0914187107

Published
2010

35. Fission yeast and other yeasts as emergent models to unravel cellular aging in eukaryotes

Author

Roux, Antoine E., Chartrand, Pascal, Ferbeyre, Gerardo, and Rokeach, Luis A.

Subjects
Cell research -- Methods, Aging -- Models, Yeast fungi -- Physiological aspects, Yeast fungi -- Genetic aspects, Health, Seniors
Abstract

In the past years, simple organisms such as yeasts and worms have contributed a great deal to aging research. Studies pioneered in Saccharomyces cerevisiae were useful to elucidate a significant number of molecular mechanisms underlying cellular aging and to discover novel longevity genes. Importantly, these genes proved many times to be conserved in multicellular eukaryotes. Consequently, such discovery approaches are being extended to other yeast models, such as Schizosaccharomyces pombe, Candida albicans, Kluyveromyces lactis, and Cryptococcus neoformans. In fission yeast, researchers have found links between asymmetrical cell division and nutrient signaling pathways with aging. In this review, we discuss the state of knowledge on the mechanisms controlling both replicative and chronological aging in S pombe and the other emergent yeast models. Key Words: Longevity--Yeast--Schizosaccharomyces pombe--Candida albicans--Replicative life span--Chronological life span. doi: 10.1093/gerona/glp152

Published
2010
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36. Interplay between the Smc5/6 complex and the Mph1 helicase in recombinational repair

Author

Chen, Yu-Hung, Choi, Koyi, Szakal, Barnabas, Arenz, Jacqueline, Duan, Xinyuan, Ye, Hong, Branzei, Dana, and Zhao, Xiaolan

Subjects
Genetic recombination -- Research, DNA repair -- Research, Yeast fungi -- Genetic aspects, Helicases -- Properties, Science and technology
Abstract

The evolutionarily conserved Smc5/6 complex is implicated in recombinational repair, but its function in this process has been elusive. Here we report that the budding yeast Smc5/6 complex directly binds to the DNA helicase Mph1. Mph1 and its helicase activity define a replication-associated recombination subpathway. We show that this pathway is toxic when the Smc5/6 complex is defective, because mph1[DELTA] and its helicase mutations suppress multiple defects in mutants of the Smc5/6 complex, including their sensitivity to replication-blocking agents, growth defects, and inefficient chromatid separation, whereas MPH1 overexpression exacerbates some of these defects. We further demonstrate that Mph1 and its helicase activity are largely responsible for the accumulation of potentially deleterious recombination intermediates in mutants of the Smc5/6 complex. We also present evidence that mphlA does not alleviate sensitivity to DNA damage or the accumulation of recombination intermediates in cells lacking Sgs1, which is thought to function together with the Smc5/6 complex. Thus, our results reveal a function of the Smc5/6 complex in the Mph1-dependent recombinational subpathway that is distinct from Sgs1. We suggest that the Smc5/6 complex can counteract/ modulate a pro-recombinogenic function of Mph1 or facilitate the resolution of recombination structures generated by Mph1. doi/10.1073/pnas.0908258106

Published
2009

37. Fungal physiology and the origins of molecular biology

Author

Brambl, Robert

Subjects
Cellular signal transduction -- Genetic aspects, Yeast fungi -- Physiological aspects, Yeast fungi -- Genetic aspects, Yeast fungi -- Research, Biological sciences
Abstract

Molecular biology has several distinct origins, but especially important are those contributed by fungal and yeast physiology, biochemistry and genetics. From the first gene action studies that became the basis of our understanding of the relationship between genes and proteins, through chromosome structure, mitochondrial genetics and membrane biogenesis, gene silencing and circadian clocks, studies with these organisms have yielded basic insight into these processes applicable to all eukaryotes. Examples are cited of pioneering studies with fungi that have stimulated new research in clinical medicine and agriculture; these studies include sexual interactions, cell stress responses, the cytoskeleton and pathogenesis. Studies with the yeasts and fungi have been effective in applying the techniques and insights gained from other types of experimental systems to research in fungal cell signalling, cell development and hyphal morphogenesis. DOI 10.1099/mic.0.035238-0

Published
2009

38. Identification of CCR4 and other essential thyroid hormone receptor co-activators by modified yeast synthetic genetic array analysis

Author

Govindan, Manjapra, Meng, Xianwang, Denis, Clyde L., Webb, Paul, Baxter, John D., and Walfish, Paul G.

Subjects
Thyroid hormones -- Research, Hormone receptors -- Identification and classification, Yeast fungi -- Genetic aspects, Yeast fungi -- Physiological aspects, Science and technology
Abstract

Identification of thyroid hormone receptor (TR) co-regulators has enhanced our understanding of thyroid hormone (TH) action. However, it is likely that many other co-regulators remained unidentified, and unbiased methods are required to discover these proteins. We have previously demonstrated that the yeast Saccharomyces cerevisiae is an excellent system in which to study TR action, and that defined TR signaling complexes in a eukaryotic background devoid of complicating influences of mammalian cell co-regulators can be constructed and analyzed for endogenous yeast genes, many of which are conserved in mammals. Here, a modified synthetic genetic array analysis was performed by crossing a yeast strain that expressed TRy1 and the co-activator GRIP1/ SRC2 with 384 yeast strains bearing deletions of known genes. Eight genes essential for TH action were isolated, of which 4 are conserved in mammals. Examination of one, the yeast CCR4 and its human homolog CCR4/NOT6 (hCCR4), confirmed that (i) transfected CCR4 potentiates a TH response in cultured cells more efficiently than established TR co-activators and (ii) knockdown of CCR4 expression strongly inhibited a TH response (>80%). TH treatment promoted rapid and sustained hCCR4 recruitment to the TH-responsive deiodinase 1 promoter and TR co-localizes with hCCR4 in the nucleus and interacts with hCCR4 in 2-hybrid and pull-down assays. These findings indicate that a modified yeast synthetic genetic array strategy is a feasible method for unbiased identification of conserved genes essential for TR and other nuclear receptor hormone functions in mammals. nuclear receptor co-activators | conserved nuclear receptor signaling genes doi/10,1073/pnas.0910134106

Published
2009

39. Ase1/Prc1-dependent spindle elongation corrects merotely during anaphase in fission yeast

Author

Courtheoux, Thibault, Gay, Guillaume, Gachet, Yannick, and Tournier, Sylvie

Subjects
Microtubules -- Physiological aspects, Microtubules -- Research, Yeast fungi -- Physiological aspects, Yeast fungi -- Genetic aspects, Yeast fungi -- Research, Anaphase -- Research, Anaphase -- Physiological aspects, Biological sciences
Abstract

Faithful segregation of sister chromatids requires the attachment of each kinetochore (Kt) to microtubules (MTs) that extend from opposite spindle poles. Merotelic Kt orientation is a Kt--MT misattachment in which a single Kt binds MTs from both spindle poles rather than just one. Genetic induction of merotelic Kt attachment during anaphase in fission yeast resulted in intra-Kt stretching followed by either correction or Kt disruption. Laser ablation of spindle MTs revealed that intra-Kt stretching and merotelic correction were dependent on MT forces. The presence of multiple merotelic chromosomes linearly antagonized the spindle elongation rate, and this phenomenon could be solved numerically using a simple force balance model. Based on the predictions of our mechanical model, we provide in vivo evidence that correction of merotelic attachment in anaphase is tension dependent and requires an Ase1/Prc1-dependent mechanism that prevents spindle collapse and thus asymmetric division and/or the appearance of the cut phenotype. doi/10.1083/jcb.200902093

Published
2009

40. Enhancement of Notch receptor maturation and signaling sensitivity by Cripto-1

Author

Watanabe, Kazuhide, Nagaoka, Tadahiro, Lee, Joseph M., Bianco, Caterina, Gonzales, Monica, Castro, Nadia P., Rangel, Maria Cristina, Sakamoto, Kei, Sun, Youping, Callahan, Robert, and Salomon, David S.

Subjects
Cancer cells -- Health aspects, Cancer cells -- Genetic aspects, Cancer cells -- Research, Cellular signal transduction -- Research, Yeast fungi -- Health aspects, Yeast fungi -- Genetic aspects, Yeast fungi -- Research, Biological sciences
Abstract

Nodal and Notch signaling pathways play essential roles in vertebrate development. Through a yeast two-hybrid screening, we identified Notch3 as a candidate binding partner of the Nodal coreceptor Cripto-1. Coimmunoprecipitation analysis confirmed the binding of Cripto-1 with all four mammalian Notch receptors. Deletion analyses revealed that the binding of Cripto-1 and Notch1 is mediated by the Cripto-1/ FRL-1/Cryptic domain of Cripto-1 and the C-terminal region of epidermal growth factor-like repeats of Notch1. Binding of Cripto-1 to Notch1 occurred mainly in the endoplasmic reticulum--Golgi network. Cripto-1 expression resulted in the recruitment of Notch1 protein into lipid raft microdomains and enhancement of the furin-like protein convertase-mediated proteolytic maturation of Notch1 (S1 cleavage). Enhanced S1 cleavage resulted in the sensitization to ligand-induced activation of Notch signaling. In addition, knockdown of Cripto-1 expression in human and mouse embryonal carcinoma cells desensitized the ligand-induced Notch signaling activation. These results suggest a novel role of Cripto-1 in facilitating the posttranslational maturation of Notch receptors. doi/10.1083/jcb.200905105

Published
2009

41. Stable transcription activities dependent on an orientation of Tam3 transposon insertions into Antirrhinum and yeast promoters occur only within chromatin

Author

Uchiyama, Takako, Fujino, Kaien, Ogawa, Takashi, Wakatsuki, Akihito, Kishima, Yuji, Mikami, Tetsuo, and Sano, Yoshio

Subjects
Transposons -- Properties, Snapdragons -- Genetic aspects, Yeast fungi -- Genetic aspects, Genetic transcription -- Research, Chromatin -- Properties, Biological sciences, Science and technology
Published
2009

42. Ectopic overproduction of a sporulation-specific transcription factor induces assembly of prespore-like membranous compartments in vegetative cells of fission yeast

Author

Nakase, Yukiko, Hirata, Aiko, Shimoda, Chikashi, and Nakamura, Taro

Subjects
Cell division -- Research, Gene expression -- Research, Genetic transcription -- Research, Yeast fungi -- Genetic aspects, Yeast fungi -- Research, Biological sciences
Abstract

Mei4 is a key sporulation-specific transcription factor in fission yeast. Ectopic expression of Mei4 in vegetative cells caused formation of nucleated membranous compartments, which shared common features with normal forespore membranes, thereby perturbing nuclear division. These results suggest why expression of development-specific transcription factors must be strictly controlled.

Published
2009

43. Toggle involving cis-interfering noncoding RNAs controls variegated gene expression in yeast

Author

Bumgarner, Stacie L., Dowell, Robin D., Grisafi, Paula, Gifford, David K., and Fink, Gerald R.

Subjects
Gene expression -- Research, Gene expression -- Physiological aspects, Yeast fungi -- Genetic aspects, Yeast fungi -- Physiological aspects, RNA -- Physiological aspects, Science and technology
Abstract

The identification of specific functional roles for the numerous long noncoding (nc)RNAs found in eukaryotic transcriptomes is currently a matter of intense study amid speculation that these ncRNAs have key regulatory roles. We have identified a pair of cis-interfering ncRNAs in yeast that contribute to the control of variegated gene expression at the FL011 locus by implementing a regulatory circuit that toggles between two stable states. These capped, polyadenylated ncRNAs are transcribed across the large intergenic region upstream of the FL011 ORF. As with mammalian long intervening (li)ncRNAs, these yeast ncRNAs (ICR1 and PWR1) are themselves regulated by transcription factors (Sfl1 and Flo8) and chromatin remodelers (Rpd3L) that are key elements in phenotypic transitions in yeast. The mechanism that we describe explains the unanticipated role of a histone deacetylase complex in activating gene expression, because Rpd3L mutants force the ncRNA circuit into a state that silences the expression of the adjacent variegating gene. FL011 | intergenictranscription | Rpd3L histone deacetylase | transcriptional interference | regulatory RNAs doi/10.1073/pnas.0909641106

Published
2009

44. The conserved Est1 protein stimulates telomerase DNA extension activity

Author

DeZwaan, Diane C. and Freeman, Brian C.

Subjects
Telomerase -- Physiological aspects, Yeast fungi -- Physiological aspects, Yeast fungi -- Genetic aspects, Plant proteins -- Properties, Science and technology
Abstract

The first telomerase cofactor identified was the budding yeast protein Est1, which is conserved through humans. While it is evident that Est1 is required for telomere DNA maintenance, understanding its mechanistic contributions to telomerase regulation has been limited. In vitro, the primary effect of Estl is to activate telomerase-mediated DNA extension. Although Est1 displayed specific DNA and RNA binding, neither activity contributed significantly to telomerase stimulation. Rather Est1 mediated telomerase upregulation through direct contacts with the reverse transcriptase subunit. In addition to intrinsic Est1 functions, we found that Est1 cooperatively activated telomerase in conjunction with Cdc13 and that the combinatorial effect was dependent upon a known salt-bridge interaction between Est1 (K444) and Cdc13 (E252). Our studies provide insights into the molecular events used to control the enzymatic activity of the telomerase holoenzyme. telomere biology | telomerase regulation doi/ 10.1073/pnas.0905703106

Published
2009

46. Mediator complex association with constitutively transcribed genes in yeast

Author

Ansari, Suraiya A., He, Qiye, and Morse, Randall H.

Subjects
Genetic transcription -- Research, Yeast fungi -- Genetic aspects, Science and technology
Abstract

Mediator is a large, multisubunit complex that is essential for transcription of mRNA by RNA PoL II in eukaryotes and is believed to bridge transcriptional activators and the general transcription machinery. However, several recent studies suggest that the requirement for Mediator during transcriptional activation is not universal, but rather activator dependent, and may be indirect for some genes. Here we have investigated Mediator association with several constitutively transcribed genes in yeast by comparing a yeast strain that harbors a temperature-sensitive mutation in an essential Mediator subunit, Srb4, with its wild-type (WT) counterpart. We find modest association of Mediator with constitutively active genes and show that this association is strongly decreased in srb4 ts yeast, whereas association with a nontranscribed region or repressed gene promoters is lower and unaffected in the mutant yeast. The tail module of Mediator remains associated with ribosomal protein (RP) gene promoters in srb4 ts yeast, while subunits from the head and middle modules are lost. Tail module association at Rap1-dependent gene promoters is lost in rap1 ts yeast, indicating that Rap1 is required for Mediator recruitment at these gene promoters and that its recruitment occurs via the tail module. Pol II association is also rapidly and severely affected in srb4 ts yeast, indicating that Mediator is directly required for pol II association at constitutively transcribed genes. Our results are consistent with Mediator functioning as a general transcription factor in yeast. Rap1 | transcription

Published
2009

47. Creating bacterial strains from genomes that have been cloned and engineered in yeast

Author

Lartigue, Carole, Vashee, Sanjay, Algire, Mikkel A., Chuang, Ray-Yuan, Benders, Gwynedd A., Ma, Li, Noskov, Vladimir N., Denisova, Evgeniya A., Gibson, Daniel G., Assad-Garcia, Nacyra, Alperovich, Nina, Thomas, David W., Merryman, Chuck, Hutchison, Clyde A., III, Smith, Hamilton O., Venter, J. Craig, and Glass, John I.

Subjects
Bacterial genetics -- Research, Genetic research -- Methods, Cloning -- Methods, Yeast fungi -- Genetic aspects, Science and technology
Abstract

We recently reported the chemical synthesis, assembly, and cloning of a bacterial genome in yeast. To produce a synthetic cell, the genome must be transferred from yeast to a receptive cytoplasm. Here we describe methods to accomplish this. We cloned a Mycoplosma mycoides genome as a yeast centromeric plasmid and then transplanted it into Mycoplasma copricolum to produce a viable M. mycoides cell. White in yeast, the genome was altered by using yeast genetic systems and then transplanted to produce a new strain of M. mycoides. These methods allow the construction of strains that could not be produced with genetic toots available for this bacterium.

Published
2009

48. Pds5 is required for homologue pairing and inhibits synapsis of sister chromatids during yeast meiosis

Author

Jin, Hui, Guacci, Vincent, and Yu, Hong-Guo

Subjects
Chromosomal proteins -- Physiological aspects, Chromosomal proteins -- Genetic aspects, Chromosomal proteins -- Research, Meiosis -- Physiological aspects, Meiosis -- Research, Yeast fungi -- Genetic aspects, Yeast fungi -- Research, Biological sciences
Abstract

During meiosis, homologues become juxtaposed and synapsed along their entire length. Mutations in the cohesin complex disrupt not only sister chromatid cohesion but also homologue pairing and synaptonemal complex formation. In this study, we report that Pds5, a cohesin-associated protein known to regulate sister chromatid cohesion, is required for homologue pairing and synapsis in budding yeast. Pds5 colocalizes with cohesin along the length of meiotic chromosomes. In the absence of Pds5, the meiotic cohesin subunit Rec8 remains bound to chromosomes with only minor defects in sister chromatid cohesion, but sister chromatids synapse instead of homologues. Double-strand breaks (DSBs) are formed but are not repaired efficiently. In addition, meiotic chromosomes undergo hypercondensation. When the mitotic cohesin subunit Mcd1 is substituted for Rec8 in Pds5-depleted cells, chromosomes still hypercondense, but synapsis of sister chromatids is abolished. These data suggest that Pds5 modulates the Rec8 activity to facilitate chromosome morphological changes required for homologue synapsis, DSB repair, and meiotic chromosome segregation.

Published
2009

49. Systems-level engineering of nonfermentative metabolism in yeast

Author

Kennedy, Caleb J., Boyle, Patrick M., Waks, Zeev, and Silver, Pamela A.

Subjects
Gene expression -- Research, Gene mutations -- Research, Genetic regulation -- Research, Microbial metabolism -- Research, Yeast fungi -- Genetic aspects, Biological sciences
Published
2009

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