Cold response in Saccharomyces cerevisiae: new functions for old mechanisms.
about
Comparative genomics among Saccharomyces cerevisiae × Saccharomyces kudriavzevii natural hybrid strains isolated from wine and beer reveals different originsUptake of inorganic phosphate is a limiting factor for Saccharomyces cerevisiae during growth at low temperatures.Ribosome-associated complex binds to ribosomes in close proximity of Rpl31 at the exit of the polypeptide tunnel in yeast.Cold-stress responses in the Antarctic basidiomycetous yeast Mrakia blollopisEvaluation of stress tolerance and fermentative behavior of indigenous Saccharomyces cerevisiaeNovel brewing yeast hybrids: creation and applicationParameter Estimation for Gene Regulatory Networks from Microarray Data: Cold Shock Response in Saccharomyces cerevisiae.Exploring temporal transcription regulation structure of Aspergillus fumigatus in heat shock by state space model.Deciphering proteomic signatures of early diapause in Nasonia.SR-like RNA-binding protein Slr1 affects Candida albicans filamentation and virulence.Sequencing and comparative analysis of the straw mushroom (Volvariella volvacea) genome.Global phenotypic and genomic comparison of two Saccharomyces cerevisiae wine strains reveals a novel role of the sulfur assimilation pathway in adaptation at low temperature fermentations.Multicopy suppression screening of Saccharomyces cerevisiae Identifies the ubiquitination machinery as a main target for improving growth at low temperatures.From Glacier to Sauna: RNA-Seq of the Human Pathogen Black Fungus Exophiala dermatitidis under Varying Temperature Conditions Exhibits Common and Novel Fungal ResponsePhosphoproteome dynamics of Saccharomyces cerevisiae under heat shock and cold stress.Transcriptome and gene expression analysis of DHA producer Aurantiochytrium under low temperature conditions.Adaptive differentiation coincides with local bioclimatic conditions along an elevational cline in populations of a lichen-forming fungusAlternative yeasts for winemaking: Saccharomyces non-cerevisiae and its hybrids.Correlation between Low Temperature Adaptation and Oxidative Stress in Saccharomyces cerevisiae.Impact of trehalose transporter knockdown on Anopheles gambiae stress adaptation and susceptibility to Plasmodium falciparum infection.Insufficiency of copper ion homeostasis causes freeze-thaw injury of yeast cells as revealed by indirect gene expression analysis.Central Role of the Trehalose Biosynthesis Pathway in the Pathogenesis of Human Fungal Infections: Opportunities and Challenges for Therapeutic Development.Continental-level population differentiation and environmental adaptation in the mushroom Suillus brevipes.Functional analysis to identify genes in wine yeast adaptation to low-temperature fermentation.Methylation of ribosomal protein L42 regulates ribosomal function and stress-adapted cell growth.Induced gene expression in industrial Saccharomyces pastorianus var. carlsbergensis TUM 34/70: evaluation of temperature and ethanol inducible native promoters.Physiological and transcriptional responses of anaerobic chemostat cultures of Saccharomyces cerevisiae subjected to diurnal temperature cycles.Regulators of ribonucleotide reductase inhibit Ty1 mobility in saccharomyces cerevisiae.Redox engineering by ectopic expression of glutamate dehydrogenase genes links NADPH availability and NADH oxidation with cold growth in Saccharomyces cerevisiaeTORC1-mediated sensing of chaperone activity alters glucose metabolism and extends lifespan.Global expression studies in baker's yeast reveal target genes for the improvement of industrially-relevant traits: the cases of CAF16 and ORC2.Enhanced enzymatic activity of glycerol-3-phosphate dehydrogenase from the cryophilic Saccharomyces kudriavzevii.Inheritance of brewing-relevant phenotypes in constructed Saccharomyces cerevisiae × Saccharomyces eubayanus hybrids.Adaptive evolution of baker's yeast in a dough-like environment enhances freeze and salinity tolerance.Saccharomyces cerevisiae FLO1 Gene Demonstrates Genetic Linkage to Increased Fermentation Rate at Low Temperatures.Positional variations among heterogeneous nucleosome maps give dynamical information on chromatin.Ethanol-inducible gene expression using gld1 (+) promoter in the fission yeast Schizosaccharomyces pombe.Saccharomyces interspecies hybrids as model organisms for studying yeast adaptation to stressful environments.Cold exposure affects carbohydrates and lipid metabolism, and induces Hog1p phosphorylation in Dekkera bruxellensis strain CBS 2499.Dissecting Nucleosome Function with a Comprehensive Histone H2A and H2B Mutant Library.
P2860
Q21266699-80236394-CFD1-4E7C-A989-BC9B178B9782Q27929899-E57F1738-8A9A-48C4-9E4C-3DEEE7632E46Q27931411-89F7406F-7AE5-4B97-A82B-B1D1AD037701Q28595607-ACB20BB3-8877-4DCB-BC25-4ED4347317EAQ28659648-EE40A858-8DF8-4771-93E5-2A2E8737D88BQ28818298-C31224A9-CCF4-4C05-85D7-9B9E70164650Q30999367-B51D8A84-00CB-4EBE-8025-DBD756C8C48CQ33479781-2763D077-DF59-4945-81DB-B0DAE3FC340BQ33487682-7EA2714E-46F7-494D-802B-95930D0B82F1Q34326239-B5932D70-80EA-4F42-8A1F-12F00D0E48E5Q34634109-D7E9155F-1C19-46AF-B1F9-01E03133E151Q35486064-60FA2C67-2FA1-446C-9222-D39B08D37B59Q35530857-271250C0-70D6-48B8-A26E-784C59427FCCQ35659942-43023830-68CB-46A8-A075-9E194C7DCE4BQ35850344-39F19136-C1E5-4AE8-A071-A7664830B467Q36099849-DCD1833D-91D9-4367-A49C-A8CADE259A30Q36328744-5CB1C5AF-321F-489F-BB45-4507AE6F1540Q36329657-B04F8063-657C-4C85-BFED-9E4C79E3DAB5Q37146995-C1E5BC2D-3F34-418F-AC4F-DA9F3F7BBD53Q37255903-739CF02B-2F98-44BD-8AFE-43FECB18E6B4Q37410132-9B3370DC-FE7F-4474-9575-70431A7727AEQ38905119-B3A701BC-9374-42F2-A684-BDCEF5B5B3D9Q38919660-22F6F0C5-521D-4DA2-93EE-8832649460B7Q39628681-9F5294FC-577A-4248-BB0D-C3B78A675477Q39707338-E1936873-2B0E-4DD0-B43E-5DC804D2186EQ39992963-648144B4-C995-4841-80D3-7E60468AA308Q41086779-EB80F6A1-DDF8-49D6-AB11-970B9D341710Q41186025-FCC3B103-D438-47B9-B5FF-F1B966F729A6Q41193171-3CDC4EA6-B438-49D1-BE5E-8F220DEBF0C3Q41628978-1AFB0881-AE36-46CB-ADD8-1DC1AC536439Q41887482-770A0FB6-4103-4768-9856-ABDBCA067FA0Q41901335-0E4B94B2-F14A-4E8B-8194-BCAD02532FD7Q41955423-90B65AD7-7E0E-424B-8BE8-5838D486AAB8Q42112195-41C96AE6-FFCD-4C7B-8202-01249FF07FD3Q42317151-13BD5A82-0E37-4377-AE07-5239D8B7BBD3Q42505589-EFEDECE0-755A-4FBD-84EE-49E67209CB7FQ43638141-4FE05171-F6E1-4FC5-8F6B-3488FC26EA97Q46262811-B1C76CF3-F536-40CB-90E3-4B9F5921A29CQ46770503-418291A2-B79C-4D7B-85C3-0B2CDB481956Q47129463-D1393104-A013-4A95-A375-E90245BA0A19
P2860
Cold response in Saccharomyces cerevisiae: new functions for old mechanisms.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Cold response in Saccharomyces cerevisiae: new functions for old mechanisms.
@ast
Cold response in Saccharomyces cerevisiae: new functions for old mechanisms.
@en
type
label
Cold response in Saccharomyces cerevisiae: new functions for old mechanisms.
@ast
Cold response in Saccharomyces cerevisiae: new functions for old mechanisms.
@en
prefLabel
Cold response in Saccharomyces cerevisiae: new functions for old mechanisms.
@ast
Cold response in Saccharomyces cerevisiae: new functions for old mechanisms.
@en
P2860
P1476
Cold response in Saccharomyces cerevisiae: new functions for old mechanisms
@en
P2093
Jaime Aguilera
P2860
P304
P356
10.1111/J.1574-6976.2007.00066.X
P577
2007-02-09T00:00:00Z