Biology of the heat shock response and protein chaperones: budding yeast (Saccharomyces cerevisiae) as a model system.
about
Modulation of Alloimmunity by Heat Shock ProteinsMechanisms of Hsp90 regulationRole of Heat-Shock Proteins in Cellular Function and in the Biology of FungiMetabolic and chaperone gene loss marks the origin of animals: evidence for Hsp104 and Hsp78 chaperones sharing mitochondrial enzymes as clientsHflX is a ribosome-splitting factor rescuing stalled ribosomes under stress conditionsUptake of inorganic phosphate is a limiting factor for Saccharomyces cerevisiae during growth at low temperatures.Peroxiredoxin chaperone activity is critical for protein homeostasis in zinc-deficient yeast.ncRNAs and thermoregulation: a view in prokaryotes and eukaryotesProteotoxicity: an underappreciated pathology in cardiac diseaseDifferences in the ovine HSP90AA1 gene expression rates caused by two linked polymorphisms at its promoter affect rams sperm DNA fragmentation under environmental heat stress conditionsProtein Thermostability Is Owing to Their Preferences to Non-Polar Smaller Volume Amino Acids, Variations in Residual Physico-Chemical Properties and More Salt-BridgesBio-ethanol production by a novel autochthonous thermo-tolerant yeast isolated from wastewaterCell periphery-related proteins as major genomic targets behind the adaptive evolution of an industrial Saccharomyces cerevisiae strain to combined heat and hydrolysate stressSelf-protective responses to norvaline-induced stress in a leucyl-tRNA synthetase editing-deficient yeast strain.Temperature-dependent regulation of rDNA condensation in Saccharomyces cerevisiaeAltered proteostasis in aging and heat shock response in C. elegans revealed by analysis of the global and de novo synthesized proteomeStress-dependent proteolytic processing of the actin assembly protein Lsb1 modulates a yeast prionThe yeast sphingolipid signaling landscape.Reversible, Specific, Active Aggregates of Endogenous Proteins Assemble upon Heat StressAssessment and reconstruction of novel HSP90 genes: duplications, gains and losses in fungal and animal lineages.Whole transcriptome characterization of the effects of dehydration and rehydration on Cladonia rangiferina, the grey reindeer lichenHuman surfactant protein D alters oxidative stress and HMGA1 expression to induce p53 apoptotic pathway in eosinophil leukemic cell line.De novo transcriptome sequencing of the snail Echinolittorina malaccana: identification of genes responsive to thermal stress and development of genetic markers for population studies.Deconstructing the genetic basis of spent sulphite liquor tolerance using deep sequencing of genome-shuffled yeast.Deteriorated stress response in stationary-phase yeast: Sir2 and Yap1 are essential for Hsf1 activation by heat shock and oxidative stress, respectively.Influence of heat shock and osmotic stresses on the growth and viability of Saccharomyces cerevisiae SUBSC01.Depletion of yeast PDK1 orthologs triggers a stress-like transcriptional response.Quantitative proteomics of the yeast Hsp70/Hsp90 interactomes during DNA damage reveal chaperone-dependent regulation of ribonucleotide reductase.Molecular Chaperones of Leishmania: Central Players in Many Stress-Related and -Unrelated Physiological Processes.A direct regulatory interaction between chaperonin TRiC and stress-responsive transcription factor HSF1.Phosphoproteome dynamics of Saccharomyces cerevisiae under heat shock and cold stress.Microbial stress priming: a meta-analysis.Differential effects of Ydj1 and Sis1 on Hsp70-mediated clearance of stress granules in Saccharomyces cerevisiae.Variable Glutamine-Rich Repeats Modulate Transcription Factor Activity.Potential Application of the Oryza sativa Monodehydroascorbate Reductase Gene (OsMDHAR) to Improve the Stress Tolerance and Fermentative Capacity of Saccharomyces cerevisiae.Global transcriptional analysis suggests Lasiodiplodia theobromae pathogenicity factors involved in modulation of grapevine defensive response.Understanding the Mechanism of Thermotolerance Distinct From Heat Shock Response Through Proteomic Analysis of Industrial Strains of Saccharomyces cerevisiaeOvine HSP90AA1 gene promoter: functional study and epigenetic modifications.The combined effects of reactant kinetics and enzyme stability explain the temperature dependence of metabolic rates.TOR and RAS pathways regulate desiccation tolerance in Saccharomyces cerevisiae
P2860
Q26739428-A3641BAD-0923-47DB-8327-D98E86FBC743Q26741834-6A839382-55AB-44A3-AAD3-C98124A752DBQ26765766-D42685F4-CE7B-40F6-9054-652F5FE27FCBQ27316581-EB25A9E9-CAE6-4642-B07F-8FF92037E491Q27702284-05558C2F-A186-4052-AD19-BA908D3CF253Q27929899-EBA84DE6-4F55-40D2-A92C-69F8547E1C67Q27936303-72B797B8-F3D7-4D55-B4C8-0ED56C98CF17Q28277943-E23A2B32-F05A-4CCA-A62D-423266EA5742Q28304890-0AEB03DF-C9F9-4BBC-AF6F-DC528951224CQ28543380-3FEE2020-6800-4133-A9AB-952B90E4EF60Q28546545-B842EE0F-270E-4865-B550-42F406F7D436Q28648168-6D3FD2B6-6EF9-498C-A4B3-E77713611303Q30657240-0EB2017A-8722-413C-84AE-5A2C76A76BB2Q33878169-9DC21CDC-0C42-45DF-8E58-29A4C279109EQ33878975-EEDACC96-2788-4A10-AC0E-7966C387B57DQ34038251-97E44F4A-F91D-4492-978F-353FBA6EC960Q34283455-3B72F5C0-B210-4BAE-B6B4-D34FAEC91412Q34414198-4D4E0DE1-3545-4EC8-9153-C25FE8B5ECB0Q34493637-B73B540F-E610-425E-8E8D-983D714659FBQ34996975-DFAAF373-178C-4E8C-ADB1-A25580DE759DQ35064497-5E91FD34-9873-4810-A182-4C9CDD9D3FA0Q35083073-52A8F853-285A-4A54-87B9-7997C7DFDF82Q35168189-D681E44A-939D-44C7-B68F-F3553E06B280Q35368081-F0C9875B-5080-479F-97B1-78736EE6A48CQ35377033-CB389467-CF11-4000-A081-13AC3DE2CC3BQ35752996-BE94D5DC-EBA3-49E1-9286-1ADC235A5035Q35782491-65658720-B597-48E9-9256-AC58BEC5D408Q35799982-F7A1C7F7-2116-428A-8227-05A6E175D31EQ35808069-AE97B3E4-588C-42A1-B3BD-1B7DFE7BC3A6Q35809140-65797EAE-0551-4560-B00A-A7301CFB4734Q35850344-14CBE791-2926-4D77-A033-BECC861082AFQ35894621-04B0D4E2-EB9E-425B-93C1-7DC411225A25Q35952798-A4F55A77-F063-42E9-BFE1-4ABFCBA01E41Q35976012-A3A8C859-1B28-4B23-9826-D9669E1AED6BQ36071769-6AF1D28E-9DFF-4DC2-AC42-86DD74822C32Q36101907-15EC40E5-3129-48FC-95E1-2A79618A7AEBQ36103874-E62FE190-C4AA-4AB0-8A10-383F7ED02F74Q36127883-B69F24FF-E10E-4523-8973-5B902E818098Q36405890-9568E1D9-224B-471B-BC19-3D5CEA01E796Q36523584-EC1A6067-0126-4BB0-BEDA-6D0E2C814845
P2860
Biology of the heat shock response and protein chaperones: budding yeast (Saccharomyces cerevisiae) as a model system.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
2012年论文
@zh
2012年论文
@zh-cn
name
Biology of the heat shock resp ...... cerevisiae) as a model system.
@ast
Biology of the heat shock resp ...... cerevisiae) as a model system.
@en
type
label
Biology of the heat shock resp ...... cerevisiae) as a model system.
@ast
Biology of the heat shock resp ...... cerevisiae) as a model system.
@en
prefLabel
Biology of the heat shock resp ...... cerevisiae) as a model system.
@ast
Biology of the heat shock resp ...... cerevisiae) as a model system.
@en
P2093
P2860
P356
P1476
Biology of the heat shock resp ...... cerevisiae) as a model system
@en
P2093
Jacob Verghese
Jennifer Abrams
Yanyu Wang
P2860
P304
P356
10.1128/MMBR.05018-11
P577
2012-06-01T00:00:00Z