A dual role for PP1 in shaping the Msn2-dependent transcriptional response to glucose starvation.
about
Fine-tuning of the Msn2/4-mediated yeast stress responses as revealed by systematic deletion of Msn2/4 partnersGlucose repression in Saccharomyces cerevisiaeNutritional control of growth and development in yeastHydrogen peroxide sensing, signaling and regulation of transcription factorsSingle cell analysis of yeast replicative aging using a new generation of microfluidic deviceCombinatorial gene regulation by modulation of relative pulse timing.Arsenic toxicity to Saccharomyces cerevisiae is a consequence of inhibition of the TORC1 kinase combined with a chronic stress responseThe role of the protein kinase A pathway in the response to alkaline pH stress in yeastAutomatic generation of predictive dynamic models reveals nuclear phosphorylation as the key Msn2 control mechanism.Activation of the G2/M-specific gene CLB2 requires multiple cell cycle signals.Gis4, a new component of the ion homeostasis system in the yeast Saccharomyces cerevisiae.Yeast protein phosphatase 2A-Cdc55 regulates the transcriptional response to hyperosmolarity stress by regulating Msn2 and Msn4 chromatin recruitment.The yeast environmental stress response regulates mutagenesis induced by proteotoxic stressOsmostress-induced cell volume loss delays yeast Hog1 signaling by limiting diffusion processes and by Hog1-specific effectsCell growth control: little eukaryotes make big contributions.Molecular phenotyping of aging in single yeast cells using a novel microfluidic deviceLight-sensing via hydrogen peroxide and a peroxiredoxin.A dynamic interplay of nucleosome and Msn2 binding regulates kinetics of gene activation and repression following stress.TF-centered downstream gene set enrichment analysis: Inference of causal regulators by integrating TF-DNA interactions and protein post-translational modifications information.Proteomic analysis of the carotenogenic yeast Xanthophyllomyces dendrorhous.The β-1,3-glucanosyltransferase Gas1 regulates Sir2-mediated rDNA stability in Saccharomyces cerevisiae.Transcriptional responses to glucose in Saccharomyces cerevisiae strains lacking a functional protein kinase A.Regulation of glycogen metabolism in yeast and bacteria.State transitions in the TORC1 signaling pathway and information processing in Saccharomyces cerevisiaeRegulation of Hxt3 and Hxt7 turnover converges on the Vid30 complex and requires inactivation of the Ras/cAMP/PKA pathway in Saccharomyces cerevisiaeNutrient sensing and signaling in the yeast Saccharomyces cerevisiae.Role of Gal11, a component of the RNA polymerase II mediator in stress-induced hyperphosphorylation of Msn2 in Saccharomyces cerevisiae.Metabolic-state-dependent remodeling of the transcriptome in response to anoxia and subsequent reoxygenation in Saccharomyces cerevisiae.Transcriptional regulation in yeast during diauxic shift and stationary phase.Access denied: Snf1 activation loop phosphorylation is controlled by availability of the phosphorylated threonine 210 to the PP1 phosphatase.Expression of three topologically distinct membrane proteins elicits unique stress response pathways in the yeast Saccharomyces cerevisiaePhosphoproteome dynamics of Saccharomyces cerevisiae under heat shock and cold stress.The response to heat shock and oxidative stress in Saccharomyces cerevisiaeBiology of the heat shock response and protein chaperones: budding yeast (Saccharomyces cerevisiae) as a model system.Condition-specific genetic interaction maps reveal crosstalk between the cAMP/PKA and the HOG MAPK pathways in the activation of the general stress responseMicroarray Analysis of Gene Expression in Saccharomyces cerevisiae kap108Δ Mutants upon Addition of Oxidative StressQuantitative fragmentome mapping reveals novel, domain-specific partners for the modular protein RepoMan (recruits PP1 onto mitotic chromatin at anaphase).Noise and interlocking signaling pathways promote distinct transcription factor dynamics in response to different stresses.SNF1/AMPK pathways in yeast.Less is more: Nutrient limitation induces cross-talk of nutrient sensing pathways with NAD(+) homeostasis and contributes to longevity.
P2860
Q24608639-644199A9-E606-4FE2-8386-6D56CAE04222Q26800074-8240D09E-FAAE-4C60-B97F-39167AB62484Q27003312-5865512A-AD57-44B9-A6CA-9AA9D9B65139Q27004438-65D3B9F6-2D88-494D-83A4-9126FA4E888FQ27312364-AF1ACD88-F7AC-4A08-B203-D2B186BDF907Q27315050-56A4C093-BC39-48BD-97A7-8EA220BD1E4CQ27930076-EF1C29FC-280F-4A1E-A704-F036C099FAACQ27931661-94C91AB1-5A98-499B-BBC9-8B37FD9E0DF5Q27933884-B3893797-45C5-4D3C-9194-1950C6A27442Q27937268-C1C79CDF-6F24-4F80-8273-35AA7AF4EC44Q27937438-375E8164-3A1C-4B9C-B2EA-571BA32FEC02Q27939447-55227C9E-06DD-4BDA-B143-C3646D11FDB7Q28535023-BEB5AD78-5B6B-4FCF-BA60-81E7B7418E22Q28535284-B77D6407-444B-4F6E-974D-F7F6166620E7Q30357437-18E494A6-16CF-4169-ABED-390EA0A23EC2Q30575087-566250B7-B095-4B6D-B4E9-FABEE67309FAQ30843632-17A80FB6-FAC4-42DB-BDF3-E7B11572FCEBQ33635531-6F05E2A3-0575-43D3-BA8E-F5A0533FE392Q33776339-5C8CAA82-28D3-4A70-9262-374912DC58C5Q33931114-136F97F8-014B-473F-B1ED-7106B504D6FBQ33983680-FB219A10-F397-43A5-8252-003258FC9169Q33986562-4B129E34-BFCB-4332-B764-7C3A7AD19985Q34082070-CACB4B34-619B-4DA2-B2FB-74AE368E984BQ34336735-43469A7B-E18A-4C77-AB42-427E0C4C6778Q34506997-CBFC95B6-44C9-43ED-966F-3532E8568780Q34548962-166C4BDD-8227-46FF-AFC3-C0B2BA9E50DCQ34571451-A47B519B-2EB4-48BD-838D-4CB4CDCAED03Q35023439-F9124437-0C85-4D7E-B7F6-55B6893EA3AFQ35097810-9B0794C0-75C3-45A7-BE0A-FB9C7EDB9EFCQ35630441-37F857D5-E879-454E-95AF-76EF394E29A9Q35671992-B8A3ADED-EA85-4DF7-9E16-F7448A972005Q35850344-EAB21396-9B0E-4C6B-B1FB-CB80F465BC36Q35863026-3221267E-B1C4-499B-9B62-5056CEDDB7D3Q36023274-85959C46-4698-4E3E-8BA9-6EA0ED7BD1F4Q36243717-F0435B52-F561-44BC-93AE-B349C7D5879CQ36780866-34C01983-48FE-4E1B-AA7E-F740C03BB24DQ36832530-1DA3119F-0CAC-45B1-A996-033A1D483CEBQ36926671-1BBE6BC5-CFAD-4C41-AC49-2768A9F0AFDEQ36992466-4530A637-7191-418F-8C3E-C9D7B654B1AAQ37283423-32742BF1-4E5A-4F27-9F48-043CFFF25BD5
P2860
A dual role for PP1 in shaping the Msn2-dependent transcriptional response to glucose starvation.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh-hant
name
A dual role for PP1 in shaping ...... esponse to glucose starvation.
@en
A dual role for PP1 in shaping ...... esponse to glucose starvation.
@nl
type
label
A dual role for PP1 in shaping ...... esponse to glucose starvation.
@en
A dual role for PP1 in shaping ...... esponse to glucose starvation.
@nl
prefLabel
A dual role for PP1 in shaping ...... esponse to glucose starvation.
@en
A dual role for PP1 in shaping ...... esponse to glucose starvation.
@nl
P2093
P2860
P356
P1433
P1476
A dual role for PP1 in shaping ...... esponse to glucose starvation.
@en
P2093
Annalisa Ballarini
Cécile Brocard
Gustav Ammerer
Veerle De Wever
Wolfgang Reiter
P2860
P304
P356
10.1038/SJ.EMBOJ.7600871
P407
P577
2005-11-10T00:00:00Z