HIF activation by pH-dependent nucleolar sequestration of VHL.
about
Analysis of Jmjd6 cellular localization and testing for its involvement in histone demethylationMultiple controls regulate nucleostemin partitioning between nucleolus and nucleoplasmThe nucleolar detention pathway: A cellular strategy for regulating molecular networksEnvironmental cues induce a long noncoding RNA-dependent remodeling of the nucleolusEmerging roles of the nucleolus in regulating the DNA damage response: the noncanonical DNA repair enzyme APE1/Ref-1 as a paradigmatical exampleA novel mechanism for SUMO system control: regulated Ulp1 nucleolar sequestrationIdentification of a common subnuclear localization signalLactic acidosis triggers starvation response with paradoxical induction of TXNIP through MondoAHEX expression and localization in normal mammary gland and breast carcinomaRegulation of ubiquitin ligase dynamics by the nucleolusIdentification and functional analysis of NOL7 nuclear and nucleolar localization signals.Cellular stress stimulates nuclear localization signal (NLS) independent nuclear transport of MRJ.A putative pH-dependent nuclear localization signal in the juxtamembrane region of c-MetThe genomic analysis of lactic acidosis and acidosis response in human cancersA chemokine targets the nucleus: Cxcl12-gamma isoform localizes to the nucleolus in adult mouse heartHIF-1α/COX-2 expression and mouse brain capillary remodeling during prolonged moderate hypoxia and subsequent re-oxygenationMetabolic markers in relation to hypoxia; staining patterns and colocalization of pimonidazole, HIF-1α, CAIX, LDH-5, GLUT-1, MCT1 and MCT4The role of nuclear bodies in gene expression and disease.Ubiquitin/SUMO modification regulates VHL protein stability and nucleocytoplasmic localization.Hypoxia inducible factor 1 alpha regulates T cell receptor signal transduction.Where no RNA polymerase has gone before: novel functional transcripts derived from the ribosomal intergenic spacer.Functional polarization of tumour-associated macrophages by tumour-derived lactic acid.Elucidation of motifs in ribosomal protein S9 that mediate its nucleolar localization and binding to NPM1/nucleophosminAcidic stress promotes a glioma stem cell phenotype.What can ecology teach us about cancer?Resistance to maribavir is associated with the exclusion of pUL27 from nucleoli during human cytomegalovirus infection.Identification and characterization of nuclear and nucleolar localization signals in 58-kDa microspherule protein (MSP58)Functional interaction between responses to lactic acidosis and hypoxia regulates genomic transcriptional outputs.Simultaneous Hypoxia and Low Extracellular pH Suppress Overall Metabolic Rate and Protein Synthesis In VitroTumor cell metabolism: an integral view.Hypoxia-inducible factor-1 facilitates cervical cancer progression in human papillomavirus type 16 transgenic mice.Hypoxia inducible factor (HIF) in rheumatology: low O2! See what HIF can do!Heat-shock protein 90 inhibitors in antineoplastic therapy: is it all wrapped up?Normal Wound Healing and Tumor Angiogenesis as a Game of Competitive Inhibition.Decreased VEGF expression and microvascular density, but increased HIF-1 and 2α accumulation and EPO expression in chronic moderate hyperoxia in the mouse brainSDF1 induction by acidosis from principal cells regulates intercalated cell subtype distribution.Requirement of the protein B23 for nucleolar disassembly induced by the FRGY2a family proteinsCancer-causing mutations in a novel transcription-dependent nuclear export motif of VHL abrogate oxygen-dependent degradation of hypoxia-inducible factor.Lacking hypoxia-mediated downregulation of E-cadherin in cancers of the uterine cervixIntrarenal oxygen in diabetes and a possible link to diabetic nephropathy.
P2860
Q24306384-26B1C725-D3B9-4230-A2D7-4CFF3375D313Q24324582-FC4E9139-1E5C-4ECC-B0B5-BD4E100FCC9FQ24609491-D5062025-18F9-4725-91A6-46E5DC2B06BBQ24622503-06FC0873-E3AF-4622-9097-8C216B9C23B1Q27026649-234AED47-C12A-4135-B60E-63D2E797E352Q27933117-87D7FD63-43CD-4B43-B0B7-B10F80BB9E20Q28237633-E6C80EBA-986C-4D32-9C0E-4C43E5F15FADQ28475481-1E455D6F-501B-4E4A-AB26-B31956E0FDABQ28504757-BCD4D198-9626-46F3-B3C3-724824408CB5Q28586399-4CCD78C6-72B7-427A-90BF-9AF20A8BFC73Q30497051-11871C7B-0014-4079-858D-22D7E19E63ECQ30523068-8932E2E7-5AE2-4198-B63C-E9290C96AC64Q30596960-3324CA3E-A440-4D49-92F3-9FAC77840184Q33389864-ECD0B249-59B6-4EC0-96B1-EB2887ED8435Q33512919-7CAB43A1-4F2C-4C88-8698-F6670BA581F7Q33790749-667CC816-54A2-421A-9838-5FC4B47D47B6Q33898862-7DC812AB-3176-4567-A626-779F502C459DQ34038183-CC89518B-04FA-4C7F-86D4-6F4047FC79AAQ34115236-C49FB78A-7D12-4073-A025-9876424203B5Q34144632-ADCF5ABF-BDDD-4485-933C-AE2D3D7B7609Q34280553-289915E8-EFC3-4D48-A2C2-148BD291165AQ34429912-02E389E1-93A7-4A2F-BAD3-4E7603ED5C7FQ34533969-C0974A13-E44B-4889-90D8-9D9BAA3FC562Q34985109-1DE02312-CF9D-40BC-A9E6-A8093E71B1F1Q35182579-9584CD93-C0FE-425C-9B6B-A73EE19DCD1EQ35596269-CE863BF0-7B6A-475E-80C6-44B4A1CF27B2Q35616896-51FE4B3D-8A56-45FE-B0E4-66C29DB881DAQ35680861-57399EE7-21BE-40EA-8C21-82BAC4D06C71Q35746325-7294FCE1-6FAB-4BC4-9EDB-EA4DFA79180FQ35760954-F719CF80-1A56-422D-8E93-6820FAA40C65Q35916052-78992742-E128-451C-935E-F24C2DF55794Q36084438-C4A0B996-5CE0-4DBE-A1F7-BD44FC28F403Q36187025-BE6F30E6-7AC4-4E9D-AAFF-6506793203AEQ36217588-C39099C6-F1B6-4863-8AB8-473C24CEF27BQ36266605-0C756018-B8A3-42A9-A58D-A27CCCDAA31FQ36335852-81EF395A-7FEE-44CE-8095-EE3D0E737C92Q36419900-AB613679-CCA3-470D-82E4-DDEFD6AD2A24Q36421050-5A1AF2F6-7FC2-48CE-903B-95FB31335B9FQ36594117-473C0E1D-C783-4328-B6E4-A22DAAE293BDQ36604424-8494D2D9-10EC-42C8-B4BB-A47172F72CAB
P2860
HIF activation by pH-dependent nucleolar sequestration of VHL.
description
2004 nî lūn-bûn
@nan
2004年の論文
@ja
2004年学术文章
@wuu
2004年学术文章
@zh
2004年学术文章
@zh-cn
2004年学术文章
@zh-hans
2004年学术文章
@zh-my
2004年学术文章
@zh-sg
2004年學術文章
@yue
2004年學術文章
@zh-hant
name
HIF activation by pH-dependent nucleolar sequestration of VHL.
@en
HIF activation by pH-dependent nucleolar sequestration of VHL.
@nl
type
label
HIF activation by pH-dependent nucleolar sequestration of VHL.
@en
HIF activation by pH-dependent nucleolar sequestration of VHL.
@nl
prefLabel
HIF activation by pH-dependent nucleolar sequestration of VHL.
@en
HIF activation by pH-dependent nucleolar sequestration of VHL.
@nl
P2093
P356
P1433
P1476
HIF activation by pH-dependent nucleolar sequestration of VHL
@en
P2093
Lakshman Gunaratnam
Marie-Eve Bonicalzi
Stephen Lee
P2888
P304
P356
10.1038/NCB1144
P577
2004-06-06T00:00:00Z