Phospho-HIF1A (Ser641/Ser643) antibody - #AF0062
产品: | 磷酸化 HIF1A (Ser641/Ser643) 抗体 |
货号: | AF0062 |
描述: | Rabbit polyclonal antibody to Phospho-HIF1A (Ser641/Ser643) |
应用: | WB |
反应: | Human, Mouse, Rat |
预测: | Pig, Bovine, Horse, Rabbit |
分子量: | 120kDa; 93kD(Calculated). |
蛋白号: | Q16665 |
RRID: | AB_2847784 |
产品描述
*The optimal dilutions should be determined by the end user.
*Tips:
WB: 适用于变性蛋白样本的免疫印迹检测. IHC: 适用于组织样本的石蜡(IHC-p)或冰冻(IHC-f)切片样本的免疫组化/荧光检测. IF/ICC: 适用于细胞样本的荧光检测. ELISA(peptide): 适用于抗原肽的ELISA检测.
引用格式: Affinity Biosciences Cat# AF0062, RRID:AB_2847784.
展开/折叠
ARNT interacting protein; ARNT-interacting protein; Basic helix loop helix PAS protein MOP1; Basic-helix-loop-helix-PAS protein MOP1; bHLHe78; Class E basic helix-loop-helix protein 78; HIF 1A; HIF 1alpha; HIF-1-alpha; HIF1 A; HIF1 Alpha; HIF1; HIF1-alpha; HIF1A; HIF1A_HUMAN; Hypoxia inducible factor 1 alpha; Hypoxia inducible factor 1 alpha isoform I.3; Hypoxia inducible factor 1 alpha subunit; Hypoxia inducible factor 1 alpha subunit basic helix loop helix transcription factor; Hypoxia inducible factor 1, alpha subunit (basic helix loop helix transcription factor); Hypoxia inducible factor1alpha; Hypoxia-inducible factor 1-alpha; Member of PAS protein 1; Member of PAS superfamily 1; Member of the PAS Superfamily 1; MOP 1; MOP1; PAS domain-containing protein 8; PASD 8; PASD8;
抗原和靶标
A synthesized peptide derived from human HIF1A around the phosphorylation site of Ser641/643.
Expressed in most tissues with highest levels in kidney and heart. Overexpressed in the majority of common human cancers and their metastases, due to the presence of intratumoral hypoxia and as a result of mutations in genes encoding oncoproteins and tumor suppressors. A higher level expression seen in pituitary tumors as compared to the pituitary gland.
- Q16665 HIF1A_HUMAN:
- Protein BLAST With
- NCBI/
- ExPASy/
- Uniprot
MEGAGGANDKKKISSERRKEKSRDAARSRRSKESEVFYELAHQLPLPHNVSSHLDKASVMRLTISYLRVRKLLDAGDLDIEDDMKAQMNCFYLKALDGFVMVLTDDGDMIYISDNVNKYMGLTQFELTGHSVFDFTHPCDHEEMREMLTHRNGLVKKGKEQNTQRSFFLRMKCTLTSRGRTMNIKSATWKVLHCTGHIHVYDTNSNQPQCGYKKPPMTCLVLICEPIPHPSNIEIPLDSKTFLSRHSLDMKFSYCDERITELMGYEPEELLGRSIYEYYHALDSDHLTKTHHDMFTKGQVTTGQYRMLAKRGGYVWVETQATVIYNTKNSQPQCIVCVNYVVSGIIQHDLIFSLQQTECVLKPVESSDMKMTQLFTKVESEDTSSLFDKLKKEPDALTLLAPAAGDTIISLDFGSNDTETDDQQLEEVPLYNDVMLPSPNEKLQNINLAMSPLPTAETPKPLRSSADPALNQEVALKLEPNPESLELSFTMPQIQDQTPSPSDGSTRQSSPEPNSPSEYCFYVDSDMVNEFKLELVEKLFAEDTEAKNPFSTQDTDLDLEMLAPYIPMDDDFQLRSFDQLSPLESSSASPESASPQSTVTVFQQTQIQEPTANATTTTATTDELKTVTKDRMEDIKILIASPSPTHIHKETTSATSSPYRDTQSRTASPNRAGKGVIEQTEKSHPRSPNVLSVALSQRTTVPEEELNPKILALQNAQRKRKMEHDGSLFQAVGIGTLLQQPDDHAATTSLSWKRVKGCKSSEQNGMEQKTIILIPSDLACRLLGQSMDESGLPQLTSYDCEVNAPIQGSRNLLQGEELLRALDQVN
翻译修饰 - Q16665 作为底物
Site | PTM Type | Enzyme | Source |
---|---|---|---|
K10 | Acetylation | Uniprot | |
K10 | Sumoylation | Uniprot | |
K11 | Acetylation | Uniprot | |
K12 | Acetylation | Uniprot | |
K19 | Acetylation | Uniprot | |
K21 | Acetylation | Uniprot | |
S31 | Phosphorylation | Uniprot | |
K32 | Ubiquitination | Uniprot | |
T63 | Phosphorylation | Uniprot | |
Y66 | Phosphorylation | Uniprot | |
K71 | Ubiquitination | Uniprot | |
K85 | Ubiquitination | Uniprot | |
S113 | Phosphorylation | Uniprot | |
K172 | Ubiquitination | Uniprot | |
K185 | Sumoylation | Uniprot | |
K185 | Ubiquitination | Uniprot | |
S247 | Phosphorylation | P48730 (CSNK1D) | Uniprot |
K251 | Ubiquitination | Uniprot | |
Y276 | Phosphorylation | Uniprot | |
K289 | Ubiquitination | Uniprot | |
K297 | Ubiquitination | Uniprot | |
K377 | Ubiquitination | Uniprot | |
K389 | Acetylation | Uniprot | |
K389 | Ubiquitination | Uniprot | |
K391 | Methylation | Uniprot | |
K391 | Sumoylation | Uniprot | |
K391 | Ubiquitination | Uniprot | |
S451 | Phosphorylation | Uniprot | |
T455 | Phosphorylation | Uniprot | |
T458 | Phosphorylation | Uniprot | |
K460 | Ubiquitination | Uniprot | |
S465 | Phosphorylation | Uniprot | |
K477 | Sumoylation | Uniprot | |
K477 | Ubiquitination | Uniprot | |
C520 | S-Nitrosylation | Uniprot | |
K532 | Acetylation | Uniprot | |
K532 | Ubiquitination | Uniprot | |
K538 | Ubiquitination | Uniprot | |
K547 | Ubiquitination | Uniprot | |
S551 | Phosphorylation | Uniprot | |
T555 | Phosphorylation | Uniprot | |
Y565 | Phosphorylation | Uniprot | |
S576 | Phosphorylation | Q9H4B4 (PLK3) | Uniprot |
S589 | Phosphorylation | Uniprot | |
K636 | Ubiquitination | Uniprot | |
S641 | Phosphorylation | P28482 (MAPK1) , P27361 (MAPK3) | Uniprot |
S643 | Phosphorylation | P28482 (MAPK1) , P27361 (MAPK3) | Uniprot |
K649 | Ubiquitination | Uniprot | |
T651 | Phosphorylation | Uniprot | |
T652 | Phosphorylation | Uniprot | |
S653 | Phosphorylation | Uniprot | |
S656 | Phosphorylation | Uniprot | |
S657 | Phosphorylation | Q9H4B4 (PLK3) | Uniprot |
S668 | Phosphorylation | P06493 (CDK1) | Uniprot |
K674 | Acetylation | Uniprot | |
K674 | Ubiquitination | Uniprot | |
K682 | Ubiquitination | Uniprot | |
S683 | Phosphorylation | Uniprot | |
S687 | Phosphorylation | Uniprot | |
S692 | Phosphorylation | Uniprot | |
S696 | Phosphorylation | Q13315 (ATM) | Uniprot |
T700 | Phosphorylation | Uniprot | |
K709 | Acetylation | Uniprot | |
K709 | Ubiquitination | Uniprot | |
K721 | Ubiquitination | Uniprot | |
S727 | Phosphorylation | Uniprot | |
S760 | Phosphorylation | Uniprot | |
S761 | Phosphorylation | Uniprot | |
K769 | Ubiquitination | Uniprot | |
T796 | Phosphorylation | Uniprot | |
S797 | Phosphorylation | Q5S007 (LRRK2) | Uniprot |
C800 | S-Nitrosylation | Uniprot | |
S809 | Phosphorylation | Uniprot |
研究背景
Functions as a master transcriptional regulator of the adaptive response to hypoxia. Under hypoxic conditions, activates the transcription of over 40 genes, including erythropoietin, glucose transporters, glycolytic enzymes, vascular endothelial growth factor, HILPDA, and other genes whose protein products increase oxygen delivery or facilitate metabolic adaptation to hypoxia. Plays an essential role in embryonic vascularization, tumor angiogenesis and pathophysiology of ischemic disease. Heterodimerizes with ARNT; heterodimer binds to core DNA sequence 5'-TACGTG-3' within the hypoxia response element (HRE) of target gene promoters (By similarity). Activation requires recruitment of transcriptional coactivators such as CREBBP and EP300. Activity is enhanced by interaction with both, NCOA1 or NCOA2. Interaction with redox regulatory protein APEX seems to activate CTAD and potentiates activation by NCOA1 and CREBBP. Involved in the axonal distribution and transport of mitochondria in neurons during hypoxia.
S-nitrosylation of Cys-800 may be responsible for increased recruitment of p300 coactivator necessary for transcriptional activity of HIF-1 complex.
Requires phosphorylation for DNA-binding. Phosphorylation at Ser-247 by CSNK1D/CK1 represses kinase activity and impairs ARNT binding. Phosphorylation by GSK3-beta and PLK3 promote degradation by the proteasome.
Sumoylated; with SUMO1 under hypoxia. Sumoylation is enhanced through interaction with RWDD3. Both sumoylation and desumoylation seem to be involved in the regulation of its stability during hypoxia. Sumoylation can promote either its stabilization or its VHL-dependent degradation by promoting hydroxyproline-independent HIF1A-VHL complex binding, thus leading to HIF1A ubiquitination and proteasomal degradation. Desumoylation by SENP1 increases its stability amd transcriptional activity. There is a disaccord between various publications on the effect of sumoylation and desumoylation on its stability and transcriptional activity.
Acetylation of Lys-532 by ARD1 increases interaction with VHL and stimulates subsequent proteasomal degradation. Deacetylation of Lys-709 by SIRT2 increases its interaction with and hydroxylation by EGLN1 thereby inactivating HIF1A activity by inducing its proteasomal degradation.
Polyubiquitinated; in normoxia, following hydroxylation and interaction with VHL. Lys-532 appears to be the principal site of ubiquitination. Clioquinol, the Cu/Zn-chelator, inhibits ubiquitination through preventing hydroxylation at Asn-803. Ubiquitinated by a CUL2-based E3 ligase.
In normoxia, is hydroxylated on Pro-402 and Pro-564 in the oxygen-dependent degradation domain (ODD) by EGLN1/PHD2 and EGLN2/PHD1. EGLN3/PHD3 has also been shown to hydroxylate Pro-564. The hydroxylated prolines promote interaction with VHL, initiating rapid ubiquitination and subsequent proteasomal degradation. Deubiquitinated by USP20. Under hypoxia, proline hydroxylation is impaired and ubiquitination is attenuated, resulting in stabilization. In normoxia, is hydroxylated on Asn-803 by HIF1AN, thus abrogating interaction with CREBBP and EP300 and preventing transcriptional activation. This hydroxylation is inhibited by the Cu/Zn-chelator, Clioquinol. Repressed by iron ion, via Fe(2+) prolyl hydroxylase (PHD) enzymes-mediated hydroxylation and subsequent proteasomal degradation.
The iron and 2-oxoglutarate dependent 3-hydroxylation of asparagine is (S) stereospecific within HIF CTAD domains.
Cytoplasm. Nucleus. Nucleus speckle.
Note: Colocalizes with HIF3A in the nucleus and speckles (By similarity). Cytoplasmic in normoxia, nuclear translocation in response to hypoxia (PubMed:9822602).
Expressed in most tissues with highest levels in kidney and heart. Overexpressed in the majority of common human cancers and their metastases, due to the presence of intratumoral hypoxia and as a result of mutations in genes encoding oncoproteins and tumor suppressors. A higher level expression seen in pituitary tumors as compared to the pituitary gland.
Interacts with the ARNT; forms a heterodimer that binds core DNA sequence 5'-TACGTG-3' within the hypoxia response element (HRE) of target gene promoters. Interacts with COPS5; the interaction increases the transcriptional activity of HIF1A through increased stability (By similarity). Interacts with EP300 (via TAZ-type 1 domains); the interaction is stimulated in response to hypoxia and inhibited by CITED2. Interacts with CREBBP (via TAZ-type 1 domains). Interacts with NCOA1, NCOA2, APEX and HSP90. Interacts (hydroxylated within the ODD domain) with VHLL (via beta domain); the interaction, leads to polyubiquitination and subsequent HIF1A proteasomal degradation. During hypoxia, sumoylated HIF1A also binds VHL; the interaction promotes the ubiquitination of HIF1A. Interacts with SENP1; the interaction desumoylates HIF1A resulting in stabilization and activation of transcription. Interacts (Via the ODD domain) with ARD1A; the interaction appears not to acetylate HIF1A nor have any affect on protein stability, during hypoxia. Interacts with RWDD3; the interaction enhances HIF1A sumoylation. Interacts with TSGA10 (By similarity). Interacts with HIF3A (By similarity). Interacts with RORA (via the DNA binding domain); the interaction enhances HIF1A transcription under hypoxia through increasing protein stability. Interaction with PSMA7 inhibits the transactivation activity of HIF1A under both normoxic and hypoxia-mimicking conditions. Interacts with USP20. Interacts with RACK1; promotes HIF1A ubiquitination and proteasome-mediated degradation. Interacts (via N-terminus) with USP19. Interacts with SIRT2. Interacts (deacetylated form) with EGLN1. Interacts with CBFA2T3. Interacts with HSP90AA1 and HSP90AB1.
Contains two independent C-terminal transactivation domains, NTAD and CTAD, which function synergistically. Their transcriptional activity is repressed by an intervening inhibitory domain (ID).
研究领域
· Cellular Processes > Transport and catabolism > Autophagy - animal. (View pathway)
· Environmental Information Processing > Signal transduction > HIF-1 signaling pathway. (View pathway)
· Human Diseases > Cancers: Overview > Pathways in cancer. (View pathway)
· Human Diseases > Cancers: Overview > Proteoglycans in cancer.
· Human Diseases > Cancers: Specific types > Renal cell carcinoma. (View pathway)
· Human Diseases > Cancers: Overview > Central carbon metabolism in cancer. (View pathway)
· Human Diseases > Cancers: Overview > Choline metabolism in cancer. (View pathway)
· Organismal Systems > Immune system > Th17 cell differentiation. (View pathway)
· Organismal Systems > Endocrine system > Thyroid hormone signaling pathway. (View pathway)
限制条款
产品的规格、报价、验证数据请以官网为准,官网链接:www.affbiotech.com | www.affbiotech.cn(简体中文)| www.affbiotech.jp(日本語)产品的数据信息为Affinity所有,未经授权不得收集Affinity官网数据或资料用于商业用途,对抄袭产品数据的行为我们将保留诉诸法律的权利。
产品相关数据会因产品批次、产品检测情况随时调整,如您已订购该产品,请以订购时随货说明书为准,否则请以官网内容为准,官网内容有改动时恕不另行通知。
Affinity保证所销售产品均经过严格质量检测。如您购买的商品在规定时间内出现问题需要售后时,请您在Affinity官方渠道提交售后申请。产品仅供科学研究使用。不用于诊断和治疗。
产品未经授权不得转售。
Affinity Biosciences将不会对在使用我们的产品时可能发生的专利侵权或其他侵权行为负责。Affinity Biosciences, Affinity Biosciences标志和所有其他商标所有权归Affinity Biosciences LTD.