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Mouse Anti-HSF1 (AA 256-359) Recombinant Antibody (CBFYH-2041) (CBMAB-H3058-FY)

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Summary

Host Animal
Mouse
Specificity
Human
Clone
CBFYH-2041
Antibody Isotype
IgG2a, κ
Application
ELISA, IF, WB

Basic Information

Immunogen
Recombinant protein with GST tag. MW of the GST tag alone is 26 KDa. Immunogen sequence: DAVASSGPII SDITELAPAS PMASPGGSID ERPLSSSPLV RVKEEPPSPP QSPRVEEASP GRPSSVDTLL SPTALIDSIL RESEPAPASV TALTDARGHT DTEG
Specificity
Human
Antibody Isotype
IgG2a, κ
Clonality
Monoclonal
Application Notes
The COA includes recommended starting dilutions, optimal dilutions should be determined by the end user.

Formulations & Storage [For reference only, actual COA shall prevail!]

Format
Liquid
Storage
Store at +4°C short term (1-2 weeks). Aliquot and store at -20°C long term. Avoid repeated freeze/thaw cycles.
Epitope
AA 256-359

Target

Full Name
Heat Shock Transcription Factor 1
Introduction
The product of this gene is a transcription factor that is rapidly induced after temperature stress and binds heat shock promoter elements (HSE). This protein plays a role in the regulation of lifespan. Expression of this gene is repressed by phosphorylation, which promotes binding by heat shock protein 90.
Entrez Gene ID
UniProt ID
Alternative Names
Heat Shock Transcription Factor 1; HSTF1; Heat Shock Factor Protein 1; HSTF 1; HSF 1
Function
Functions as a stress-inducible and DNA-binding transcription factor that plays a central role in the transcriptional activation of the heat shock response (HSR), leading to the expression of a large class of molecular chaperones heat shock proteins (HSPs) that protect cells from cellular insults' damage (PubMed:1871105, PubMed:11447121, PubMed:1986252, PubMed:7760831, PubMed:7623826, PubMed:8946918, PubMed:8940068, PubMed:9341107, PubMed:9121459, PubMed:9727490, PubMed:9499401, PubMed:9535852, PubMed:12659875, PubMed:12917326, PubMed:15016915, PubMed:25963659, PubMed:26754925, PubMed:18451878).

In unstressed cells, is present in a HSP90-containing multichaperone complex that maintains it in a non-DNA-binding inactivated monomeric form (PubMed:9727490, PubMed:11583998, PubMed:16278218).

Upon exposure to heat and other stress stimuli, undergoes homotrimerization and activates HSP gene transcription through binding to site-specific heat shock elements (HSEs) present in the promoter regions of HSP genes (PubMed:1871105, PubMed:1986252, PubMed:8455624, PubMed:7935471, PubMed:7623826, PubMed:8940068, PubMed:9727490, PubMed:9499401, PubMed:10359787, PubMed:11583998, PubMed:12659875, PubMed:16278218, PubMed:25963659, PubMed:26754925).

Upon heat shock stress, forms a chromatin-associated complex with TTC5/STRAP and p300/EP300 to stimulate HSR transcription, therefore increasing cell survival (PubMed:18451878).

Activation is reversible, and during the attenuation and recovery phase period of the HSR, returns to its unactivated form (PubMed:11583998, PubMed:16278218).

Binds to inverted 5'-NGAAN-3' pentamer DNA sequences (PubMed:1986252, PubMed:26727489).

Binds to chromatin at heat shock gene promoters (PubMed:25963659).

Plays also several other functions independently of its transcriptional activity. Involved in the repression of Ras-induced transcriptional activation of the c-fos gene in heat-stressed cells (PubMed:9341107).

Positively regulates pre-mRNA 3'-end processing and polyadenylation of HSP70 mRNA upon heat-stressed cells in a symplekin (SYMPK)-dependent manner (PubMed:14707147).

Plays a role in nuclear export of stress-induced HSP70 mRNA (PubMed:17897941).

Plays a role in the regulation of mitotic progression (PubMed:18794143).

Plays also a role as a negative regulator of non-homologous end joining (NHEJ) repair activity in a DNA damage-dependent manner (PubMed:26359349).

Involved in stress-induced cancer cell proliferation in a IER5-dependent manner (PubMed:26754925).

(Microbial infection) Plays a role in latent human immunodeficiency virus (HIV-1) transcriptional reactivation. Binds to the HIV-1 long terminal repeat promoter (LTR) to reactivate viral transcription by recruiting cellular transcriptional elongation factors, such as CDK9, CCNT1 and EP300.
Biological Process
Cellular protein-containing complex assembly Source: UniProtKB
Cellular response to angiotensin Source: Ensembl
Cellular response to cadmium ion Source: UniProtKB
Cellular response to copper ion Source: UniProtKB
Cellular response to diamide Source: UniProtKB
Cellular response to estradiol stimulus Source: Ensembl
Cellular response to gamma radiation Source: UniProtKB
Cellular response to heat Source: UniProtKB
Cellular response to hydrogen peroxide Source: Ensembl
Cellular response to L-glutamine Source: Ensembl
Cellular response to lipopolysaccharide Source: Ensembl
Cellular response to nitroglycerin Source: Ensembl
Cellular response to potassium ion Source: Ensembl
Cellular response to sodium arsenite Source: UniProtKB
Cellular response to unfolded protein Source: UniProtKB
Cellular response to xenobiotic stimulus Source: Ensembl
Defense response Source: Ensembl
DNA repair Source: UniProtKB-KW
MAPK cascade Source: UniProtKB
mRNA processing Source: UniProtKB-KW
mRNA transcription Source: UniProtKB
mRNA transport Source: UniProtKB-KW
Negative regulation of cardiac muscle cell apoptotic process Source: Ensembl
Negative regulation of double-strand break repair via nonhomologous end joining Source: UniProtKB
Negative regulation of gene expression Source: Ensembl
Negative regulation of inclusion body assembly Source: Ensembl
Negative regulation of neuron death Source: Ensembl
Negative regulation of protein-containing complex assembly Source: GO_Central
Negative regulation of transcription by RNA polymerase II Source: UniProtKB
Positive regulation of apoptotic DNA fragmentation Source: Ensembl
Positive regulation of cell population proliferation Source: UniProtKB
Positive regulation of cold-induced thermogenesis Source: YuBioLab
Positive regulation of cysteine-type endopeptidase activity involved in apoptotic process Source: Ensembl
Positive regulation of DNA-binding transcription factor activity Source: ARUK-UCL
Positive regulation of gene expression Source: Ensembl
Positive regulation of inclusion body assembly Source: Ensembl
Positive regulation of macrophage differentiation Source: ARUK-UCL
Positive regulation of microtubule binding Source: Ensembl
Positive regulation of mitotic cell cycle Source: UniProtKB
Positive regulation of mRNA polyadenylation Source: UniProtKB
Positive regulation of transcription by RNA polymerase II Source: UniProtKB
Positive regulation of transcription from RNA polymerase II promoter in response to heat stress Source: UniProtKB
Positive regulation of tyrosine phosphorylation of STAT protein Source: Ensembl
Regulation of cellular response to heat Source: UniProtKB
Regulation of transcription by RNA polymerase II Source: GO_Central
Response to activity Source: Ensembl
Response to hypobaric hypoxia Source: Ensembl
Response to nutrient Source: Ensembl
Response to psychosocial stress Source: Ensembl
Response to testosterone Source: Ensembl
Cellular Location
Nucleus; Nucleoplasm; Spindle pole; Centrosome; Cytoplasm; Perinuclear region; Kinetochore. The monomeric form is cytoplasmic in unstressed cells (PubMed:8455624, PubMed:26159920). Predominantly nuclear protein in both unstressed and heat shocked cells (PubMed:10413683, PubMed:10359787). Translocates in the nucleus upon heat shock (PubMed:8455624). Nucleocytoplasmic shuttling protein (PubMed:26159920). Colocalizes with IER5 in the nucleus (PubMed:27354066). Colocalizes with BAG3 to the nucleus upon heat stress (PubMed:8455624, PubMed:26159920). Localizes in subnuclear granules called nuclear stress bodies (nSBs) upon heat shock (PubMed:11447121, PubMed:11514557, PubMed:10359787, PubMed:25963659, PubMed:10747973, PubMed:24581496, PubMed:19229036). Colocalizes with SYMPK and SUMO1 in nSBs upon heat shock (PubMed:11447121, PubMed:12665592, PubMed:11514557, PubMed:14707147, PubMed:10359787). Colocalizes with PRKACA/PKA in the nucleus and nSBs upon heat shock (PubMed:21085490). Relocalizes from the nucleus to the cytoplasm during the attenuation and recovery phase period of the heat shock response (PubMed:26159920). Translocates in the cytoplasm in a YWHAE- and XPO1/CRM1-dependent manner (PubMed:12917326). Together with histone H2AX, redistributed in discrete nuclear DNA damage-induced foci after ionizing radiation (IR) (PubMed:26359349). Colocalizes with calcium-responsive transactivator SS18L1 at kinetochore region on the mitotic chromosomes (PubMed:18794143). Colocalizes with gamma tubulin at centrosome (PubMed:18794143). Localizes at spindle pole in metaphase (PubMed:18794143). Colocalizes with PLK1 at spindle poles during prometaphase (PubMed:18794143).
PTM
Phosphorylated (PubMed:9499401, PubMed:10359787, PubMed:11583998, PubMed:26159920). Phosphorylated in unstressed cells; this phosphorylation is constitutive and implicated in the repression of HSF1 transcriptional activity (PubMed:8946918, PubMed:8940068, PubMed:9121459, PubMed:16278218). Phosphorylated on Ser-121 by MAPKAPK2; this phosphorylation promotes interaction with HSP90 proteins and inhibits HSF1 homotrimerization, DNA-binding and transactivation activities (PubMed:16278218). Phosphorylation on Ser-303 by GSK3B/GSK3-beta and on Ser-307 by MAPK3 within the regulatory domain is involved in the repression of HSF1 transcriptional activity and occurs in a RAF1-dependent manner (PubMed:8946918, PubMed:8940068, PubMed:9121459, PubMed:9535852, PubMed:10747973, PubMed:12646186). Phosphorylation on Ser-303 and Ser-307 increases HSF1 nuclear export in a YWHAE- and XPO1/CRM1-dependent manner (PubMed:12917326). Phosphorylation on Ser-307 is a prerequisite for phosphorylation on Ser-303 (PubMed:8940068). According to PubMed:9535852, Ser-303 is not phosphorylated in unstressed cells. Phosphorylated on Ser-419 by PLK1; phosphorylation promotes nuclear translocation upon heat shock (PubMed:15661742). Hyperphosphorylated upon heat shock and during the attenuation and recovery phase period of the heat shock response (PubMed:11447121, PubMed:12659875, PubMed:24581496). Phosphorylated on Thr-142; this phosphorylation increases HSF1 transactivation activity upon heat shock (PubMed:12659875). Phosphorylation on Ser-230 by CAMK2A; this phosphorylation enhances HSF1 transactivation activity upon heat shock (PubMed:11447121). Phosphorylation on Ser-326 by MAPK12; this phosphorylation enhances HSF1 nuclear translocation, homotrimerization and transactivation activities upon heat shock (PubMed:15760475, PubMed:27354066). Phosphorylated on Ser-320 by PRKACA/PKA; this phosphorylation promotes nuclear localization and transcriptional activity upon heat shock (PubMed:21085490). Phosphorylated on Ser-363 by MAPK8; this phosphorylation occurs upon heat shock, induces HSF1 translocation into nuclear stress bodies and negatively regulates transactivation activity (PubMed:10747973). Neither basal nor stress-inducible phosphorylation on Ser-230, Ser-292, Ser-303, Ser-307, Ser-314, Ser-319, Ser-320, Thr-323, Ser-326, Ser-338, Ser-344, Ser-363, Thr-367, Ser-368 and Thr-369 within the regulatory domain is involved in the regulation of HSF1 subcellular localization or DNA-binding activity; however, it negatively regulates HSF1 transactivation activity (PubMed:25963659). Phosphorylated on Ser-216 by PLK1 in the early mitotic period; this phosphorylation regulates HSF1 localization to the spindle pole, the recruitment of the SCF(BTRC) ubiquitin ligase complex inducing HSF1 degradation, and hence mitotic progression (PubMed:18794143). Dephosphorylated on Ser-121, Ser-307, Ser-314, Thr-323 and Thr-367 by phosphatase PPP2CA in an IER5-dependent manner, leading to HSF1-mediated transactivation activity (PubMed:26754925).
Sumoylated with SUMO1 and SUMO2 upon heat shock in a ERK2-dependent manner (PubMed:12646186, PubMed:12665592). Sumoylated by SUMO1 on Lys-298; sumoylation occurs upon heat shock and promotes its localization to nuclear stress bodies and DNA-binding activity (PubMed:11514557). Phosphorylation on Ser-303 and Ser-307 is probably a prerequisite for sumoylation (PubMed:12646186, PubMed:12665592).
Acetylated on Lys-118; this acetylation is decreased in a IER5-dependent manner (PubMed:26754925). Acetylated on Lys-118, Lys-208 and Lys-298; these acetylations occur in a EP300-dependent manner (PubMed:24581496, PubMed:27189267). Acetylated on Lys-80; this acetylation inhibits DNA-binding activity upon heat shock (PubMed:19229036). Deacetylated on Lys-80 by SIRT1; this deacetylation increases DNA-binding activity (PubMed:19229036).
Ubiquitinated by SCF(BTRC) and degraded following stimulus-dependent phosphorylation at Ser-216 by PLK1 in mitosis (PubMed:18794143). Polyubiquitinated (PubMed:24581496). Undergoes proteasomal degradation upon heat shock and during the attenuation and recovery phase period of the heat shock response (PubMed:24581496).
More Infomation

Kmiecik, S. W., & Mayer, M. P. (2022). Molecular mechanisms of heat shock factor 1 regulation. Trends in biochemical sciences, 47(3), 218-234.

Kmiecik, S. W., Drzewicka, K., Melchior, F., & Mayer, M. P. (2021). Heat shock transcription factor 1 is SUMOylated in the activated trimeric state. Journal of Biological Chemistry, 296.

Srivastava, P., Takii, R., Okada, M., Fujimoto, M., & Nakai, A. (2021). MED12 interacts with the heat‐shock transcription factor HSF1 and recruits CDK8 to promote the heat‐shock response in mammalian cells. FEBS letters, 595(14), 1933-1948.

Dong, B., Jaeger, A. M., Hughes, P. F., Loiselle, D. R., Hauck, J. S., Fu, Y., ... & Thiele, D. J. (2020). Targeting therapy-resistant prostate cancer via a direct inhibitor of the human heat shock transcription factor 1. Science translational medicine, 12(574), eabb5647.

Haybar, H., Shahrabi, S., Rezaeeyan, H., Shirzad, R., & Saki, N. (2019). Protective role of heat shock transcription factor 1 in heart failure: A diagnostic approach. Journal of Cellular Physiology, 234(6), 7764-7770.

Kovács, D., Sigmond, T., Hotzi, B., Bohár, B., Fazekas, D., Deák, V., ... & Barna, J. (2019). HSF1Base: a comprehensive database of HSF1 (heat shock factor 1) target genes. International Journal of Molecular Sciences, 20(22), 5815.

Du, P., Chang, Y., Dai, F., Wei, C., Zhang, Q., & Li, J. (2018). Role of heat shock transcription factor 1 (HSF1)-upregulated macrophage in ameliorating pressure overload-induced heart failure in mice. Gene, 667, 10-17.

Fujimoto, M., Takii, R., Katiyar, A., Srivastava, P., & Nakai, A. (2018). Poly (ADP-Ribose) polymerase 1 promotes the human heat shock response by facilitating heat shock transcription factor 1 binding to DNA. Molecular and Cellular Biology, 38(13), e00051-18.

Lellahi, S. M., Rosenlund, I. A., Hedberg, A., Kiær, L. T., Mikkola, I., Knutsen, E., & Perander, M. (2018). The long noncoding RNA NEAT1 and nuclear paraspeckles are up-regulated by the transcription factor HSF1 in the heat shock response. Journal of Biological Chemistry, 293(49), 18965-18976.

Veri, A. O., Robbins, N., & Cowen, L. E. (2018). Regulation of the heat shock transcription factor Hsf1 in fungi: implications for temperature-dependent virulence traits. FEMS yeast research, 18(5), foy041.

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For research use only. Not intended for any clinical use.

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