about
sameAs
DP1/2: E2F1/2/3: SP1: CDKN2A Genep-2S-SMAD2/3:SMAD4:SP1POU2F1;2:SP1:ZNF143:snRNA geneSREBP1A;1C;2:NF-Y:SP1:FDFT1 geneSREBP1A;1C:ACACB geneSREBP1A;1C:NF-Y:SP1:FASN geneSREBP1A;2:NF-Y:SP1:CYP51A1 geneSREBP1A;2:NF-Y:SP1:DHCR7 geneSREBP1A;2:NF-Y:SP1:GGPS1 geneSREBP1A;2:NF-Y:SP1:IDI1 geneSREBP1A;2:NF-Y:SP1:MVK geneSREBP1A;2:NF-Y:SP1:PMVK geneE2F1; E2F2; or E2F3 and SP1 bind p14-ARF promoterSMAD2/3:SMAD4 heterotrimer binds SP1POU2F1 (OCT1) or POU2F2 (OCT2); SP1; and ZNF143 (STAF) bind the DSE of snRNA gene (U1; U2; U4; U4atac; U5; U11; U12)SREBP1A;1C binds the ACACB promoterSREBP1A;1C binds the FASN promoterSREBP1A;2 binds the CYP51A1 promoterSREBP1A;2 binds the DHCR7 promoterSREBP1A;2 binds the GGPS1 promoterSREBP1A;2 binds the IDI1 promoterSREBP1A;2 binds the MVK promoterSREBP1A;2 binds the PMVK promoterSREBP1A;1C;2 binds the FDFT1 promoterCTSD gene:ESR1:ESTG:SP1:USF1:USF2:NCOA:EP300:MED1HATs and coactivators are recruited to the CTSD gene
P527
P688
Interaction between the two ubiquitously expressed transcription factors NF-Y and Sp1Human Sug1/p45 is involved in the proteasome-dependent degradation of Sp1Differential distribution of unmodified and phosphorylated histone deacetylase 2 in chromatinReciprocal regulation of expression of the human adenosine 5'-triphosphate binding cassette, sub-family A, transporter 2 (ABCA2) promoter by the early growth response-1 (EGR-1) and Sp-family transcription factorsA functional variant in NKX3.1 associated with prostate cancer susceptibility down-regulates NKX3.1 expressionO-glycosylation of eukaryotic transcription factors: implications for mechanisms of transcriptional regulationThe TBN protein, which is essential for early embryonic mouse development, is an inducible TAFII implicated in adipogenesisFunctional genomics identifies a mechanism for estrogen activation of the retinoic acid receptor alpha1 gene in breast cancer cellsZBP-89 represses vimentin gene transcription by interacting with the transcriptional activator, Sp1The role of Sp1 and AP-2 in basal and protein kinase A--induced expression of mitochondrial serine:pyruvate aminotransferase in hepatocytesIdentification of heterogeneous nuclear ribonucleoprotein K as a transactivator for human low density lipoprotein receptor gene transcriptionCo-operative interactions between NFAT (nuclear factor of activated T cells) c1 and the zinc finger transcription factors Sp1/Sp3 and Egr-1 regulate MT1-MMP (membrane type 1 matrix metalloproteinase) transcription by glomerular mesangial cellsGATA-4 and GATA-6 modulate tissue-specific transcription of the human gene for P450c17 by direct interaction with Sp1The high-mobility-group domain of Sox proteins interacts with DNA-binding domains of many transcription factorsPeroxisome proliferator-activated receptor gamma activates fas ligand gene promoter inducing apoptosis in human breast cancer cellsIdentification of Sp1-elements in the promoter region of human homeobox gene NKX3.1HDAC4 represses p21(WAF1/Cip1) expression in human cancer cells through a Sp1-dependent, p53-independent mechanismEnhancer binding factors AP-4 and AP-1 act in concert to activate SV40 late transcription in vitroMicroRNA-29b promotes the adipogenic differentiation of human adipose tissue-derived stromal cellsThe cell cycle regulatory factor TAF1 stimulates ribosomal DNA transcription by binding to the activator UBFSpecificity protein-1 as a critical regulator of human cystathionine gamma-lyase in smooth muscle cellsA metabolic enzyme of the short-chain dehydrogenase/reductase superfamily may moonlight in the nucleus as a repressor of promoter activitymiR-365, a novel negative regulator of interleukin-6 gene expression, is cooperatively regulated by Sp1 and NF-kappaB.Posttranscriptional regulation of interleukin-10 expression by hsa-miR-106aTranscriptional regulation of BACE1, the beta-amyloid precursor protein beta-secretase, by Sp1.Hypoxia mediates mutual repression between microRNA-27a and PPARγ in the pulmonary vasculature.MiR-492 impairs the angiogenic potential of endothelial cells.Cooperation of Sp1 and p300 in the induction of the CDK inhibitor p21WAF1/CIP1 during NGF-mediated neuronal differentiation.
P921
Q50252360-9A056D4F-0CAC-482E-ABFC-41274F6BA80AQ50257936-69825210-5083-4204-9D52-52E6A86D844EQ50258681-E4DBA158-FA32-4FA5-A378-07DFE461B093Q50264579-0227CE59-C86B-4235-A2B1-D834D3953B91Q50265359-E8AA0FEC-AD2D-4795-8593-AD2F45268234Q50265365-9884429B-4A32-47A5-960F-2459CE49772FQ50265375-22D4FDF6-93AA-46BD-92A6-E11E5C261031Q50265377-339C38C1-117A-407F-B59B-878C5A25A909Q50265378-A4CD0A4F-549F-4413-8AC0-C45901BD500EQ50265380-6AC547D3-585A-40F1-9C87-4A4F8B64F663Q50265381-5C7E2C16-9AB8-4D53-B0EE-E66B9DBEDC4BQ50265383-5D6A6DF9-7F7A-41F7-B4FF-0D6C984AD141Q50286648-1DAFA502-1B50-4255-8581-B07940C86A5BQ50290114-6C575448-256A-4C04-8422-91B1C19BBDC0Q50290869-C5DDDF2C-6901-4EF5-8F93-7F31DA8D5BFAQ50294113-C27CE799-C5C6-4D8D-B3F5-56DDE365B260Q50294116-05E389E7-D397-4361-8451-20042994992BQ50294123-26B0BB22-B32F-4A1A-9849-2A8BE18C51FAQ50294124-EE18BBF0-EDE2-4FB0-88CC-56B9EC5E6481Q50294125-83A7A57B-6F59-43D9-B03F-D47F14896390Q50294126-E4886099-AAFD-420A-BC81-366425E7AB78Q50294127-4DB3EBF0-9246-43D5-9DC2-A3EA0F36E60FQ50294128-3782E8EE-657A-40D5-BE96-90210AC12239Q50294133-30A96B44-A047-4015-96A1-3515E105702CQ55192626-CC3B5DF9-5541-4310-92C8-02475297A1FBQ55219955-EB462F9E-14B6-46F8-9D28-AAB97889AFA6
P527
Q22010213-1182F918-04F0-4654-B211-FC0878CAA95BQ22254112-3980A677-BE6B-4002-BDCE-5DE7EA601E97Q24293063-6F9F3658-9ECE-42B3-86BA-B8A5F9B97FF8Q24293615-C353BA98-6374-47D4-8404-BF28C1A7D1DBQ24296481-7F32DD18-D1B2-441B-BBD8-E5C601A3F6BCQ24296741-6701D94B-FF03-4624-8F1E-E183C262D10DQ24298533-8D0FA8FA-8CC0-426B-B617-F3320E717A54Q24300107-F3078EF0-05BE-4CB3-8E50-423C43009F8FQ24303376-BA97DFBF-DC2D-44EC-A37F-C79E04CC6761Q24304141-EAE16B4A-92EF-40BC-BA51-29E51B34ADE5Q24305958-1D5E953B-17EC-4A62-A022-B0C00EC0D8B4Q24311377-22CB6B37-8F2D-41B5-B22F-4DB62F5DF9F5Q24313004-AF3B52BE-B762-4E0D-B84D-8B3E4E4871C2Q24313036-C1062BCC-2B7C-49DA-9518-522144C88B7EQ24316364-89A437F5-EB13-4AC0-A930-87BE9718EB72Q24317649-CBAB89E5-30AE-43D6-B152-0A7886240D2EQ24321756-6AA0399C-F8C0-442A-B262-C711097FBD62Q24339646-C214EFC8-1872-4495-AC3D-DBCBD701BE53Q28116029-6AAED554-45B2-45B8-92E3-49C70DFBC78EQ28117581-B10EC4FE-C947-4342-B4E8-DDF33025E188Q28118074-E1AB3817-ED7E-4C70-9AFC-75BF88B7A414Q28910481-33CF3B7E-055E-4966-8236-E5CBA9FE3619Q34180373-593CEA27-644D-49CA-9D53-B3CBEA81ABCDQ34967479-63464518-156F-4CAC-A8A1-529EE8590941Q40581861-BB28A61C-52BF-4567-9D2C-9C0AB3CB24A8Q42593185-65588A3C-83BF-4837-A079-6CE7AA379174Q42971453-A5F1E7D9-347A-4F0B-8364-34E30F84C7E3Q50315355-C9F8C0CB-9472-4375-A254-3769C5D9DA83
P921
description
humanes Protein
@de
mammalian protein found in Homo sapiens
@en
menselijk eiwit
@nl
protein
@id
protein
@sv
proteinë
@sq
protèin
@ace
protéine humaine
@fr
بروتين بشري
@ar
name
Sp1 transcription factor
@en
Sp1 transcription factor
@nl
Sp1
@es
Sp1
@pl
Sp1
@ru
type
label
Sp1 transcription factor
@en
Sp1 transcription factor
@nl
Sp1
@es
Sp1
@pl
Sp1
@ru
altLabel
Factor de transcripcion Sp1
@es
Factor de transcripción Sp1
@es
SP1
@en
Sp1 (фактор транскрипции)
@ru
Transcription factor Sp1 (Fragment)
@en
specificity protein 1
@en
transcription factor Sp1
@en
Транскрипционный фактор Sp1
@ru
prefLabel
Sp1 transcription factor
@en
Sp1 transcription factor
@nl
Sp1
@es
Sp1
@pl
Sp1
@ru
P637
P638
P680
P681
P682
P705
P352
P486
P646
P31
P352
P486
P637
NP_001238754
P638
P646
P680
P681
P682
P702
P703
P705
ENSP00000329357
ENSP00000404263
ENSP00000457804
ENSP00000458133