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Transactivation domain

December 17, 2023

The transactivation domain or trans-activating domain (TAD) is a transcription factor scaffold domain which contains binding sites for other proteins such as transcription coregulators. These binding sites are frequently referred to as activation functions (AFs).[1] TADs are named after their amino acid composition. These amino acids are either essential for the activity or simply the most abundant in the TAD. Transactivation by the Gal4 transcription factor is mediated by acidic amino acids, whereas hydrophobic residues in Gcn4 play a similar role. Hence, the TADs in Gal4 and Gcn4 are referred to as acidic or hydrophobic, respectively.[2][3][4][5][6][7][8][9]

In general we can distinguish four classes of TADs:[10]

  • acidic domains (called also “acid blobs” or “negative noodles", rich in D and E amino acids, present in Gal4, Gcn4 and VP16).[11]
  • glutamine-rich domains (contains multiple repetitions like "QQQXXXQQQ", present in SP1)[12]
  • proline-rich domains (contains repetitions like "PPPXXXPPP" present in c-jun, AP2 and Oct-2)[13]
  • isoleucine-rich domains (repetitions "IIXXII", present in NTF-1)[14]

Alternatively, since similar amino acid compositions does not necessary mean similar activation pathways, TADs can be grouped by the process they stimulate, either initiation or elongation.[15]

Acidic/9aaTAD edit

 
9aaTAD-KIX domain complexes

Nine-amino-acid transactivation domain (9aaTAD) defines a domain common to a large superfamily of eukaryotic transcription factors represented by Gal4, Oaf1, Leu3, Rtg3, Pho4, Gln3, Gcn4 in yeast, and by p53, NFAT, NF-κB and VP16 in mammals. The definition largely overlaps with an "acidic" family definition. A 9aaTAD prediction tool is available.[16] 9aaTADs tend to have an associated 3-aa hydrophobic (usually Leu-rich) region immediately to its N-terminal.[17]

9aaTAD transcription factors p53, VP16, MLL, E2A, HSF1, NF-IL6, NFAT1 and NF-κB interact directly with the general coactivators TAF9 and CBP/p300.[16][18][19][20][21][22][23][24][25][26][27][28][29] p53 9aaTADs interact with TAF9, GCN5 and with multiple domains of CBP/p300 (KIX, TAZ1,TAZ2 and IBiD).[30][31][32][33][34]

The KIX domain of general coactivators Med15(Gal11) interacts with 9aaTAD transcription factors Gal4, Pdr1, Oaf1, Gcn4, VP16, Pho4, Msn2, Ino2 and P201. Positions 1, 3-4, and 7 of the 9aaTAD are the main residues that interact with KIX.[35][36][37][38][39][40][41][42][43][44][45][46][47][48][49][50] Interactions of Gal4, Pdr1 and Gcn4 with Taf9 have been observed.[8][51][52] 9aaTAD is a common transactivation domain which recruits multiple general coactivators TAF9, MED15, CBP/p300 and GCN5.[16]

Example 9aaTADs and KIX interactions[17]
Source 9aaTAD Peptide-KIX interaction (NMR)
p53 TAD1 E TFSD LWKL LSPEETFSDLWKLPE
p53 TAD2 D DIEQ WFTE QAMDDLMLSPDDIEQWFTEDPGPD
MLL S DIMD FVLK DCGNILPSDIMDFVLKNTP
E2A D LLDF SMMF PVGTDKELSDLLDFSMMFPLPVT
Rtg3 E TLDF SLVT E2A homolog
CREB R KILN DLSS RREILSRRPSYRKILNDLSSDAP
CREBaB6 E AILA ELKK CREB-mutant binding to KIX
Gli3 D DVVQ YLNS TAD homology to CREB/KIX
Gal4 D DVYN YLFD Pdr1 and Oaf1 homolog
Oaf1 D LFDY DFLV DLFDYDFLV
Pip2 D FFDY DLLF Oafl homolog
Pdr1 E DLYS ILWS EDLYSILWSDWY
Pdr3 T DLYH TLWN Pdr1 homolog

Glutamine-rich edit

Glutamine (Q)-rich TADs are found in POU2F1 (Oct1), POU2F2 (Oct2), and Sp1 (see also Sp/KLF family).[12] Although such is not the case for every Q-rich TAD, Sp1 is shown to interact with TAF4 (TAFII 130), a part of the TFIID assembly.[15][53]

See also edit

References edit

  1. ^ Wärnmark A, Treuter E, Wright AP, Gustafsson JA (Oct 2003). "Activation functions 1 and 2 of nuclear receptors: molecular strategies for transcriptional activation". Molecular Endocrinology. 17 (10): 1901–9. doi:10.1210/me.2002-0384. PMID 12893880.
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External links edit

  • 9aaTAD prediction tool

December 17, 2023
transactivation, domain, transactivation, domain, trans, activating, domain, transcription, factor, scaffold, domain, which, contains, binding, sites, other, proteins, such, transcription, coregulators, these, binding, sites, frequently, referred, activation, . The transactivation domain or trans activating domain TAD is a transcription factor scaffold domain which contains binding sites for other proteins such as transcription coregulators These binding sites are frequently referred to as activation functions AFs 1 TADs are named after their amino acid composition These amino acids are either essential for the activity or simply the most abundant in the TAD Transactivation by the Gal4 transcription factor is mediated by acidic amino acids whereas hydrophobic residues in Gcn4 play a similar role Hence the TADs in Gal4 and Gcn4 are referred to as acidic or hydrophobic respectively 2 3 4 5 6 7 8 9 In general we can distinguish four classes of TADs 10 acidic domains called also acid blobs or negative noodles rich in D and E amino acids present in Gal4 Gcn4 and VP16 11 glutamine rich domains contains multiple repetitions like QQQXXXQQQ present in SP1 12 proline rich domains contains repetitions like PPPXXXPPP present in c jun AP2 and Oct 2 13 isoleucine rich domains repetitions IIXXII present in NTF 1 14 Alternatively since similar amino acid compositions does not necessary mean similar activation pathways TADs can be grouped by the process they stimulate either initiation or elongation 15 Contents 1 Acidic 9aaTAD 2 Glutamine rich 3 See also 4 References 5 External linksAcidic 9aaTAD edit nbsp 9aaTAD KIX domain complexesNine amino acid transactivation domain 9aaTAD defines a domain common to a large superfamily of eukaryotic transcription factors represented by Gal4 Oaf1 Leu3 Rtg3 Pho4 Gln3 Gcn4 in yeast and by p53 NFAT NF kB and VP16 in mammals The definition largely overlaps with an acidic family definition A 9aaTAD prediction tool is available 16 9aaTADs tend to have an associated 3 aa hydrophobic usually Leu rich region immediately to its N terminal 17 9aaTAD transcription factors p53 VP16 MLL E2A HSF1 NF IL6 NFAT1 and NF kB interact directly with the general coactivators TAF9 and CBP p300 16 18 19 20 21 22 23 24 25 26 27 28 29 p53 9aaTADs interact with TAF9 GCN5 and with multiple domains of CBP p300 KIX TAZ1 TAZ2 and IBiD 30 31 32 33 34 The KIX domain of general coactivators Med15 Gal11 interacts with 9aaTAD transcription factors Gal4 Pdr1 Oaf1 Gcn4 VP16 Pho4 Msn2 Ino2 and P201 Positions 1 3 4 and 7 of the 9aaTAD are the main residues that interact with KIX 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 Interactions of Gal4 Pdr1 and Gcn4 with Taf9 have been observed 8 51 52 9aaTAD is a common transactivation domain which recruits multiple general coactivators TAF9 MED15 CBP p300 and GCN5 16 Example 9aaTADs and KIX interactions 17 Source 9aaTAD Peptide KIX interaction NMR p53 TAD1 E TFSD LWKL LSPEETFSDLWKLPEp53 TAD2 D DIEQ WFTE QAMDDLMLSPDDIEQWFTEDPGPDMLL S DIMD FVLK DCGNILPSDIMDFVLKNTPE2A D LLDF SMMF PVGTDKELSDLLDFSMMFPLPVTRtg3 E TLDF SLVT E2A homologCREB R KILN DLSS RREILSRRPSYRKILNDLSSDAPCREBaB6 E AILA ELKK CREB mutant binding to KIXGli3 D DVVQ YLNS TAD homology to CREB KIXGal4 D DVYN YLFD Pdr1 and Oaf1 homologOaf1 D LFDY DFLV DLFDYDFLVPip2 D FFDY DLLF Oafl homologPdr1 E DLYS ILWS EDLYSILWSDWYPdr3 T DLYH TLWN Pdr1 homologGlutamine rich editGlutamine Q rich TADs are found in POU2F1 Oct1 POU2F2 Oct2 and Sp1 see also Sp KLF family 12 Although such is not the case for every Q rich TAD Sp1 is shown to interact with TAF4 TAFII 130 a part of the TFIID assembly 15 53 See also editDNA binding protein Transcription factorReferences edit Warnmark A Treuter E Wright AP Gustafsson JA Oct 2003 Activation functions 1 and 2 of nuclear receptors molecular strategies for transcriptional activation Molecular Endocrinology 17 10 1901 9 doi 10 1210 me 2002 0384 PMID 12893880 Ma J Ptashne M Oct 1987 A new class of yeast transcriptional activators Cell 51 1 113 9 doi 10 1016 0092 8674 87 90015 8 PMID 3115591 Sadowski I Ma J Triezenberg S Ptashne M Oct 1988 GAL4 VP16 is an unusually potent transcriptional activator Nature 335 6190 563 4 Bibcode 1988Natur 335 563S doi 10 1038 335563a0 PMID 3047590 S2CID 4276393 Sullivan SM Horn PJ Olson VA Koop AH Niu W Ebright RH Triezenberg SJ Oct 1998 Mutational analysis of a transcriptional activation region of the VP16 protein of herpes simplex virus Nucleic Acids Research 26 19 4487 96 doi 10 1093 nar 26 19 4487 PMC 147869 PMID 9742254 Gill G Ptashne M Oct 1987 Mutants of GAL4 protein altered in an activation function Cell 51 1 121 6 doi 10 1016 0092 8674 87 90016 X PMID 3115592 Hope IA Mahadevan S Struhl K Jun 1988 Structural and functional characterization of the short acidic transcriptional activation region of yeast GCN4 protein Nature 333 6174 635 40 Bibcode 1988Natur 333 635H doi 10 1038 333635a0 PMID 3287180 S2CID 2635634 Hope IA Struhl K Sep 1986 Functional dissection of a eukaryotic transcriptional activator protein GCN4 of yeast Cell 46 6 885 94 doi 10 1016 0092 8674 86 90070 X PMID 3530496 S2CID 40730692 a b Drysdale CM Duenas E Jackson BM Reusser U Braus GH Hinnebusch AG Mar 1995 The transcriptional activator GCN4 contains multiple activation domains that are critically dependent on hydrophobic amino acids Molecular and Cellular Biology 15 3 1220 33 doi 10 1128 mcb 15 3 1220 PMC 230345 PMID 7862116 Regier JL Shen F Triezenberg SJ Feb 1993 Pattern of aromatic and hydrophobic amino acids critical for one of two subdomains of the VP16 transcriptional activator Proceedings of the National Academy of Sciences of the United States of America 90 3 883 7 Bibcode 1993PNAS 90 883R doi 10 1073 pnas 90 3 883 PMC 45774 PMID 8381535 Mitchell PJ Tjian R July 1989 Transcriptional regulation in mammalian cells by sequence specific DNA binding proteins Science 245 4916 371 8 Bibcode 1989Sci 245 371M doi 10 1126 science 2667136 PMID 2667136 Sadowski I Ma J Triezenberg S Ptashne M October 1988 GAL4 VP16 is an unusually potent transcriptional activator Nature 335 6190 563 4 Bibcode 1988Natur 335 563S doi 10 1038 335563a0 PMID 3047590 S2CID 4276393 a b Courey AJ Holtzman DA Jackson SP Tjian R December 1989 Synergistic 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1074 jbc M808263200 PMC 3837390 PMID 19056732 Klein J Nolden M Sanders SL Kirchner J Weil PA Melcher K Feb 2003 Use of a genetically introduced cross linker to identify interaction sites of acidic activators within native transcription factor IID and SAGA The Journal of Biological Chemistry 278 9 6779 86 doi 10 1074 jbc M212514200 PMID 12501245 Milgrom E West RW Gao C Shen WC Nov 2005 TFIID and Spt Ada Gcn5 acetyltransferase functions probed by genome wide synthetic genetic array analysis using a Saccharomyces cerevisiae taf9 ts allele Genetics 171 3 959 73 doi 10 1534 genetics 105 046557 PMC 1456853 PMID 16118188 Hibino E Inoue R Sugiyama M Kuwahara J Matsuzaki K Hoshino M November 2016 Interaction between intrinsically disordered regions in transcription factors Sp1 and TAF4 Protein Science 25 11 2006 2017 doi 10 1002 pro 3013 PMC 5079245 PMID 27515574 External links edit9aaTAD prediction tool Retrieved from https en wikipedia org w index php title Transactivation domain amp oldid 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