A Role for TBP Dimerization in Preventing Unregulated Gene Expression

Jackson-Fisher, Amy; Chitikila, Carmelata; Mitra, Madhusmita; Pugh, B. Franklin

doi:10.1016/s1097-2765(01)80004-6

Cited by 66 publications

(85 citation statements)

References 47 publications

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“…On the other hand, TBP is capable of selfassociation. Dimers, tetramers, octamers, and higher oligomers have been previously reported in vitro (15, 16, 30 -35), while in vivo cross-linking results are consistent with association to at least the dimer level in HeLa and yeast cells (16,36,37). On the basis of these results, it has been proposed that monomeroligomer equilibria affect the concentration of TBP monomer that is available for transport into the nucleus for transcription-regulatory functions or for degradation (15, 16, 32-34, 38, 39).…”

supporting

confidence: 80%

Self-association of the Amino-terminal Domain of the Yeast TATA-binding Protein

Adams

Kar

Hopper

et al. 2004

Journal of Biological Chemistry

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The amino-terminal domain of yeast TATA-binding protein has been proposed to play a crucial role in the self-association mechanism(s) of the full-length protein.Here we tested the ability of this domain to self-associate under a variety of solution conditions. Escherichia coli two-hybrid assays, in vitro pull-down assays, and in vitro cross-linking provided qualitative evidence for a limited and specific self-association. Sedimentation equilibrium analysis using purified protein was consistent with a monomer-dimer equilibrium with an apparent dissociation constant of ϳ8.4 M. Higher stoichiometry associations remain possible but could not be detected by any of these methods. These results demonstrate that the minimal structure necessary for aminoterminal domain self-association must be present even in the absence of carboxyl-terminal domain structures. On the basis of these results we propose that aminoterminal domain structures contribute to the oligomerization interface of the full-length yeast TATA-binding protein.The TATA-binding protein (TBP) 1 is required for transcription initiation in eukaryotes and Archaea (1, 2). Together with TBP-associated protein factors (TAFs (3, 4)), it forms multisubunit complexes required for transcription by RNA polymerases I, II, and III (2, 5-7). TBP is a two-domain protein with a strongly conserved carboxyl-terminal domain (ϳ80% sequence identity among eukaryotes (8, 9)) and an amino-terminal domain highly divergent in both length (18 -173 residues) and sequence (8, 10 -12). The carboxyl-terminal domain is required for DNA binding and interactions with TAFs, general transcription factors (2,13,14), and self-association reactions (15,16). Less is known about the function of the amino-terminal domain, although it has been shown to be necessary for activated transcription of some polymerase II-and III-dependent genes (8,10,(17)(18)(19)(20).TBP functions in transcription initiation as a monomer. It binds TATA sequence DNA as a monomer (21-26) and interacts with TAFs and general transcription factors as a monomer (13,14,(27)(28)(29). On the other hand, TBP is capable of selfassociation. Dimers, tetramers, octamers, and higher oligomers have been previously reported in vitro (15, 16, 30 -35), while in vivo cross-linking results are consistent with association to at least the dimer level in HeLa and yeast cells (16,36,37). On the basis of these results, it has been proposed that monomeroligomer equilibria affect the concentration of TBP monomer that is available for transport into the nucleus for transcription-regulatory functions or for degradation (15, 16, 32-34, 38, 39).Little is known about the mechanism(s) of TBP self-association. Crystal structures of the carboxyl-terminal domain of yeast TBP reveal a saddle-shaped molecule of ϳ180 amino acid residues with a concave DNA-binding face and a convex TAFand transcription factor-binding face (9,21,23,30,31). In the absence of DNA, this crystallizes as a dimer, stabilized by extensive contacts between the concave surfaces (9, 30, 31...

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supporting

confidence: 80%

Self-association of the Amino-terminal Domain of the Yeast TATA-binding Protein

Adams

Kar

Hopper

et al. 2004

Journal of Biological Chemistry

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“…TBP dimers in vitro is that they are present at lower steadystate levels in vivo (8,15). For example, TBP(N69R) is present in yeast cells at levels that are only about 10% of wild type TBP.…”

Section: R98e and R171e Increase The Steady-state Levels Of Tbp(n69r)mentioning

confidence: 99%

“…We reasoned that changing one or the other to an acidic residue might generate a positive electrostatic interaction whose effect can be measured in vitro using dimerization and DNA binding assays. Previous in vivo data suggested that TBP normally resides as dimers only when not bound to DNA (8,15). Under such circumstances, enhanced dimer stability might have little impact on its already autorepressed state.…”

mentioning

confidence: 96%

“…The structure of TBP dimers has been defined crystallographically and through biochemical analysis. Dimer instability caused by mutations along the crystallographic dimer interface correlate with transcriptional derepression in yeast cells (8,15), and this derepression occurs genome-wide at about 7% of all genes (16). Together, these findings indicated that TBP dimerization represents a physiologically important mechanism for auto-inhibiting its DNA binding activity.…”

mentioning

confidence: 99%

“…Under such circumstances, enhanced dimer stability might have little impact on its already autorepressed state. Therefore, we utilized a previously characterized unstable dimer mutant N69R (8) and created additional mutations at Arg-98 and Arg-171 to assess whether such mutations might suppress phenotypes associated with the N69R mutation. Phenotypes include lowered steady-state protein levels of the mutants, transcriptional derepression of a basal promoter, and inhibition of cell growth (toxicity).…”

mentioning

confidence: 99%

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Engineering Dimer-stabilizing Mutations in the TATA-binding Protein

Kou

Pugh

2004

Journal of Biological Chemistry

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The TATA-binding protein (TBP) plays a central role in assembling eukaryotic transcription complexes and is subjected to extensive regulation including auto-inhibition of its DNA binding activity through dimerization. Previously, we have shown that mutations that disrupt TBP dimers in vitro have three detectable phenotypes in vivo, including decreased steady-state levels of the mutants, transcriptional derepression, and toxicity toward cell growth. In an effort to more precisely define the multimeric structure of TBP in vivo, the crystallographic dimer structure was used to design mutations that might enhance dimer stability. These mutations were found to enhance dimer stability in vitro and significantly suppress in vivo phenotypes arising from a dimer-destabilizing mutation. Although it is conceivable that phenotypes associated with dimer-destabilizing mutants could arise through defective interactions with other cellular factors, intragenic suppression of these phenotypes by mutations designed to stabilize dimers provides compelling evidence for a crystallographic dimer configuration in vivo.Gene expression levels are derived from a net output of a dynamic interplay of positive and negative regulatory factors. The main steps leading toward gene activation include chromatin modification and remodeling, TBP 1 delivery, and assembly of the RNA polymerase II holoenzyme (1-3). Each of these steps is the target of multiple regulatory factors. TBP delivery to promoters is directed by the positive action of transcriptional activators, acetylated histone tails, SAGA and TFIID delivery complexes, basal factors such as TFIIA and TFIIB, and the TATA box. Counteracting this delivery are Mot1, NC2, a portion of TAF1 (termed TAND), the amino-terminal domain of TBP, and TBP auto-inhibition, which occurs through dimerization and occlusion of its DNA binding surface.TBP auto-inhibition through dimerization is an evolutionary conserved process, occurring from yeast to mammals (4 -15). The structure of TBP dimers has been defined crystallographically and through biochemical analysis. Dimer instability caused by mutations along the crystallographic dimer interface correlate with transcriptional derepression in yeast cells (8,15), and this derepression occurs genome-wide at about 7% of all genes (16). Together, these findings indicated that TBP dimerization represents a physiologically important mechanism for auto-inhibiting its DNA binding activity. Nonetheless, the notion of an autoinhibited TBP dimer has been sufficiently controversial (17) that we pursued the possibility of using the x-ray crystal structure of TBP dimers to design stabilizing mutations that might intragenically suppress a dimerization mutant.We focused on two residues, Arg-98 and Arg-171, which lie on opposite sides of a TBP monomer. In the dimer configuration, Arg-98 of one monomer lies immediately across Arg-171 of the opposing monomer (11). We reasoned that changing one or the other to an acidic residue might generate a positive electrostatic interaction wh...

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