Pre-bending of a promoter sequence enhances affinity for the TATA-binding factor

DNA bending is induced by binding of the peroxisome proliferator-activated receptor gamma 2 heterodimer to its response element in the murine lipoprotein lipase promoter

The peroxisome proliferator activated receptor gamma 2 (PPAR gamma 2) is a critical transcriptional regulator of adipogenesis. Lipoprotein lipase is one of the earliest genes induced following exposure of pre-adipocytes to PPAR gamma 2 ligands such as the thiazolidinediones. A unique PPAR gamma 2 DNA recognition element was mapped to the region between -171 to -149 bp of the murine LPL promoter, based on transfection analysis of deletion constructs and gel retention assays using bacterially expressed, affinity purified recombinant proteins. Circular permutation analysis determined that binding of the PPAR gamma 2/retinoic acid X receptor (RXR) heterodimer to its LPL promoter recognition element induced DNA bending at an angle of approximately 46 degrees. Parallel studies using an optimal PPAR recognition element obtained a comparable bending angle of 56 degrees. This is the first demonstration that binding of a PPAR protein to its recognition element causes a distortion of the DNA configuration. It indicates that PPAR gamma 2 utilizes a common mechanism shared by other nuclear hormone receptor proteins reported to induce bending at their DNA binding sites.

Transcription initiation from a poly(dA) tract

The mammalian ME1 gene encodes a non-tissue-specific, helix-loop-helix transcription factor that is enriched in morphogenetically active regions during development. Regulation of mouse ME1 gene expression is controlled by a novel initiator (ME1 Inr) that promotes transcription from the center of a 13 bp poly(dA) tract. We show here that the ME1 Inr autonomously directs initiation from the poly(dA) tract both in vitro and in vivo. This transcription was dependent upon two protein complexes; MBPalpha, which associated directly with the poly(dA) tract, and MBPbeta, which introduced an approximately 60 degrees bend immediately downstream of the poly(dA) tract. The MBPalpha and MBPbeta binding sites were strikingly conserved in homologous DNA from several mammalian species and the frog Xenopus laevis. These results suggest that the ME1 Inr constitutes a robust nucleation site that promotes transcription initiation in the absence of conventional promoter elements.

Measurement of the DNA bend angle induced by the catabolite activator protein using Monte Carlo simulation of cyclization kinetics

A Monte Carlo simulation method for studying DNA cyclization (or ring-closure) has been extended to the case of protein-induced bending, and its application to experimental data has been demonstrated. Estimates for the geometric parameters describing the DNA bend induced by the catabolite activator protein (CAP or CRP) were obtained which correctly predict experimental DNA cyclization probabilities (J factors), determined for a set of 11 150 to 166 bp DNA restriction fragments bearing A tracts phased against CAP binding sites. We find that simulation of out-of-phase molecules is difficult and time consuming, requiring the geometric parameters to be optimized individually rather than globally. A wedge angle model for DNA bending was found to make reasonable predictions for the free DNA. The bend angle in the CAP-DNA complex is estimated to be 85 to 90 degrees, in agreement with estimates from gel electrophoresis and X-ray co-crystal structures. Since the DNA is found to have a pre-existing bend of 15 degrees, the change in bend angle induced by CAP is 70 to 75 degrees, in a agreement with an estimate from topological measurements. We find evidence for slight (approximately 10 degrees) unwinding by CAP. The persistence length and helical repeat of the unbound portion of the DNA are in accord with literature-cited values, but the best-fit DNA torsional modulus C is found to be 1.7 (+/- 0.2) x 10(-19) erg. cm, versus literature estimates and best-fit values for the free DNA of 2.0 x 10(-19) to 3.4 x 10(-19) erg.com. Simulations using this low value of C predict that cyclization of molecules with out-of-phase bends proceeds via undertwisting or overtwisting of the DNA between the bends, so as to align the bends, rather than through conformations with substantial writhe. We present experiments on the topoisomers formed by cyclization with CAP which support this conclusion, and thereby rationalize the surprising result that cyclization can actually be enhanced by out-of-phase bends if the twist required to align the bends improves the torsional alignment of the ends. The relationship between the present work and previous studies on DNA bending by CAP is discussed, and recommendations are given for the efficient application of the cyclization/simulation approach to DNA bending.

Preinitation complex assembly: potentially a bumpy path

During 1996 and 1997, several chemical issues that arise in the early stages of preinitiation complex (PIC) formation were resolved. Kinetics experiments indicated that both TBP dimerization and DNA bending influence the rate of TBP-TATA box assembly. Affinity cleavage experiments indicated that TBP lacks the specificity to nucleate assembly of a properly oriented PIC. Finally, high-resolution structures provided the atomic detail of early intermediates in PIC formation.

DNA bending and the curious case of Fos/Jun

DNA bending has been implicated as an important regulatory mechanism in several processes involving protein-DNA interactions. Various methods for examining intrinsic and protein-induced DNA bending may lead to different conclusions. For the Fos and Jun transcription factors, this has resulted in controversy over whether these factors significantly bend DNA at all.

Molecular analyses of metallothionein gene regulation

Metallothionein (MT) genes encode small proteins that chelate metal ions through metal-thiolate bonds with cysteine residues. MTs may have a role in cellular zinc homeostasis and metal detoxification. Congruent with these putative functions, MT gene transcription is induced by metals via multiple metal-responsive elements (MREs) present in the MT gene 5'-regulatory regions. This chapter mainly is focused on studies of the functional and physical interactions of MRE binding proteins with MT promoters from human and rainbow trout. In addition to mediating zinc induction, MREs may make important contributions to nonmetal induced promoter activity. In part, differential basal activity of MREs appears to be determined by sequence and position in the promoter. During zinc induction, increased functional MRE activity correlates with increased activity of mammalian MRE binding proteins by zinc treatment in vivo or in vitro, as detected by electrophoretic mobility shift assays. Interestingly, the addition of cadmium in vitro or in vivo has no detectable effect even though it strongly induces MT gene expression in the same time course. This raises questions about how the effects of cadmium are mediated by MREs. The molecular masses and MRE complex migration of the zinc-responsive factors we detect are consistent with mouse and human metal-responsive transcription factor (MTF) and expression of the MTF cDNAs increases co-transfected MT promoter activity in both mammalian and trout cell lines underlining the conservation of MRE binding factor function among diverse species.

Functional analysis of DNA bending and unwinding by the high mobility group domain of LEF-1

LEF-1 (lymphoid enhancer-binding factor 1) is a cell type-specific member of the family of high mobility group (HMG) domain proteins that recognizes a specific nucleotide sequence in the T cell receptor (TCR) alpha enhancer. In this study, we extend the analysis of the DNA-binding properties of LEF-1 and examine their contributions to the regulation of gene expression. We find that LEF-1, like nonspecific HMG-domain proteins, can interact with irregular DNA structures such as four-way junctions, albeit with lower efficiency than with specific duplex DNA. We also show by a phasing analysis that the LEF-induced DNA bend is directed toward the major groove. In addition, we find that the interaction of LEF-1 with a specific binding site in circular DNA changes the linking number of DNA and unwinds the double helix. Finally, we identified two nucleotides in the LEF-1-binding site that are important for protein-induced DNA bending. Mutations of these nucleotides decrease both the extent of DNA bending and the transactivation of the TCR alpha enhancer by LEF-1, suggesting a contribution of protein-induced DNA bending to the function of TCR alpha enhancer.

Clues and consequences of DNA bending in transcription

This review attempts to substantiate the notion that nonlinear DNA structures allow prokaryotic cells to evolve complex signal integration devices that, to some extent, parallel the transduction cascades employed by higher organisms to control cell growth and differentiation. Regulatory cascades allow the possibility of inserting additional checks, either positive or negative, in every step of the process. In this context, the major consequence of DNA bending in transcription is that promoter geometry becomes a key regulatory element. By using DNA bending, bacteria afford multiple metabolic control levels simply through alteration of promoter architecture, so that positive signals favor an optimal constellation of protein-protein and protein-DNA contacts required for activation. Additional effects of regulated DNA bending in prokaryotic promoters include the amplification and translation of small physiological signals into major transcriptional responses and the control of promoter specificity for cognate regulators.

Curvature and sequence analysis of eukaryotic promoters

We have calculated the curvature of 504 eukaryotic promoters predicted by the bent A-tract model of Bolshoy et al. (Proc. Natl. Acad. Sci. USA, 88(6), pp. 2312-16) and the bent non-A-tract models of Calladine et al. (J. Mol. Biol., 201, pp. 127-37) and Satchwell et al. (J. Mol. Biol., 191, pp. 659-75) and found in each case a correlation between TBP binding sites and DNA curvature. Characterizing the TBP binding sites revealed that in addition to the classical TATA box (TATAAA) five more elements occur significantly often in the promoters, nearly all of them being one point mutations of the classical TATA box element. Separate curvature calculations for promoters with canonical and non-canonical TATA boxes have shown that in both cases the strong curvature of the helix axes in the domain of the binding sites is maintained (classical TBP binding sites: + 64-135%, non-classical TBP binding sites: + 27-49%). These results support the proposition that beside DNA flexibility and DNA-protein interactions intrinsic curvature of DNA is one further important criterion for the recognition of different DNA elements by TBP.

Considerations of transcriptional control mechanisms: do TFIID-core promoter complexes recapitulate nucleosome-like functions?

The general transcription initiation factor TFIID was originally identified, purified, and characterized with a biochemical assay in which accurate transcription initiation is reconstituted with multiple, chromatographically separable activities. Biochemical analyses have demonstrated that TFIID is a multiprotein complex that directs preinitiation complex assembly on both TATA box-containing and TATA-less promoters, and some TFIID subunits have been shown to be molecular targets for activation domains in DNA-binding regulatory proteins. These findings have most commonly been interpreted to support the view that transcriptional activation by upstream factors is the result of enhanced TFIID recruitment to the core promoter. Recent insights into the architecture and cell-cycle regulation of the multiprotein TFIID complex prompt both a reassessment of the functional role of TFIID in gene activation and a review of some of the less well-appreciated literature on TFIID. We present a speculative model for diverse functional roles of TFIID in the cell, explore the merits of the model in the context of published data, and suggest experimental approaches to resolve unanswered questions. Finally, we point out how the proposed functional roles of TFIID in eukaryotic class II transcription fit into a model for promoter recognition and activation that applies to both eubacteria and eukaryotes.

Comparative analyses of LTRs of the ERV-H family of primate-specific retrovirus-like elements isolated from marmoset, African green monkey, and man

We have isolated 8 different long terminal repeat (LTR) sequences of the ERV-H family of endogenous retrovirus-like elements from human chromosome 18, 9 from African green monkey, and 28 from marmoset. Human ERV-H LTRs have been divided into three types designated Type I, Type Ia, and Type II. Comparative analyses of the 45 isolated LTRs and 60 human ERV-H LTRs enabled a further subdivision into 13 subtypes. Type I elements were widely distributed in all three species. Their average evolutionary age (40 MYr), estimated by a consensus sequence approach, suggests that they first expanded in the genomes at the time New- and Old World monkeys diverged. The occurence of some very old Type I sequences indicate that ERV-H elements may have integrated even before prosimians and primates diverged. Type Ia and - II elements were found in both monkey species. Promoter active Type I and Type Ia LTRs were found while Type II LTRs were inactive. Promoter active Type I LTRs generally contained a functional GC/GT box immediately 3' to the TATA box, providing strong binding of Sp1 family proteins, while the highly promoter active Type Ia element H6 contained synergistically acting Sp1 binding sites located in the U3 enhancer region.

Slow dimer dissociation of the TATA binding protein dictates the kinetics of DNA binding

The association of the TATA binding protein (TBP) to eukaryotic promoters is a possible rate-limiting step in gene expression. Slow promoter binding might be related to TBP's ability to occlude its DNA binding domain through dimerization. Using a "pull-down" based assay, we find that TBP dimers dissociate slowly (t1/2 = 6-10 min), and thus present a formidable kinetic barrier to TATA binding. At 10 nM, TBP appears to exist as a mixed population of monomers and dimers. In this state, TATA binding displays burst kinetics that appears to reflect rapid binding of monomers and slow dissociation of dimers. The kinetics of the slow phase is in excellent agreement with direct measurements of the kinetics of dimer dissociation.

Conformational properties of the TATA-box binding sequence of DNA

Nanosecond scale molecular dynamics simulations in water demonstrate that the DNA oligomer, GCGTATATAAAACGC, which contains a target site for the TATA-box binding protein (TBP), has an intrinsic preference to adopt an A-like conformation in the region of the TATA-box and undergoes bending related to that seen within in the TBP complex. This result is obtained from two independent simulations using different starting structures. In line with earlier suggestions of Guzikevich-Guerstein and Shakked, these simulations imply that an A-DNA conformation may be an important intermediate step in forming the strongly distorted DNA observed within the crystallographically determined complex with TBP. These results also support modeling studies by Lebrun et al. which suggest that the TBP binding mechanism can be broken down into a backbone transition to an A-like form coupled with a mechanical distortion which locally stretches and unwinds the DNA.

Prebending the estrogen response element destabilizes binding of the estrogen receptor DNA binding domain

Binding of many eukaryotic transcription regulatory proteins to their DNA recognition sequences results in conformational changes in DNA. To test the effect of altering DNA topology by prebending a transcription factor binding site, we examined the interaction of the estrogen receptor (ER) DNA binding domain (DBD) with prebent estrogen response elements (EREs). When the ERE in minicircle DNA was prebent toward the major groove, which is in the same direction as the ER-induced DNA bend, there was no significant effect on ER DBD binding relative to the linear counterparts. However, when the ERE was bent toward the minor groove, in a direction that opposes the ER-induced DNA bend, there was a four- to eightfold reduction in ER DBD binding. Since reduced binding was also observed with the ERE in nicked circles, the reduction in binding was not due to torsional force induced by binding of ER DBD to the prebent ERE in covalently closed minicircles. To determine the mechanism responsible for reduced binding to the prebent ERE, we examined the effect of prebending the ERE on the association and dissociation of the ER DBD. Binding of the ER DBD to ERE-containing minicircles was rapid when the EREs were prebent toward either the major or minor groove of the DNA (k(on) of 9.9 x 10(6) to 1.7 x 10(7) M(-1) s(-1)). Prebending the ERE toward the minor groove resulted in an increase in k(off) of four- to fivefold. Increased dissociation of the ER DBD from the ERE is, therefore, the major factor responsible for reduced binding of the ER DBD to an ERE prebent toward the minor groove. These data provide the first direct demonstration that the interaction of a eukaryotic transcription factor with its recognition sequence can be strongly influenced by altering DNA topology through prebending the DNA.

Angle and locus of the bend induced by the msp I DNA methyltransferase in a sequence-specific complex with DNA

Bending of DNA induced by M.Msp I, one of the m5C-DNA methyltransferases, has been investigated using circular permutation analysis. The M.Msp I MTase induced sharp bends in DNA containing its recognition sequence 5'-CCGG-3'which was estimated to be 142+/-4 degrees and 132+/-4 degrees for circularly permuted DNA fragments of 127 and 1459 bp respectively. The bend centre was found to be asymmetric with respect to the CCGG sequence and appeared to exclude the 'target cytosine'. An estimate of approximately 15 kcal/mol was obtained for the free energy associated with M.Msp I-induced DNA bending.

Template topology and transcription: chromatin templates relaxed by localized linearization are transcriptionally active in yeast

To address the role of transient torsional stress in transcription, we have utilized the regulated expression of HO endonuclease in yeast to create double-strand breaks in DNA templates in vivo at preselected sites. Linearization of circular minichromosomes, either 2 kb upstream or immediately downstream of a lacZ reporter gene controlled by the yeast metallothionein gene (CUP1) promoter, did not alter the copper induction profile of lacZ RNA transcripts compared to that of nonlinearized controls. Constructs site-specifically integrated into yeast chromosome II gave similar results. In vivo cross-linking with psoralen as a probe for negative DNA supercoiling demonstrated that template linearization efficiently dissipated DNA supercoiling induced by transcription. Therefore, the efficient transcription of linearized, relaxed templates found here demonstrates that transient torsional tension is not required for transcription of chromatin templates in yeast.

Structural and functional analyses of DNA bending induced by Sp1 family transcription factors

DNA bending induced by eukaryotic transcription factors may play a direct role in the activation of transcription by bringing together factors bound at non-adjacent sites or facilitate binding of factors involved in the formation of an initiation complex. The ubiquitously expressed zinc-finger transcription factor Sp1 is involved in the regulation of a variety of viral and cellular genes. During the past few years proteins homologous to Sp1 have been described constituting a family of Sp1 transcription factors. We have used gel electrophoretic methods to analyse the extent, location and direction of the DNA bend induced by four different Sp1 family proteins upon binding to a consensus GC box. We found that the Sp1 family proteins induce an asymmetric bend in DNA directed towards the major groove, with a bend centre displaced towards the 3' end of the GC box. The zinc-finger domain was alone responsible for introducing this distortion. The magnitude of the induced bend varied between the different proteins. Construction of a hybrid protein and mutation of the 3' end of the GC box indicated that zinc finger 1 is important both for the magnitude of the bend angle, location of the bend centre and the binding affinity. Transactivation studies of a Sp1-dependent promoter revealed that a 5 bp insertion between the TATA box and the GC box, or inversion of the GC box significantly reduced the promoter activity, indicating that protein-induced bending could be important for promoter activity. However, no stimulatory effect could be observed in cotransfections with the DNA binding domain of Sp1 in Drosophila SL-2 cells, suggesting that the bending activity alone is not sufficient for transactivation.

The transcription promoter of the spliced leader gene from Trypanosoma cruzi

A putative promoter element responsible for transcription of the spliced leader (SL) gene of Trypanosoma cruzi was identified by overlapping deletion and linker scanning analyses of the upstream flanking sequences using the bacterial chloramphenicol acetyltransferase (CAT) gene as a reporter in transient transfections of cultured epimastigotes. Deletion or substitution of a proximal sequence element (PSE) between positions -53 and -40 relative to the transcription start point eliminated CAT gene expression. Comparison of SL genes from several strains of T. cruzi revealed two alternative sequence patterns for the putative SL PSE, both composed of a short run of purines followed by a run of pyrimidines. Moreover, an examination of these sequences supports the subdivision of T. cruzi isolates into two divergent groups. Double-stranded oligonucleotides containing the sequence of the PSE exhibited specific gel mobility shifts after incubation with T. cruzi nuclear extracts, suggesting that a transcription factor binds this site. Finally, experiments designed to increase the level of CAT expression from the SL promoter suggest that it is not a strong promoter in cultured T. cruzi epimastigotes.

DNA curvature controls termination of plus strand DNA synthesis at the centre of HIV-1 genome

In vivo and in vitro, reverse transcriptase (RT) from human immunodeficiency virus type 1 (HIV-1) terminates plus strand synthesis at the centre of the viral genome. The central termination sequence (CTS) contains curved DNA fragments located upstream of each terminator site. Two different models, relying either on the A-tract or general sequence roll assumptions, were used to predict the extent and the direction of this curvature as well as to design mutants, which abolished it. Straightening of each curved element abolished termination at the site located immediately downstream from the curvature. When synthesis was performed on the other strand and in the opposite direction, the two curved elements C1 and C2 associated with the two termination sites Ter1 and Ter2, led again to termination of DNA synthesis. Therefore, termination occurred as a nascent bent duplex was synthesized within the template primer binding cleft of RT, even when putative strand-specific motifs have been removed by the inversion. Computation of DNA paths upstream of other known arrest sites suggested that this feature was of general relevance for termination. At the CTS, termination occurred more precisely at the 3' end of an AnTm motif (n + m = 7). The possible structures, adopted by this motif, are discussed and confronted with the present crystallographic and biochemical data obtained on HIV-1 RT-DNA interactions and on HIV-1 RT processivity.

The transcriptional activity of a muscle-specific promoter depends critically on the structure of the TATA element and its binding protein

We have previously characterized the proximal promoter of the mouse IIB myosin heavy chain (MyHC) gene, which is expressed only in fast-contracting glycolytic skeletal muscle fibers. We show here that the substitution into this promoter of a non-canonical TATA sequence from the IgH gene results in inactivity in muscle cells, even though TATA-binding protein (TBP) can bind strongly to this mutated promoter. Chemical foot-printing data show, however, that TBP makes different DNA contacts on this heterologous TATA sequence. The inactivity of such a non-canonical TATA motif in the IIB promoter context appears to be caused by a non-functional conformation of the bound TBP-DNA complex that is incapable of sustaining transcription. The conclusions imply that the precise sequence of the promoter TATA motif needs to be matched with the specific functional class of upstream activator proteins present in a given cell type in order for the gene to be transcriptionally active.

RNA polymerase II transcription initiation: a structural view

In eukaryotes, RNA polymerase II transcribes messenger RNAs and several small nuclear RNAs. Like RNA polymerases I and III, polymerase II cannot act alone. Instead, general initiation factors [transcription factor (TF) IIB, TFIID, TFIIE, TFIIF, and TFIIH] assemble on promoter DNA with polymerase II, creating a large multiprotein-DNA complex that supports accurate initiation. Another group of accessory factors, transcriptional activators and coactivators, regulate the rate of RNA synthesis from each gene in response to various developmental and environmental signals. Our current knowledge of this complex macromolecular machinery is reviewed in detail, with particular emphasis on insights gained from structural studies of transcription factors.

Eukaryotic transcription factor-DNA complexes

Eukaryotes have three distinct RNA polymerases that catalyze transcription of nuclear genes. RNA polymerase II is responsible for transcribing nuclear genes encoding the messenger RNAs and several small nuclear RNAs. Like RNA polymerases I and III, polymerase II cannot recognize its target promoter directly and initiate transcription without accessory factors. Instead, this large multisubunit enzyme relies on general transcription factors and transcriptional activators and coactivators to regulate transcription from class II promoters. X-ray crystallography and nuclear magnetic resonance spectroscopy have been used to study complexes of general transcription factors and transcriptional activators with their specific DNA targets. This work has provided important structural insights into transcription initiation by polymerase II and the more general problem of DNA sequence recognition.

DNA bending is induced by binding of the glucocorticoid receptor DNA binding domain and progesterone receptors to their response element

Circular permutation analysis was used to determine the degree of DNA bending induced by binding of the glucocorticoid receptor (GR) DNA binding domain (DBD), the human progesterone receptor (PR) DBD, PR-A:A and PR-B:B homodimers, and PR-A:B heterodimers to the glucocorticoid response element/progesterone response element (GRE/PRE). The bending angles induced by the GR DBD and the PR DBD were approximately 28 degrees and 25 degrees, respectively. The PR-B:B and PR-A:A homodimers and the PR-A:B heterodimers all induced similar DNA bending angles of 72-77 degrees. The substantially greater DNA bend induced by full-length PR compared to the PR DBD indicates that sequences outside the classic zinc finger DNA binding domain may play an important role in the interaction of PR with the GRE/PRE. Because PR-A:A and PR-B:B homodimers and the PR-A:B heterodimers induce similar DNA bends, the different abilities of the PR-A and PR-B isoforms to activate transcription are not due to differences in their abilities to distort DNA structure.

The leucine zipper may induce electrophoretic mobility anomalies without DNA bending

Numerous proteins bend DNA upon binding, a phenomenon of potential significance for regulation of gene expression and chromatin. DNA bending is commonly predicted from the presence of electrophoretic mobility anomalies in protein-DNA complexes. However, as compared with electrophoretic methods, several DNA binding oncoprotein families do not display comparable evidence of DNA bends in x-ray structural studies. Herein, circularization kinetics and affinity measurements with prebent DNA templates were employed to assess bending and DNA structural preferences for Max and other basic helix-loop-helix/leucine zipper proteins. In this way, proteins in the Myc/Max basic helix-loop-helix/ leucine zipper family were found not to bend DNA in solution but to actually stabilize DNA in an unbent configuration that resists circularization. The mobility anomaly was found to be induced by the leucine zipper protein motif, rather than structural distortions of DNA. Thus rigid protein domain structures may induce anomalous electrophoretic mobility. Moreover, the energetic preference of non-DNA bending proteins for unbent templates suggests mechanisms whereby chromatin structure may regulate transcription.

Binding of YY1 to a site overlapping a weak TATA box is essential for transcription from the uteroglobin promoter in endometrial cells

The gene for rabbit uteroglobin codes for a small calcium-, steroid-, and biphenyl metabolite-binding homodimeric protein which is expressed in a variety of epithelial cell types such as Clara cells (lung) and the glandular and luminal cells of the endometrium. One important region mediating its efficient transcription in a human endometrium-derived cell line, Ishikawa, is centered around a noncanonical TATA box. Two factors, TATA core factor (TCF), expressed in cell lines derived from uteroglobin-expressing tissues, and the ubiquitously expressed TATA palindrome factor, bind to the DNA major groove at two adjacent sites within this region. Here, we report the identification of the TATA palindrome factor as the transcription/initiation factor YY1 by microsequencing of the biochemically purified factor from HeLa cells. The binding site for YY1 within the uteroglobin gene is unique in its sequence and its location overlapping a weak TATA box (TACA). Binding of YY1 was required for efficient transcription in TCF-positive Ishikawa cells, which responded only weakly to a change of TACA to TATA, although in vitro binding affinity for the TATA-box-binding protein increased by 1 order of magnitude. In contrast, in CV-1 cells, lacking TCF, binding of YY1 was not required for transcription in the context of a wild-type TACA box, whereas a change from TACA to TATA led to significantly increased reporter gene expression. DNA binding data exclude a role of YY1 in stabilizing the interaction of the TATA-box-binding protein with the uteroglobin promoter. We conclude that cell lines derived from uteroglobin-expressing tissues overcome the weak TATA box with the help of auxiliary factors, one of them being YY1.

In simple synthetic promoters YY1-induced DNA bending is important in transcription activation and repression

Depending on promoter context, YY1 can activate or repress transcription, or provide a site for transcription initiation. To investigate whether the ability of YY1 to induce DNA bending influenced its ability to activate and repress transcription, simple synthetic promoters were constructed in which the YY1 binding site was inserted between the TATA box and either the NF1 or AP1 recognition sequences. In transient transfections of COS cells, the NF1YY1TATA and NF1RYY1TATA promoters exhibited a dramatic 15-20-fold increase in correctly initiated transcription. These promoters exhibited even larger 60-80-fold increases in transcription in HeLa cells. Neither multiple copies of the YY1 binding site alone, nor placement of a YY1 site upstream of the NF1 site activated transcription. Deletion of 4 bp between the NF1 and YY1 sites, which changes the phase of the DNA bends, abolished the 16-fold activation of transcription by NF1YY1TATA. Insertion of the YY1 site between the AP1 site and the TATA box decreased transcription approximately 3-fold. Replacing the YY1 binding site with an intrinsic DNA bending sequence mimicked this transcription repression. Sequences of similar length which do not bend DNA fail to repress AP1-mediated transcription. Gel mobility shift assays were used to show that binding of YY1 to its recognition sequence did not repress binding of AP1 to its recognition sequences. Our data indicate that YY1-induced DNA bending may activate and repress transcription by changing the spatial relationships between transcription activators and components of the basal transcription apparatus.

The design of an agent to bend DNA

An artificial DNA bending agent has been designed to assess helix flexibility over regions as small as a protein binding site. Bending was obtained by linking a pair of 15-base-long triple helix forming oligonucleotides (TFOs) by an adjustable polymeric linker. By design, DNA bending was introduced into the double helix within a 10-bp spacer region positioned between the two sites of 15-base triple helix formation. The existence of this bend has been confirmed by circular permutation and phase-sensitive electrophoresis, and the directionality of the bend has been determined as a compression of the minor helix groove. The magnitude of the resulting duplex bend was found to be dependent on the length of the polymeric linker in a fashion consistent with a simple geometric model. Data suggested that a 50-70 degrees bend was achieved by binding of the TFO chimera with the shortest linker span (18 rotatable bonds). Equilibrium analysis showed that, relative to a chimera which did not bend the duplex, the stability of the triple helix possessing a 50-70 degrees bend was reduced by less than 1 kcal/mol of that of the unbent complex. Based upon this similarity, it is proposed that duplex DNA may be much more flexible with respect to minor groove compression than previously assumed. It is shown that this unusual flexibility is consistent with recent quantitation of protein-induced minor groove bending.

A shared, non-canonical DNA conformation detected at DNA/protein contact sites and bent DNA in the absence of supercoiling or cognate protein binding

A hybrid protein (H144), consisting of Lac repressor and T7 endonuclease I, binds at the lac operator and cleaves relaxed double-stranded DNA at distal but distinct sites. These sites are shown here to coincide with a bacterial promoter, a phage T7 promoter, a site for gyrase and intrinsically bent DNA. The targets do not seem to share a particular DNA sequence, and in bent DNA, cleavage occurs at the physical center rather than at the common A-tracts. These results indicate that protein contact sites and intrinsic bends assume a non-canonical conformation in the absence of supercoiling or cognate protein binding. This feature may serve as a recognition signal or facilitate protein binding to initiate transcription and recombination.

Sequence-specific recognition of cytosine C5 and adenine N6 DNA methyltransferases requires different deformations of DNA

DNA methyltransferases modify specific cytosines and adenines within 2-6 bp recognition sequences. We used scanning force microscopy and gel shift analysis to show that M.HhaI, a cytosine C-5 DNA methyltransferase, causes only a 2 degree bend upon binding its recognition site. Our results are consistent with prior crystallographic analysis showing that the enzyme stabilizes an extrahelical base while leaving the DNA duplex otherwise unperturbed. In contrast, similar analysis of M.EcoRI, an adenine N6 DNA methyltransferase, shows an average bend angle of approximately 52 degrees. This distortion of DNA conformation by M.EcoRI is shown to be important for sequence-specific binding.

Cooperation between core binding factor and adjacent promoter elements contributes to the tissue-specific expression of interleukin-3

Tissue-specific expression of interleukin-3 (IL-3) is mediated via cis-acting elements located within 315 base pairs of the transcription start. This is achieved in part through the positive activities of the AP-1 and Elf-1 sites in the IL-3 promoter. The contribution to T cell-specific expression by other promoter sites was assessed in a transient expression assay with IL-3 promoter constructs linked to a luciferase gene, focusing initially on the core binding factor (CBF) site, which is footprinted in vivo upon T cell activation. Activity of the CBF site is shown to be critically dependent on the adjacent activator site Act-1. Together the Act-1 and CBF sites form a functional unit (AC unit) with dual activity. The AC unit is demonstrated to enhance basal activity of promoters both in fibroblasts and T cells. This activity is further inducible in activated T cells, but not in fibroblasts. In addition to the already identified NIP repressor site, evidence is presented for a second repressor region that restricts promoter activity in fibroblasts. Finally, a novel positive regulatory element has been mapped in the IL-3 promoter between nucleotide -180 and -210 that leads to increased expression in T cells. Together these results demonstrate that T cell expression of IL-3 is not specified by the activity of a single tissue-specific element, but instead involves multiple interacting elements that provide both specific positive regulation in T cells and specific negative regulation in fibroblasts.

Complex formation between CREB and Tax enhances the binding affinity of CREB for the human T-cell leukemia virus type 1 21-base-pair repeats

The regulation of human T-cell leukemia virus type 1 (HTLV-1) gene expression is dependent on three cis-acting elements, known as the 21-bp repeats, in the long terminal repeat. Each of the 21-bp repeats contains a nonpalindromic cyclic AMP response element (CRE) sequence which is capable of binding members of the ATF/CREB family of transcription factors. The HTLV-1 transactivator protein Tax is able to markedly stimulate the in vitro binding of CREB to the CRE sites present in each of the 21-bp repeats but not to CRE sites present in cellular promoters. The ability to Tax to stimulate CREB binding to different CRE sites correlates with the ability of Tax to activate gene expression from these sites. We wished to determine how sequence differences between the somatostatin CRE and the 21-bp repeat were involved in this different response to Tax. Scatchard analysis indicated that CREB bound to the somatostatin CRE with a single class of high-affinity binding while CREB bound to the 21-bp repeats with a biphasic binding pattern, indicating the presence of both low- and high-affinity binding. Tax increased the affinity of CREB binding but not that of another ATF/CREB protein, CREB2, to the 21-bp repeat. However, Tax did not increase affinity of binding of CREB to the somatostatin CRE. To determine the mechanism by which Tax increased dCREB binding affinity, immobilized oligonucleotides corresponding to either the 21-bp repeat or the somatostatin CRE were used to demonstrate that Tax formed a highly specific complex with CREB on the 21-bp repeat but not on the somatostatin CRE. These results indicate that formation of a complex between Tax and CREB results in specific high-affinity binding of this ternary complex to the HTLV-1 21 bp repeats.

Anatomy of a flexer-DNA complex inside a higher-order transposition intermediate

SUMMARY

Escherichia coli HU, a nonsequence-specific histone- and HMG-like DNA-binding protein, was chemically converted into a series of HU-nucleases with an iron-EDTA-based cleavage moiety positioned at 16 rationally selected sites. Specific DNA cleavage patterns from each of these HU-nucleases allowed us to determine the precise localization, stoichiometry, and orientation of HU binding in the Mu transpososome, a multiprotein structure that mediates the chemical reactions in DNA transposition. Correlation of the DNA cleavage data with the position of the cleavage moiety in the HU three-dimensional structure indicates the presence of a dramatic DNA bend, for which the bend center, direction, and magnitude were assessed. The data, which directly localize selected HU amino acids with respect to DNA in the transpososome, were used as constraints for computer-based molecular modeling to derive the first snapshot of an HU-DNA interaction.

X-ray crystallographic studies of eukaryotic transcription initiation factors

TATA box-binding protein (TBP) is required by all three eukaryotic RNA polymerases for correct initiation of transcription of ribosomal, messenger, small nuclear and transfer RNAs. Since the first gene encoding a TBP was cloned, it has been the object of considerable biochemical and genetic study. Substantial progress has also been made on structural and mechanistic studies, including our three-dimensional crystal structures of TBP, TBP bound to a consensus TATA elements, and the ternary complex of transcription factor IIB (TFIIB) recognizing TBP bound to a TATA element. The structure of apo TBP was determined at 2.1 A resolution. This highly symmetric alpha/beta structure represents a new DNA-binding fold, which resembles a molecular "saddle' that sits astride the DNA. The DNA-binding surface is a novel curved, antiparallel beta-sheet. The structure of TBP complexed with the TATA element of the Adenovirus major late promoter was determined at 1.9 A resolution. Binding of the protein induces a dramatic conformational change in the DNA, by tracking the minor groove and inducing two sharp kinks at either end of the sequence TATAAAAG. Between the kinks, the right-handed double helix is smoothly curved and partly unwound, presenting a widened minor groove to TBP's concave, antiparallel beta-sheet. Side chain-base interactions are completely restricted to the minor groove, and include hydrogen bonds, van der Waals contacts and phenylalanine-base stacking interactions. The structure of a TFIIB/TBP/TATA element ternary complex was determined at 2.7 A resolution. Core TFIIB resembles cyclinA, and recognizes the preformed TBP-DNA complex via protein-protein and protein-DNA interactions. The N-terminal domain of core TFIIB forms the downstream surface of the ternary complex, where it could fix the transcription start site. The remaining surfaces of TBP and the TFIIB can interact with TBP-associated factors, other class II initiation factors, and transcriptional activators and coactivators.

cAMP-response element-binding protein induces directed DNA bending of the HTLV-I 21-base pair repeat

Gene expression from the human T-cell leukemia virus type I (HTLV-I) long terminal repeat (LTR) is mediated by three cis-acting regulatory elements known as 21-base pair (bp) repeats in addition to the transactivator protein Tax. Each of the 21-bp repeats contain nucleotide sequences which are homologous to a cAMP response element (CRE) which bind members of the ATF/CREB family of transcription factors. In this study, we investigated whether CREB alone or in the presence of Tax was able to induce DNA structural changes when bound to CRE sites in the HTLV-I 21 bp, the cellular somatostatin promoter, or a hybrid CRE construct comprised of both the somatostatin and 21-bp repeat sequences. Circular permutation analysis indicated that CREB was able to induce DNA flexure upon binding to each of these elements. However, phasing analysis, which is a more sensitive method to determine the degree and orientation of directed DNA bending, demonstrated that CREB induced DNA bending of the HTLV-I 21-bp repeat and the hybrid CRE but not the somatostatin CRE. The addition of Tax did not change CREB-mediated bending of the 21-bp repeat or the hybrid CRE although it markedly increased the amount of CREB bound to each of these DNA elements. These results indicate that sequence motifs flanking the CRE in the 21-bp repeat are critical for inducing DNA structural changes and that these changes are likely important in mediating Tax activation of the HTLV-I LTR.

Intercalation, DNA kinking, and the control of transcription

Biological processes involved in the control and regulation of transcription are dependent on protein-induced distortions in DNA structure that enhance the recruitment of proteins to their specific DNA targets. This function is often accomplished by accessory factors that bind sequence specifically and locally bend or kink the DNA. The recent determination of the three-dimensional structures of several protein-DNA complexes, involving proteins that perform such architectural tasks, brings to light a common theme of side chain intercalation as a mechanism capable of driving the deformation of the DNA helix. The protein scaffolds orienting the intercalating side chain (or side chains) are structurally diverse, presently comprising four distinct topologies that can accomplish the same task. The intercalating side chain (or side chains), however, is exclusively hydrophobic. Intercalation can either kink or bend the DNA, unstacking one or more adjacent base pairs and locally unwinding the DNA over as much as a full turn of helix. Despite these distortions, the return to B-DNA helical parameters generally occurs within the adjacent half-turns of DNA.

DNA binding by TATA-box binding protein (TBP): a molecular dynamics computational study

TATA-box binding protein (TBP) in a monomeric form and the complexes it forms with DNA have been elucidated with molecular dynamics simulations. Large TBP domain motions (bend and twist) are detected in the monomer as well as in the DNA complexes; these motions can be important for TBP binding of DNA. TBP interacts with guanine bases flanking the TATA element in the simulations of the complex; these interactions may explain the preference for guanine observed at these DNA positions. Side chains of some TBP residues at the binding interface display significant dynamic flexibility that results in 'flip-flop' contacts involving multiple base pairs of the DNA. We discuss the possible functional significance of these observations.

The TATA box binding protein

The TATA box binding protein is required by all three eukaryotic RNA polymerases to correctly initiate the transcription of ribosomal, messenger, small nuclear and transfer RNAs. Since the first gene encoding a TATA box binding protein was cloned from Saccharomyces cerevisiae, it has been the object of considerable biochemical and genetic study. Substantial progress has recently been made on structural and mechanistic studies of the protein. Three-dimensional structures newly elucidated include two TATA box binding proteins alone and bound to distinct TATA elements, and the ternary complex of transcription factor IIB recognizing a TATA box binding protein bound to a TATA element.

Characterization of the bone sialoprotein (BSP) gene promoter

Bone sialoprotein is a 34 kDa phosphorylated and sulphated glycoprotein that is essentially unique to mineralizing connective tissues. Recent studies on the developmental expression of BSP mRNA and the temporo-spatial appearance of the protein during bone formation in vivo and in vitro have demonstrated that BSP is expressed by differentiated osteoblasts and that it may function in the initial nucleation of hydroxyapatite crystals in de novo bone formation. To study the cell-specific regulation of BSP we have isolated genomic clones that encompass the BSP promoter regions of both the human and rat genes. These promoters are characterized by a highly conserved region (BSP Box) that extends upstream from the transcription start site to nt -370. Within this region the immediate promoter is further characterized by a unique inverted TATA box and an inverted CCAAT box, both of which are required for basal transcriptional activity. The TATA box is overlapped by a vitamin D3 response element (VDRE) which appears to mediate vitamin D suppression of BSP gene transcription by competing with the TATA-binding protein (TBP) for occupancy of the site of the pre-initiation complex formation. Mutation of the inverted TATA box into a normal TATA sequence increases transcription slightly but does not affect the functionality of the VDRE indicating that the orientation of the TATA box is not critical for these functions. Further upstream an AP-1 site, overlapped by a steroid hormone response-like sequence, mediates down-regulation of BSP transcription induced by TPA that is abrogated by a complex interaction between Jun and the glucocorticoid receptor protein induced by dexamethasone. Thus, the characterization of approximately 3 kb of the BSP promoter and approximately 2 kb of the first intron has revealed several sites of transcriptional regulation that are important in regulating BSP expression and, consequently, bone formation.

The promoter activity of long terminal repeats of the HERV-H family of human retrovirus-like elements is critically dependent on Sp1 family proteins interacting with a GC/GT box located immediately 3' to the TATA box

The HERV-H family of endogenous retrovirus-like elements is widely distributed in the human genome, with about 1,000 full-length elements and a similar number of solitary long terminal repeats (LTRs). HERV-H LTRs have been shown to direct the transcription of both HERV-H-encoded and adjacent cellular genes. Transcripts of HERV-H elements are especially abundant in placenta, teratocarcinoma cell lines, and cell lines derived from testicular and lung tumors. Here we report that only a subset of HERV-H LTRs display promoter activity in human cell lines and that these LTRs are characterized by the presence of a GC/GT box immediately downstream of the TATA box. This GC/GT box is required for promoter activity, while, surprisingly, the TATA box is dispensable. The ubiquitously expressed transcription factors Sp1 and Sp3 bound to this GC/GT box and stimulated transcription from the promoter-active LTRs in the teratocarcinoma cell line NTera2-D1. However, in HeLa and Drosophila SL-2 cells, Sp1 acted as a transcriptional activator of the LTRs, while Sp3 acted as a repressor of Sp1-mediated transcriptional activation. Cotransfection studies also revealed that the tissue-specific Sp1-related protein BTEB bound to this GC/GT box and stimulated transcription from the LTR promoters in NTera2-D1 cells. These results show that members of the Sp1 protein family are crucial determinants for transcriptional activation of HERV-H LTR promoters and suggest that these proteins may also be involved in determining the tissue-specific expression pattern of HERV-H elements.

The symmetry of the yeast U6 RNA gene's TATA box and the orientation of the TATA-binding protein in yeast TFIIIB

The central RNA polymerase III (Pol III) transcription factor TFIIIB is composed of the TATA-binding protein (TBP), Brf, a protein related to TFIIB, and the product of the newly cloned TFC5 gene. TFIIIB assembles autonomously on the upstream promoter of the yeast U6 snRNA (SNR6) gene in vitro, through the interaction of its TBP subunit with a consensus TATA box located at base pair -30. As both the DNA-binding domain of TBP and the U6 TATA box are nearly twofold symmetrical, we have examined how the binding polarity of TFIIIB is determined. We find that TFIIIB can bind to the U6 promoter in both directions, that TBP is unable to discern the natural polarity of the TATA element and that, as a consequence, the U6 TATA box is functionally symmetrical. A modest preference for TFIIIB binding in the natural direction of the U6 promoter is instead dictated by flanking DNA. Because the assembly of TFIIIB on the yeast U6 gene in vivo occurs via a TFIIIC-dependent mechanism, we investigated the influence of TFIIIC on the binding polarity of TFIIIB. TFIIIC places TFIIIB on the promoter in one direction only; thus, it is TFIIIC that primarily specifies the direction of transcription. Experiments using TFIIIB reconstituted with the altered DNA specificity mutant TBPm3 demonstrate that in the TFIIIB-U6 promoter complex, the carboxy-terminal repeat of TBP contacts the upstream half of the TATA box. This orientation of yeast TBP in Pol III promoter-bound TFIIIB is the same as in Pol II promoter-bound TFIID and in TBP-DNA complexes that have been analyzed by X-ray crystallography.

Mutations on the DNA-binding surface of TATA-binding protein can specifically impair the response to acidic activators in vivo

The TATA-binding protein (TBP) contains a concave surface that interacts specifically with TATA promoter elements and a convex surface that mediates protein-protein interactions with general and gene-specific transcription factors. Biochemical experiments suggest that interactions between activator proteins and TBP are important in stimulating transcription by the RNA polymerase II machinery. To gain insight into the role of TBP in mediating transcriptional activation in vivo, we implemented a genetic strategy in Saccharomyces cerevisiae that involved the use of a TBP derivative with altered specificity for TATA elements. By genetically screening a set of TBP mutant libraries that were biased to the convex surface that mediates protein-protein interactions, we identified TBP derivatives that are impaired in the response to three acidic activators (Gcn4, Gal4, and Ace1) but appear normal for constitutive polymerase II transcription. A genetic complementation assay indicates that the activation-defective phenotypes reflect specific functional properties of the TBP derivatives rather than an indirect effect on transcription. Surprisingly, three of the four activation-defective mutants affect residues that directly contact DNA. Moreover, all four mutants are defective for TATA element binding, but they interact normally with an acidic activation domain and TFIIB. In addition, we show that a subset of TBP derivatives with mutations on the DNA-binding surface of TBP are also compromised in their responses to acidic activators in vivo. These observations suggest that interactions at the TBP-TATA element interface can specifically affect the response to acidic activator proteins in vivo.

Thermodynamic and kinetic characterization of the binding of the TATA binding protein to the adenovirus E4 promoter

A thermodynamic analysis of the binding of the TATA binding protein (TBP) from Saccharomyces cerevisiae to the adenovirus E4 promoter was conducted using quantitative DNase I "footprint" titration techniques. These studies were conducted to provide a foundation for studies of TBP structure-function relations and its assembly into transcription preinitiation complexes. The binding of TBP to the E4 promoter is well described by the Langmuir binding polynomial, suggesting that no linked equilibria contribute to the binding reaction under the conditions examined. Van't Hoff analysis yielded a nonlinear dependence on temperature with the TBP-E4 promoter interaction displaying maximal affinity at 30 degrees C. An unusually negative value of the apparent standard heat capacity change, delta Cp degrees = -3.5 +/- 0.5 kcal/mol.K, was determined from these data. The dependence of the TBP-E4 promoter interaction on [KCl] indicates that 3.6 +/- 0.3 K+ ions are displaced upon complex formation. Within experimental error, no linkage of proton binding with the TBP-E4 promoter interaction is detectable between pH 5.9 and 8.7. Rates of association of TBP for the E4 promoter were obtained using a novel implementation of a quench-flow device and DNase I "footprinting" techniques. The value determined for the second-order rate constant at pH 7.4, 100 mM KCl, 5 mM MgCl2, 1 mM CaCl2, 30 degrees C (ka = 5.2 +/- 0.5) x 10(5) M-1 s-1) confirms the results obtained by Hawley and co-workers [Hoopes, B.C., LeBlanc, J.F., & Hawley, D.K. (1992) J. Biol. Chem. 267, 11539-11547] and extends them through TBP concentrations of 636 nM.(ABSTRACT TRUNCATED AT 250 WORDS)

Higher-order nucleoprotein complexes in transcription: analogies with site-specific recombination

Regulation of transcription involves the assembly of multiprotein complexes at enhancers and promoters. Interactions between adjacent and non-adjacent DNA-binding proteins can augment the specificity and stability of multi-component nucleoprotein complexes. Recently, several proteins have been identified that can function as 'architectural' elements in the assembly of higher-order nucleoprotein structures reminiscent of those involved in site-specific recombination in prokaryotes.