Indirect readout of DNA sequence at the primary-kink site in the CAP-DNA complex: DNA binding specificity based on energetics of DNA kinking

The catabolite activator protein (CAP) makes no direct contact with the consensus base-pair T:A at position 6 of the DNA half-site 5'-A(1)A(2)A(3)T(4)G(5)T(6)G(7)A(8)T(9)C(10)T(11)-3' but, nevertheless, exhibits strong specificity for T:A at position 6. Binding of CAP results in formation of a sharp DNA kink, with a roll angle of approximately 40 degrees and a twist angle of approximately 20 degrees, between positions 6 and 7 of the DNA half-site. The consensus base-pair T:A at position 6 and the consensus base-pair G:C at position 7 form a T:A/G:C step, which is known to be associated with DNA flexibility. It has been proposed that specificity for T:A at position 6 is a consequence of formation of the DNA kink between positions 6 and 7, and of effects of the T:A(6)/G:C(7) step on the geometry of DNA kinking, or the energetics of DNA kinking. In this work, we determine crystallographic structures of CAP-DNA complexes having the consensus base-pair T:A at position 6 or the non-consensus base-pair C:G at position 6. We show that complexes containing T:A or C:G at position 6 exhibit similar overall DNA bend angles and local geometries of DNA kinking. We infer that indirect readout in this system does not involve differences in the geometry of DNA kinking but, rather, solely differences in the energetics of DNA kinking. We further infer that the main determinant of DNA conformation in this system is protein-DNA interaction, and not DNA sequence.

Indirect readout of DNA sequence at the primary-kink site in the CAP-DNA complex: alteration of DNA binding specificity through alteration of DNA kinking

The catabolite activator protein (CAP) sharply bends DNA in the CAP-DNA complex, introducing a DNA kink, with a roll angle of approximately 40 degrees and a twist angle of approximately 20 degrees, between positions 6 and 7 of the DNA half-site, 5'-A(1)A(2)A(3)T(4)G(5)T(6)G(7)A(8)T(9)C(10)T(11)-3' ("primary kink"). CAP recognizes the base-pair immediately 5' to the primary-kink site, T:A(6), through an "indirect-readout" mechanism involving sequence effects on the energetics of primary-kink formation. CAP recognizes the base-pair immediately 3' to the primary-kink site, G:C(7), through a "direct-readout" mechanism involving formation of a hydrogen bond between Glu181 of CAP and G:C(7). Here, we report that substitution of the carboxylate side-chain of Glu181 of CAP by the one-methylene-group-shorter carboxylate side-chain of Asp changes DNA binding specificity at position 6 of the DNA half site, changing specificity for T:A(6) to specificity for C:G(6), and we report a crystallographic analysis defining the structural basis of the change in specificity. The Glu181-->Asp substitution eliminates the primary kink and thus eliminates indirect-readout-based specificity for T:A(6). The Glu181-->Asp substitution does not eliminate hydrogen-bond formation with G:C(7), and thus does not eliminate direct-readout-based specificity for G:C(7).

Mean DNA bend angle and distribution of DNA bend angles in the CAP-DNA complex in solution

In order to define the mean DNA bend angle and distribution of DNA bend angles in the catabolite activator protein (CAP)-DNA complex in solution under standard transcription initiation conditions, we have performed nanosecond time-resolved fluorescence measurements quantifying energy transfer between a probe incorporated at a specific site in CAP, and a complementary probe incorporated at each of five specific sites in DNA. The results indicate that the mean DNA bend angle is 77(+/-3) degrees - consistent with the mean DNA bend angle observed in crystallographic structures (80(+/-12) degrees ). Lifetime-distribution analysis indicates that the distribution of DNA bend angles is relatively narrow, with <10 % of DNA bend angles exceeding 100 degrees. Millisecond time-resolved luminescence measurements using lanthanide-chelate probes provide independent evidence that the upper limit of the distribution of DNA bend angles is approximately 100 degrees. The methods used here will permit mutational analysis of CAP-induced DNA bending and the role of CAP-induced DNA bending in transcriptional activation.

Translocation of sigma(70) with RNA polymerase during transcription: fluorescence resonance energy transfer assay for movement relative to DNA

Using fluorescence resonance energy transfer, we show that, in the majority of transcription complexes, sigma(70) is not released from RNA polymerase upon transition from initiation to elongation, but, instead, remains associated with RNA polymerase and translocates with RNA polymerase. The results argue against the presumption that there are necessary subunit-composition differences, and corresponding necessary mechanistic differences, in initiation and elongation. The methods of this report should be generalizable to monitor movement of any molecule relative to any nucleic acid.

Bacterial RNA polymerase subunit omega and eukaryotic RNA polymerase subunit RPB6 are sequence, structural, and functional homologs and promote RNA polymerase assembly

Bacterial DNA-dependent RNA polymerase (RNAP) has subunit composition beta'betaalpha(I)alpha(II)omega. The role of omega has been unclear. We show that omega is homologous in sequence and structure to RPB6, an essential subunit shared in eukaryotic RNAP I, II, and III. In Escherichia coli, overproduction of omega suppresses the assembly defect caused by substitution of residue 1362 of the largest subunit of RNAP, beta'. In yeast, overproduction of RPB6 suppresses the assembly defect caused by the equivalent substitution in the largest subunit of RNAP II, RPB1. High-resolution structural analysis of the omega-beta' interface in bacterial RNAP, and comparison with the RPB6-RPB1 interface in yeast RNAP II, confirms the structural relationship and suggests a "latching" mechanism for the role of omega and RPB6 in promoting RNAP assembly.

RNA polymerase: structural similarities between bacterial RNA polymerase and eukaryotic RNA polymerase II

Bacterial RNA polymerase and eukaryotic RNA polymerase II exhibit striking structural similarities, including similarities in overall structure, relative positions of subunits, relative positions of functional determinants, and structures and folding topologies of subunits. These structural similarities are paralleled by similarities in mechanisms of interaction with DNA.

Structural organization of the RNA polymerase-promoter open complex

We have used systematic site-specific protein-DNA photocrosslinking to define interactions between bacterial RNA polymerase (RNAP) and promoter DNA in the catalytically competent RNAP-promoter open complex (RPo). We have mapped more than 100 distinct crosslinks between individual segments of RNAP subunits and individual phosphates of promoter DNA. The results provide a comprehensive description of protein-DNA interactions in RPo, permit construction of a detailed model for the structure of RPo, and permit analysis of effects of a transcriptional activator on the structure of RPo.

Mechanism of ATP-dependent promoter melting by transcription factor IIH

We show that transcription factor IIH ERCC3 subunit, the DNA helicase responsible for adenosine triphosphate (ATP)-dependent promoter melting during transcription initiation, does not interact with the promoter region that undergoes melting but instead interacts with DNA downstream of this region. We show further that promoter melting does not change protein-DNA interactions upstream of the region that undergoes melting but does change interactions within and downstream of this region. Our results rule out the proposal that IIH functions in promoter melting through a conventional DNA-helicase mechanism. We propose that IIH functions as a molecular wrench: rotating downstream DNA relative to fixed upstream protein-DNA interactions, thereby generating torque on, and melting, the intervening DNA.

Roles of the histone H2A-H2B dimers and the (H3-H4)(2) tetramer in nucleosome remodeling by the SWI-SNF complex

SWI-SNF is an ATP-dependent chromatin remodeling complex required for expression of a number of yeast genes. Previous studies have suggested that SWI-SNF action may remove or rearrange the histone H2A-H2B dimers or induce a novel alteration in the histone octamer. Here, we have directly tested these and other models by quantifying the remodeling activity of SWI-SNF on arrays of (H3-H4)(2) tetramers, on nucleosomal arrays reconstituted with disulfide-linked histone H3, and on arrays reconstituted with histone H3 derivatives site-specifically modified at residue 110 with the fluorescent probe acetylethylenediamine-(1,5)-naphthol sulfonate. We find that SWI-SNF can remodel (H3-H4)(2) tetramers, although tetramers are poor substrates for SWI-SNF remodeling compared with nucleosomal arrays. SWI-SNF can also remodel nucleosomal arrays that harbor disulfide-linked (H3-H4)(2) tetramers, indicating that SWI-SNF action does not involve an obligatory disruption of the tetramer. Finally, we find that although the fluorescence emission intensity of acetylethylenediamine-(1,5)-naphthol sulfonate-modified histone H3 is sensitive to octamer structure, SWI-SNF action does not alter fluorescence emission intensity. These data suggest that perturbation of the histone octamer is not a requirement or a consequence of ATP-dependent nucleosome remodeling by SWI-SNF.

Identification of the subunit of cAMP receptor protein (CRP) that functionally interacts with CytR in CRP-CytR-mediated transcriptional repression

At promoters of the Escherichia coli CytR regulon, the cAMP receptor protein (CRP) interacts with the repressor CytR to form transcriptionally inactive CRP-CytR-promoter or (CRP)(2)-CytR-promoter complexes. Here, using "oriented heterodimer" analysis, we show that only one subunit of the CRP dimer, the subunit proximal to CytR, functionally interacts with CytR in CRP-CytR-promoter and (CRP)(2)-CytR-promoter complexes. Our results provide information about the architecture of CRP-CytR-promoter and (CRP)(2)-CytR-promoter complexes and rule out the proposal that masking of activating region 2 of CRP is responsible for the transcriptional inactivity of the complexes.

Activation mutants in yeast RNA polymerase II subunit RPB3 provide evidence for a structurally conserved surface required for activation in eukaryotes and bacteria

We have identified a mutant in RPB3, the third-largest subunit of yeast RNA polymerase II, that is defective in activator-dependent transcription, but not defective in activator-independent, basal transcription. The mutant contains two amino-acid substitutions, C92R and A159G, that are both required for pronounced defects in activator-dependent transcription. Synthetic enhancement of phenotypes of C92R and A159G, and of several other pairs of substitutions, is consistent with a functional relationship between residues 92-95 and 159-161. Homology modeling of RPB3 on the basis of the crystallographic structure of alphaNTD indicates that residues 92-95 and 159-162 are likely to be adjacent within the structure of RPB3. In addition, homology modeling indicates that the location of residues 159-162 within RPB3 corresponds to the location of an activation target within alphaNTD (the target of activating region 2 of catabolite activator protein, an activation target involved in a protein-protein interaction that facilitates isomerization of the RNA polymerase promoter closed complex to the RNA polymerase promoter open complex). The apparent finding of a conserved surface required for activation in eukaryotes and bacteria raises the possibility of conserved mechanisms of activation in eukaryotes and bacteria.

Transcription activation by catabolite activator protein (CAP)

Transcription activation by Escherichia coli catabolite activator protein (CAP) at each of two classes of simple CAP-dependent promoters is understood in structural and mechanistic detail. At class I CAP-dependent promoters, CAP activates transcription from a DNA site located upstream of the DNA site for RNA polymerase holoenzyme (RNAP); at these promoters, transcription activation involves protein-protein interactions between CAP and the RNAP alpha subunit C-terminal domain that facilitate binding of RNAP to promoter DNA to form the RNAP-promoter closed complex. At class II CAP-dependent promoters, CAP activates transcription from a DNA site that overlaps the DNA site for RNAP; at these promoters, transcription activation involves both: (i) protein-protein interactions between CAP and RNAP alpha subunit C-terminal domain that facilitate binding of RNAP to promoter DNA to form the RNAP-promoter closed complex; and (ii) protein-protein interactions between CAP and RNAP alpha subunit N-terminal domain that facilitates isomerization of the RNAP-promoter closed complex to the RNAP-promoter open complex. Straightforward combination of the mechanisms for transcription activation at class I and class II CAP-dependent promoters permits synergistic transcription activation by multiple molecules of CAP, or by CAP and other activators. Interference with determinants of CAP or RNAP involved in transcription activation at class I and class II CAP-dependent promoters permits "anti-activation" by negative regulators. Basic features of transcription activation at class I and class II CAP-dependent promoters appear to be generalizable to other activators.

Bacterial promoter architecture: subsite structure of UP elements and interactions with the carboxy-terminal domain of the RNA polymerase alpha subunit

We demonstrate here that the previously described bacterial promoter upstream element (UP element) consists of two distinct subsites, each of which, by itself, can bind the RNA polymerase holoenzyme alpha subunit carboxy-terminal domain (RNAP alphaCTD) and stimulate transcription. Using binding-site-selection experiments, we identify the consensus sequence for each subsite. The selected proximal subsites (positions -46 to -38; consensus 5'-AAAAAARNR-3') stimulate transcription up to 170-fold, and the selected distal subsites (positions -57 to -47; consensus 5'-AWWWWWTTTTT-3') stimulate transcription up to 16-fold. RNAP has subunit composition alpha(2)betabeta'sigma and thus contains two copies of alphaCTD. Experiments with RNAP derivatives containing only one copy of alphaCTD indicate, in contrast to a previous report, that the two alphaCTDs function interchangeably with respect to UP element recognition. Furthermore, function of the consensus proximal subsite requires only one copy of alphaCTD, whereas function of the consensus distal subsite requires both copies of alphaCTD. We propose that each subsite constitutes a binding site for a copy of alphaCTD, and that binding of an alphaCTD to the proximal subsite region (through specific interactions with a consensus proximal subsite or through nonspecific interactions with a nonconsensus proximal subsite) is a prerequisite for binding of the other alphaCTD to the distal subsite.

Mechanisms of viral activators

Adenovirus large E1A, Epstein-Barr virus Zebra, and herpes simplex virus VP16 were studied as models of animal cell transcriptional activators. Large E1A can activate transcription from a TATA box, a result that leads us to suggest that it interacts with a general transcription factor. Initial studies showed that large E1A binds directly to the TBP subunit of TFIID. However, analysis of multiple E1A and TBP mutants failed to support the significance of this in vitro interaction for the mechanism of activation. Recent studies to be reported elsewhere indicate that conserved region 3 of large E1A, which is required for its activation function, binds to one subunit of a multisubunit protein that stimulates in vitro transcription in response to large E1A and other activators. A method was developed for the rapid purification of TFIID approximately 25,000-fold to near homogeneity from a cell line engineered to express an epitope-tagged form of TBP. Purified TFIID contains 11 major TAFs ranging in mass from approximately 250 to 20 kD. Zta and VP16, but not large E1A, greatly stimulate the rate and extent of assembly of a TFIID-TFIIA complex on promoter DNA (DA complex). For VP16, this is a function of the carboxy-terminal activation subdomain. An excellent correlation was found between the ability of VP16C mutants to stimulate DA complex assembly and their ability to activate transcription in vivo. Consequently, for a subset of activation domains, DA complex assembly activity is an important component of the overall mechanism of activation.

Orientation of OmpR monomers within an OmpR:DNA complex determined by DNA affinity cleaving

Escherichia coli OmpR is a transcription factor that regulates the differential expression of the porin genes ompF and ompC. Phosphorylated OmpR binds as a dimer to a 20-bp region of DNA consisting of two tandemly arranged 10-bp half-sites. Expression of the ompF gene is achieved by the hierarchical occupation of three adjacent 20-bp binding sites, designated F1, F2, and F3 and a distally located site, F4. Despite genetic, biochemical, and structural studies, specific details of the interaction between phosphorylated OmpR and the DNA remain unknown. We have linked the DNA cleaving moiety o-phenanthroline-copper to eight different sites within the DNA binding domain of OmpR in order to determine the orientation of the two OmpR monomers in the OmpR:F1 complex. Five of the resulting conjugates exhibited DNA cleaving activity, and four of these yielded patterns that could be used to construct a model of the OmpR:F1 complex. We propose that OmpR binds asymmetrically to the F1 site as a tandemly arranged dimer with each monomer having its recognition helix in the major groove. The N-terminal end of the recognition helix is promoter-proximal and flanked by "wings" W1 and W2 positioned proximally and distally, respectively, to the transcription start site of ompF. We further propose that the C-terminal end of the recognition helix makes the most extensive contacts with DNA and predict bases within the F1 site that are sufficiently close to be contacted by the recognition helix.

Mutational analysis of a transcriptional activation region of the VP16 protein of herpes simplex virus

The VP16 protein of herpes simplex virus is a potent transcriptional activator of the viral immediate early genes. The transcriptional activation region of VP16 can be divided into two functional subregions, here designated VP16N (comprising amino acids 413-456) and VP16C (amino acids 450-490). Assays of VP16C mutants resulting from both random and alanine-scanning mutagenesis indicated that the sidechains of three phenylalanines (at positions 473, 475 and 479) and one acidic residue (glutamate 476) are important for transcriptional activation. Aromatic and bulky hydrophobic amino acids were effective substitutes for each of the three Phe residues, whereas replacement with smaller or polar amino acids resulted in loss of transcriptional function. In contrast, many changes were tolerated for Glu476, including bulky hydrophobic and basic amino acids, indicating that the negative charge at this position contributes little to the function of this subregion. Similar relative activities for most of the mutants were observed in yeast and in mammalian cells, indicating that the structural requirements for this activation region are comparable in these two species. These results reinforce the hypothesis that bulky hydrophobic residues, not acidic residues, are most critical for the activity of this 'acidic' transcriptional activation region.

Transcription activation at Class II CRP-dependent promoters: identification of determinants in the C-terminal domain of the RNA polymerase alpha subunit

Many transcription factors, including the Escherichia coli cyclic AMP receptor protein (CRP), act by making direct contacts with RNA polymerase. At Class II CRP-dependent promoters, CRP activates transcription by making two such contacts: (i) an interaction with the RNA polymerase alpha subunit C-terminal domain (alphaCTD) that facilitates initial binding of RNA polymerase to promoter DNA; and (ii) an interaction with the RNA polymerase alpha subunit N-terminal domain that facilitates subsequent promoter opening. We have used random mutagenesis and alanine scanning to identify determinants within alphaCTD for transcription activation at a Class II CRP-dependent promoter. Our results indicate that Class II CRP-dependent transcription requires the side chains of residues 265, 271, 285-288 and 317. Residues 285-288 and 317 comprise a discrete 20x10 A surface on alphaCTD, and substitutions within this determinant reduce or eliminate cooperative interactions between alpha subunits and CRP, but do not affect DNA binding by alpha subunits. We propose that, in the ternary complex of RNA polymerase, CRP and a Class II CRP-dependent promoter, this determinant in alphaCTD interacts directly with CRP, and is distinct from and on the opposite face to the proposed determinant for alphaCTD-CRP interaction in Class I CRP-dependent transcription.

New core promoter element in RNA polymerase II-dependent transcription: sequence-specific DNA binding by transcription factor IIB

A sequence element located immediately upstream of the TATA element, and having the consensus sequence 5'-G/C-G/C-G/A-C-G-C-C-3', affects the ability of transcription factor IIB to enter transcription complexes and support transcription initiation. The sequence element is recognized directly by the transcription factor IIB. Recognition involves alpha-helices 4' and 5' of IIB, which comprise a helix-turn-helix DNA-binding motif. These observations establish that transcription initiation involves a fourth core promoter element, the IIB recognition element (BRE), in addition to the TATA element, the initiator element, and the downstream promoter element, and involves a second sequence-specific general transcription factor, IIB, in addition to transcription factor IID.

Trajectory of DNA in the RNA polymerase II transcription preinitiation complex

By using site-specific protein-DNA photocrosslinking, we define the positions of TATA-binding protein, transcription factor IIB, transcription factor IIF, and subunits of RNA polymerase II (RNAPII) relative to promoter DNA within the human transcription preinitiation complex. The results indicate that the interface between the largest and second-largest subunits of RNAPII forms an extended, approximately 240 A channel that interacts with promoter DNA both upstream and downstream of the transcription start. By using electron microscopy, we show that RNAPII compacts promoter DNA by the equivalent of approximately 50 bp. Together with the published structure of RNAPII, the results indicate that RNAPII wraps DNA around its surface and suggest a specific model for the trajectory of the wrapped DNA.

RNA polymerase beta' subunit: a target of DNA binding-independent activation

The bacteriophage N4 single-stranded DNA binding protein (N4SSB) activates transcription by the Escherichia coli final sigma70-RNA polymerase at N4 late promoters. Here it is shown that the single-stranded DNA binding activity of N4SSB is not required for transcriptional activation. N4SSB interacts with the carboxyl terminus of the RNA polymerase beta' subunit in a region that is highly conserved in the largest subunits of prokaryotic and eukaryotic RNA polymerases.

Transcription activation at class II CAP-dependent promoters

Transcription activation at Class II CAP-dependent promoters provides a paradigm for understanding how a single activator molecule can make multiple interactions with the transcription machinery, with each interaction being responsible for a specific mechanistic consequence. At Class II CAP-dependent promoters, the DNA target site for CAP is centred near position -42, overlapping and replacing the -35 determinant for binding of RNA polymerase (RNAP). Transcription activation requires two distinct mechanistic components. The first component is 'anti-inhibition,' overcoming an inhibitory effect of the RNAP alpha subunit C-terminal domain (alpha CTD). This component involves direct contact between amino acids 156-164 (activating region 1) of the upstream subunit of the CAP dimer and a target in alpha CTD. The second component is 'direct activation', facilitating isomerization of the RNAP-promoter closed complex to the transcriptionally competent open complex. This component involves direct contact between amino acids 19, 21 and 101 (activating region 2) of the downstream subunit of the CAP dimer and a target in the RNAP alpha subunit N-terminal domain (alpha NTD).

Transcription activation at class II CAP-dependent promoters: two interactions between CAP and RNA polymerase

At Class II catabolite activator protein (CAP)-dependent promoters, CAP activates transcription from a DNA site overlapping the DNA site for RNA polymerase. We show that transcription activation at Class II CAP-dependent promoters requires not only the previously characterized interaction between an activating region of CAP and the RNA polymerase alpha subunit C-terminal domain, but also an interaction between a second, promoter-class-specific activating region of CAP and the RNA polymerase alpha subunit N-terminal domain. We further show that the two interactions affect different steps in transcription initiation. Transcription activation at Class II CAP-dependent promoters provides a paradigm for understanding how an activator can make multiple interactions with the transcription machinery, each interaction being responsible for a specific mechanistic consequence.

High-resolution mapping of nucleoprotein complexes by site-specific protein-DNA photocrosslinking: organization of the human TBP-TFIIA-TFIIB-DNA quaternary complex

We have used a novel site-specific protein-DNA photocrosslinking procedure to define the positions of polypeptide chains relative to promoter DNA in binary, ternary, and quaternary complexes containing human TATA-binding protein, human or yeast transcription factor IIA (TFIIA), human transcription factor IIB (TFIIB), and promoter DNA. The results indicate that TFIIA and TFIIB make more extensive interactions with promoter DNA than previously anticipated. TATA-binding protein, TFIIA, and TFIIB surround promoter DNA for two turns of DNA helix and thus may form a "cylindrical clamp" effectively topologically linked to promoter DNA. Our results have implications for the energetics, DNA-sequence-specificity, and pathway of assembly of eukaryotic transcription complexes.

Determinants of RNA polymerase alpha subunit for interaction with beta, beta', and sigma subunits: hydroxyl-radical protein footprinting

Escherichia coli RNA polymerase (RNAP) alpha subunit serves as the initiator for RNAP assembly, which proceeds according to the pathway 2 alpha-->alpha 2-->alpha 2 beta-->alpha 2 beta beta'-->alpha 2 beta beta' sigma. In this work, we have used hydroxyl-radical protein footprinting to define determinants of alpha for interaction with beta, beta', and sigma. Our results indicate that amino acids 30-75 of alpha are protected from hydroxyl-radical-mediated proteolysis upon interaction with beta (i.e., in alpha 2 beta, alpha 2 beta beta', and alpha 2 beta beta' sigma), and amino acids 175-210 of alpha are protected from hydroxyl-radical-mediated proteolysis upon interaction with beta' (i.e., in alpha 2 beta beta' and alpha 2 beta beta' sigma). The protected regions are conserved in the alpha homologs of prokaryotic, eukaryotic, archaeal, and chloroplast RNAPs and contain sites of substitutions that affect RNAP assembly. We conclude that the protected regions define determinants of alpha for direct functional interaction with beta and beta'. The observed maximal magnitude of protection upon interaction with beta and the observed maximal magnitude of protection upon interaction with beta' both correspond to the expected value for complete protection of one of the two alpha protomers of RNAP (i.e., 50% protection). We propose that only one of the two alpha protomers of RNAP interacts with beta and that only one of the two alpha protomers of RNAP interacts with beta'.

Structure of the CAP-DNA complex at 2.5 angstroms resolution: a complete picture of the protein-DNA interface

The crystallographic structure of the CAP-DNA complex at 3.0 A resolution has been reported previously. For technical reasons, the reported structure had been determined using a gapped DNA molecule lacking two phosphates important for CAP-DNA interaction. In this work, we report the crystallographic structure of the CAP-DNA complex at 2.5 A resolution using a DNA molecule having all phosphates important for CAP-DNA interaction. The present resolution permits unambiguous identification of amino acid-base and amino acid-phosphate hydrogen bonded contacts in the CAP-DNA complex. In addition, the present resolution permits accurate definition of the kinked DNA conformation in the CAP-DNA complex.

S-[2-(4-azidosalicylamido)ethylthio]-2-thiopyridine: radioiodinatable, cleavable, photoactivatible cross-linking agent

S-[2-(4-Azidosalicylamido)ethylthio]-2-thiopyridine (AET) contains a 2-thiopyridyl moiety, which permits cysteine-specific incorporation into protein through a cleavable disulfide bond, and a 4-azidosalicylamido moiety, which permits radioiodination and photoactivatible cross-linking. In contrast to the related compound S-[2-[N-[4-(4-azidosalicylamido)butyl]carbomoyl]ethylthio]-2 -thiopyridine [APDP; Zecherle, G., Oleinikov, A., and Traut, R. (1992) Biochemistry 31, 9526], AET contains a relatively short linker arm between the 2-thiopyridyl moiety and the 4-azidosalicylamido moiety. In a previous paper, it was shown that AET could be used in site-specific protein-protein photocross-linking to identify nearest-neighbor protein domains within a multiprotein complex [Chen, Y., Ebright, Y., and Ebright, R. (1994) Science 265, 90]. In this paper, the synthesis, radioiodination, and incorporation into protein of AET are described.

Structure of the LexA repressor-DNA complex probed by affinity cleavage and affinity photo-cross-linking

The structure of the complex of full-length Escherichia coli LexA repressor with a consensus operator DNA fragment has been probed by affinity photo-cross-linking and affinity cleavage. These methods allow the determination of approximate intermolecular distances between a given protein residue and a base or sugar moiety within the operator. In a first step unique cysteine residues were introduced in positions 7, 28, 38, or 52 of the protein. In all four cases, the original amino acid was an arginine. The four amino acids in these positions were expected to be situated on the surface of LexA interacting with DNA, as inferred from the structure of the LexA DNA binding domain [Fogh et al. (1994) EMBO J. 13, 3936-3944]. In a second step, these unique cysteine side chains of the purified proteins were chemically modified either with 4-azidophenacyl bromide or with S-(2-pyridylthio)cysteaminyl-EDTA. The first set of derivatives gives rise to UV-induced cross-linking which may be revealed by alkali/heat treatment; the second leads to direct DNA cleavage in the proximity of the derivatized amino acid. To reduce hydroxyl radical diffusion, the EDTA-iron cleavage reactions were done in the presence of high amounts of glycerol. The results indicate that amino acids 7 and 52 are near nucleotide pairs 8-12 of the operator and that amino acids 28 and 36 of LexA are near nucleotide pairs 5-8 of the operator. The results unambiguously define the orientation of the LexA DNA binding domain relative to the operator and provide support for the model of the LexA-operator complex proposed by Knegtel et al. [(1995) Proteins 21, 226-236]. Ethylation interference experiments further suggest that Arg-7 contacts the phosphate group between nucleotides 8 and 9 as predicted by the model.

Protein-protein interactions in eukaryotic transcription initiation: structure of the preinitiation complex

We have used alanine scanning to analyze protein-protein interactions by human TATA-element binding protein (TBP) within the transcription preinitiation complex. The results indicate that TBP interacts with RNA polymerase II and general transcription factors IIA, IIB, and IIF within the functional transcription preinitiation complex and define the determinants of TBP for each of these interactions. The results permit construction of a model for the structure of the preinitiation complex.

DNA-binding determinants of the alpha subunit of RNA polymerase: novel DNA-binding domain architecture

The Escherichia coli RNA polymerase alpha-subunit binds through its carboxy-terminal domain (alpha CTD) to a recognition element, the upstream (UP) element, in certain promoters. We used genetic and biochemical techniques to identify the residues in alpha CTD important for UP-element-dependent transcription and DNA binding. These residues occur in two regions of alpha CTD, close to but distinct from, residues important for interactions with certain transcription activators. We used NMR spectroscopy to determine the secondary structure of alpha CTD, alpha CTD contains a nonstandard helix followed by four alpha-helices. The two regions of alpha CTD important for DNA binding correspond to the first alpha-helix and the loop between the third and fourth alpha-helices. The alpha CTD DNA-binding domain architecture is unlike any DNA-binding architecture identified to date, and we propose that alpha CTD has a novel mode of interaction with DNA. Our results suggest models for alpha CTD-DNA and alpha CTD-DNA-activator interactions during transcription initiation.

Rapid RNA polymerase genetics: one-day, no-column preparation of reconstituted recombinant Escherichia coli RNA polymerase

We present a simple, rapid procedure for reconstitution of Escherichia coli RNA polymerase holoenzyme (RNAP) from individual recombinant alpha, beta, beta', and sigma 70 subunits. Hexahistidine-tagged recombinant alpha subunit purified by batch-mode metal-ion-affinity chromatography is incubated with crude recombinant beta, beta', and sigma 70 subunits from inclusion bodies, and the resulting reconstituted recombinant RNAP is purified by batch-mode metal-ion-affinity chromatography. RNAP prepared by this procedure is indistinguishable from RNAP prepared by conventional methods with respect to subunit stoichiometry, alpha-DNA interaction, catabolite gene activator protein (CAP)-independent transcription, and CAP-dependent transcription. Experiments with alpha (1-235), an alpha subunit C-terminal deletion mutant, establish that the procedure is suitable for biochemical screening of subunit lethal mutants.

The Escherichia coli RNA polymerase alpha subunit: structure and function

Recent work has established that the Escherichia coli RNA polymerase alpha subunit consists of an amino-terminal domain containing determinants for interaction with the remainder of RNA polymerase, a carboxy-terminal domain containing determinants for interaction with DNA and interaction with transcriptional activator proteins, and a 13-36 amino acid unstructured and/or flexible linker. These findings suggest a simple, integrated model for the mechanism of involvement of alpha in promoter recognition and transcriptional activation.

Transcription activation at the Escherichia coli uhpT promoter by the catabolite gene activator protein

Transport and utilization of sugar phosphates in Escherichia coli depend on the transport protein encoded by the uhpT gene. Transmembrane induction of uhpT expression by external glucose 6-phosphate is positively regulated by the promoter-specific activator protein UhpA and the global regulator catabolite gene activator protein (CAP). Activation by UhpA requires a promoter element centered at -64 bp, relative to the start of transcription, and activation by CAP requires a DNA site centered at position -103.5. This DNA site binds the cyclic AMP-CAP complex in vitro, and its deletion from the promoter reduces transcription activity to 7 to 9% of the wild-type level. Ten uhpT promoter derivatives with altered spacing between the DNA site for CAP and the remainder of the promoter were constructed. Their transcription activities indicated that the action of CAP at this promoter is dependent on proper helical phasing of promoter elements, with CAP binding on the same face of the helix as RNA polymerase does. Five CAP mutants defective in transcription activation at class I and class II CAP-dependent promoters but not defective in DNA binding or DNA bending (positive control mutants) were tested for the ability to activate transcription. These CAPpc mutants exhibited little or no defect in transcription activation at uhpT, indicating that CAP action at uhpTp involves a different mechanism than that which is used for its action at other classes of CAP-dependent promoters.

Location, structure, and function of the target of a transcriptional activator protein

We have isolated and characterized single-amino-acid substitution mutants of RNA polymerase alpha subunit defective in CAP-dependent transcription at the lac promoter but not defective in CAP-independent transcription. Our results establish that (1) amino acids 258-265 of alpha constitute an "activation target" essential for CAP-dependent transcription at the lac promoter but not essential for CAP-independent transcription, (2) amino acid 261 is the most critical amino acid of the activation target, (3) amino acid 261 is distinct from the determinants for alpha-DNA interaction, and (4) the activation target may fold as a surface amphipathic alpha-helix. We propose a model for transcriptional activation at the lac promoter that integrates these and other recent results regarding transcriptional activation and RNA polymerase structure and function.

Characterization of the activating region of Escherichia coli catabolite gene activator protein (CAP). I. Saturation and alanine-scanning mutagenesis

It has been proposed that the surface loop consisting of amino acid residues 152 to 166 of the catabolite gene activator protein (CAP) of Escherichia coli makes direct protein-protein contact with RNA polymerase at the lac promoter. In this work, we have used targeted saturation mutagenesis of codons 152 to 166 of the gene encoding CAP, followed by a screen, to isolate more than 200 independent mutants of CAP defective in transcription activation but not defective in DNA binding. All isolated single-substitution mutants map to just eight amino acid residues; 156, 157, 158, 159, 160, 162, 163 and 164. We propose that these residues define the full extent of the epitope on CAP for the proposed CAP-RNA polymerase interaction. In addition, we have constructed alanine substitutions at each position from residue 152 to 166 of CAP, and we have analyzed the effects on transcription activation at the lac promoter and on DNA binding. Alanine substitution of Thr158 results in an approximately eightfold specific defect in transcription activation. In contrast, alanine substitution of no other residue tested results in a more than twofold specific defect in transcription activation. We conclude that, for Thr158, side-chain atoms beyond C beta are essential for transcription activation at the lac promoter, and we propose that Thr158 OH7 gamma makes direct contact with RNA polymerase in the ternary complex of lac promoter, CAP and RNA polymerase. We conclude further that for no residue other than Thr158 are side-chain atoms beyond C beta essential for transcription activation at the lac promoter.

Characterization of the activating region of Escherichia coli catabolite gene activator protein (CAP). II. Role at Class I and class II CAP-dependent promoters

CAP-dependent promoters can be divided into classes based on the position of the DNA site for CAP. In class I CAP-dependent promoters, the DNA site for CAP is located upstream of the DNA site for polymerase; the DNA site for CAP can be located at various distances from the transcription start point, provided that the DNS site for CAP and the DNA site for RNA polymerase are on the same face of the DNA helix. In class II CAP-dependent promoters, the DNA site for CAP overlaps the DNA site for RNA polymerase, replacing the -35 determinants for binding of RNA polymerase. In previous work, we have shown that a surface loop consisting of amino acid residues 152 to 166 of CAP is essential for transcription activation at the best-characterized class I CAP-dependent promoter, the lac promoter, and we proposed that this surface loop makes direct protein-protein contact with RNA polymerase in the ternary complex of lac promoter, CAP, and RNA polymerase. Here, we show that the surface loop consisting of amino acid residues 152 to 166 is essential for transcription activation at other class I CAP-dependent promoters and at a class II CAP-dependent promoter. We show further that the effects of alanine substitutions of residues 152 to 166 are qualitatively identical at the lac promoter and other class I CAP-dependent promoters, but are different at a class II CAP-dependent promoter. We propose that the surface loop consisting of residues 152 to 166 makes identical molecular interactions in transcription activation at all class I CAP-dependent promoters, irrespective of distance between the DNA site for CAP and the transcription start point, but makes a different set of molecular interactions in transcription activation at class II CAP-dependent promoters.

The functional subunit of a dimeric transcription activator protein depends on promoter architecture

In Class I CAP-dependent promoters, the DNA site for CAP is located upstream of the DNA site for RNA polymerase. In Class II CAP-dependent promoters, the DNA site for CAP overlaps the DNA site for RNA polymerase, replacing the -35 site. We have used an 'oriented heterodimers' approach to identify the functional subunit of CAP at two Class I promoters having different distances between the DNA sites for CAP and RNA polymerase [CC(-61.5) and CC(-72.5)] and at one Class II promoter [CC(-41.5)]. Our results indicate that transcription activation at Class I promoters, irrespective of the distance between the DNA sites for CAP and RNA polymerase, requires the activating region of the promoter-proximal subunit of CAP. In striking contrast, our results indicate that transcription activation at Class II promoters requires the activating region of the promoter-distal subunit of CAP.

Domain organization of RNA polymerase alpha subunit: C-terminal 85 amino acids constitute a domain capable of dimerization and DNA binding

Using limited proteolysis, we show that the Escherichia coli RNA polymerase alpha subunit consists of an N-terminal domain comprised of amino acids 8-241, a C-terminal domain comprised of amino acids 249-329, and an unstructured and/or flexible interdomain linker. We have carried out a detailed structural and functional analysis of an 85 amino acid proteolytic fragment corresponding to the C-terminal domain (alpha CTD-2). Our results establish that alpha CTD-2 has a defined secondary structure (approximately 40% alpha helix, approximately 0% beta sheet). Our results further establish that alpha CTD-2 is a dimer and that alpha CTD-2 exhibits sequence-specific DNA binding activity. Our results suggest a model for the mechanism of involvement of alpha in transcription activation by promoter upstream elements and upstream-binding activator proteins.

High-specificity DNA cleavage agent: design and application to kilobase and megabase DNA substrates

Strategies to cleave double-stranded DNA at specific DNA sites longer than those of restriction endonucleases (longer than 8 base pairs) have applications in chromosome mapping, chromosome cloning, and chromosome sequencing--provided that the strategies yield high DNA-cleavage efficiency and high DNA-cleavage specificity. In this report, the DNA-cleaving moiety copper:o-phenanthroline was attached to the sequence-specific DNA binding protein catabolite activator protein (CAP) at an amino acid that, because of a difference in DNA bending, is close to DNA in the specific CAP-DNA complex but is not close to DNA in the nonspecific CAP-DNA complex. The resulting CAP derivative, OP26CAP, cleaved kilobase and megabase DNA substrates at a 22-base pair consensus DNA site with high efficiency and exhibited no detectable nonspecific DNA-cleavage activity.

Identification of the target of a transcription activator protein by protein-protein photocrosslinking

Here it is shown, with the use of protein-protein photocrosslinking, that the carboxyl-terminal region of the alpha subunit of RNA polymerase (RNAP) is in direct physical proximity to the activating region of the catabolite gene activator protein (CAP) in the ternary complex of the lac promoter, RNAP, and CAP. These results strongly support the proposal that transcription activation by CAP involves protein-protein contact between the carboxyl-terminal region of the alpha subunit and the activating region of CAP.

DNA affinity cleaving analysis of homeodomain-DNA interaction: identification of homeodomain consensus sites in genomic DNA

We have incorporated the DNA-cleaving moiety o-phenanthroline-copper at amino acid 10 of the Msx-1 homeodomain, and we have analyzed site-specific DNA cleavage by the resulting Msx-1 derivative. We show that amino acid 10 of the Msx-1 homeodomain is close to the 5' end of the consensus DNA site 5'-(C/G)TAATTG-3' in the Msx-1-DNA complex. Our results indicate that the orientation of the Msx-1 homeodomain relative to DNA is analogous to the orientation of the engrailed and Antennapedia homeodomains. We show further that DNA affinity cleaving permits identification of consensus DNA sites for Msx-1 in kilobase DNA substrates. The specificity of the approach enabled us to identify an Msx-1 consensus DNA site within the transcriptional control region of the developmental regulatory gene Wnt-1. We propose that incorporation of o-phenanthroline-copper at amino acid 10 of a homeodomain may provide a generalizable strategy to determine the orientation of a homeodomain relative to DNA and to identify homeodomain consensus DNA sites in genomic DNA.