Coli Catabolite Activator Protein Research Articles

Structural Basis of Dual Specificity of Sinorhizobium meliloti Clr, a cAMP and cGMP Receptor Protein.

In bacteria, the most prevalent receptor proteins of 3',5'-cyclic AMP (cAMP) and 3',5'-cyclic GMP (cGMP) are found among transcription factors of the Crp-Fnr superfamily. The prototypic Escherichia coli catabolite activator protein (CAP) represents the main Crp cluster of this superfamily and is known to bind cAMP and cGMP but to mediate transcription activation only in its cAMP-bound state. In contrast, both cyclic nucleotides mediate transcription activation by Sinorhizobium meliloti Clr, mapping to cluster G of Crp-like proteins. We present crystal structures of Clr-cAMP and Clr-cGMP bound to the core motif of the palindromic Clr DNA binding site (CBS). We show that both cyclic nucleotides shift ternary Clr-cNMP-CBS-DNA complexes (where cNMP is cyclic nucleotide monophosphate) to almost identical active conformations, unlike the situation known for the E. coli CAP-cNMP complex. Isothermal titration calorimetry measured similar affinities of cAMP and cGMP binding to Clr in the presence of CBS core motif DNA (equilibrium dissociation constant for cNMP (KDcNMP], ~7 to 11 μM). However, different affinities were determined in the absence of this DNA (KDcGMP, ~24 μM; KDcAMP, ~6 μM). Sequencing of Clr-coimmunoprecipitated DNA as well as electrophoretic mobility shift and promoter-probe assays expanded the list of experimentally proven Clr-regulated promoters and CBS. This comprehensive set of CBS features conserved nucleobases that are consistent with the sequence readout through interactions of Clr amino acid residues with these nucleobases, as revealed by the Clr-cNMP-CBS-DNA crystal structures. IMPORTANCE Cyclic 3',5'-AMP (cAMP) and cyclic 3',5'-GMP (cGMP) are both long known as important nucleotide secondary messengers in eukaryotes. This is also the case for cAMP in prokaryotes, whereas a signaling role for cGMP in this domain of life has been recognized only recently. Catabolite repressor proteins (CRPs) are the most ubiquitous bacterial cAMP receptor proteins. Escherichia coli CAP, the prototypic transcription regulator of the main Crp cluster, binds both cyclic mononucleotides, but only the CAP-cAMP complex promotes transcription activation. In contrast, Crp cluster G proteins studied so far are activated by cGMP or by both cAMP and cGMP. Here, we report a structural analysis of the cAMP- and cGMP-activatable cluster G member Clr from Sinorhizobium meliloti, how binding of cAMP and cGMP shifts Clr to its active conformation, and the structural basis of its DNA binding site specificity.

Three-dimensional EM structure of an intact activator-dependent transcription initiation complex

We present the experimentally determined 3D structure of an intact activator-dependent transcription initiation complex comprising the Escherichia coli catabolite activator protein (CAP), RNA polymerase holoenzyme (RNAP), and a DNA fragment containing positions -78 to +20 of a Class I CAP-dependent promoter with a CAP site at position -61.5 and a premelted transcription bubble. A 20-A electron microscopy reconstruction was obtained by iterative projection-based matching of single particles visualized in carbon-sandwich negative stain and was fitted using atomic coordinate sets for CAP, RNAP, and DNA. The structure defines the organization of a Class I CAP-RNAP-promoter complex and supports previously proposed interactions of CAP with RNAP alpha subunit C-terminal domain (alphaCTD), interactions of alphaCTD with sigma(70) region 4, interactions of CAP and RNAP with promoter DNA, and phased-DNA-bend-dependent partial wrapping of DNA around the complex. The structure also reveals the positions and shapes of species-specific domains within the RNAP beta', beta, and sigma(70) subunits.

Protein–DNA photo-crosslinking with a genetically encoded benzophenone-containing amino acid

The photo-crosslinking amino acid, p-benzoyl- l-phenylalanine ( pBpa), was genetically incorporated into Escherichia coli catabolite activator protein (CAP) in bacteria in response to an amber nonsense codon using an orthogonal tRNA/aminoacyl-tRNA synthetase pair. The mutant CAP (CAP-K26Bpa) containing pBpa formed a covalent complex with a DNA fragment containing the consensus operator sequence upon UV irradiation. Because this amino acid can be genetically incorporated into any DNA-binding protein in E. coli, yeast or mammalian cells with minimal perturbation of protein structure, this method should be generally useful for investigating DNA–protein interactions.

Biosynthesis of a Site-Specific DNA Cleaving Protein

An E. coli catabolite activator protein (CAP) has been converted into a sequence-specific DNA cleaving protein by genetically introducing (2,2'-bipyridin-5-yl)alanine (Bpy-Ala) into the protein. The mutant CAP (CAP-K26Bpy-Ala) showed comparable binding affinity to CAP-WT for the consensus operator sequence. In the presence of Cu(II) and 3-mercaptopropionic acid, CAP-K26Bpy-Ala cleaves double-stranded DNA with high sequence specificity. This method should provide a useful tool for mapping the molecular details of protein-nucleic acid interactions.

Structural basis of transcription activation: the CAP-alpha CTD-DNA complex.

The Escherichia coli catabolite activator protein (CAP) activates transcription at P(lac), P(gal), and other promoters through interactions with the RNA polymerase alpha subunit carboxyl-terminal domain (alphaCTD). We determined the crystal structure of the CAP-alphaCTD-DNA complex at a resolution of 3.1 angstroms. CAP makes direct protein-protein interactions with alphaCTD, and alphaCTD makes direct protein-DNA interactions with the DNA segment adjacent to the DNA site for CAP. There are no large-scale conformational changes in CAP and alphaCTD, and the interface between CAP and alphaCTD is small. These findings are consistent with the proposal that activation involves a simple "recruitment" mechanism.

Charge neutralization and DNA bending by the Escherichia coli catabolite activator protein.

We are interested in the role of asymmetric phosphate neutralization in DNA bending induced by proteins. We describe an experimental estimate of the actual electrostatic contribution of asymmetric phosphate neutralization to the bending of DNA by the Escherichia coli catabolite activator protein (CAP), a prototypical DNA-bending protein. Following assignment of putative electrostatic interactions between CAP and DNA phosphates based on X-ray crystal structures, appropriate phosphates in the CAP half-site DNA were chemically neutralized by methylphosphonate substitution. DNA shape was then evaluated using a semi-synthetic DNA electrophoretic phasing assay. Our results confirm that the unmodified CAP DNA half-site sequence is intrinsically curved by 26 degrees in the direction enhanced in the complex with protein. In the absence of protein, neutralization of five appropriate phosphates increases DNA curvature to 32 degrees (approximately 23% increase), in the predicted direction. Shifting the placement of the neutralized phosphates changes the DNA shape, suggesting that sequence-directed DNA curvature can be modified by the asymmetry of phosphate neutralization. We suggest that asymmetric phosphate neutralization contributes favorably to DNA bending by CAP, but cannot account for the full DNA deformation.

Catabolite activator protein-induced DNA bending in transcription initiation

We describe experiments that enable us to track the presence and direction of the DNA bend induced by Escherichia coli catabolite activator protein (CAP) through the intermediate stages of transcription initiation at the lac promoter. Transcriptional complexes examined were formed on superhelical templates to enhance specific complex formation, and detected by electrophoretic analysis after restriction digestion. We found that the bend is maintained and even increased upon formation of closed and open complexes. Our results exclude the hypothesis that the energy of the CAP-induced bend is used to promote open complex formation. We now suggest a new model, in which DNA wraps around the CAP-polymerase complex to form a writhing structure equivalent to that at the end of an interwound superhelical domain. Formation of this structure may facilitate open complex formation. We further propose that the stored bend energy may be used to help counteract strong protein-protein or protein-DNA interactions, thus assisting the process of RNA polymerase escape from the promoter.

Mutations that alter the charge of type I regulatory subunit and modify activation properties of cyclic AMP-dependent protein kinase from S49 mouse lymphoma cells

Mutations in regulatory (R) subunit of cAMP-dependent protein kinase were analyzed from cAMP-resistant mutants of S49 mouse lymphoma cells by direct sequencing of amplified regions of mutant R subunit cDNAs. Eight distinct single base-change lesions were identified in 24 independent mutants that were hemizygous for expression of mutant R subunits with altered protein charge. CG----TA transitions predominated, but AT----GC transitions and GC----TA transversions were also observed. Four of five spontaneous mutants had identical C----T transitions at CG causing substitution of Trp for Arg-334. Sites mutated in isolates obtained after mutagenesis with ethyl methanesulfonate or N-methyl-N'-nitro-N-nitrosoguanidine were more varied. Six of the lesions (two in binding site A and four in site B) were at amino acid residues that are highly conserved among cAMP-binding sites of R subunits and the Escherichia coli catabolite activator protein. These mutations all either prevented or strongly hindered binding of cyclic nucleotides to the mutated site. One of the remaining lesions (at Arg-242) also prevented cyclic nucleotide binding to the mutated binding site; the other (at Gly-170) had only minimal effects on binding of cyclic nucleotides but, nevertheless, increased the apparent constant for cAMP-dependent kinase activation. These results are discussed with reference to a model for the cAMP-binding sites of R subunit based on the crystal structure of the E. coli catabolite activator protein.

Modulation of the stability of a gene-regulatory protein dimer by DNA and cAMP.

We describe an experimental approach to the measurement of protein subunit exchange in which biotinylated subunits mediate attachment of 35S-labeled subunits to a streptavidin column as a result of the exchange process. Application of the method to Escherichia coli catabolite activator protein (CAP) revealed that in the absence of cAMP, the dimerization equilibrium constant is 3 x 10(10) M-1, with a dimer lifetime of 300 min. Exchange of CAP subunits is accelerated at least 1000-fold by the presence of nonspecific DNA, under low ionic strength conditions. Catalysis of exchange also occurs at physiological ionic conditions. In contrast, physiological concentrations of cAMP stabilize CAP with respect to subunit exchange in either the presence or the absence of DNA. We discuss the functional implications of monomerization of gene-regulatory proteins resulting from kinetic and thermodynamic lability of their dimers.

Studies of DNA‐protein interactions by gel electrophoresis

The use of gel electrophoresis in studies of nucleic acid-protein (especially DNA-protein) interactions has yielded much qualitative and quantitative information about a variety of such systems. The reduction in mobility of complexes relative to free DNA allows isolation and characterization of the complexes as well as determination of thermodynamic and kinetic properties of the interactions. This article begins with a review of recent applications of the "gel retardation" assay, by way of introduction to experiments in two areas. In the first, a hypothesis is tested regarding whether a DNA molecule with sizable proteins bound very near to each end migrates through a polyacrylamide gel differently than does the corresponding complex having the proteins in the middle of the DNA fragment. The data show little mobility differences for these types of complexes, implying that both may move in a linear, "snakelike", manner through the gel. The experiments also provide results pertaining to questions of DNA bending caused by the binding of the E. coli catabolite activator protein (CAP) and RNA polymerase to the lactose promoter region. It appears that DNA bending by CAP at its wild type lac binding site is retained in complexes where RNA polymerase is bound simultaneously at the lac UV5 promoter.