Specific association of the CRP-cyclic AMP complex with the control region of the lactose operon of Escherichia coli K 12: a direct fluorimetric study using DNA fragments of different lengths

Specific-site binding of the cAMP . CRP complex to the control region of the lactose operon of E. coli was measured directly. All of the protein molecules did bind specifically, and the binding constant for the major CRP site was not dependent on the length (62, 219 or 301 base pairs) of the DNA fragments used. Comparing the values of the binding constant measured for the major site and for the weaker "operator" CRP site, and referring to the published "consensus sequence" derived from the known CRP sites in a series of operons, we suggest that two sub-sites support additive contribution to the total binding free energy.     

Complement Factor H Binds at Two Independent Sites to C-reactive Protein in Acute Phase Concentrations

Factor H (FH) regulates the activation of C3b in the alternative complement pathway, both in serum and at host cell surfaces. It is composed of 20 short complement regulator (SCR) domains. The Y402H polymorphism in FH is a risk factor for age-related macular degeneration. C-reactive protein (CRP) is an acute phase protein that binds Ca²⁺. We established the FH-CRP interaction using improved analytical ultracentrifugation (AUC), surface plasmon resonance (SPR), and synchrotron x-ray scattering methods. Physiological FH and CRP concentrations were used in 137 mm NaCl and 2 mm Ca²⁺, in which the occurrence of denatured CRP was avoided. In solution, AUC revealed FH-CRP binding. The FH-CRP interaction inhibited the formation of higher FH oligomers, indicating that CRP blocked FH dimerization sites at both SCR-6/8 and SCR-16/20. SPR confirmed the FH-CRP interaction and its NaCl concentration dependence upon using either immobilized FH or CRP. The SCR-1/5 fragment of FH did not bind to CRP. In order of increasing affinity, SCR-16/20, SCR-6/8 (His-402), and SCR-6/8 (Tyr-402) fragments bound to CRP. X-ray scattering showed that FH became more compact when binding to CRP, which is consistent with CRP binding at two different FH sites. We concluded that FH and CRP bind at elevated acute phase concentrations of CRP in physiological buffer. The SCR-16/20 site is novel and indicates the importance of the FH-CRP interaction for both age-related macular degeneration and atypical hemolytic uremic syndrome.     

Binding of the Escherichia coli cyclic AMP receptor protein to DNA fragments containing consensus nucleotide sequences.

Binding of the Escherichia coli CRP protein to DNA fragments carrying nucleotide sequences closely corresponding to the consensus is very tight with a dissociation time of over 2 h in our conditions. The concentration of cyclic AMP required for this binding is below the physiological range of intracellular cyclic AMP concentrations. Changes in nucleotide sequence at positions that are not well-conserved between different naturally-occurring CRP sites allow a more rapid dissociation of CRP-DNA complexes. There is an inverse correlation between the stability of CRP binding to sites in vitro and the repression by glucose of expression dependent on these sites in vivo: expression that is dependent on the tighter binding sites cannot be repressed by the inclusion of glucose in the growth medium.     

SEAM: a Stochastic EM-type Algorithm for Motif-finding in biopolymer sequences

Position weight matrix-based statistical modeling for the identification and characterization of motif sites in a set of unaligned biopolymer sequences is presented. This paper describes and implements a new algorithm, the Stochastic EM-type Algorithm for Motif-finding (SEAM), and redesigns and implements the EM-based motif-finding algorithm called deterministic EM (DEM) for comparison with SEAM, its stochastic counterpart. The gold standard example, cyclic adenosine monophosphate receptor protein (CRP) binding sequences, together with other biological sequences, is used to illustrate the performance of the new algorithm and compare it with other popular motif-finding programs. The convergence of the new algorithm is shown by simulation. The in silico experiments using simulated and biological examples illustrate the power and robustness of the new algorithm SEAM in de novo motif discovery.     

Selection of DNA binding sites by regulatory proteins. II. The binding specificity of cyclic AMP receptor protein to recognition sites

The statistics of base-pair usage within known recognition sites for a particular DNA-binding protein can be used to estimate the relative protein binding affinities to these sites, as well as to sites containing any other combinations of base-pairs. As has been described elsewhere, the connection between base-pair statistics and binding free energy is made by an equal probability selection assumption; i.e. that all base-pair sequences that provide appropriate binding strength are equally likely to have been chosen as recognition sites in the course of evolution. This is analogous to a statistical-mechanical system where all configurations with the same energy are equally likely to occur. In this communication, we apply the statistical-mechanical selection theory to analyze the base-pair statistics of the known recognition sequences for the cyclic AMP receptor protein (CRP). The theoretical predictions are found to be in reasonable agreement with binding data for those sequences for which experimental binding information is available, thus lending support to the basic assumptions of the selection theory. On the basis of this agreement, we can predict the affinity for CRP binding to any base-pair sequence, albeit with a large statistical uncertainty. When the known recognition sites for CRP are ranked according to predicted binding affinities, we find that the ranking is consistent with the hypothesis that the level of function of these sites parallels their fractional saturation with CRP-cAMP under in-vivo conditions. When applied to the entire genome, the theory predicts the existence of a large number of randomly occurring "pseudosites" with strong binding affinity for CRP. It appears that most CRP molecules are engaged in non-productive binding at non-specific or pseudospecific sites under in-vivo conditions. In this sense, the specificity of the CRP binding site is very low. Relative specificity requirements for polymerases, repressors and activators are compared in light of the results of this and the first paper in this series.     

Isolation and characterization of the amino and carboxyl proximal fragments of the adenosine cyclic 3' ,5'-phosphate receptor protein of Escherichia coli

The cyclic AMP receptor protein (CRP) is a positive and negative regulatory protein for gene expression in Escherichia coli. The protein has been cleaved proteolytically to determine the relation between CRP structure and function. In the presence of sodium dodecyl sulfate (NaDodSO4), chymotrypsin dissects CRP into two stable fragments of molecular weight 9500 (9.5K) and 13 000 (13K). After removal of NaDodSO4, the two fragments are resolved by Bio-Rex 70 chromatography in 6 M urea. Analyses of the terminal amino acids released from each fragment and cyanogen bromide cleavage products indicate that the 9.5K fragment is amino proximal in CRP while the 13K fragment is carboxyl proximal. Notable features of amino acid composition are the relatively high amount of arginine and methionine in the 13K fragment and the retention in the 9.5K fragment of the two tryptophans present in the CRP subunit. Following isoelectric focusing in 8 M urea, the 9.5K fragment, 22.5K CRP, and 13K fragment migrate to pH 5.5, 8.3, and 10.3, respectively. While CRP is a cAMP-stimulated DNA binding protein, the 13K fragment binds to DNA in the presence and absence of cAMP. The 9.5K fragment associates to form dimers and decamers. These data are consonant with a model in which the DNA binding domain is present in the carboxyl proximal region of CRP while the amino proximal region contains the subunit-subunit interaction sites and much of the cAMP binding domain.     

Specific binding of cyclic-AMP receptor protein to DNA. Effect of the sequence and of the introduction of a nick in the binding site.

The binding of Escherichia coli Cyclic AMP Receptor Protein (CRP) to several DNA fragments of about 45 base pairs, bearing the natural lactose or galactose sites, as well as several synthetic related sites, was investigated using fluorescence spectroscopy and gel retardation experiments. The salt dependence of the equilibrium binding constant indicates that CRP makes an identical number of ion pairs with the lac, lacL8 and gal sites although the binding constants are drastically different. However increasing the symmetry of the gal site leads to an increase of the number of ion pairs between the protein and the DNA. A single strand nick was introduced at the centre of a symmetrized gal site and this reduces the binding energy of CRP by about 0.6 Kcal. These results are discussed with respect to the bending constraints imposed on the DNA by the binding of CRP. The results are in agreement with the recently published crystal structure of the CRP complexed with DNA [Schutz, S.C., Shields, G.C. and Steitz, T.A., Science 253, 1001-1007 (1991)] showing that the 90 degrees bending of the DNA in the complex results from two kinks.     

Kinetic and structural studies of the allosteric conformational changes induced by binding of cAMP to the cAMP receptor protein from Escherichia coli

The cAMP receptor protein, allosterically activated by cAMP, regulates the expression of more than 100 genes in Escherichia coli. CRP is a homodimer of two-domain subunits. It has been suggested that binding of cAMP to CRP leads to a long-distance signal transduction from the N-terminal cAMP binding domain to the C-terminal domain of the protein responsible for interaction with specific sequences of DNA. In this study, the stopped-flow and time-resolved fluorescence lifetime measurements were used to observe the kinetics of the distance changes between the N-terminal and C-terminal domain of CRP induced by binding of cAMP to high-affinity binding sites. In these measurements, we used the constructed CRP heterodimer, which possesses a single Trp85 residue localized at the N-terminal domain of one CRP subunit, and fluorescently labeled by 1,5-I-AEDANS Cys178 localized at the C-terminal domain of the same subunit or at the opposite one. The F?rster resonance energy transfer method has been used to study the distance changes, induced by binding of cAMP, between Trp85 (fluorescence donor) and Cys178-AEDANS (fluorescence acceptor) in the CRP structure. The obtained results show that the allosteric transitions of CRP at micromolar cAMP concentrations follow the sequential binding model, in which binding of cAMP to high-affinity sites causes a 4 A movement of the C-terminal domain toward N-terminal domains of the protein, with kinetics faster than 2 ms, and CRP adopts the "closed" conformation. This fast process is followed by the slower reorientation of both CRP subunits.     

Automatic identification and representation of protein binding sites for molecular docking.

Molecular docking is a popular way to screen for novel drug compounds. The method involves aligning small molecules to a protein structure and estimating their binding affinity. To do this rapidly for tens of thousands of molecules requires an effective representation of the binding region of the target protein. This paper presents an algorithm for representing a protein's binding site in a way that is specifically suited to molecular docking applications. Initially the protein's surface is coated with a collection of molecular fragments that could potentially interact with the protein. Each fragment, or probe, serves as a potential alignment point for atoms in a ligand, and is scored to represent that probe's affinity for the protein. Probes are then clustered by accumulating their affinities, where high affinity clusters are identified as being the "stickiest" portions of the protein surface. The stickiest cluster is used as a computational binding "pocket" for docking. This method of site identification was tested on a number of ligand-protein complexes; in each case the pocket constructed by the algorithm coincided with the known ligand binding site. Successful docking experiments demonstrated the effectiveness of the probe representation.     

Identification of reactive cysteines in a protein using arsenic labeling and collision-induced dissociation tandem mass spectrometry

Trivalent arsenicals have high affinity for thiols (such as free cysteines) in proteins. We describe here the use of this property to develop a collision-induced dissociation (CID) tandem mass spectrometry (MS/MS) technique for the identification of reactive cysteines in proteins. A trivalent arsenic species, dimethylarsinous acid (DMA (III)), with a residue mass (103.9607) and mass defect distinct from the normal 20 amino acids, was used to selectively label reactive cysteine residues in proteins. The CID fragment ions of the arsenic-labeled sequences shifted away from the more abundant normal fragments that would otherwise overlap with the ions of interest. Along with the internal and immonium ions, the arsenic-labeled fragment ions served as MS/MS signatures for identification of the binding sites and for assessment of the relative reactivity of individual cysteine residues in a protein. Using this method, we have identified two highly reactive binding sites in rat hemoglobin (Hb): Cys-13alpha and Cys-125beta. Cys-13alpha was bound to DMA (III) in the Hb of rats fed with arsenic, and this binding was responsible for arsenic accumulation in rat blood, while Cys-125beta was found to bind to glutathione in rat blood. This study revealed the relative reactivity of the cysteines in rat Hb in the following decreasing order: Cys-13alpha > Cys-111alpha > Cys-104alpha and Cys-13alpha > Cys-125beta > Cys-93beta. Arsenic-labeling is easy and fast for identification of active binding sites without enzymatic digestion and acid hydrolysis, and useful for characterization and identification of metal binding sites in other proteins.     

Turn of promotor DNA by cAMP receptor protein characterized by bead model simulation of rotational diffusion

The rotation diffusion of DNA double helices and their complexes with the cAMP receptor protein (CRP) has been simulated by bead models, in order to derive information on their structure in solution by comparison with results obtained from dichroism decay measurements. Straight DNA double helices are simulated by linear, rigid strings of overlapping beads. The radius of the beads and the length of the string are increased simultaneously by the same increments from initial outer dimensions derived from crystallographic data to final values, which are fitted to experimental rotation time constants observed for short DNA fragments (less than 100 bp). The final values reflect the solvated structure with the same 'solvation layer' added in all three dimensions. The protein is simulated by overlapping beads, which are assembled to a structure very similar to that found by x-ray crystallography. Complexes of the protein with DNA are formed with the centres of palindromic DNA sites at the centre of the two helix-turn-helix-motifs of the protein with some overlap of the two components. Simulation of the experimental data obtained for CRP complexes with specific DNA in the presence of cAMP requires strong bending of the double helices. According to our simulation the DNA is almost completely wrapped around the protein both in the complexes with a 62 bp fragment containing the standard CRP site and with a 80 bp fragment containing the second binding site of the lac operon. Simulations of the data obtained for a 203 bp fragment with both binding sites suggest that the two bound CRP proteins are in contact with each other and that the DNA is wrapped around the two protein dimers. A stereochemical model is suggested with a tetrahedral arrangement of the four protein subunits, which provides the advantage that two binding sites of the protein formed by two subunits each are located favorable for tight contacts to two binding sites on bent DNA, provided that the DNA sites are separated by an integer number of helix turns. In summary, the simulations demonstrate strong bending, which can be reflected by an arc radius in the range around 50 A. According to these data the overall bending angle of our longest DNA fragment is approximately 180 degrees, and thus the protruding ends are sufficiently close to each other such that RNA polymerase, for example, could contact both helical segments.     

Turn of Promotor DNA by cAMP Receptor Protein Characterized by Bead Model Simulation of Rotational Diffusion

Abstract

The rotation diffusion of DNA double helices and their complexes with the cAMP receptor protein (CRP) has been simulated by bead models, in order to derive information on their structure in solution by comparison with results obtained from dichroism decay measurements. Straight DNA double helices are simulated by linear, rigid strings of overlapping beads. The radius of the beads and the length of the string are increased simultaneously by the same increments from initial outer dimensions derived from crystallographic data to final values, which are fitted to experimental rotation time constants observed for short DNA fragments (< 100 bp). The final values reflect the solvated structure with the same ‘solvation layer’ added in all three dimensions. The protein is simulated by overlapping beads, which are assembled to a structure very similar to that found by x-ray crystallography. Complexes of the protein with DNA are formed with the centres of palindromic DNA sites at the centre of the two helix- turn-helix-motifs of the protein with some overlap of the two components. Simulation of the experimental data obtained for CRP complexes with specific DNA in the presence of cAMP requires strong bending of the double helices. According to our simulation the DNA is almost completely wrapped around the protein both in the complexes with a 62 bp fragment containing the standard CRP site and with a 80 bp fragment containing the second binding site of the lac operon. Simulations of the data obtained for a 203 bp fragment with both binding sites suggest that the two bound CRP proteins are in contact with each other and that the DNA is wrapped around the two protein dimers. A stereochemical model is suggested with a tetrahedral arrangement of the four protein subunits, which provides the advantage that two binding sites of the protein formed by two subunits each are located favorable for tight contacts to two binding sites on bent DNA provided that the DNA sites are separated by an integer number of helix turns. In summary, the simulations demonstrate strong bending, which can be reflected by an arc radius in the range around 50 Å. According to these data the overall bending angle of our longest DNA fragment is approximately 180°, and thus the protruding ends are sufficiently close to each other such that RNA polymerase, for example, could contact both helical segments.     

The change of DNA structure by specific binding of the cAMP receptor protein from rotation diffusion and dichroism measurements.

The structure of complexes formed between cAMP receptor protein (CRP) and various restriction fragments from the promoter region of the lactose operon has been analysed by measurements of electrodichroism. Binding of CRP to a 62-bp fragment containing the major site leads to an increase of the rotation time constant from 0.33 to 0.43 microseconds; addition of cAMP to the complex induces a decrease to 0.25 microseconds. Similar data are obtained for a 80-bp fragment containing the operator site; however, in this case the decrease of the rotation time for the specific complex is only observed when the salt concentration is increased from 3 to 13 mM. A 203-bp fragment containing both sites showed a corresponding change after pre-incubation at 50 mM salt. The salt dependence of the rotation time for the specific complex formed with the 203-bp fragment also indicates that a compact structure is formed at 13 mM salt, whereas the structure is not as compact at 3 mM salt. A 98-bp fragment without specific CRP sites did not reveal changes corresponding to those observed for the specific fragments. The rotation time constants together with the dichroism amplitudes indicate that binding of CRP to specific sites in the presence of cAMP leads to the formation of compact structures, which are consistent with bending of DNA helices. The observed strong salt dependence of the structure is apparently due to electrostatic repulsion between adjoining helix segments.     

Definition of a C-reactive protein binding determinant on histones

C-reactive protein (CRP) is an acute phase inflammatory protein in man which binds to phosphocholine, chromatin, histones, and the 70-kDa protein of the U1 small nuclear ribonucleoprotein particle in a calcium-dependent, phosphocholine-inhibitable manner. CRP also binds to other proteins including fibronectin. The determinants involved in CRP binding to these diverse proteins have not been identified. The binding of CRP to histones was examined as these proteins are available in large quantity at high purity and subject to protease digestion with well characterized products. Histone H1 was digested with thrombin and trypsin to produce three distinct fragments, N-terminal, central globular, and C-terminal. CRP was shown only to bind to the C-terminal fragment. Binding to histone H2A was also examined. CRP binding was not diminished by cleavage of the C-terminal fragment but was greatly decreased when the central globular region of H2A was tested. Peptides were prepared to be identical to the N- and C-terminal fragments of H2A. The N-terminal (15 amino acid) fragment of H2A blocked CRP-induced precipitation of phosphocholine-coupled bovine serum albumin and histone H2A, whereas the C-terminal fragment showed no inhibition. Thus we have defined the first reported CRP binding determinant on a protein.