To explore how distal mutations affect binding sites and how binding sites in proteins communicate, an ensemble-based model of the native state was used to define the energetic connectivities between the different structural elements of Escherichia coli dihydrofolate reductase. Analysis of this model protein has allowed us to identify two important aspects of intramolecular communication. First, within a protein, pair-wise couplings exist that define the magnitude and extent to which mutational effects propagate from the point of origin. These pair-wise couplings can be identified from a quantity we define as the residue-specific connectivity. Second, in addition to the pair-wise energetic coupling between residues, there exists functional connectivity, which identifies energetic coupling between entire functional elements (i.e., binding sites) and the rest of the protein. Analysis of the energetic couplings provides access to the thermodynamic domain structure in dihydrofolate reductase as well as the susceptibility of the different regions of the protein to both small-scale (e.g., point mutations) and large-scale perturbations (e.g., binding ligand). The results point toward a view of allosterism and signal transduction wherein perturbations do not necessarily propagate through structure via a series of conformational distortions that extend from one active site to another. Instead, the observed behavior is a manifestation of the distribution of states in the ensemble and how the distribution is affected by the perturbation. M ost cellular processes, which are facilitated by proteins, are modulated by effectors. The basic features of such a mechanism of regulation are the presence of multiple binding sites for various ligands and communication between these binding sites, which often are situated many angstroms apart. An understanding of the ground rules of this regulatory mechanism requires a quantitative definition of the functional linkages between these binding sites. In 1964, Wyman introduced the thermodynamic concept of linked functions to establish a quantitative formulation for describing the mutual influence of binding sites on each other (1). Linkage theory is based on thermodynamic principles, is applicable to all biological systems, and exhibits quantitative predictive power. Although Wyman's theory provides the mathematical relationships, it does not address the mechanism through which different binding sites communicate. Thus, besides functional linkage, there are underlying structural-thermodynamic linkages that define the mechanism of site-site communication.Despite a significant body of literature showing that information is transmitted through biological systems via a series of interand intramolecular communication events (refs. 2-5 and references therein), a quantitative predictive theory of structural linkage analogous to the Wyman Linkage Theory is not available. Recently, however, a theoretical approach was established to treat the native state of a protein as an ensemble of conformationa...
The activation domains of many transcription factors appear to exist naturally in an unfolded or only partially folded state. This seems to be the case for AF1/tau1, the major transactivation domain of the human glucocorticoid receptor. We show here that in buffers containing the natural osmolyte trimethylamine N-oxide (TMAO), recombinant AF1 folds into more a compact structure, as evidenced by altered fluorescence emission, circular dichroism spectra, and ultracentrifugal analysis. This conformational transition is cooperative, a characteristic of proteins folding to natural structures. The structure resulting from incubation in TMAO causes the peptide to resist proteolysis by trypsin, chymotrypsin, endoproteinase Arg-C and endoproteinase Gluc-C. Ultracentrifugation studies indicate that AF1/tau1 exists as a monomer in aqueous solution and that the presence of TMAO does not lead to oligomerization or aggregation. It has been suggested that recombinant AF1 binds both the ubiquitous coactivator CBP and the TATA boxbinding protein, TBP. Interactions with both of these are greatly enhanced in the presence of TMAO. Co-immunoadsorption experiments indicate that in TMAO each of these and the coactivator SRC-1 are found complexed with AF1. These data indicate that TMAO induces a conformation in AF1/tau1 that is important for its interaction with certain co-regulatory proteins.
Amino acid substitutions at distant sites in the Escherichia coli cyclic AMP receptor protein (CRP) have been shown to affect both the nature and magnitude of the energetics of cooperativity of cAMP binding, ranging from negative to positive. In addition, the binding to DNA is concomitantly affected. To correlate the effects of amino acid substitutions on the functional energetics and global structural properties in CRP, the partial specific volume (v(o)), the coefficient of adiabatic compressibility (beta(s)(o)), and the rate of amide proton exchange were determined for the wild-type and eight mutant CRPs (K52N, D53H, S62F, T127L, G141Q, L148R, H159L, and K52N/H159L) by using sound velocity, density measurements, and hydrogen-deuterium exchange as monitored by Fourier transform infrared spectroscopy at 25 degrees C. These mutations induced large changes in v(o) (0.747-0.756 mL/g) and beta(s)(o) (6.89-9.68 Mbar(-1)) compared to the corresponding values for wild-type CRP (v(o)= 0.750 mL/g and beta(s)(o)= 7.98 Mbar(-1)). These changes in global structural properties correlated with the rate of amide proton exchange. A linear correlation was established between beta(s)(o) and the energetics of cooperativity of binding of cAMP to the high-affinity sites, regardless of the nature of cooperativity, be it negative or positive. This linear correlation indicates that the nature and magnitude of cooperativity are a continuum. A similar linear correlation was established between compressibility and DNA binding affinity. In addition, linear correlations were also found among the dynamics of CRP and functional energetics. Double mutation (K52N/H159L) at positions 52 and 159, whose alpha-carbons are separated by 34.6 A, showed nonadditive effects on v(o) and beta(s)(o). These results demonstrate that a small alteration in the local structure due to amino acid substitution is dramatically magnified in the overall protein dynamics which plays an important role in modulating the allosteric behavior of CRP.
Studies of individual domains or subdomains of the proteins making up the nuclear receptor family have stressed their modular nature. Nevertheless, these receptors function as complete proteins. Studies of specific mutations suggest that in the holoreceptors, intramolecular domain-domain interactions are important for complete function, but there is little knowledge concerning these interactions. The important transcriptional transactivation function in the N-terminal part of the glucocorticoid receptor (GR) appears to have little inherent structure. To study its interactions with the DNA binding domain (DBD) of the GR, we have expressed the complete sequence from the N-terminal through the DBD of the human GR. Circular dichroism analyses of this highly purified, multidomain protein show that it has a considerable helical content. We hypothesized that binding of its DBD to the cognate glucocorticoid response element would confer additional structure upon the N-terminal domain. Circular dichroism and fluorescence emission studies suggest that additional helicity as well as tertiary structure occur in the two-domain protein upon DNA binding. In sum, our data suggest that interdomain interactions consequent to DNA binding imparts structure to the portion of the GR that contains a major transactivation domain.The major identified domains of the nuclear family of receptors are those for ligand binding, DNA binding (DBD), 1 and transactivation, with other functional areas mapped throughout the molecule (1-4). Although the ligand and DNA binding domains have modular structures and, in "domain swapping" experiments, a remarkable ability to carry out their function within the context of other proteins, intramolecular signaling is also important for the proper natural functions of these receptors. Recent experiments studying the effect of mutations on function emphasize the importance of this intramolecular signaling (5, 6). How and when information is exchanged between domains is largely unknown. This is due in part to the fact that no structures are yet available for multidomain proteins from the nuclear receptor family. One intriguing problem is the structural basis for the major transcriptional transactivation function (AF1, tau1) that mutagenesis experiments have defined in the human GR (7). By molecular genetics, AF1 is defined by amino acids 77-262. It appears to function by evoking physical interactions with the basal transcription mechanism, including Ada2 and TATA-binding protein (TBP), possibly through intermediary adapter protein (8, 9). But unlike the ligand binding domain and DBD, AF1 does not appear to function well out of its protein context. Studies of recombinant peptides from the GR containing AF1 have shown it to have little or no structure in simple buffer solutions (10). In the presence of the strong ␣-helix stabilizing agent trifluoroethanol, up to three ␣-helices could form at the C-terminal end of AF1, and functional mutagenesis has shown that the primary sequences at the C-terminal end of AF1 may...
West Nile virus NS4B is a small hydrophobic nonstructural protein approximately 27 kDa in size whose function is poorly understood. Amino acid substitutions were introduced into the NS4B protein primarily targeting two distinct regions; the N-terminal domain (residues 35 through 60) and the central hydrophobic domain (residues 95 through 120). Only the NS4B P38G substitution was associated with both temperature-sensitive and small-plaque phenotypes. Importantly, this mutation was found to attenuate neuroinvasiveness greater than 10,000,000-fold and lower viremia titers compared to the wild-type NY99 virus in a mouse model. Full genome sequencing of the NS4B P38G mutant virus revealed two unexpected mutations at NS4B T116I and NS3 N480H (P38G/T116I/N480H), however, neither mutation alone was temperature sensitive or attenuated in mice. Following incubation of P38G/T116I/N480H at 41 °C, five mutants encoding compensatory substitutions in the NS4B protein exhibited a reduction in the temperature-sensitive phenotype and reversion to a virulent phenotype in the mouse model.
Escherichia coli cyclic AMP receptor protein (CRP) is a global transcriptional regulator which controls the expression of many different genes. Although different cyclic nucleotides can bind to CRP with almost equal affinity, only in the presence of cAMP could wild-type CRP bind to specific DNA sequences. Molecular genetic studies have identified a class of mutants, CRP*, which either do not require exogenous cAMP for activation or can be activated by cGMP. Thus, these mutants might aid in identifying the structural elements that are involved in the modulation of CRP to correctly differentiate the messages embedded in cyclic nucleotides. In this in vitro study, five CRP* mutants, namely, D53H, S62F, G141Q, G141K, and L148R, were tested for their abilities to bind the lac promoter sequence and the effects of cyclic nucleotides in modulating DNA sequence recognition. For comparison, non-CRP* mutants K52N, T127L, H159L, and K52N/H159L were studied. cCMP and cGMP can replace cAMP as an allosteric effector in all of these CRP mutants except S62F and non-CRP* mutants. The D53H, G141Q, G141K, and L148R mutants exhibit significantly higher affinity for the lac promoter sequence than wild-type CRP while S62F and the non-CRP* mutants exhibit reduced affinity. To probe the pathway of communication, the energetics of subunit assembly in these mutants were monitored by sedimentation equilibrium, and the conformational states of these mutants were probed by proteolysis and accessibility of Cys178 to chemical modifications. Results from these studies imply that signals due to mutations are mostly transmitted through the subunit interface. Thus, residues in CRP outside of the cyclic nucleotide binding site modulate the ability of CRP to differentiate these three cyclic nucleotides through long-range communication. Furthermore, this study shows that CRP* mutations do not impart any unique properties to CRP except that the DNA binding constants are shifted to a regime of higher affinity.
The disease dengue (DEN) is caused by four genetically and serologically related viruses termed DENV-1, -2, -3, and -4. The DENV envelope (E) protein ectodomain can be divided into three structural domains designated ED1, ED2, and ED3. The ED3 contains the DENV type-specific and DENV complex-reactive (epitopes shared by DENV 1-4) antigenic sites. In this study the epitopes recognized by four DENV complex-reactive monoclonal antibodies (MAbs) with neutralizing activity were mapped on the DENV-3 ED3 using a combination of physical and biological techniques. Amino acid residues L306, K308, G381, I387, and W389 were critical for all four MAbs, with residues V305, E309, V310, K325, D382, A384, K386, and R391 being critical for various subsets of the MAbs. A previous study by our group (Gromowski, G.D., Barrett, N.D., Barrett, A.D., 2008. Characterization of dengue complex-specific neutralizing epitopes on the envelope protein domain III of dengue 2 virus. J. Virol 82, 8828-8837) characterized the same panel of MAbs with DENV-2. The location of the DENV complex-reactive antigenic site on the DENV-2 and DENV-3 ED3s is similar; however, the critical residues for binding are not identical. Overall, this indicates that the DENV complex-reactive antigenic site on ED3 may be similar in location, but the surprising result is that DENV 2 and 3 exhibit unique sets of residues defining the energetics of interaction to the same panel of MAbs. These results imply that the amino acid sequences of DENV define a unique interaction network among these residues in spite of the fact that all flavivirus ED3s to date assume the same structural fold.
Linkage of Multiequilibria in DNA Recognition by the D53H Escherichia coli cAMP Receptor Protein
The transcription factor cyclic AMP receptor protein, CRP, regulates the operons that encode proteins involved in translocation and metabolism of carbohydrates in Escherichia coli. The structure of the CRP-cAMP complex reveals the presence of two sets of cAMP binding sites. Solution biophysical studies show that there are two high-affinity and two low-affinity binding sites, to which the binding of cAMP is characterized by varying degrees of cooperativity. A stoichiometry of four implies that potentially CRP can exist in five conformers with different numbers of bound cAMP. These conformers may exhibit differential affinities for specific DNA sequences. In this study, the affinity between DNA and each conformer of D53H CRP was defined through a dissection of the thermodynamic linkage scheme that included all the conformers. Loading of the high- and low-affinity sites with cAMP leads to high and low affinity for DNA, respectively. The specific magnitude of the binding constants of these conformers is DNA sequence dependent. The various association constants defined by the present study provide a solution to address an enigma of the CRP system, namely, the 3 orders of magnitude difference between the cAMP binding constants determined by in vitro studies and the cAMP concentration regime to which the bacteria respond. Under physiological conditions, the apo-CRP-DNA complex is the dominant species. As a consequence of the 1000-fold stronger affinity of cAMP to the apo-CRP-DNA complex than that to CRP, the relevant reaction is the binding of cAMP to this DNA-protein complex. The binding constant is of the order of 10(7) M(-)(1), the same concentration regime as that of cellular concentration of cAMP. In addition, under physiological conditions the species that binds to the lac and gal operons is predicted to be CRP-(cAMP)(1). A comparison of parameters between the wild type and the mutant CRP shows that the mutation apparently shifts the various thermodynamically linked equilibria without a change in the basic mechanism that governs CRP activities. Thus, the conclusions derived from a study of the mutant are relevant to wild-type CRP. A dissection of the individual binding constants in this multiequilibria reaction scheme leads to a definition of the mechanism of action of this transcription factor.
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