Communications between the high-affinity cyclic nucleotide binding sites in E. coli cyclic AMP receptor protein: effect of single site mutations

The binding of adenosine 3',5'-cyclic monophosphate (cAMP) and its nonfunctional analogue, guanosine 3',5'-cyclic monophosphate (cGMP), to the adenosine 3',5'-cyclic monophosphate receptor protein (CRP) from Escherichia coli was investigated by means of fluorescence and isothermal titration calorimetry (ITC) at pH 7.8 and 25 degrees C. A biphasic fluorescence titration curve was observed, confirming the previous observation reported by this laboratory (Heyduk and Lee (1989) Biochemistry 28, 6914-6924). However, the triphasic titration curve obtained from the ITC study suggests that the cAMP binding to CRP is more complicated than the previous conclusion that CRP binds sequentially two molecules of cAMP with negative cooperativity. The binding data can best be represented by a model for two identical interactive high-affinity sites and one low-affinity binding site. Unlike cAMP, the binding of cGMP to CRP exhibits no cooperativity between the high-affinity sites. The effects of mutations on the bindings of cAMP and cGMP to CRP were also investigated. The eight CRP mutants studied were K52N, D53H, S62F, T127L, G141Q, L148R, H159L, and K52N/H159L. These sites are located neither in the ligand binding site nor at the subunit interface. The binding was monitored by fluorescence. Although these mutations are at a variety of locations in CRP, the basic mechanism of CRP binding to cyclic nucleotides has not been affected. Two cyclic nucleotide molecules bind to the high-affinity sites of CRP. The cooperativity of cAMP binding is affected by mutation. It ranges from negative to positive cooperativity. The binding of cGMP shows none. With the exception of the T127L mutant, the free energy change for DNA-CRP complex formation increases linearly with increasing free energy change associated with the cooperativity of cAMP binding. This linear relationship implies that the protein molecule modulates the signal in the binding of cAMP, even though the mutation is not directly involved in cAMP or DNA binding. In addition, the significant differences in the amplitude of fluorescent signal indicate that the mutations also affect the surface characteristics of CRP. These results imply that these mutations are not perturbing specific pathways of signal transmission. Instead, these results are more consistent with the concept that CRP exists as an ensemble of native states, the distribution of which can be altered by these mutations.     

Mutagenesis of the cyclic AMP receptor protein of Escherichia coli: targeting positions 72 and 82 of the cyclic nucleotide binding pocket.

The 3', 5' cyclic adenosine monophosphate (cAMP) binding pocket of the cAMP receptor protein (CRP) of Escherichia coli was mutagenized to substitute leucine, glutamine, or aspartate for glutamate 72; and lysine, histidine, leucine, isoleucine, or glutamine for arginine 82. Substitutions were made in wild-type CRP and in a CRP*, or cAMP-independent, form of the protein to assess the effects of the amino acid substitutions on CRP structure. Cells containing the binding pocket residue-substituted forms of CRP were characterized through beta-galactosidase activity and by measurement of cAMP binding activity. This study confirms a role for both glutamate 72 and arginine 82 in cAMP binding and activation of CRP. Glutamine or leucine substitution of glutamate 72 produced forms of CRP having low affinity for the cAMP and unresponsive to the nucleotide. Aspartate substituted for glutamate 72 produced a low affinity cAMP-responsive form of CRP. CRP has a stringent requirement for the positioning of the position 72 glutamate carboxyl group within the cyclic nucleotide binding pocket. Results of this study also indicate that there are differences in the binding requirements of cAMP and cGMP, a competitive inhibitor of cAMP binding to CRP.     

Interplay between site-specific mutations and cyclic nucleotides in modulating DNA recognition by Escherichia coli cyclic AMP receptor protein

Mutagenesis of various amino acids in Escherichia coli cyclic AMP receptor protein (CRP) has been shown to modulate protein compressibility and dynamics [Gekko et al. (2004) Biochemistry 43, 3844-3852]. Cooperativity of cAMP binding to CRP and the apparent DNA binding affinity are perturbed [Lin and Lee (2002) Biochemistry 41, 11857-11867]. The aim of this study is to explore the effects of mutation on the surface chemistry of CRP and to define the consequences of these changes in affecting specific DNA sequence recognition by CRP. Furthermore, the role of the interplay between mutation and specific identity of the bound cyclic nucleotide in this DNA recognition was explored. In the current study, effects of eight site-specific mutations (K52N, D53H, S62F, T127L, G141Q, L148R, H159L, and K52N/H159L) on DNA recognition of four sequences (Class I (site PI of lac), Class II (site PI of gal), and synthetic sequences that are hybrids of Classes I and II sites) modulated by three different cyclic nucleotides (cAMP, cCMP, and cGMP) were investigated. All mutations altered the surface chemistry of CRP as evidenced by the change in elution properties of these proteins from different matrixes. While T127L, S62F, K52N, and H159L exhibited unexpected behavior under combinations of specific experimental conditions, such as the identity of bound cyclic nucleotide and DNA sequence, in general, results showed that the affinities of CRP for DNA were sequence-dependent, increasing in the order of lacgal26 < gal26 < lac26 < gallac26 for all the mutants in the presence of 200 microM cAMP. The apparent association constants significantly increased in the order of no cyclic nucleotide approximately cGMP < cCMP < cAMP for all the examined DNA sequences. Linear correlation between the DeltaG for CRP-DNA complex formation and the cooperativity energy for cAMP binding was observed with gallac26, gal26, and lacgal26; however, the slope of this linear correlation is DNA sequence dependent. Structural information was presented to rationalize the interplay between CRP sequence and cyclic nucleotides in defining the recognition of DNA sequences.     

The role of loops 3 and 4 in the interdomains and intersubunits communication of E. coli cAMP receptor protein

Cyclic AMP serves as an intracellular messenger in cells and regulates a variety of biological functions by transmitting information through proteins. These proteins of different functions all consist of a cAMP-binding motif, and the structure of this motif is highly conserved with an exception of the loop 3 and 4. In current study, cAMP receptor protein was employed as a model system to investigate the function of the two loops. The results indicated that the loop 3 involves in the intersubunits communication of CRP, whereas the loop 4 involves in cAMP binding and interdomains communication.     

Mutations that prevent cyclic nucleotide binding to binding sites A or B of type I cyclic AMP-dependent protein kinase

Cyclic nucleotide binding and activation properties of cAMP-dependent protein kinases from five independent mutants of S49 mouse lymphoma cells were studied. These mutants were all hemizygous for expression of mutant regulatory (R) subunits of the type I kinase with lesions that altered the electrostatic charge of R subunit: lesions in three of the mutants mapped to cAMP-binding site A, and those in two of the mutants mapped to cAMP-binding site B. A nucleotide mismatch assay using 32P-labeled cRNA and ribonuclease A confirmed and refined localization of the mutations to single amino acid residues implicated in cAMP binding. R subunits from all mutants retained the ability to bind cAMP, but binding behaved as if it were entirely to nonmutated sites: 1) relative affinities of 11 adenine-modified derivatives of cAMP for mutant enzymes were identical to their relative affinities for the site of wild-type kinase that corresponded to the nonmutated site of the mutant; 2) the potencies of these analogs as activators of mutant kinases were strictly correlated with their binding affinities (for wild-type enzyme activation potencies were correlated with mean affinities of the analogs for cAMP-binding sites A and B); 3) combinations of analogs with strong preferences for opposite cAMP-binding sites in wild-type kinase showed no synergism in activating mutant kinases; 4) dissociation of cAMP from mutant kinases was monophasic; and 5) high salt accelerated dissociation of cAMP from kinases with site B lesions but retarded dissociation from those with site A lesions.     

Sites of allosteric shift in the structure of the cyclic AMP receptor protein

We have characterized crp mutations in E. coli that allow CRP to function without cAMP. crp* mutants carrying a deletion of the gene encoding adenylate cyclase (cya) show significant lac expression. Cyclic GMP, normally an ineffective activator of CRP+, can stimulate these mutant CRP*s to permit greater lac expression in vivo. Cyclic AMP binding to the amino-terminal domain of CRP+ induces an allosteric transition that changes the DNA-binding property of the carboxy domain. The CRP* phenotype is caused by substitution of amino acids with bulkier side chains in the D alpha-helix of the protein's carboxy domain, near the hinge connecting the two domains. These results are consistent with a model in which the mutant CRP*s assume, in part, a conformation normally evoked only by cAMP binding: one in which the relative orientation of the C, D, and F alpha-helices is altered. We define precisely the amino acids of these alpha-helices that interact to cause the allosteric shift.     

Analysis of the cyclic nucleotide binding domain of the HERG potassium channel and interactions with KCNE2

Mutations in the cyclic nucleotide binding domain (CNBD) of the human ether-a-go-go-related gene (HERG) K+ channel are associated with LQT2, a form of hereditary Long QT syndrome (LQTS). Elevation of cAMP can modulate HERG K+ channels both by direct binding and indirect regulation through protein kinase A. To assess the physiological significance of cAMP binding to HERG, we introduced mutations to disrupt the cyclic nucleotide binding domain. Eight mutants including two naturally occurring LQT2 mutants V822M and R823W were constructed. Relative cAMP binding capacity was reduced or absent in CNBD mutants. Mutant homotetramers carry little or no K+ current despite normal protein abundance and surface expression. Co-expression of mutant and wild-type HERG resulted in currents with altered voltage dependence but without dominant current suppression. The data from co-expression of V822M and wild-type HERG best fit a model where one normal subunit within a tetramer allows nearly normal current expression. The presence of KCNE2, an accessory protein that associates with HERG, however, conferred a partially dominant current suppression by CNBD mutants. Thus KCNE2 plays a pivotal role in determining the phenotypic severity of some forms of LQT2, which suggests that the CNBD of HERG may be involved in its interaction with KCNE2.     

AraC-DNA looping: orientation and distance-dependent loop breaking by the cyclic AMP receptor protein.

The arabinose operon promoter, pBAD, is negatively regulated in the absence of arabinose by AraC protein, which forms a DNA loop by binding to two sites separated by 210 base-pairs, araO2 and araI1. pBAD is also positively regulated by AraC-arabinose and the cyclic AMP receptor protein, CRP. We provide evidence that CRP breaks the araO2-araI1 repression loop in vitro. The ability of CRP to break the loop in vitro and to activate pBAD in vivo is dependent upon the orientation and distance of the CRP binding site relative to araI1. An insertion of one DNA helical turn, 11 base-pairs, between CRP and araI only partially inhibits CRP loop breaking and activation of pBAD, while an insertion of less than one DNA helical turn, 4 base-pairs, not only abolishes CRP activation and loop breaking, but actually causes CRP to stabilize the loop and increases the araO2-mediated repression of pBAD. Both integral and non-integral insertions of greater than one helical turn completely abolish CRP activation and loop breaking in vitro.     

Escherichia coli cyclic AMP receptor protein mutants provide evidence for ligand contacts important in activation.

The three-dimensional model of the Escherichia coli cyclic AMP (cAMP) receptor protein (CRP) shows that several amino acids are involved as chemical contacts for binding cAMP. We have constructed and characterized mutants at four of these positions, E72, R82, S83, and R123. The mutations were made in wild-type crp as well as a cAMP-independent crp, crp*. The activities of the mutant proteins were characterized in vivo for their ability to activate the lac operon. These results provide genetic evidence to support that E72 and R82 are essential and S83 and R123 are important in the activation of CRP by cAMP.     

An equilibrium study of the cooperative binding of adenosine cyclic 3',5'-monophosphate and guanosine cyclic 3',5'-monophosphate to the adenosine cyclic 3',5'-monophosphate receptor protein from Escherichia coli

The binding of adenosine cyclic 3',5'-monophosphate (cAMP) and guanosine cyclic 3',5'-monophosphate (cGMP) to the adenosine cyclic 3',5'-monophosphate receptor protein (CRP) from Escherichia coli was investigated by equilibrium dialysis at pH 8.0 and 20 degrees C at different ionic strengths (0.05--0.60 M). Both cAMP and cGMP bind to CRP with a negative cooperativity that is progressively changed to positive as the ionic strength is increased. The binding data were analyzed with an interactive model for two identical sites and site/site interactions with the interaction free energy--RT ln alpha, and the intrinsic binding constant K and cooperativity parameter alpha were computed. Double-label experiments showed that cGMP is strictly competitive with cAMP, and its binding parameters K and alpha are not very different from that for cAMP. Since two binding sites exist for each of the cyclic nucleotides in dimeric CRP and no change in the quaternary structure of the protein is observed on binding the ligands, it is proposed that the cooperativity originates in ligand/ligand interactions. When bound to double-stranded deoxyribonucleic acid (dsDNA), CRP binds cAMP more efficiently, and the cooperativity is positive even in conditions of low ionic strength where it is negative for the free protein. By contrast, cGMP binding properties remained unperturbed in dsDNA-bound CRP. Neither the intrinsic binding constant K nor the cooperativity parameter alpha was found to be very sensitive to changes of pH between 6.0 and 8.0 at 0.2 M ionic strength and 20 degrees C. For these conditions, the intrinsic free energy and entropy of binding of cAMP are delta H degree = -1.7 kcal . mol-1 and delta S degree = 15.6 eu, respectively.     

CAMP-dependent protein kinase: prototype for a family of enzymes

Protein kinases represent a diverse family of enzymes that play critical roles in regulation. The simplest and best-understood biochemically is the catalytic (C) subunit of cAMP-dependent protein kinase, which can serve as a framework for the entire family. The amino-terminal portion of the C subunit constitutes a nucleotide binding site based on affinity labeling, labeling of lysines, and a conserved triad of glycines. The region beyond this nucleotide fold also contains essential residues. Modification of Asp 184 with a hydrophobic carbodiimide leads to inactivation, and this residue may function as a general base in catalysis. Despite the diversity of the kinase family, all share a homologous catalytic core, and the residues essential for nucleotide binding or catalysis in the C subunit are invariant in every protein kinase. Affinity labeling and intersubunit cross-linking have localized a portion of the peptide binding site, and this region is variable in the kinase family. The crystal structure of the C subunit also is being solved. The C subunit is maintained in its inactive state by forming a holoenzyme complex with an inhibitory regulatory (R) subunit. This R subunit has a well-defined domain structure that includes two tandem cAMP binding domains at the carboxy-terminus, each of which is homologous to the catabolite gene activator protein in Escherichia coli. Affinity labeling with 8N3 cAMP has identified residues that are in close proximity to the cAMP binding sites and is consistent with models of the cAMP binding sites based on the coordinates of the CAP crystal structure. An expression vector was constructed for the RI subunit and several mutations have been introduced. These mutations address 1) the major site of photoaffinity labeling, 2) a conserved arginine in the cAMP binding site, and 3) the consequences of deleting the entire second cAMP binding domain.     

Coupling effects of distal loops on structural stability and enzymatic activity of Escherichia coli dihydrofolate reductase revealed by deletion mutants

Residues distal from the active site in dihydrofolate reductase (DHFR) have regulatory roles in catalytic reaction and also folding stability. The couplings of the distal residues to the ones in the active site have been analyzed using site-directed mutants. To expand our understanding of the structural and functional influences of distal residue mutation, we explored the structural stability and enzymatic activity of deletion mutants. Deletion has greater structural and dynamical impacts on the corresponding part than site-directed mutation does. Thus, deletion amplifies the effects caused by distal mutations, which should make the mutual couplings among the distant residues more apparent. We focused on residues 52, 67, 121, and 145 in the four distinct loops of DHFR. All the single-residue deletion mutants showed marked reduction in stability, except for Δ52 in an αC–βC loop. Double deletion mutants showed that the loop αC–βC has nonadditive couplings with the βF–βG and βG–βH loops regarding stability. Single deletion to the loops αC–βC or βC–βD resulted in considerable activity reduction, demonstrating that the loops couple to the residues near the active site. The four loops were shown to be functionally interdependent from the double deletion experiments.