Structure of a complex of catabolite gene activator protein and cyclic AMP refined at 2.5 A resolution

The structure of a dimer of the Escherichia coli catabolite gene activator protein has been refined at 2.5 A resolution to a crystallographic R-factor of 20.7% starting with coordinates fitted to the map at 2.9 A resolution. The two subunits are in different conformations and each contains one bound molecule of the allosteric activator, cyclic AMP. The amino-terminal domain is linked to the smaller carboxy-terminal domain by a nine-residue hinge region that exists in different conformations in the two subunits, giving rise to approximately a 30 degree rotation between the positions of the small domains relative to the larger domains. The amino-terminal domain contains an antiparallel beta-roll structure in which the interstrand hydrogen bonding is well-determined. The beta-roll can be described as a long antiparallel beta-ribbon that folds into a right-handed supercoil and forms part of the cyclic AMP binding site. Each cyclic AMP molecule is in an anti conformation and has ionic and hydrogen bond interactions with both subunits.     

Structural and functional relationships between Pasteurella multocida and enterobacterial adenylate cyclases.

The Pasteurella multocida adenylate cyclase gene has been cloned and expressed in Escherichia coli. The primary structure of the protein (838 amino acids) deduced from the corresponding nucleotide sequence was compared with that of E. coli. The two enzymes have similar molecular sizes and, based on sequence conservation at the protein level, are likely to be organized in two functional domains: the amino-terminal catalytic domain and the carboxy-terminal regulatory domain. It was shown that P. multocida adenylate cyclase synthesizes increased levels of cyclic AMP in E. coli strains deficient in the catabolite gene activator protein compared with wild-type strains. This increase does not occur in strains deficient in both the catabolite gene activator protein and enzyme III-glucose, indicating that a protein similar to E. coli enzyme III-glucose is involved in the regulation of P. multocida adenylate cyclase. It also indicates that the underlying process leading to enterobacterial adenylate cyclase activation has been conserved through evolution.     

Predicted structures of cAMP binding domains of type I and II regulatory subunits of cAMP-dependent protein kinase

The mammalian cAMP-dependent protein kinases have regulatory (R) subunits that show substantial homology in amino acid sequence with the catabolite gene activator protein (CAP), a cAMP-dependent gene regulatory protein from Escherichia coli. Each R subunit has two in-tandem cAMP binding domains, and the structure of each of these domains has been modeled by analogy with the crystal structure of CAP. Both the type I and II regulatory subunits have been considered, so that four cAMP binding domains have been modeled. The binding of cAMP in general is analogous in all the structures and has been correlated with previous results based on photolabeling and binding of cAMP analogues. The model predicts that the first cAMP binding domain correlates with the previously defined fast dissociation site, which preferentially binds N6-substituted analogues of cAMP. The second domain corresponds to the slow dissociation site, which has a preference for C8-substituted analogues. The model also is consistent with cAMP binding in the syn conformation in both sites. Finally, this model has targeted specific regions that are likely to be involved in interdomain contacts. This includes contacts between the two cAMP binding domains as well as contacts with the amino-terminal region of the R subunit and with the catalytic subunit.     

Molecular model of the cyclic GMP-binding domain of the cyclic GMP-gated ion channel.

The structure of the cyclic GMP-binding domain of the cyclic GMP-gated ion channel from bovine retinal rod photoreceptors has been modeled by analogy to the crystal structure of the homologous cyclic AMP-binding domain of catabolite gene activator protein (CAP). The modeled cyclic GMP-binding domain has a three-residue deletion and a five-residue insertion between beta strands compared to CAP. The major interactions of the ion channel with cyclic GMP are similar to those observed for cyclic AMP bound to CAP and predicted for cGMP bound to the cGMP-dependent protein kinase: Gly 543 and Glu 544 make hydrogen-bond interactions with the ribose 2'-OH, Arg 559 forms an ion pair with the charged phosphate oxygen, and Thr 560 forms hydrogen-bond interactions with an exocyclic phosphate oxygen and with the 2-amino group of cGMP. Three additional potential interactions were predicted from the model structure. Ile 545 O and Ser 546 OH form hydrogen-bond interactions with an exocyclic phosphate oxygen, and Phe 533 may interact with the aromatic ring of cGMP. This model is in agreement with both the analogue binding experiments and the mutational analysis of Thr 560.     

Interaction between mutant alleles of araC of the Escherichia coli B/r L-arabinose operon.

Strains were constructed that contain mutational alterations affecting two distinct functional domains within the araC gene protein. The araCi (catabolite repression insensitivity) and araCh (catabolite repression hypersensitivity) mutations were used to alter the catabolite repression sensitivity domain, and mutation to D-fucose resistance was used to alter the inducer binding domain. araCh, D-fucose-resistant double mutants never exhibited constitutive ara operon expression, whereas all of the araCi, D-fucose-resistant double mutants did exhibit constitutivity. When L-arabinose was used as an inducer, most of the double mutants exhibited the sensitivity to catabolite repression associated with the araCi or araCh mutation. However, when D-fucose was used as an inducer, changes in sensitivity to catabolite repression were observed that were attributed to interactions between the two protein domains. The roles of catabolite activator protein and araC gene protein in the induction of the araBAD operon were discussed.     

Effects of cyclic nucleotides on the conformational states of the alpha core of the cyclic AMP receptor protein.

The alpha core gragment produced by limited proteolysis contains the cyclic AMP binding domain and the two buried sulfhydryl groups of the cyclic AMP receptor protein. The buried sulfhydryl groups of the alpha core react with 5,5'-dithio-bis(2-nitrobenzoic acid) after denaturation by 3 M urea or digestion with subtilisin. The rate of sulfhydryl modification in the presence of 3 M urea or subtilisin is markedly decreased in the presence of cyclic nucleotides which are proposed to tighten the conformation of the alpha core. Incubation of the alpha core in 3 M urea or dithionitrobenzoic acid does not affect cyclic AMP binding while dithionitrobenzoic acid plus 3 M urea inhibits cyclic AMP binding suggesting a role for the buried sulfhydryls in cyclic AMP binding or their proximity to the cyclic AMP binding domain of the alpha core. The data are consistent with a ligand-induced conformational change in the alpha region of the native cyclic AMP receptor protein that is required for DNA binding.     

The 1.6Å resolution structure of activated D138L mutant of catabolite gene activator protein with two cAMP bound in each monomer

The X-ray crystal structure of the cAMP-liganded D138L mutant of Escherichia coli catabolite gene activator protein (CAP) was determined at a resolution of 1.66?. This high resolution crystal structure reveals four cAMP binding sites in the homodimer. Two anti conformations of cAMPs (anti-cAMP) locate between the β-barrel and the C-helix of each subunit; two syn conformations of cAMPs (syn-cAMP) bind on the surface of the C-terminal domain. With two syn-cAMP molecules bound, the D138L CAP is highly symmetrical with both subunits assuming a "closed" conformation. These differences make the hinge region of the mutant more flexible. Protease susceptibility measurements indicate that D138L is more susceptible to proteases than that of wild type (WT) CAP. The results of protein dynamic experiments (H/D exchange measurements) indicate that the structure of D138L mutant is more dynamic than that of WT CAP, which may impact the recognition of specific DNA sequences.     

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.     

Predicted structures of the cGMP binding domains of the cGMP-dependent protein kinase: a key alanine/threonine difference in evolutionary divergence of cAMP and cGMP binding sites

Mammalian cGMP- and cAMP-dependent protein kinase show considerable similarity in amino acid sequence, although they specifically bind different cyclic nucleotides. Results of cGMP analogue binding experiments, combined with modeling of the cGMP binding sites by analogy to the structure of the homologous catabolite gene activator protein, suggest that a threonine residue forms a hydrogen bond with the 2-NH2 of cGMP. This threonine is invariant in all cGMP binding domains, but the corresponding residue in 23 out of 24 cAMP binding sites of protein kinases is alanine, which cannot form the same hydrogen bond. This alanine/threonine difference has the potential for discriminating between cAMP and cGMP and may be important in the evolutionary divergence of cyclic nucleotide binding sites.     

Catabolite repression in Escherichia coli mutants lacking cyclic AMP.

Summary The regulation of catabolite repression of -galactosidase has been studied in Escherichia coli mutants deleted for the adenyl cyclase gene (cya ), and thus unable to synthesize cyclic AMP. It has been found that, provided a second mutation occurs either in the crp gene coding for the catabolite gene activator protein (CAP) or in the Lactose region, these mutants exhibit catabolite repression. If the catabolite repression seen in the mutant strains corresponds to the mechanism operating in wild-type cells, the results would suggest that the intracellular concentration of cyclic AMP cannot be the unique regulator of catabolite repression.Jacques Monod was still with us when most of the work described in this and the following paper was accomplished. His constant interest, his unfailing advice, his warm support, were invaluable. It will be difficult for us to ever enjoy a successful experiment without regretting that he cannot share this pleasure with us.     

Molecular basis for regulatory subunit diversity in cAMP-dependent protein kinase: crystal structure of the type II beta regulatory subunit

BACKGROUND: Cyclic AMP binding domains possess common structural features yet are diversely coupled to different signaling modules. Each cAMP binding domain receives and transmits a cAMP signal; however, the signaling networks differ even within the same family of regulatory proteins as evidenced by the long-standing biochemical and physiological differences between type I and type II regulatory subunits of cAMP-dependent protein kinase. RESULTS: We report the first type II regulatory subunit crystal structure, which we determined to 2.45 A resolution and refined to an R factor of 0.176 with a free R factor of 0.198. This new structure of the type II beta regulatory subunit of cAMP-dependent protein kinase demonstrates that the relative orientations of the two tandem cAMP binding domains are very different in the type II beta as compared to the type I alpha regulatory subunit. Each structural unit for binding cAMP contains the highly conserved phosphate binding cassette that can be considered the "signature" motif of cAMP binding domains. This motif is coupled to nonconserved regions that link the cAMP signal to diverse structural and functional modules. CONCLUSIONS: Both the diversity and similarity of cAMP binding sites are demonstrated by this new type II regulatory subunit structure. The structure represents an intramolecular paradigm for the cooperative triad that links two cAMP binding sites through a domain interface to the catalytic subunit of cAMP-dependent protein kinase. The domain interface surface is created by the binding of only one cAMP molecule and is enabled by amino acid sequence variability within the peptide chain that tethers the two domains together.     

A simple electrostatic switch important in the activation of type I protein kinase A by cyclic AMP

Cyclic AMP activates protein kinase A by binding to an inhibitory regulatory (R) subunit and releasing inhibition of the catalytic (C) subunit. Even though crystal structures of regulatory and catalytic subunits have been solved, the precise molecular mechanism by which cyclic AMP activates the kinase remains unknown. The dynamic properties of the cAMP binding domain in the absence of cAMP or C-subunit are also unknown. Here we report molecular-dynamics simulations and mutational studies of the RIalpha R-subunit that identify the C-helix as a highly dynamic switch which relays cAMP binding to the helical C-subunit binding regions. Furthermore, we identify an important salt bridge which links cAMP binding directly to the C-helix that is necessary for normal activation. Additional mutations show that a hydrophobic "hinge" region is not as critical for the cross-talk in PKA as it is in the homologous EPAC protein, illustrating how cAMP can control diverse functions using the evolutionarily conserved cAMP-binding domains.     

Guanosine cyclic 3',5'-phosphate dependent protein kinase, a chimeric protein homologous with two separate protein families

The amino acid sequence of bovine lung cGMP-dependent protein kinase has been determined by degradation and alignment of two primary overlapping sets of peptides generated by cleavage at methionyl or arginyl residues. The protein contains 670 residues in a single N alpha-acetylated chain corresponding to a molecular weight of 76 331. The function of the molecule is considered in six segments of sequence which may correspond to four folding domains. From the amino terminus, the first segment is related to the dimerizing property of the protein. The second and third segments appear to have evolved from an ancestral tandem internal gene duplication, generating twin cGMP-binding domains which are homologous to twin domains in the regulatory subunits of cAMP-dependent protein kinase and to the cAMP-binding domain of the catabolite gene activator of Escherichia coli. The fourth and fifth segments may comprise one domain which is homologous to the catalytic subunits of cAMP-dependent protein kinase, of calcium-dependent phosphorylase b kinase, and of certain oncogenic viral protein tyrosine kinases. The regulatory, amino-terminal half of cGMP-dependent protein kinase appears to be related to a family of smaller proteins that bind cAMP for diverse purposes, whereas the catalytic, carboxyl-terminal half is related to a family of protein kinases of varying specificity and varying sensitivity to regulators. These data suggest that ancestral gene splicing events may have been involved in the fusion of two families of proteins to generate the allosteric character of this chimeric enzyme.     

Opposite allosteric mechanisms in TetR and CAP

Regulation of the DNA binding affinity of an oligomeric protein can be considered to consist of an intrinsic component, in which the affinity of an individual DNA‐binding domain is modulated in response to effector binding, and an extrinsic component, in which the relative position of the protein's two DNA‐binding domains are altered so that they can or cannot contact both half‐site operators simultaneously. We demonstrated directly that the TetR repressor utilizes an extrinsic mechanism and CAP, the catabolite activator protein, utilizes an intrinsic mechanism.