A point mutation abolishes binding of cAMP to site A in the regulatory subunit of cAMP-dependent protein kinase

Each regulatory subunit of cAMP-dependent protein kinase has two tandem cAMP-binding sites, A and B, at the carboxyl terminus. Based on sequence homologies with the cAMP-binding domain of the Escherichia coli catabolite gene activator protein, a model has been constructed for each cAMP-binding domain. Two of the conserved features of each cAMP-binding site are an arginine and a glutamic acid which interact with the negatively charged phosphate and with the 2'-OH on the ribose ring, respectively. In the type I regulatory subunit, this arginine in cAMP binding site A is Arg-209. Recombinant DNA techniques have been used to change this arginine to a lysine. The resulting protein binds cAMP with a high affinity and associates with the catalytic subunit to form holoenzyme. The mutant holoenzyme also is activated by cAMP. However, the mutant R-subunit binds only 1 mol of cAMP/R-monomer. Photoaffinity labeling confirmed that the mutant R-subunit has only one functional cAMP-binding site. In contrast to the native R-subunit which is labeled at Trp-260 and Tyr-371 by 8-N3cAMP, the mutant R-subunit is convalently modified at a single site, Tyr-371, which correlates with a functional cAMP-binding site B. The lack of functional cAMP-binding site A also was confirmed by activating the mutant holoenzyme with analogs of cAMP which have a high specificity for either site A or site B. 8-NH2-methyl cAMP which preferentially binds to site B was similar to cAMP in its ability to activate both mutant and wild type holoenzyme whereas N6-monobutyryl cAMP, a site A-specific analog, was a very poor activator of the mutant holoenzyme. The results support the conclusions that 1) Arg-209 is essential for cAMP binding to site A and 2) cAMP binding to domain A is not essential for dissociation of the mutant holoenzyme.     

Effects of cAMP-binding site mutations on intradomain cross-communication in the regulatory subunit of cAMP-dependent protein kinase I

Each protomer of the regulatory subunit dimer of cAMP-dependent protein kinase contains two tandem and homologous cAMP-binding domains, A and B, and cooperative cAMP binding to these two sites promotes holoenzyme dissociation. Several amino acid residues in the type I regulatory subunit, predicted to lie in close proximity to each bound cyclic nucleotide based on affinity labeling and model building, were replaced using recombinant techniques. The mutations included replacement of 1) Glu-200, predicted to hydrogen bond to the 2'-OH of cAMP bound to site A, with Asp, 2) Tyr-371, the site of affinity labeling with 8-N3-cAMP in site B, with Trp, and 3) Phe-247, the position in site A that is homologous to Tyr-371 in site B, with Tyr. Each mutation caused an approximate 2-fold increase in both the Ka(cAMP) and Kd(cAMP); however, the off-rates for cAMP and the characteristic pattern of affinity labeling with 8-N3-cAMP differed markedly for each mutant protein. Furthermore, these mutations affect the cAMP binding properties not only of the site containing the mutation, but of the adjacent nonmutated site as well, thus confirming that extensive cross-communication occurs between the two cAMP-binding domains. Photoaffinity labeling of the native R-subunit results in the covalent modification of two residues, Trp-260 and Tyr-371, by 8-N3-cAMP bound to sites A and B, respectively, with a stoichiometry of 1 mol of 8-N3-cAMP incorporated per mol of R-monomer (Bubis, J., and Taylor, S. S. (1987) Biochemistry 26, 3478-3486). A stoichiometry of 1 mol of 8-N3-cAMP incorporated per R-monomer was observed for each mutant regulatory subunit as well, even when 2 mol of 8-N3-cAMP were bound per R-monomer; however, the major sites of covalent modification were altered as follows: R(Y371/W), Trp-371; R(E200/D), Tyr-371, and R(F247/Y), Tyr-371.     

Limited proteolysis alters the photoaffinity labeling of adenosine 3',5'-monophosphate dependent protein kinase II with 8-azidoadenosine 3',5'-monophosphate

Photoaffinity labeling of the regulatory subunits of cAMP-dependent protein kinase with 8-azidoadenosine 3',5'-monophosphate (8-N3cAMP) has proved to be a very specific method for identifying amino acid residues that are in close proximity to the cAMP-binding sites. Each regulatory subunit contains two tandem cAMP-binding sites. The type II regulatory subunit (RII) from porcine heart was modified at a single site, Tyr-381 [Kerlavage, A., & Taylor, S.S. (1980) J. Biol. Chem. 255, 8483-8488]. When a proteolytic fragment of this RII subunit was photolabeled with 8-N3cAMP, two sites were covalently modified. One site corresponded to Tyr-381 and, thus, was analogous to the native RII. The other site of modification was identified as Tyr-196, which is not labeled in the native protein. Photoaffinity labeling was carried out in the presence of various analogues of cAMP that show a preference for one of the two tandem cAMP-binding sites. These studies established that the covalent modification of Tyr-381 was derived from 8-N3cAMP that was bound to the second cAMP-binding site (domain B) and that covalent modification to Tyr-196 was due to 8-N3cAMP that was bound to the first cAMP-binding site (domain A). These sites of covalent modification have been correlated with a model of each cAMP-binding site on the basis of the crystal structure of the catabolite gene activator protein (CAP), which is the major cAMP-binding protein in Escherichia coli.     

Consequences of cAMP-binding site mutations on the structural stability of the type I regulatory subunit of cAMP-dependent protein kinase

The regulatory (R) subunit of cAMP-dependent protein kinase (cAPK) is a multidomain protein with two tandem cAMP-binding domains, A and B. The importance of cAMP binding on the stability of the R subunit was probed by intrinsic fluorescence and circular dichroism (CD) in the presence and absence of urea. Several mutants were characterized. The site-specific mutants R(R209K) and R(R333K) had defects in cAMP-binding sites A and B, respectively. R(M329W) had an additional tryptophan in domain B. Delta(260-379)R lacked Trp260 and domain B. The most destabilizing mutation was R209K. Both CD and fluorescence experiments carried out in the presence of urea showed a decrease in cooperativity of the unfolding, which also occurred at lower urea concentrations. Unlike native R, R(R209K) was not stabilized by excess cAMP. Additionally, CD revealed significant alterations in the secondary structure of the R209K mutant. Therefore, Arg209 is important not only as a contact site for cAMP binding but also for the intrinsic structural stability of the full-length protein. Introducing the comparable mutation into domain B, R333K, had a smaller effect on the integrity and stability of domain A. Unfolding was still cooperative; the protein was stabilized by excess cAMP, but the unfolding curve was biphasic. The R(M329W) mutant behaved functionally like the native protein. The Delta(260-379)R deletion mutant was not significantly different from wild-type RIalpha in its stability. Consequently, domain B and the interaction between Trp260 and cAMP bound to site A are not critical requirements for the structural stability of the cAPK regulatory subunit.     

Expression of the type I regulatory subunit of cAMP-dependent protein kinase in Escherichia coli

An expression vector has been constructed for the type I regulatory subunit of cAMP-dependent protein kinase. A cDNA clone for the bovine RI-subunit has been inserted into pUC7. When Escherichia coli JM105 was transformed with this plasmid, R-subunit was expressed in amounts that approached 4 mg/liter. The expressed protein was visualized in total cell extracts by photolabeling with 8-azidoadenosine 3':5'-mono[32P]phosphate following transfer from sodium dodecyl sulfate-polyacrylamide gels to nitrocellulose. Expression of R-subunit was independent of isopropyl-beta-D-thiogalactopyranoside. R-subunit accumulated in large amounts only in the stationary phase of growth, and the addition of isopropyl-beta-D-thiogalactopyranoside during the log phase of growth actually blocked the accumulation of R-subunit. Maximum expression (20 mg/liter) was achieved when E. coli 222 was transformed with the RI-containing plasmid. E. coli 222 is a strain that contains two mutations; it is cya- and also has a mutation in the catabolite gene activator protein (crp) that enables the protein to bind to DNA in the absence of cAMP. The expressed RI-subunit was a soluble, dimeric protein, and no significant proteolysis was apparent in the cell extract. The purified RI-subunit bound 2 mol of cAMP/mol of R monomer, reassociated with C-subunit to form holoenzyme, and migrated as a dimer on sodium dodecyl sulfate-polyacrylamide gels in the absence of reducing agents. The expressed protein was also susceptible to limited proteolysis, yielding a monomeric cAMP-binding fragment having a molecular weight of 35,000. In all of these properties, the expressed protein was indistinguishable from RI purified from bovine tissue even though the R-subunit expressed in E. coli represents a fusion protein that contains 10 additional amino acids at the amino terminus that are provided by the lac Z' gene of the vector. This NH2-terminal sequence was confirmed by amino acid sequencing.     

Tyrosine-371 contributes to the positive cooperativity between the two cAMP binding sites in the regulatory subunit of cAMP-dependent protein kinase I

The regulatory (R) subunit of cAMP-dependent protein kinase I has been expressed in Escherichia coli, and oligonucleotide-directed mutagenesis was initiated in order to better understand structural changes that are induced as a consequence of cAMP-binding. Photoaffinity labeling of the type I holoenzyme with 8-azidoadenosine 3',5'-monophosphate (8-N3cAMP) leads to the covalent modification of two residues, Trp-260 and Tyr-371 [Bubis, J., & Taylor, S.S. (1987) Biochemistry 26, 3478-3486]. The site that was targeted for mutagenesis was Tyr-371. The intention was to establish whether the interactions between the tyrosine ring and the adenine ring of cAMP are primarily hydrophobic in nature or whether the hydroxyl group is critical for cAMP binding and/or for inducing conformational changes. A single base change converted Tyr-371 to Phe. This yielded an R subunit that reassociated with the catalytic subunit to form holoenzyme and bound 2 mol of cAMP/mol of R monomer. The cAMP binding properties of the holoenzyme that was formed with this mutant R subunit, however, were altered: (a) the apparent Kd(cAMP) was shifted from 16 to 60 nM; (b) Scatchard plots showed no cooperativity between the cAMP binding sites in the mutant in contrast to the positive cooperativity that is observed for the wild-type holoenzyme; (c) the Hill coefficient of 1.6 for the wild-type holoenzyme was reduced to 0.99. The Ka's for activation by cAMP were altered in the mutant holoenzyme in a manner that was proportional to the shift in Kd(cAMP).(ABSTRACT TRUNCATED AT 250 WORDS)     

Expression and characterization of mutant forms of the type I regulatory subunit of cAMP-dependent protein kinase. The effect of defective cAMP binding on holoenzyme activation

The mouse wild type and four mutant regulatory type I (RI) subunits were expressed in Escherichia coli and subjected to kinetic analyses. The defective RI subunits had point mutations in either cAMP-binding site A (G200/E), site B (G324/D, R332/H), or in both binding sites. In addition, a truncated form of RI which lacked the entire cAMP-binding site B was generated. All of the mutant RI subunits which bound [3H]cAMP demonstrated more rapid rates of cAMP dissociation compared to the wild type RI subunit. Dissociation profiles showed only a single dissociation component, suggesting that a single nonmutated binding site was functional. The mutant RI subunits associated with purified native catalytic subunit to form chromatographically separable holoenzyme complexes in which catalytic activity was suppressed. Each of these holoenzymes could be activated but showed varying degrees of cAMP responsiveness with apparent Ka values ranging from 40 nM to greater than 5 microM. The extent to which the mutated cAMP-binding sites were defective was also shown by the resistance of the respective holoenzymes to activation by cAMP analogs selective for the mutated binding sites. Kinetic results support the conclusions that 1) Gly-200 of cAMP-binding site A and Gly-324 or Arg-332 of site B are essential to normal conformation and function, 2) activation of type I cAMP-dependent protein kinase requires that only one of the cAMP-binding sites be functional, 3) mutational inactivation of site B (slow exchange) has a much more drastic effect than that of site A on increasing the Ka of the holoenzyme for cAMP, as well as in altering the rate of cAMP dissociation from the remaining site of the free RI subunit. The strong dependence of one cAMP-binding site on the integrity of the other site suggests a tight association between the two sites.     

Deletion mutants as probes for localizing regions of subunit interaction in cAMP-dependent protein kinase

The regulatory subunit of cAMP-dependent protein kinase has a well-defined domain structure, and recombinant DNA techniques have been used to define further the functional properties that are associated with each domain. Our initial question was to define the minimal structural unit that is required for forming a stable complex with the catalytic subunit that will still bind and hence be dissociated by cAMP. To answer these questions, the entire second cAMP-binding domain was deleted using oligonucleotide-directed mutagenesis to introduce a premature stop codon at Trp260. This mutation results in the expression of a stable protein with an Mr of 38,000 based on polyacrylamide gel electrophoresis. The resulting mutant protein is a dimer; and like the native R-subunit, the two protomers of the dimer are cross-linked by disulfide bonds at the amino terminus. The mutant R-subunit binds 1 mol of cAMP/monomer based on equilibrium dialysis. The Kd(cAMP) was 25 nM, which is slightly higher than the Kd(cAMP) for the native R-subunit. The removal of the second cAMP domain does not prevent aggregation with the catalytic subunit, and the inactive holoenzyme complex that is formed in the absence of cAMP can still be dissociated and consequently activated by cAMP. In conjunction with previous results based on limited proteolysis, it is concluded that the region extending from Arg94 to Lys259 constitutes a structural unit that will be sufficient to interact with the catalytic subunit in a cAMP-dependent manner.     

Probing the multidomain structure of the type I regulatory subunit of cAMP-dependent protein kinase using mutational analysis: role and environment of endogenous tryptophans

The regulatory R-subunit of cAMP-dependent protein kinase (cAPK) is a thermostable multidomain protein. It contains a dimerization domain at the N-terminus followed by an inhibitor site that binds the catalytic C-subunit and two tandem cAMP-binding domains (A and B). Two of the three tryptophans in the RIalpha subunit, Trp188 and Trp222, lie in cAMP-binding domain A while Trp260 lies at the junction between domains A and B. The unfolding of wild-type RIalpha (wt-RI), monitored by intrinsic fluorescence, was described previously [Leon, D. A., Dostmann, W. R. G., and Taylor, S. S. (1991) Biochemistry 30, 3035 (1)]. To determine the environment of each tryptophan and the role of the adjacent domain in folding and stabilization of domain A, three point mutations, W188Y, W222Y, and W260Y, were introduced. The secondary structure of wt-RI and the point mutants has been studied by far-UV circular dichroism spectropolarimetry (CD). The CD spectra of wt-RI and the three point mutants are practically identical, and the thermal unfolding behavior is very similar. Intrinsic fluorescence and iodide quenching in the presence of increasing urea established that: (a) Trp222 is the most buried, whereas Trp188 is the most exposed to solvent; (b) Trp260 accounts for the quenching of fluorescence when cAMP is bound; and (c) Trp222 contributes most to the intrinsic fluorescence of the wt-RI-subunit, while Trp188 contributes least. For wt-RI, rR(W188Y), and rR(W260Y), removal of cAMP causes a destabilization, while excess cAMP stabilizes these three proteins. In contrast, rR(W222Y) was not stabilized by excess cAMP.     

Quinone (QB) reduction by B-branch electron transfer in mutant bacterial reaction centers from Rhodobacter sphaeroides: quantum efficiency and X-ray structure

The photosynthetic reaction center (RC) from purple bacteria converts light into chemical energy. Although the RC shows two nearly structurally symmetric branches, A and B, light-induced electron transfer in the native RC occurs almost exclusively along the A-branch to a primary quinone electron acceptor Q(A). Subsequent electron and proton transfer to a mobile quinone molecule Q(B) converts it to a quinol, Q(B)H(2). We report the construction and characterization of a series of mutants in Rhodobacter sphaeroides designed to reduce Q(B) via the B-branch. The quantum efficiency to Q(B) via the B-branch Phi(B) ranged from 0.4% in an RC containing the single mutation Ala-M260 --> Trp to 5% in a quintuple mutant which includes in addition three mutations to inhibit transfer along the A-branch (Gly-M203 --> Asp, Tyr-M210 --> Phe, Leu-M214 --> His) and one to promote transfer along the B-branch (Phe-L181 --> Tyr). Comparing the value of 0.4% for Phi(B) obtained in the AW(M260) mutant, which lacks Q(A), to the 100% quantum efficiency for Phi(A) along the A-branch in the native RC, we obtain a ratio for A-branch to B-branch electron transfer of 250:1. We determined the structure of the most effective (quintuple) mutant RC at 2.25 A (R-factor = 19.6%). The Q(A) site did not contain a quinone but was occupied by the side chain of Trp-M260 and a Cl(-). In this structure a nonfunctional quinone was found to occupy a new site near M258 and M268. The implications of this work to trap intermediate states are discussed.     

Photoaffinity labeling of functionally different lysine-binding sites in human plasminogen and plasmin

Photoaffinity labeling of human plasmin using 4-azidobenzoylglycyl-L-lysine inhibits clot lysis activity, while the activity toward the active-site titrant, p-nitrophenyl-p'-guanidinobenzoate, or alpha-casein are maintained. Photoaffinity labeling of native Glu-plasminogen with the same reagent causes incorporation of approximately 1.5 mol label per mol plasminogen. This labeled plasminogen can be activated to plasmin by either urokinase or streptokinase. The resulting plasmin has full clot lysis activity and can be subsequently photoaffinity labeled with a loss of clot lysis activity. The rate of activation of labeled plasminogen by urokinase is increased relative to that of native plasminogen. epsilon-Aminocaproic acid blocks incorporation of photoaffinity label into both plasminogen and plasmin, indicating that the labeling is specific to the lysine-binding sites. The labels are located in the kringle 1+2+3 fragment in either photoaffinity-labeled plasminogen or plasmin. These results indicate that the specific lysine-binding site blocked in plasmin acts in concert with the active-site in binding and using fibrin as a substrate. This clot lysis regulating site is not available for labeling in plasminogen, but is exposed or changed upon activation to plasmin. The different lysine-binding sites labeled in plasminogen may regulate the conformation of the molecule as evidence by an enhanced rate of activation to plasmin.     

Analysis of the substrate binding sites of human galactosyltransferase by protein engineering.

An expression vector, pIN-GT, encoding the soluble form of beta 1,4-galactosyltransferase (GT) has been constructed from human GT cDNAs and the pIN-III-ompA2 expression vector. Escherichia coli strain SB221 harboring the pIN-GT plasmid produces and secretes a fusion protein consisting of the ompA signal and GT. The expression of GT was detected by assaying enzymatic activity as well as by Western blotting using anti-GT antibodies. The recombinant GT was purified to homogeneity by N-acetylglucosamine-Sepharose affinity chromatography. The NH2-terminal peptide sequence of purified GT confirmed the cleavage site of the fusion protein by bacterial signal peptidase. This expression system was utilized to produce mutant forms of GT in order to identify specific amino acids involved in substrate binding sites. Photoaffinity labeling of GT with UDP-galactose analog, 4-azido-2-nitrophenyluridylylpyrophosphate (ANUP), followed by cyanogen bromide (CNBr) cleavage revealed that ANUP bound to a fragment of GT composed of amino acid residues from Asp276 to Met328. Within this peptide segment, Tyr284, Tyr287, Tyr309, Trp310 and Trp312 were separately substituted into Gly and Tyr287 into Phe by site-directed mutagenesis. Enzymatic activity assay showed drastic reduction of the activity in all of the mutants except that Tyr287----Phe remained as active as wild-type GT. Kinetic studies of the mutated GT showed that Tyr284, Tyr309 and Trp310 are critically involved in the N-acetyglucosamine binding and Tyr309 is involved in UDP-galactose binding as well.(ABSTRACT TRUNCATED AT 250 WORDS)     

Endogenous tryptophan residues of cAPK regulatory subunit type IIbeta reveal local variations in environments and dynamics

The amino terminal dimerization/docking domain and the two-tandem, carboxy-terminal cAMP-binding domains (A and B) of cAMP-dependent protein kinase regulatory (R) subunits are connected by a variable linker region. In addition to providing a docking site for the catalytic subunit, the linker region is a major source of sequence diversity between the R-subunit isoforms. The RIIbeta isoform uniquely contains two endogenous tryptophan residues, one at position 58 in the linker region and the other at position 243 in cAMP-binding domain A, which can act as intrinsic reporter groups of their dynamics and microenvironment. Two single-point mutations, W58F and W243F, allowed the local environment of each Trp to be probed using steady-state and time-resolved fluorescence techniques. We report that: (a) the tryptophan fluorescence of the wild-type protein largely reflects Trp243 emission; (2) cAMP selectively quenches Trp243 and thus acts as a cAMP sensor; (3) Trp58 resides in a highly solvated, unstructured, and mobile region of the protein; and (4) Trp243 resides in a stable, folded domain and is relatively buried and rigid within the domain. The use of endogenous Trp residues presents a non-perturbing method for studying R-subunit subdomain characteristics in addition to providing the first biophysical data on the RIIbeta linker region.     

Dynamics of cAPK type IIbeta activation revealed by enhanced amide H/2H exchange mass spectrometry (DXMS)

cAMP-dependent protein kinase (cAPK) is a key component in numerous cell signaling pathways. The cAPK regulatory (R) subunit maintains the kinase in an inactive state until cAMP saturation of the R-subunit leads to activation of the enzyme. To delineate the conformational changes associated with cAPK activation, the amide hydrogen/deuterium exchange in the cAPK type IIbeta R-subunit was probed by electrospray mass spectrometry. Three states of the R-subunit, cAMP-bound, catalytic (C)-subunit bound, and apo, were incubated in deuterated water for various lengths of time and then, prior to mass spectrometry analysis, subjected to digestion by pepsin to localize the deuterium incorporation. High sequence coverage (>99%) by the pepsin-digested fragments enables us to monitor the dynamics of the whole protein. The effects of cAMP binding on RIIbeta amide hydrogen exchange are restricted to the cAMP-binding pockets, while the effects of C-subunit binding are evident across both cAMP-binding domains and the linker region. The decreased amide hydrogen exchange for residues 253-268 within cAMP binding domain A and for residues 102-115, which include the pseudosubstrate inhibitory site, support the prediction that these two regions represent the conserved primary and peripheral C-subunit binding sites. An increase in amide hydrogen exchange for a broad area within cAMP-binding domain B and a narrow area within cAMP-binding domain A (residues 222-232) suggest that C-subunit binding transmits long-distance conformational changes throughout the protein.     

Probing the CYP3A4 active site by cysteine scanning mutagenesis and photoaffinity labeling

The mechanism of CYP3A4-substrate interactions has been investigated using a battery of techniques including cysteine scanning mutagenesis, photoaffinity labeling, and structural modeling. In this study, cysteine scanning mutagenesis was performed at seven sites within CYP3A4 proposed to be involved in substrate interaction and/or cooperativity. Photolabeled CYP3A4 peptide adducts were further characterized by mass spectrometric analysis for each mutant after proteolytic digestion and isolation of fluorescent photolabeled peptides. Among the tryptic peptides of seven tested mutants, three photolabeled peptides of the F108C mutant, ECYSVFTNR (positions 97-105), VLQNFSFKPCK (positions 459-469), and RPCGPVGFMK (positions 106-115) were identified by MALDI-TOF-MS and nano-LC/ESI QTOF MS. The site of modification was further localized to the substituted Cys-108 residue in the mutant peptide adduct RPCGPVGFMK (positions 106-115) by nano-LC/ESI QTOF MS/MS. In summary, we described a potentially useful method to study P450 active sites using a combination of cysteine scanning mutagenesis and photoaffinity labeling.     

Monoclonal antibodies as probes for functional domains in cAMP-dependent protein kinase II

The antigenic regions of the type II regulatory subunit of cAMP-dependent kinase from bovine heart have been correlated with the previously established domain structure of the molecule. Immunoblotting with both serum and monoclonal antibodies of fragments generated by limited proteolysis or chemical cleavage of the R-subunit established that the major antigenic sites were confined to the amino-terminal portion of the polypeptide chain (residues 1-145). Radioimmunoassays using two different antisera suggested that one or more of the high affinity serum antibody recognition sites were further restricted to residues 91-145. This amino-terminal portion of the R-subunit includes the hinge region which is particularly sensitive to proteolysis, allowing the R-subunit to be cleaved readily into a COOH-terminal domain which retains the cAMP-binding sites and an NH2-terminal fragment which appears to be the major site for interaction of the R-subunits in the native dimer. Monoclonal antibodies that recognized determinants on both sides of this hinge region were characterized and their specific recognition sites localized. Accessibility of antigenic sites in the holoenzyme in contrast to free R2 was compared. Although cAMP did tend to slightly increase the affinity of the holoenzyme for one of the monoclonal antibodies, all of the antigenic sites clearly were exposed and accessible in the holoenzyme. Furthermore, despite the presumed close proximity of antigenic sites to interaction sites between the R- and C-subunits, in no case did binding of antibody to the holoenzyme promote dissociation of the complex. The fact that the monoclonal antibodies would precipitate holoenzyme as well as free R2 was used to ascertain the importance of specific amino acid residues in the interaction of the R- and C-subunits. cAMP-binding domains were isolated following limited proteolysis with chymotrypsin and thermolysin. These fragments differed by only three amino acid residues at the NH2-terminal end. U of these fragments in conjunction with immunoadsorption established that the chymotryptic fragment, which contained the Asp-Arg-Arg preceding the site of autophosphorylation, was capable of forming a stable complex with the C-subunit. In contrast, the thermolytic fragment which differed by only those three residues no longer complexed with the C-subunit, indicating that the arginine residues not only contribute to the specificity of the phosphorylation site but also are an essential component for energetically stabilizing the holoenzyme complex.     

Photoaffinity labeling of mutant neurokinin-1 receptors reveals additional structural features of the substance P/NK-1 receptor complex

Photoaffinity labeling, receptor site-directed mutagenesis, and high-resolution NMR spectroscopy have been combined to further define the molecular details of the binding of substance P (SP) to the rat neurokinin-1 (NK-1) receptor. Mutant NK-1 receptors were constructed by substituting Ala for Met174 and/or Met181: residues previously identified as the sites of covalent attachment of radioiodinated, photoreactive derivatives of SP containing p-benzoyl-L-phenylalanine (Bpa) in positions 4 and 8, respectively. Photoaffinity labeling of the M181A mutant using radioiodinated Bpa8-SP resulted in a marked reduction in photoincorporation efficiency compared to the wild-type receptor. In contrast, photoaffinity labeling of the M174A mutant using radioiodinated Bpa4-SP gave the unexpected result of an increase in the efficiency of photoincorporation compared to the wild-type receptor. Enzymatic and chemical fragmentation analysis of the photolabeled receptor mutants established that the sites of covalent attachment were not the substituted alanine, but rather the other methionine on the second extracellular (E2) loop sequence, that is not the primary site of attachment in the wild-type receptor. The results thus suggest a close spatial relationship between Met174 and Met181 on the NK-1 receptor. To evaluate this structural disposition, NMR analyses were performed on a synthetic peptide with a sequence corresponding to the entire E2 loop and segments of the adjoining transmembrane helices to anchor the peptide in the lipids used to mimic a membrane. The structural features of the E2 loop include a centrally located alpha-helix, extending from Pro175 to Glu183, as well as smaller alpha-helices at the termini, corresponding to the transmembrane regions. The two methionine residues are located on the same face of the central alpha-helix, approximately 11 A apart from each other, and are therefore consistent with the conclusions of the photoaffinity labeling results.     

Identification of peptides from the adenine binding domains of ATP and AMP in adenylate kinase: isolation of photoaffinity-labeled peptides by metal chelate chromatography.

Photoaffinity labeling with azidoadenine nucleotides was used to identify peptides from the ATP and AMP binding domains on chicken muscle adenylate kinase. Competition binding studies and enzyme assays showed that the 8-azido analogues of Ap4A and ATP modified only the MgATP2- site of adenylate kinase, whereas the 2-azido analogue of ADP modified the enzyme at both the ATP and AMP sites. The positions of the two nucleotide binding sites on the enzyme were deduced by isolating and sequencing the modified peptides. Photolabeled peptides were isolated by a new procedure that used metal chelate chromatography to affinity purify the photolabeled peptides prior to final purification by reverse-phase HPLC. The sequences of the peptides that were photolabeled with the 8-azido analogues corresponded to residues K28-L44, T153-K166, and T125-E135 of the chicken muscle enzyme. The residues that were present in both tryptic- and Staphylococcus aureus V-8 protease-generated versions of these peptides were assigned to the ATP binding domain on the basis of selective photoaffinity labeling with the 8-azidoadenine analogues. These peptides and an additional peptide corresponding to positions I110-K123 were photolabeled with 2-N3ADP. Since I110-K123 was photolabeled by 2-N3ADP but not by 8-N3Ap4A, it was assigned to the AMP binding domain.     

Structure of a complex of Thermoactinomyces vulgaris R-47 alpha-amylase 2 with maltohexaose demonstrates the important role of aromatic residues at the reducing end of the substrate binding cleft

Thermoactinomyces vulgaris R-47 alpha-amylase 2 (TVAII) can efficiently hydrolyze both starch and cyclomaltooligosaccharides (cyclodextrins). The crystal structure of an inactive mutant TVAII in a complex with maltohexaose was determined at a resolution of 2.1A. TVAII adopts a dimeric structure to form two catalytic sites, where substrates are found to bind. At the catalytic site, there are many hydrogen bonds between the enzyme and substrate at the non-reducing end from the hydrolyzing site, but few hydrogen bonds at the reducing end, where two aromatic residues, Trp356 and Tyr45, make effective interactions with a substrate. Trp356 drastically changes its side-chain conformation to achieve a strong stacking interaction with the substrate, and Tyr45 from another molecule forms a water-mediated hydrogen bond with the substrate. Kinetic analysis of the wild-type and mutant enzymes in which Trp356 and/or Tyr45 were replaced with Ala suggested that Trp356 and Tyr45 are essential to the catalytic reaction of the enzyme, and that the formation of a dimeric structure is indispensable for TVAII to hydrolyze both starch and cyclodextrins.     

Quinone (Q(B)) binding site and protein stuctural changes in photosynthetic reaction center mutants at Pro-L209 revealed by vibrational spectroscopy

The effect of substituting Pro-L209 with Tyr, Phe, Glu, and Thr in photosynthetic reaction centers (RCs) from Rhodobacter sphaeroides was investigated by monitoring the light-induced FTIR absorption changes associated with the photoreduction of the secondary quinone Q(B). Pro-L209 is close to a chain of ordered water molecules connecting Q(B) to the bulk phase. In wild-type RCs, two distinct main Q(B) binding sites (distal and proximal to the non-heme iron) have been described in the literature. The X-ray structures of the mutant RCs Pro-L209 --> Tyr, Pro-L209 --> Phe, and Pro-L209 --> Glu have revealed that Q(B) occupies a proximal, intermediate, and distal position, respectively [Kuglstatter, A., Ermler, U., Michel, H., Baciou, L., and Fritzsch, G. (2001) Biochemistry 40, 4253-4260]. FTIR absorption changes associated with the reduction of Q(B) in Pro-L209 --> Phe RCs reconstituted with (13)C-labeled ubiquinone show a highly specific IR fingerprint for the C=O and C=C modes of Q(B) upon selective labeling at C(1) or C(4). This IR fingerprint is similar to those of wild-type RCs and the Pro-L209 --> Tyr mutant [Breton, J., Boullais, C., Mioskowski, C., Sebban, P., Baciou, L., and Nabedryk, E. (2002) Biochemistry 41, 12921-12927], demonstrating that equivalent interactions occur between neutral Q(B) and the protein in wild-type and mutant RCs. It is concluded that in all RCs, neutral Q(B) in its functional state occupies a unique binding site which is favored to be the proximal site. This result contrasts with the multiple Q(B) binding sites found in crystal structures. With respect to wild-type RCs, the largest FTIR spectral changes upon Q(B)(-) formation are observed for the Phe-L209 and Tyr-L209 mutants which undergo similar protein structural changes and perturbations of the semiquinone modes. Smaller changes are observed for the Glu-L209 mutant, while the vibrational properties of the Thr-L209 mutant are essentially the same as those for native RCs.