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 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.     

Mapping intersubunit interactions of the regulatory subunit (RIalpha) in the type I holoenzyme of protein kinase A by amide hydrogen/deuterium exchange mass spectrometry (DXMS)

Protein kinase A (PKA), a central locus for cAMP signaling in the cell, is composed of regulatory (R) and catalytic (C) subunits. The C-subunits are maintained in an inactive state by binding to the R-subunit dimer in a tetrameric holoenzyme complex (R(2)C(2)). PKA is activated by cAMP binding to the R-subunits which induces a conformational change leading to release of the active C-subunit. Enzymatic activity of the C-subunit is thus regulated by cAMP via the R-subunit, which toggles between cAMP and C-subunit bound states. The R-subunit is composed of a dimerization/docking (D/D) domain connected to two cAMP-binding domains (cAMP:A and cAMP:B). While crystal structures of the free C-subunit and cAMP-bound states of a deletion mutant of the R-subunit are known, there is no structure of the holoenzyme complex or of the cAMP-free state of the R-subunit. An important step in understanding the cAMP-dependent activation of PKA is to map the R-C interface and characterize the mutually exclusive interactions of the R-subunit with cAMP and C-subunit. Amide hydrogen/deuterium exchange mass spectrometry is a suitable method that has provided insights into the different states of the R-subunit in solution, thereby allowing mapping of the effects of cAMP and C-subunit on different regions of the R-subunit. Our study has localized interactions with the C-subunit to a small contiguous surface on the cAMP:A domain and the linker region. In addition, C-subunit binding causes increased amide hydrogen exchange within both cAMP-domains, suggesting that these regions become more flexible in the holoenzyme and are primed to bind cAMP. Furthermore, the difference in the protection patterns between RIalpha and the previously studied RIIbeta upon cAMP-binding suggests isoform-specific differences in cAMP-dependent regulation of PKA activity.     

cAMP-dependent protein kinase regulatory subunit type IIbeta: active site mutations define an isoform-specific network for allosteric signaling by cAMP

cAMP-dependent protein kinase (cAPK) contains a regulatory (R) subunit dimer bound to two catalytic (C) subunits. Each R monomer contains two cAMP-binding domains, designated A and B. The sequential binding of two cAMPs releases active C. We describe here the properties of RIIbeta and two mutant RIIbeta subunits, engineered by converting a conserved Arg to Lys in each cAMP-binding domain thereby yielding a protein that contains one intact, high affinity cAMP-binding site and one defective site. Structure and function were characterized by circular dichroism, steady-state fluorescence, surface plasmon resonance and holoenzyme activation assays. The Ka for RIIbeta is 610 nM, which is 10-fold greater than its Kd(cAMP) and significantly higher than for RIalpha and RIIalpha. The Arg mutant proteins demonstrate that the conserved Arg is important for both cAMP binding and organization of each domain and that binding to domain A is required for activation. The Ka of the A domain mutant protein is 21-fold greater than that of wild-type and the Kd(cAMP) is increased 7-fold, confirming that cAMP must bind to the mutated site to initiate activation. The domain B mutant Ka is 2-fold less than its Kd(cAMP), demonstrating that, unlike RIalpha, cAMP can access the A site even when the B site is empty. Removal of the B domain yields a Ka identical to the Kd(cAMP) of full-length RIIbeta, indicating that the B domain inhibits holoenzyme activation for RIIbeta. In RIalpha, removal of the B domain generates a protein that is more difficult to activate than the wild-type protein.     

Deletion of cAMP-binding site B in the regulatory subunit of cAMP-dependent protein kinase alters the photoaffinity labeling of site A

Photoaffinity labeling with 8-azidoadenosine 3':5'-monophosphate is a highly selective method for probing the cAMP-binding sites of the regulatory subunits of cAMP-dependent protein kinase and for identifying specific residues that are in close proximity to the cAMP-binding sites. The cAMP-binding site of a mutant RI-subunit has been characterized here and contrasted to the native RI-subunit. This mutant RI-subunit was generated by oligonucleotide-directed muta-genesis and lacks the entire second cAMP-binding domain which includes both of the residues, Trp260 and Tyr371, that are photolabeled in the native RI-subunit. The mutant RI-subunit, nevertheless, is photoaffinity-labeled with high efficiency, and the residue covalently modified was identified as Tyr244. The position of Tyr244 based on a computer graphic model of cAMP-binding site A is proposed and correlated with the presumed locations of Tyr371 and Trp260 in the native R-subunit. Photoaffinity labeling also can be used to detect functional cAMP-binding sites following electrophoretic transfer of the denatured protein to nitrocellulose. Labeling of the immobilized protein on nitrocellulose required a functional cAMP-binding site A that can be photoaffinity-labeled in solution based on the following criteria. 1) The type I R-subunit is photolabeled, whereas the type II R-subunit is not. A primary feature which distinguishes these two R-subunits is that the RI-subunit is photolabeled at both sites A and B, whereas covalent modification of the RII-subunit occurs only at site B. 2) The truncated mutant of the RI-subunit which lacks the entire second cAMP-binding domain can be photolabeled on nitrocellulose. 3) A mutant RI-subunit which can no longer be photolabeled in site B is still photolabeled on nitrocellulose. 4) A mutation which abolished cAMP binding to site A also abolished photoaffinity labeling after transfer to nitrocellulose.     

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.     

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.     

Dissecting interdomain communication within cAPK regulatory subunit type IIbeta using enhanced amide hydrogen/deuterium exchange mass spectrometry (DXMS)

cAMP-dependent protein kinase (cAPK) is a heterotetramer containing a regulatory (R) subunit dimer bound to two catalytic (C) subunits and is involved in numerous cell signaling pathways. The C-subunit is activated allosterically when two cAMP molecules bind sequentially to the cAMP-binding domains, designated A and B (cAB-A and cAB-B, respectively). Each cAMP-binding domain contains a conserved Arg residue that is critical for high-affinity cAMP binding. Replacement of this Arg with Lys affects cAMP affinity, the structural integrity of the cAMP-binding domains, and cAPK activation. To better understand the local and long-range effects that the Arg-to-Lys mutation has on the dynamic properties of the R-subunit, the amide hydrogen/deuterium exchange in the RIIbeta subunit was probed by electrospray mass spectrometry. Mutant proteins containing the Arg-to-Lys substitution in either cAMP-binding domain were deuterated for various times and then, prior to mass spectrometry analysis, subjected to pepsin digestion to localize the deuterium incorporation. Mutation of this Arg in cAB-A (Arg230) causes an increase in amide hydrogen exchange throughout the mutated domain that is beyond the modest and localized effects of cAMP removal and is indicative of the importance of this Arg in domain organization. Mutation of Arg359 (cAB-B) leads to increased exchange in the adjacent cAB-A domain, particularly in the cAB-A domain C-helix that lies on top of the cAB-B domain and is believed to be functionally linked to the cAB-B domain. This interdomain communication appears to be a unidirectional pathway, as mutation of Arg230 in cAB-A does not effect dynamics of the cAB-B domain.     

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.     

Conformational differences among solution structures of the type Ialpha, IIalpha and IIbeta protein kinase A regulatory subunit homodimers: role of the linker regions

The regulatory (R) subunits of the cAMP-dependent protein kinase (protein kinase A or PKA) are multi-domain proteins responsible for conferring cAMP-dependence and localizing PKA to specific subcellular locations. There are four isoforms of the R subunit in mammals that are similar in molecular mass and domain organization, but clearly serve different biological functions. Although high-resolution structures are available for the cAMP-binding domains and dimerization/docking domains of two isoforms, there are no high-resolution structures of any of the intact R subunit homodimer isoforms. The results of small-angle X-ray scattering studies presented here indicate that the RIalpha, RIIalpha, and RIIbeta homodimers differ markedly in overall shape, despite extensive sequence homology and similar molecular masses. The RIIalpha and RIIbeta homodimers have very extended, rod-like shapes, whereas the RIalpha homodimer likely has a compact Y-shape. Based on a comparison of the R subunit sequences, we predict that the linker regions are the likely cause of these large differences in shape among the isoforms. In addition, we show that cAMP binding does not cause large conformational changes in type Ialpha or IIalpha R subunit homodimers, suggesting that the activation of PKA by cAMP involves only local conformational changes in the R subunits.     

Design and evaluation of a tryptophanless RecA protein with wild type activity

The C-terminal domain of the Escherichia coli RecA protein contains two tryptophan residues whose native fluorescence emission provides an interfering background signal when other fluorophores such as 1,N(6)-ethenoadenine, 2-aminopurine and other tryptophan residues are used to probe the protein's activities. Replacement of the wild type tryptophans with nonfluorescent residues is not trivial because one tryptophan is highly conserved and the C-terminal domain functions in both DNA binding as well as interfilament protein-protein contact. We undertook the task of creating a tryptophanless RecA protein with WT RecA activity by selecting suitable amino acid replacements for Trp290 and Trp308. Mutant proteins were screened in vivo using assays of SOS induction and cell survival following UV irradiation. Based on its activity in these assays, the W290H-W308F W-less RecA was purified for in vitro characterization and functioned like WT RecA in DNA-dependent ATPase and DNA strand exchange assays. Spectrofluorometry indicates that the W290H-W308F RecA protein generates no significant emission when excited with 295-nm light. Based on its ability to function as wild type protein in vivo and in vitro, this dark RecA protein will be useful for future fluorescence experiments.     

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.     

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.     

Spectral contribution of the individual tryptophan of alphaB-crystallin: a study by site-directed mutagenesis

There are two tryptophan residues in the lens alphaB-crystallin, Trp9 and Trp60. We prepared two Trp --> Phe substituted mutants, W9F and W60F, for use in a spectroscopic study. The two tryptophan residues contribute to Trp fluorescence and near-ultraviolet circular dichroism (UV CD) differently. The major difference in the near-UV CD is the contribution of 1La of Trp: it is positive in W60F but becomes negative in W9F. Further analysis of the near-UV CD shows an increased intensity in the region of 270-280 nm for W60F, suggesting that the Tyr48 is affected by the W60F mutation. It appears that Trp60 is located in a more rigid environment than Trp9, which agrees with a recent structural model in which Trp60 is in a beta-strand.     

Probing folding and fluorescence quenching in human gammaD crystallin Greek key domains using triple tryptophan mutant proteins

Human gammaD crystallin (HgammaD-Crys), a major component of the human eye lens, is a 173-residue, primarily beta-sheet protein, associated with juvenile and mature-onset cataracts. HgammaD-Crys has four tryptophans, with two in each of the homologous Greek key domains, which are conserved throughout the gamma-crystallin family. HgammaD-Crys exhibits native-state fluorescence quenching, despite the absence of ligands or cofactors. The tryptophan absorption and fluorescence quenching may influence the lens response to ultraviolet light or the protection of the retina from ambient ultraviolet damage. To provide fluorescence reporters for each quadrant of the protein, triple mutants, each containing three tryptophan-to-phenylalanine substitutions and one native tryptophan, have been constructed and expressed. Trp 42-only and Trp 130-only exhibited fluorescence quenching between the native and denatured states typical of globular proteins, whereas Trp 68-only and Trp 156-only retained the anomalous quenching pattern of wild-type HgammaD-Crys. The three-dimensional structure of HgammaD-Crys shows Tyr/Tyr/His aromatic cages surrounding Trp 68 and Trp 156 that may be the source of the native-state quenching. During equilibrium refolding/unfolding at 37 degrees C, the tryptophan fluorescence signals indicated that domain I (W42-only and W68-only) unfolded at lower concentrations of GdnHCl than domain II (W130-only and W156-only). Kinetic analysis of both the unfolding and refolding of the triple-mutant tryptophan proteins identified an intermediate along the HgammaD-Crys folding pathway with domain I unfolded and domain II intact. This species is a candidate for the partially folded intermediate in the in vitro aggregation pathway of HgammaD-Crys.     

Cyclic AMP-induced conformational changes in mycobacterial protein acetyltransferases

The activities of a number of proteins are regulated by the binding of cAMP and cGMP to cyclic nucleotide binding (CNB) domains that are found associated with one or more effector domains with diverse functions. Although the conserved architecture of CNB domains has been extensively studied by x-ray crystallography, the key to unraveling the mechanisms of cAMP action has been protein dynamics analyses. Recently, we have identified a novel cAMP-binding protein from mycobacteria, where cAMP regulates the activity of an associated protein acetyltransferase domain. In the current study, we have monitored the conformational changes that occur upon cAMP binding to the CNB domain in these proteins, using a combination of bioluminescence resonance energy transfer and amide hydrogen/deuterium exchange mass spectrometry. Coupled with mutational analyses, our studies reveal the critical role of the linker region (positioned between the CNB domain and the acetyltransferase domain) in allosteric coupling of cAMP binding to activation of acetyltransferase catalysis. Importantly, major differences in conformational change upon cAMP binding were accompanied by stabilization of the CNB and linker domain alone. This is in contrast to other cAMP-binding proteins, where cyclic nucleotide binding has been shown to involve intricate and parallel allosteric relays. Finally, this powerful convergence of results from bioluminescence resonance energy transfer and hydrogen/deuterium exchange mass spectrometry reaffirms the power of solution biophysical tools in unraveling mechanistic bases of regulation of proteins in the absence of high resolution structural information.     

Communication between the regulatory and the catalytic region of the cAMP-responsive guanine nucleotide exchange factor Epac

Epac1 is a guanine nucleotide exchange factor (GEF) for the small GTPase Rap1 that is directly activated by cAMP. This protein consists of a regulatory region with a cAMP-binding domain and a catalytic region that mediates the GEF activity. Epac is inhibited by an intramolecular interaction between the cAMP-binding domain and the catalytic region in the absence of cAMP. cAMP binding is proposed to induce a conformational change, which allows a LID, an alpha-helix at the C-terminal end of the cAMP-binding site, to cover the cAMP-binding site (Rehmann, H., Prakash, B., Wolf, E., Rueppel, A., de Rooij, J., Bos, J. L., and Wittinghofer, A. (2003) Nat. Struct. Biol. 10, 26-32). Here we show that mutations of conserved residues in the LID region affect cAMP binding only marginally but have a drastic effect on cAMP-induced GEF activity. Surprisingly, some of the mutants have an increased maximal GEF activity compared with wild type. Furthermore, mutation of the conserved VLVLE sequence at the C-terminal end of the LID into five alanine residues makes Epac constitutively active. From these results we conclude that the LID region plays a pivotal role in the communication between the regulatory and catalytic part of Epac.     

Probing a pheromone binding protein of the silkmoth Antheraea polyphemus by endogenous tryptophan fluorescence.

One subtype of the pheromone binding proteins of the silkmoth Antheraea polyphemus (ApolPBP1) has been analysed exploiting the two endogenous tryptophan residues as fluorescent probe. The intrinsic fluorescence exhibited a rather narrow spectrum with a maximum at 336 nm. Site-directed mutagenesis experiments revealed that one of the tryptophan residues (Trp37) is located in a hydrophobic environment whereas Trp127 is more solvent exposed, as was predicted modeling the ApolPBP1 sequence on the proposed structure of the Bombyx mori pheromone binding protein. Monitoring the interaction of ApolPBP1 as well as its Trp mutants with the three species-specific pheromone compounds by recording the endogenous fluorescence emission revealed profound differences; whereas (E6,Z11)-hexadecadienal induced a dose-dependent quenching of the fluorescence, both (E6,Z11)-hexadecadienyl-1-acetate and (E4,Z9)-tetradecadienyl-1-acetate elicited an augmentation of the endogenous fluorescence. These data indicate that although ApolPBP1 can bind all three pheromones, there are substantial differences concerning their interaction with the protein, which may have important functional implications.     

Immunochemical properties of the regulatory subunit of cAMP-dependent protein kinase II]

Immunochemical analysis of the cAMP-dependent protein kinase regulatory subunit type II was performed with the use of two rabbit antisera elicited to a free R-subunit from pig brain and to a RcAMP complex. Quantitative precipitation of the homogeneous antigen revealed six determinants on the R-molecule. Of these at least one is localized in the R-fragment (37 kD), the others--in the N-terminal part of the R-molecule. The antigenic determinants seem to be remoted from the cAMP-binding centers, since the attachment of the affinity purified antibody Fab-fragments to the R-subunit did not influence the cAMP-binding activity of the latter. The antibodies to RcAMP caused dissociation of the holoenzyme. The antibody Fab-fragment binding to the R-subunit prevented its association with the catalytic subunit. The results of immunochemical analysis suggest that the R-subunit adopts different conformations when bound to cAMP or to the catalytic subunit.     

Interaction of the Extreme N-Terminal Region of FliH with FlhA Is Required for Efficient Bacterial Flagellar Protein Export

The flagellar type III protein export apparatus plays an essential role in the formation of the bacterial flagellum. FliH forms a complex along with FliI ATPase and is postulated to provide a link between FliI ring formation and flagellar protein export. Two tryptophan residues of FliH, Trp7 and Trp10, are required for the effective docking of the FliH-FliI complex to the export gate made of six membrane proteins. However, it remains unknown which export gate component interacts with these two tryptophan residues. Here, we performed targeted photo-cross-linking of the extreme N-terminal region of FliH (FliH(EN)) with its binding partners. We replaced Trp7 and Trp10 of FliH with p-benzoyl-phenylalanine (pBPA), a photo-cross-linkable unnatural amino acid, to produce FliH(W7pBPA) and FliH(W10pBPA). They were both functional and were photo-cross-linked with one of the export gate proteins, FlhA, but not with the other gate proteins, indicating that these two tryptophan residues are in close proximity to FlhA. Mutant FlhA proteins that are functional in the presence of FliH and FliI but not in their absence showed a significantly reduced function also by N-terminal FliH mutations even in the presence of FliI. We suggest that the interaction of FliH(EN) with FlhA is required for anchoring the FliI hexamer ring to the export gate for efficient flagellar protein export.