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.     

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.     

Amide H/2H exchange reveals communication between the cAMP and catalytic subunit-binding sites in the R(I)alpha subunit of protein kinase A

The changes in backbone hydrogen/deuterium (H/2H) exchange in the regulatory subunit (R(I)alpha(94-244)) of cyclic AMP-dependent protein kinase A (PKA) were probed by MALDI-TOF mass spectrometry. The three naturally occurring states of the regulatory subunit were studied: (1) free R(I)alpha(94-244), which likely represents newly synthesized protein, (2) R(I)alpha(94-244) bound to the catalytic (C) subunit, or holoenzyme, and (3) R(I)alpha(94-244) bound to cAMP. Protection from amide exchange upon C-subunit binding was observed for the helical subdomain, including the A-helix and B-helix, pointing to regions adjacent to those shown to be important by mutagenesis. In addition, C-subunit binding caused changes in observed amide exchange in the distal cAMP-binding pocket. Conversely, cAMP binding caused protection in the cAMP-binding pocket and increased exchange in the helical subdomain. These results suggest that the mutually exclusive binding of either cAMP or C-subunit is controlled by binding at one site transmitting long distance changes to the other site.     

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.     

Cyclic AMP analog blocks kinase activation by stabilizing inactive conformation: conformational selection highlights a new concept in allosteric inhibitor design

The regulatory (R) subunit of protein kinase A serves to modulate the activity of protein kinase A in a cAMP-dependent manner and exists in two distinct and structurally dissimilar, end point cAMP-bound "B" and C-subunit-bound "H"-conformations. Here we report mechanistic details of cAMP action as yet unknown through a unique approach combining x-ray crystallography with structural proteomics approaches, amide hydrogen/deuterium exchange and ion mobility mass spectrometry, applied to the study of a stereospecific cAMP phosphorothioate analog and antagonist((Rp)-cAMPS). X-ray crystallography shows cAMP-bound R-subunit in the B form but surprisingly the antagonist Rp-cAMPS-bound R-subunit crystallized in the H conformation, which was previously assumed to be induced only by C-subunit-binding. Apo R-subunit crystallized in the B form as well but amide exchange mass spectrometry showed large differences between apo, agonist and antagonist-bound states of the R-subunit. Further ion mobility reveals the apo R-subunit as an ensemble of multiple conformations with collisional cross-sectional areas spanning both the agonist and antagonist-bound states. Thus contrary to earlier studies that explained the basis for cAMP action through "induced fit" alone, we report evidence for conformational selection, where the ligand-free apo form of the R-subunit exists as an ensemble of both B and H conformations. Although cAMP preferentially binds the B conformation, Rp-cAMPS interestingly binds the H conformation. This reveals the unique importance of the equatorial oxygen of the cyclic phosphate in mediating conformational transitions from H to B forms highlighting a novel approach for rational structure-based drug design. Ideal inhibitors such as Rp-cAMPS are those that preferentially "select" inactive conformations of target proteins by satisfying all "binding" constraints alone without inducing conformational changes necessary for activation.     

Phosphodiesterases catalyze hydrolysis of cAMP-bound to regulatory subunit of protein kinase A and mediate signal termination

Although extensive structural and biochemical studies have provided molecular insights into the mechanism of cAMP-dependent activation of protein kinase A (PKA), little is known about signal termination and the role of phosphodiesterases (PDEs) in regulatory feedback. In this study we describe a novel mode of protein kinase A-anchoring protein (AKAP)-independent feedback regulation between a specific PDE, RegA and the PKA regulatory (RIα) subunit, where RIα functions as an activator of PDE catalysis. Our results indicate that RegA, in addition to its well-known role as a PDE for bulk cAMP in solution, is also capable of hydrolyzing cAMP-bound to RIα. Furthermore our results indicate that binding of RIα activates PDE catalysis several fold demonstrating a dual function of RIα, both as an inhibitor of the PKA catalytic (C) subunit and as an activator for PDEs. Deletion mutagenesis has localized the sites of interaction to one of the cAMP-binding domains of RIα and the catalytic PDE domain of RegA whereas amide hydrogen/deuterium exchange mass spectrometry has revealed that the cAMP-binding site (phosphate binding cassette) along with proximal regions important for relaying allosteric changes mediated by cAMP, are important for interactions with the PDE catalytic domain of RegA. These sites of interactions together with measurements of cAMP dissociation rates demonstrate that binding of RegA facilitates dissociation of cAMP followed by hydrolysis of the released cAMP to 5'AMP. cAMP-free RIα generated as an end product remains bound to RegA. The PKA C-subunit then displaces RegA and reassociates with cAMP-free RIα to regenerate the inactive PKA holoenzyme thereby completing the termination step of cAMP signaling. These results reveal a novel mode of regulatory feedback between PDEs and RIα that has important consequences for PKA regulation and cAMP signal termination.     

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.     

Ligand-induced conformational and structural dynamics changes in Escherichia coli cyclic AMP receptor protein

Cyclic AMP receptor protein (CRP) regulates the expression of a large number of genes in E. coli. It is activated by cAMP binding, which leads to some yet undefined conformational changes. These changes do not involve significant redistribution of secondary structures. A potential mechanism of activation is a ligand-induced change in structural dynamics. Hence, the cAMP-mediated conformational and structural dynamics changes in the wild-type CRP were investigated using hydrogen-deuterium exchange and Fourier transform infrared spectroscopy. Upon cAMP binding, the two functional domains within the wild-type CRP undergo conformational and structural dynamics changes in two opposite directions. While the smaller DNA-binding domain becomes more flexible, the larger cAMP-binding domain shifts to a less dynamic conformation, evidenced by a faster and a slower amide H-D exchange, respectively. To a lesser extent, binding of cGMP, a nonfunctional analogue of cAMP, also stabilizes the cAMP-binding domain, but it fails to mimic the relaxation effect of cAMP on the DNA-binding domain. Despite changes in the conformation and structural dynamics, cAMP binding does not alter significantly the secondary structural composition of the wild-type CRP. The apparent difference between functional and nonfunctional analogues of cAMP is the ability of cAMP to effect an increase in the dynamic motions of the DNA binding 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.     

Active Site Coupling in PDE:PKA Complexes Promotes Resetting of Mammalian cAMP Signaling

Cyclic 3′5′ adenosine monophosphate (cAMP)-dependent-protein kinase (PKA) signaling is a fundamental regulatory pathway for mediating cellular responses to hormonal stimuli. The pathway is activated by high-affinity association of cAMP with the regulatory subunit of PKA and signal termination is achieved upon cAMP dissociation from PKA. Although steps in the activation phase are well understood, little is known on how signal termination/resetting occurs. Due to the high affinity of cAMP to PKA (K_D ∼ low nM), bound cAMP does not readily dissociate from PKA, thus begging the question of how tightly bound cAMP is released from PKA to reset its signaling state to respond to subsequent stimuli. It has been recently shown that phosphodiesterases (PDEs) can catalyze dissociation of bound cAMP and thereby play an active role in cAMP signal desensitization/termination. This is achieved through direct interactions with the regulatory subunit of PKA, thereby facilitating cAMP dissociation and hydrolysis. In this study, we have mapped direct interactions between a specific cyclic nucleotide phosphodiesterase (PDE8A) and a PKA regulatory subunit (RIα isoform) in mammalian cAMP signaling, by a combination of amide hydrogen/deuterium exchange mass spectrometry, peptide array, and computational docking. The interaction interface of the PDE8A:RIα complex, probed by peptide array and hydrogen/deuterium exchange mass spectrometry, brings together regions spanning the phosphodiesterase active site and cAMP-binding sites of RIα. Computational docking combined with amide hydrogen/deuterium exchange mass spectrometry provided a model for parallel dissociation of bound cAMP from the two tandem cAMP-binding domains of RIα. Active site coupling suggests a role for substrate channeling in the PDE-dependent dissociation and hydrolysis of cAMP bound to PKA. This is the first instance, to our knowledge, of PDEs directly interacting with a cAMP-receptor protein in a mammalian system, and highlights an entirely new class of binding partners for RIα. This study also highlights applications of structural mass spectrometry combined with computational docking for mapping dynamics in transient signaling protein complexes. Together, these results present a novel and critical role for phosphodiesterases in moderating local concentrations of cAMP in microdomains and signal resetting.     

R-subunit isoform specificity in protein kinase A: distinct features of protein interfaces in PKA types I and II by amide H/2H exchange mass spectrometry

The two isoforms (RI and RII) of the regulatory (R) subunit of cAMP-dependent protein kinase or protein kinase A (PKA) are similar in sequence yet have different biochemical properties and physiological functions. To further understand the molecular basis for R-isoform-specificity, the interactions of the RIIβ isoform with the PKA catalytic (C) subunit were analyzed by amide H/²H exchange mass spectrometry to compare solvent accessibility of RIIβ and the C subunit in their free and complexed states. Direct mapping of the RIIβ-C interface revealed important differences between the intersubunit interfaces in the type I and type II holoenzyme complexes. These differences are seen in both the R-subunits as well as the C-subunit. Unlike the type I isoform, the type II isoform complexes require both cAMP-binding domains, and ATP is not obligatory for high affinity interactions with the C-subunit. Surprisingly, the C-subunit mediates distinct, overlapping surfaces of interaction with the two R-isoforms despite a strong homology in sequence and similarity in domain organization. Identification of a remote allosteric site on the C-subunit that is essential for interactions with RII, but not RI subunits, further highlights the considerable diversity in interfaces found in higher order protein complexes mediated by the C-subunit of PKA.     

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.     

Active Site Coupling in PDE:PKA Complexes Promotes Resetting of Mammalian cAMP Signaling

Cyclic 3′5′ adenosine monophosphate (cAMP)-dependent-protein kinase (PKA) signaling is a fundamental regulatory pathway for mediating cellular responses to hormonal stimuli. The pathway is activated by high-affinity association of cAMP with the regulatory subunit of PKA and signal termination is achieved upon cAMP dissociation from PKA. Although steps in the activation phase are well understood, little is known on how signal termination/resetting occurs. Due to the high affinity of cAMP to PKA (K_D ∼ low nM), bound cAMP does not readily dissociate from PKA, thus begging the question of how tightly bound cAMP is released from PKA to reset its signaling state to respond to subsequent stimuli. It has been recently shown that phosphodiesterases (PDEs) can catalyze dissociation of bound cAMP and thereby play an active role in cAMP signal desensitization/termination. This is achieved through direct interactions with the regulatory subunit of PKA, thereby facilitating cAMP dissociation and hydrolysis. In this study, we have mapped direct interactions between a specific cyclic nucleotide phosphodiesterase (PDE8A) and a PKA regulatory subunit (RIα isoform) in mammalian cAMP signaling, by a combination of amide hydrogen/deuterium exchange mass spectrometry, peptide array, and computational docking. The interaction interface of the PDE8A:RIα complex, probed by peptide array and hydrogen/deuterium exchange mass spectrometry, brings together regions spanning the phosphodiesterase active site and cAMP-binding sites of RIα. Computational docking combined with amide hydrogen/deuterium exchange mass spectrometry provided a model for parallel dissociation of bound cAMP from the two tandem cAMP-binding domains of RIα. Active site coupling suggests a role for substrate channeling in the PDE-dependent dissociation and hydrolysis of cAMP bound to PKA. This is the first instance, to our knowledge, of PDEs directly interacting with a cAMP-receptor protein in a mammalian system, and highlights an entirely new class of binding partners for RIα. This study also highlights applications of structural mass spectrometry combined with computational docking for mapping dynamics in transient signaling protein complexes. Together, these results present a novel and critical role for phosphodiesterases in moderating local concentrations of cAMP in microdomains and signal resetting.     

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.     

Regulatory subunit of cAMP-dependent protein kinase inhibits phosphoprotein phosphatase

The activity of a purified high molecular weight phosphoprotein phosphatase was inhibited by purified type II cAMP-dependent protein kinase. This effect required cAMP and was obtained in the absence of ATP. The isolated type II regulatory subunits (R-subunits) from several species also inhibited the phosphatase activity in both crude extracts and purified preparations. Half maximal inhibition was observed at 0.06-0.25 microM, well within the physiological range of R-subunit concentrations. The inhibitory potency of R-subunit was greater using the thiophosphorylated form. Limited trypsinization of the R-subunit abolished the inhibitory activity. The C-subunit released the bound cAMP when combined with R-subunit, but the phosphatase did not, implying that the inhibited species is a R.cAMP-phosphatase complex. The results suggest that the R-subunit might have at least one physiological role in addition to inhibition of the C-subunit, i.e., inhibition of phosphatase. The latter would occur only when cAMP is elevated.     

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.     

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.     

Deuterium exchange and mass spectrometry reveal the interaction differences of two synthetic modulators of RXRalpha LBD

Protein amide hydrogen/deuterium (H/D) exchange was used to compare the interactions of two antagonists, UVI 2112 and UVI 3003, with that of the agonist, 9-cis-retinoic acid, upon binding to the human retinoid X receptor alpha ligand-binding domain (hRXRalpha LBD) homodimer. Analysis of the H/D content by mass spectrometry showed that in comparison to 9-cis-retinoic acid, the antagonists provide much greater protection toward deuterium exchange-in throughout the protein, suggesting that the protein-antagonist complex adopts a more restricted conformation or ensemble of conformations in which solvent accesses to amide protons are reduced. A comparison between the two antagonists shows that UVI 3003 is more protective in the C-terminal region due to the extra hydrophobic interactions derived from the atoms in the benzene ring of the carboxylic acid chain. It was less protective within regions comprising peptides 271-278 and 326-330 due to differences in conformational orientation, and/or shorter carboxylic acid chain length. Decreased deuterium exchange-in in the segment 234-239 where the residues do not involve interactions with the ligand was observed with the two antagonists, but not with 9-cis-RA. The amide protons of helix 12 of the agonist- or antagonist-occupied protein in solution have the same deuterium exchange rates as the unliganded protein, supporting a suggestion made previously that helix 12 can cover the occupied binding cavity only with the cofactor present to adjust its location.     

Conformational analysis of Epac activation using amide hydrogen/deuterium exchange mass spectrometry

Exchange proteins directly activated by cAMP (Epac) play important roles in mediating the effects of cAMP through the activation of downstream small GTPases, Rap. To delineate the mechanism of Epac activation, we probed the conformation and structural dynamics of Epac using amide hydrogen/deuterium exchange and structural modeling. Our studies show that cAMP induces significant conformational changes that lead to a spatial rearrangement of the regulatory components of Epac and allows the exposure of the catalytic core for effector binding without imposing significant conformational change on the catalytic core. Homology modeling and comparative structural analyses of the cAMP binding domains of Epac and cAMP-dependent protein kinase (PKA) lead to a model of Epac activation, in which Epac and PKA activation by cAMP employs the same underlying principle, although the detailed structural and conformational changes associated with Epac and PKA activation are significantly different.     

Mechanism of intracellular cAMP sensor Epac2 activation: cAMP-induced conformational changes identified by amide hydrogen/deuterium exchange mass spectrometry (DXMS)

Epac2, a guanine nucleotide exchange factor, regulates a wide variety of intracellular processes in response to second messenger cAMP. In this study, we have used peptide amide hydrogen/deuterium exchange mass spectrometry to probe the solution structural and conformational dynamics of full-length Epac2 in the presence and absence of cAMP. The results support a mechanism in which cAMP-induced Epac2 activation is mediated by a major hinge motion centered on the C terminus of the second cAMP binding domain. This conformational change realigns the regulatory components of Epac2 away from the catalytic core, making the later available for effector binding. Furthermore, the interface between the first and second cAMP binding domains is highly dynamic, providing an explanation of how cAMP gains access to the ligand binding sites that, in the crystal structure, are seen to be mutually occluded by the other cAMP binding domain. Moreover, cAMP also induces conformational changes at the ionic latch/hairpin structure, which is directly involved in RAP1 binding. These results suggest that in addition to relieving the steric hindrance imposed upon the catalytic lobe by the regulatory lobe, cAMP may also be an allosteric modulator directly affecting the interaction between Epac2 and RAP1. Finally, cAMP binding also induces significant conformational changes in the dishevelled/Egl/pleckstrin (DEP) domain, a conserved structural motif that, although missing from the active Epac2 crystal structure, is important for Epac subcellular targeting and in vivo functions.