"EPAC1: Molecular architecture, physiological regulation, and therapeutic implications in diseases".

The exchange protein directly activated by cAMP (EPAC) is a key receptor of cAMP in eukaryotes and controls critical signaling pathways. Currently, no residue resolution information is available on the full-length EPAC dynamics, which are known to be pivotal determinants of allostery. In addition, no information is presently available on the intermediates for the classical induced fit and conformational selection activation pathways. Here these questions are addressed through molecular dynamics simulations on five key states along the thermodynamic cycle for the cAMP-dependent activation of a fully functional construct of EPAC2, which includes the cAMP-binding domain and the integral catalytic region. The simulations are not only validated by the agreement with the experimental trends in cAMP-binding domain dynamics determined by NMR, but they also reveal unanticipated dynamic attributes, rationalizing previously unexplained aspects of EPAC activation and autoinhibition. Specifically, the simulations show that cAMP binding causes an extensive perturbation of dynamics in the distal catalytic region, assisting the recognition of the Rap1b substrate. In addition, analysis of the activation intermediates points to a possible hybrid mechanism of EPAC allostery incorporating elements of both the induced fit and conformational selection models. In this mechanism an entropy compensation strategy results in a low free-energy pathway of activation. Furthermore, the simulations indicate that the autoinhibitory interactions of EPAC are more dynamic than previously anticipated, leading to a revised model of autoinhibition in which dynamics fine tune the stability of the autoinhibited state, optimally sensitizing it to cAMP while avoiding constitutive activation.

The activation of protein kinase A involves the synergistic binding of cAMP to two cAMP binding sites on the inhibitory R subunit, causing release of the C subunit, which subsequently can carry out catalysis. We used NMR to structurally characterize in solution the RIalpha-(98-381) subunit, a construct comprising both cyclic nucleotide binding (CNB) domains, in the presence and absence of cAMP, and map the effects of cAMP binding at single residue resolution. Several conformationally disordered regions in free RIalpha become structured upon cAMP binding, including the interdomain alphaC:A and alphaC':A helices that connect CNB domains A and B and are primary recognition sites for the C subunit. NMR titration experiments with cAMP, B site-selective 2-Cl-8-hexylamino-cAMP, and A site-selective N(6)-monobutyryl-cAMP revealed that cyclic nucleotide binding to either the B or A site affected the interdomain helices. The NMR resonances of this interdomain region exhibited chemical shift changes upon ligand binding to a single site, either site B or A, with additional changes occurring upon binding to both sites. Such distinct, stepwise conformational changes in this region reflect the synergistic interplay between the two sites and may underlie the positive cooperativity of cAMP activation of the kinase. Furthermore, nucleotide binding to the A site also affected residues within the B domain. The present NMR study provides the first structural evidence of unidirectional allosteric communication between the sites. Trp(262), which lines the CNB A site but resides in the sequence of domain B, is an important structural determinant for intersite communication.

Cyclic nucleotides (cAMP and cGMP) regulate multiple intracellular processes and are thus of a great general interest for molecular and structural biologists. To study the allosteric mechanism of different cyclic nucleotide binding (CNB) domains, we compared cAMP-bound and cAMP-free structures (PKA, Epac, and two ionic channels) using a new bioinformatics method: local spatial pattern alignment. Our analysis highlights four major conserved structural motifs: 1) the phosphate binding cassette (PBC), which binds the cAMP ribose-phosphate, 2) the “hinge,” a flexible helix, which contacts the PBC, 3) the β2,3 loop, which provides precise positioning of an invariant arginine from the PBC, and 4) a conserved structural element consisting of an N-terminal helix, an eight residue loop and the A-helix (N3A-motif). The PBC and the hinge were included in the previously reported allosteric model, whereas the definition of the β2,3 loop and the N3A-motif as conserved elements is novel. The N3A-motif is found in all cis-regulated CNB domains, and we present a model for an allosteric mechanism in these domains. Catabolite gene activator protein (CAP) represents a trans-regulated CNB domain family: it does not contain the N3A-motif, and its long range allosteric interactions are substantially different from the cis-regulated CNB domains.

Cyclic AMP synthesized by Mycobacterium tuberculosis has been shown to play a role in pathogenesis. However, the high levels of intracellular cAMP found in both pathogenic and non-pathogenic mycobacteria suggest that additional and important biological processes are regulated by cAMP in these organisms. We describe here the biochemical characterization of novel cAMP-binding proteins in M. smegmatis and M. tuberculosis (MSMEG_5458 and Rv0998, respectively) that contain a cyclic nucleotide binding domain fused to a domain that shows similarity to the GNAT family of acetyltransferases. We detect protein lysine acetylation in mycobacteria and identify a universal stress protein (USP) as a substrate of MSMEG_5458. Acetylation of a lysine residue in USP is regulated by cAMP, and using a strain deleted for MSMEG_5458, we show that USP is indeed an in vivo substrate for MSMEG_5458. The Rv0998 protein shows a strict cAMP-dependent acetylation of USP, despite a lower affinity for cAMP than MSMEG_5458. Thus, this report not only represents the first demonstration of protein lysine acetylation in mycobacteria but also describes a unique functional interplay between a cyclic nucleotide binding domain and a protein acetyltransferase.

Structural and evolutionary divergence of cyclic nucleotide binding domains in eukaryotic pathogens: Implications for drug design

The regulatory subunits of cAMP-dependent protein kinase (PKA) are the major receptors of cAMP in most eukaryotic cells. As the cyclic nucleotide binding (CNB) domains release cAMP and bind to the catalytic subunit of PKA, they undergo a major conformational change. The change is mediated by the B/C helix in CNB-A, which extends into one long helix that now separates the two CNB domains and docks onto the surface of the catalytic subunit. We explore here the role of three key residues on the B/C helix that dock onto the catalytic subunit, Arg226, Leu233, and Met 234. By replacing each residue with Ala, we show that each contributes significantly to creating the R:C interface. By also deleting the second CNB domain (CNB-B), we show furthermore that CNB-B is a critical part of the cAMP-induced conformational switch that dislodges the B/C helix from the surface of the catalytic subunit. Without CNB-B the K(a) for activation by cAMP increases from 80 to 1000 nM. Replacing any of the key interface residues with Ala reduces the K(a) to 25-40 nM. Leu233 and M234 contribute to a hydrophobic latch that binds the B/C helix onto the large lobe of the C-subunit, while Arg226 is part of an electrostatic switch that couples the B/C helix to the phosphate binding cassette where the cAMP docks.

BackgroundCyclic nucleotide-gated channels (CNGCs) are Ca2+-permeable cation transport channels, which are present in both animal and plant systems. They have been implicated in the uptake of both essential and toxic cations, Ca2+ signaling, pathogen defense, and thermotolerance in plants. To date there has not been a genome-wide overview of the CNGC gene family in any economically important crop, including rice (Oryza sativa L.). There is an urgent need for a thorough genome-wide analysis and experimental verification of this gene family in rice.ResultsIn this study, a total of 16 full length rice CNGC genes distributed on chromosomes 1–6, 9 and 12, were identified by employing comprehensive bioinformatics analyses. Based on phylogeny, the family of OsCNGCs was classified into four major groups (I-IV) and two sub-groups (IV-A and IV- B). Likewise, the CNGCs from all plant lineages clustered into four groups (I-IV), where group II was conserved in all land plants. Gene duplication analysis revealed that both chromosomal segmentation (OsCNGC1 and 2, 10 and 11, 15 and 16) and tandem duplications (OsCNGC1 and 2) significantly contributed to the expansion of this gene family. Motif composition and protein sequence analysis revealed that the CNGC specific domain “cyclic nucleotide-binding domain (CNBD)” comprises a “phosphate binding cassette” (PBC) and a “hinge” region that is highly conserved among the OsCNGCs. In addition, OsCNGC proteins also contain various other functional motifs and post-translational modification sites. We successively built a stringent motif: (LI-X(2)-[GS]-X-[FV]-X-G-[1]-ELL-X-W-X(12,22)-SA-X(2)-T-X(7)-[EQ]-AF-X-L) that recognizes the rice CNGCs specifically. Prediction of cis-acting regulatory elements in 5′ upstream sequences and expression analyses through quantitative qPCR demonstrated that OsCNGC genes were highly responsive to multiple stimuli including hormonal (abscisic acid, indoleacetic acid, kinetin and ethylene), biotic (Pseudomonas fuscovaginae and Xanthomonas oryzae pv. oryzae) and abiotic (cold) stress.ConclusionsThere are 16 CNGC genes in rice, which were probably expanded through chromosomal segmentation and tandem duplications and comprise a PBC and a “hinge” region in the CNBD domain, featured by a stringent motif. The various cis-acting regulatory elements in the upstream sequences may be responsible for responding to multiple stimuli, including hormonal, biotic and abiotic stresses.Electronic supplementary materialThe online version of this article (doi:10.1186/1471-2164-15-853) contains supplementary material, which is available to authorized users.

Ras and Rap proteins are closely related small GTPases. Whereas Ras is known for its role in cell proliferation and survival, Rap1 is predominantly involved in cell adhesion and cell junction formation. Ras and Rap are regulated by different sets of guanine nucleotide exchange factors and GTPase-activating proteins, determining one level of specificity. In addition, although the effector domains are highly similar, Rap and Ras interact with largely different sets of effectors, providing a second level of specificity. In this review, we discuss the regulatory proteins and effectors of Ras and Rap, with a focus on those of Rap.

Chapter 186 - Epac, cAMP-Regulated Guanine Nucleotide Exchange Factors for Rap1 and Rap2

Ligand-gated cation channels are a frequent component of signaling cascades in eukaryotes. Eukaryotes contain numerous diverse gene families encoding ion channels, some of which are shared and some of which are unique to particular kingdoms. Among the many different types are cyclic nucleotide-gated channels (CNGCs). CNGCs are cation channels with varying degrees of ion conduction selectivity. They are implicated in numerous signaling pathways and permit diffusion of divalent and monovalent cations, including Ca2+ and K+. CNGCs are present in both plant and animal cells, typically in the plasma membrane; recent studies have also documented their presence in prokaryotes. All eukaryote CNGC polypeptides have a cyclic nucleotide-binding domain and a calmodulin binding domain as well as a six transmembrane/one pore tertiary structure. This review summarizes existing knowledge about the functional domains present in these cation-conducting channels, and considers the evidence indicating that plant and animal CNGCs evolved separately. Additionally, an amino acid motif that is only found in the phosphate binding cassette and hinge regions of plant CNGCs, and is present in all experimentally confirmed CNGCs but no other channels was identified. This CNGC-specific amino acid motif provides an additional diagnostic tool to identify plant CNGCs, and can increase confidence in the annotation of open reading frames in newly sequenced genomes as putative CNGCs. Conversely, the absence of the motif in some plant sequences currently identified as probable CNGCs may suggest that they are misannotated or protein fragments.

Hyperpolarization‐activated cyclic nucleotide‐gated 2 (HCN2) channels regulate action potential firing in nociceptors and are critical mediators of neuronal hyperexcitability in response to inflammation and nerve injury. These channels are activated by membrane hyperpolarization and potentiated by direct cAMP binding to their C‐terminal cyclic nucleotide‐binding domain (CNBD). Although a role for cAMP in modulating HCN2 activity and contributing to neuropathic pain has been hypothesized, direct evidence has been lacking. To test this causal link, here we employ TRIP8b nano , comprising a minimal peptide derivative from the brain protein TRIP8b that selectively antagonizes cAMP binding to HCN channels. TRIP8b nano effectively abolished cAMP‐mediated potentiation of HCN2 currents in small‐diameter dorsal root ganglion (DRG) neurons, validating its utility as a functional inhibitor. In a rat model of neuropathic pain, DRG‐targeted expression of TRIP8b nano significantly reduced mechanical and thermal hypersensitivity. These findings provide the first direct evidence that cAMP binding to HCN2 channels drives nociceptor hyperexcitability and neuropathic pain and establishes disruption of this interaction as a promising therapeutic strategy. image Key points Activation of HCN2 channels is potentiated by cAMP binding to their cyclic nucleotide binding domain (CNBD). TRIP8b nano abolishes cAMP binding to CNBD, thus inhibiting potentiation of HCN2 currents in both HEK 293T cells and rat DRG neurons. TRIP8b nano reduces mechanical and thermal hypersensitivity in a rat model of neuropathic pain. Our findings confirm a direct role of cAMP–HCN2 signalling in neuropathic pain and suggest a new therapeutic target.

Further understanding of vascular endothelial barrier modulation will better enable clinical control of fluid balance and aid drug delivery. Acute inflammatory mediators increase intracellular Ca2+ very rapidly in vascular endothelium, leading to breakdown of the barrier. Investigations both in vivo and in cell culture show that this response is strongly inhibited by increased intracellular cAMP. Ca2+ and cAMP signalling pathways are subject to potential crosstalk through Ca2+-regulated adenylate cyclase 6 (AC6) and Ca2+-dependent phosphodiesterase I as well as interaction at converging downstream effectors which regulate endothelial cell contraction and endothelial junctions. Ca2+-sensitive fluorophores enable rapid optical-based measurement of intracellular Ca2+. However, understanding pathway crosstalk has been hampered by poor temporal resolution of cAMP measurement. Previous studies of cAMP in endothelium used enzyme immunoassays and yielded limited temporal information (Cioffi et al. 2002; Baumer et al. 2008). Fluorescence resonance energy transfer (FRET) has been used previously to determine changes in cAMP concentration but use of the regulatory and catalytic subunits of protein kinase A (PKA) was problematic (Adams et al. 1991). A new technique enables FRET measurement based on a single cAMP binding domain and yields a fast, sensitive indicator that has no catalytic or targeting domains to interfere with cellular processes (Nikolaev et al. 2004). The latter research group has now used their technique to investigate endothelium. The study by Werthmann et al. (2009) in this issue of The Journal of Physiology uses the new FRET assay to measure cAMP in real time using cultured endothelial cells stimulated with thrombin and pre-stimulated with isoproterenol to elevate cAMP. The data clearly demonstrate that the rapid initial Ca2+ rise is closely followed by transient suppression of cAMP concentration. This thrombin-induced fall in cAMP was abolished by prior transfection with siRNA to downregulate AC6, thus directly implicating Ca2+-inhibited AC6 in rapid cAMP regulation. While the study yields important new data on early intracellular signals after thrombin stimulation, questions remain about the link between these mechanisms and endothelial barrier regulation. For example, while both the Ca2+ increase and subsequent cAMP decrease reach respective peaks in seconds, the permeability increase of thrombin-stimulated endothelial monolayers that can be measured (in the absence of pre-stimulation of cAMP) does not peak for about 10 min in vivo and can last an hour or more in cell culture (Baumer et al. 2009) even though the present study suggests cAMP levels return toward pre-thrombin levels in 1.5 min. Several potential pathways lead from Ca2+ and cAMP to modulation of the adhesion and contraction of endothelial cells via both PKA and small GTPases (Adamson et al. 2008). Rho family GTPases RhoA and Rac1 regulate the actin cytoskeleton and endothelial barrier and are potential targets of modulated cAMP pathways; cAMP has been shown to activate Rac1 via activation of Ras family GTPase Rap1 through the GTP exchange factor (GEF) Epac. Further investigations will require measurement of changes in these GTPases under conditions where the time course of cAMP is followed. This will require use of inflammatory agents such as bradykinin and platelet-activating factor that do not stimulate the RhoA pathway in intact microvessels as much as the thrombin response in cell culture (Adamson et al. 2003). Also the role of an increase in cAMP in both cAMP pre-stimulated and non-pre-stimulated cells that followed the initial reduction about 60 s after thrombin application needs evaluation. It is notable that pre-stimulation with isoproterenol or forskolin was required in the experiments of Werthmann et al. to demonstrate a thrombin-induced decrease in cAMP concentration. As elevated cAMP blocks permeability increase, any thrombin-induced change in permeability could not be measured under the same conditions that cAMP concentration was measured in this study. Thus, an important goal will be to determine whether cAMP can be monitored at lower concentrations in the absence of pharmacological stimulation or whether such changes can be measured in vivo, where endothelium may be in a different state perhaps having higher basal cAMP. The recent collaborative study by the two Wurzburg groups using thrombin to stimulate a drop in trans-endothelial resistance may point the way using a variety of cell culture and intact endothelial barriers (Baumer et al. 2009). A focus on signalling pathways, changes in permeability and possible spatial imaging of cAMP will enable further investigation of vascular permeability regulation.

BackgroundThe reactivity enhancement of pain sensitive neurons in the nervous system is a feature of the pathogenesis for neuropathic pain (NP), yet the underlying mechanisms need to be fully understood. In this study, we made an attempt to clarify the NP-related hub genes and signaling pathways so as to provide effective diagnostic and therapeutic methods toward NP.MethodsMicroarray expression profile GSE30691 including the mRNA-seq data of the spared nerve injury (SNI)-induced NP rats was accessed from the GEO database. Then, genes associated with NP development were screened using differential analysis along with random walk with restart (RWR). GO annotation and KEGG pathway analyses were performed to explore the biological functions and signaling pathways where the genes were activated. Afterward, protein-protein interaction (PPI) analysis and GO analysis were conducted to further identify the hub genes which showed an intimate correlation with NP development.ResultsTotally 94 genes associated with NP development were screened by differential analysis and RWR analysis, and they were observed to be predominantly enriched in hormone secretion and transport, cAMP signaling pathway and other NP occurrence associated functions and pathways. Thereafter, the 94 genes were subjected to PPI analysis to find the genes much more associated with NP and a functional module composed of 48 genes were obtained. 8 hub genes including C3, C1qb, Ccl2, Cxcl13, Timp1, Fcgr2b, Gal, and Lyz2 were eventually identified after further association and functional enrichment analyses, and the expression of these 8 genes were all higher in SNI rats by comparison with those in Sham rats.ConclusionBased on the data collected from GEO database, this study discovered 8 hub genes that were closely related to NP occurrence and development, which help to provide potent theoretical basis for NP treatment.

We took a discovery approach to explore the actions of cAMP and two of its analogs, one a cAMP mimic ((S(p))-adenosine cyclic 3':5'-monophosphorothioate ((S(p))-cAMPS)) and the other a diastereoisomeric antagonist ((R(p))-cAMPS), on a model system of the type Iα cyclic AMP-dependent protein kinase holoenzyme, RIα(91-244)·C-subunit, by using fluorescence spectroscopy and amide H/(2)H exchange mass spectrometry. Specifically, for the fluorescence experiments, fluorescein maleimide was conjugated to three cysteine single residue substitution mutants, R92C, T104C, and R239C, of RIα(91-244), and the effects of cAMP, (S(p))-cAMPS, and (R(p))-cAMPS on the kinetics of R-C binding and the time-resolved anisotropy of the reporter group at each conjugation site were measured. For the amide exchange experiments, ESI-TOF mass spectrometry with pepsin proteolytic fragmentation was used to assess the effects of (R(p))-cAMPS on amide exchange of the RIα(91-244)·C-subunit complex. We found that cAMP and its mimic perturbed at least parts of the C-subunit interaction Sites 2 and 3 but probably not Site 1 via reduced interactions of the linker region and αC of RIα(91-244). Surprisingly, (R(p))-cAMPS not only increased the affinity of RIα(91-244) toward the C-subunit by 5-fold but also produced long range effects that propagated through both the C- and R-subunits to produce limited unfolding and/or enhanced conformational flexibility. This combination of effects is consistent with (R(p))-cAMPS acting by enhancing the internal entropy of the R·C complex. Finally, the (R(p))-cAMPS-induced increase in affinity of RIα(91-244) toward the C-subunit indicates that (R(p))-cAMPS is better described as an inverse agonist because it decreases the fractional dissociation of the cyclic AMP-dependent protein kinase holoenzyme and in turn its basal activity.

cAMP (adenosine 3',5'-cyclic monophosphate) is a ubiquitous second messenger that activates a multitude of essential cellular responses. Two key receptors for cAMP in eukaryotes are protein kinase A (PKA) and the exchange protein directly activated by cAMP (EPAC), which is a recently discovered guanine nucleotide exchange factor (GEF) for the small GTPases Rap1 and Rap2. Previous attempts to investigate the mechanism of allosteric activation of eukaryotic cAMP-binding domains (CBDs) at atomic or residue resolution have been hampered by the instability of the apo form, which requires the use of mixed apo/holo systems, that have provided only a partial picture of the CBD apo state and of the allosteric networks controlled by cAMP. Here, we show that, unlike other eukaryotic CBDs, both apo and cAMP-bound states of the EPAC1 CBD are stable under our experimental conditions, providing a unique opportunity to define at an unprecedented level of detail the allosteric interactions linking two critical functional sites of this CBD. These are the phosphate binding cassette (PBC), where cAMP binds, and the N-terminal helical bundle (NTHB), which is the site of the inhibitory interactions between the regulatory and catalytic regions of EPAC. Specifically, the combined analysis of the cAMP-dependent changes in chemical shifts, 2 degrees structure probabilities, hydrogen/hydrogen exchange (H/H) and hydrogen/deuterium exchange (H/D) protection factors reveals that the long-range communication between the PBC and the NTHB is implemented by two distinct intramolecular cAMP-signaling pathways, respectively, mediated by the beta2-beta3 loop and the alpha6 helix. Docking of cAMP into the PBC perturbs the NTHB inner core packing and the helical probabilities of selected NTHB residues. The proposed model is consistent with the allosteric role previously hypothesized for L273 and F300 based on site-directed mutagenesis; however, our data show that such a contact is part of a significantly more extended allosteric network that, unlike PKA, involves a tight coupling between the alpha- and beta-subdomains of the EPAC CBD. The proposed mechanism of allosteric activation will serve as a basis to understand agonism and antagonism in the EPAC system and provides also a general paradigm for how small ligands control protein-protein interfaces.