Mapping sites in guanylyl cyclase activating protein-1 required for regulation of photoreceptor membrane guanylyl cyclases

Guanylyl cyclase activating protein (GCAP)-1 regulates photoreceptor membrane guanylyl cyclase, RetGC, in a Ca2+-sensitive manner. It contains four Ca2+-binding motifs, EF-hands, three of which are capable of binding Ca2+. GCAP-1 activates RetGC in low Ca2+ and inhibits it in high Ca2+. In this study we used deletion and substitution analysis to identify regions of GCAP-1 sequence that are specifically required for inhibition and activation. A COOH-terminal sequence within Met157 to Arg182 is required for activation but not for inhibition of RetGC. We localized one essential stretch to 5 residues from Arg178 to Arg182. Another sequence essential for activation is within the N-terminal residues Trp21 to Thr27. The region between EF-hands 1 and 3 of GCAP-1 also contains elements needed for activation of RetGC. Finally, we found that inhibition of RetGC requires the first 9 amino-terminal residues of GCAP-1, but none of the residues from Gln33 to the COOH-terminal Gly205 are specifically required for inhibition. The ability of GCAP-1 mutants to regulate RetGC was tested on total guanylyl cyclase activity present in rod outer segments. In addition, the key mutants were also shown to produce similar effects on recombinant bovine outer segment cyclases GC1 and GC2.     

Factors that determine Ca2+ sensitivity of photoreceptor guanylyl cyclase. Kinetic analysis of the interaction between the Ca2+-bound and the Ca2+-free guanylyl cyclase activating proteins (GCAPs) and recombinant photoreceptor guanylyl cyclase 1 (RetGC-1)

We explored the possibility that, in the regulation of an effector enzyme by a Ca(2+)-sensor protein, the actual Ca(2+) sensitivity of the effector enzyme can be determined not only by the affinity of the Ca(2+)-sensor protein for Ca(2+) but also by the relative affinities of its Ca(2+)-bound versus Ca(2+)-free form for the effector enzyme. As a model, we used Ca(2+)-sensitive activation of photoreceptor guanylyl cyclase (RetGC-1) by guanylyl cyclase activating proteins (GCAPs). A substitution Arg(838)Ser in RetGC-1 found in human patients with cone-rod dystrophy is known to shift the Ca(2+) sensitivity of RetGC-1 regulation by GCAP-1 to a higher Ca(2+) range. We find that at physiological concentrations of Mg(2+) this mutation increases the free Ca(2+) concentration required for half-maximal inhibition of the cyclase from 0.27 to 0.61 microM. Similar to rod outer segment cyclase, Ca(2+) sensitivity of recombinant RetGC-1 is strongly affected by Mg(2+), but the shift in Ca(2+) sensitivity for the R838S mutant relative to the wild type is Mg(2+)-independent. We determined the apparent affinity of the wild-type and the mutant RetGC-1 for both Ca(2+)-bound and Ca(2+)-free GCAP-1 and found that the net shift in Ca(2+) sensitivity of the R838S RetGC-1 observed in vitro can arise predominantly from the change in the affinity of the mutant cyclase for the Ca(2+)-free versus Ca(2+)-loaded GCAP-1. Our findings confirm that the dynamic range for RetGC regulation by Ca(2+)/GCAP is determined by both the affinity of GCAP for Ca(2+) and relative affinities of the effector enzyme for the Ca(2+)-free versus Ca(2+)-loaded GCAP.     

Studying the structure and regulation of soluble guanylyl cyclase

Soluble guanylyl cyclase acts as the receptor for the signaling molecule nitric oxide. The enzyme consists of two different subunits. Each subunit shows the cyclase catalytic domain, which is also conserved in the membrane-bound guanylyl cyclases and the adenylyl cyclases. The N-terminal regions of the subunits are responsible for binding of the prosthetic heme group of the enzyme, which is required for the stimulatory effect of nitric oxide (NO). The five-coordinated ferrous heme displays a histidine as the axial ligand; activation of soluble guanylyl cyclase by NO is initiated by binding of NO to the heme iron and proceeds via breaking of the histidine-to-iron bond. Recently, a novel pharmacological and possibly physiological principle of guanylyl cyclase sensitization was demonstrated. The substance YC-1 has been shown to activate the enzyme independent of NO, to potentiate the effect of submaximally effective NO concentrations, and to turn carbon monoxide into an effective activator of soluble guanylyl cyclase.     

Identification of residues in the heme domain of soluble guanylyl cyclase that are important for basal and stimulated catalytic activity

Nitric oxide signals through activation of soluble guanylyl cyclase (sGC), a heme-containing heterodimer. NO binds to the heme domain located in the N-terminal part of the β subunit of sGC resulting in increased production of cGMP in the catalytic domain located at the C-terminal part of sGC. Little is known about the mechanism by which the NO signaling is propagated from the receptor domain (heme domain) to the effector domain (catalytic domain), in particular events subsequent to the breakage of the bond between the heme iron and Histidine 105 (H105) of the β subunit. Our modeling of the heme-binding domain as well as previous homologous heme domain structures in different states point to two regions that could be critical for propagation of the NO activation signal. Structure-based mutational analysis of these regions revealed that residues T110 and R116 in the αF helix-β1 strand, and residues I41 and R40 in the αB-αC loop mediate propagation of activation between the heme domain and the catalytic domain. Biochemical analysis of these heme mutants allows refinement of the map of the residues that are critical for heme stability and propagation of the NO/YC-1 activation signal in sGC.     

Crystal structure of the Alpha subunit PAS domain from soluble guanylyl cyclase

Soluble guanylate cyclase (sGC) is a heterodimeric heme protein of ～150 kDa and the primary nitric oxide receptor. Binding of NO stimulates cyclase activity, leading to regulation of cardiovascular physiology and providing attractive opportunities for drug discovery. How sGC is stimulated and where candidate drugs bind remains unknown. The α and β sGC chains are each composed of Heme‐Nitric Oxide Oxygen (H‐NOX), Per‐ARNT‐Sim (PAS), coiled‐coil and cyclase domains. Here, we present the crystal structure of the α₁ PAS domain to 1.8 Å resolution. The structure reveals the binding surfaces of importance to heterodimer function, particularly with respect to regulating NO binding to heme in the β₁ H‐NOX domain. It also reveals a small internal cavity that may serve to bind ligands or participate in signal transduction.     

Olfaction and odor discrimination are mediated by the C. elegans guanylyl cyclase ODR-1

Animals in complex environments must discriminate between salient and uninformative sensory cues. Caenorhabditis elegans uses one pair of olfactory neurons called AWC to sense many different odorants, yet the animal can distinguish each odorant from the others in discrimination assays. We demonstrate that the transmembrane guanylyl cyclase ODR-1 is essential for responses to all AWC-sensed odorants. ODR-1 appears to be a shared signaling component downstream of odorant receptors. Overexpression of ODR-1 protein indicates that ODR-1 can influence odor discrimination and adaptation as well as olfaction. Adaptation to one odorant, butanone, is disrupted by ODR-1 overexpression. Olfactory discrimination is also disrupted by ODR-1 overexpression, probably by overproduction of the shared second messenger cGMP. We propose that AWC odorant signaling pathways are insulated to permit odor discrimination.     

Identification of a domain in guanylyl cyclase-activating protein 1 that interacts with a complex of guanylyl cyclase and tubulin in photoreceptors

The membrane-bound guanylyl cyclase in rod photoreceptors is activated by guanylyl cyclase-activating protein 1 (GCAP-1) at low free [Ca2+]. GCAP-1 is a Ca2+-binding protein and belongs to the superfamily of EF-hand proteins. We created an oligopeptide library of overlapping peptides that encompass the entire amino acid sequence of GCAP-1. Peptides were used in competitive screening assays to identify interaction regions in GCAP-1 that directly bind the guanylyl cyclase in bovine photoreceptor cells. We found four regions in GCAP-1 that participate in regulating guanylyl cyclase. A 15-amino acid peptide located adjacent to the second EF-hand motif (Phe73-Lys87) was identified as the main interaction domain. Inhibition of GCAP-1-stimulated guanylyl cyclase activity by the peptide Phe73-Lys87 was completely relieved when an excess amount of GCAP-1 was added. An affinity column made from this peptide was able to bind a complex of photoreceptor guanylyl cyclase and tubulin. Using an anti-GCAP-1 antibody, we coimmunoprecipitated GCAP-1 with guanylyl cyclase and tubulin. Complex formation between GCAP-1 and guanylyl cyclase was observed independent of [Ca2+]. Our experiments suggest that there exists a tight association of guanylyl cyclase and tubulin in rod outer segments.     

Cell-specific expression and regulation of soluble guanylyl cyclase alpha 1 and beta 1 subunits in the rat ovary

Soluble guanylyl cyclase (sGC) is activated by nitric oxide (NO) and carbon monoxide, resulting in cGMP production. Recent studies indicate that NO and cGMP influence ovarian functions. However, little information is available regarding the ovarian expression of sGC. The present study examined sGC alpha(1) and beta(1) subunit protein levels in the ovary during postnatal development, gonadotropin-induced follicle growth, ovulation, and luteinization as well as in cultured rat granulosa cells. In postnatal rats, sGC alpha(1) subunit immunoreactivity was high in granulosa cells of primordial and primary follicles on Day 5 but low in granulosa cells of larger follicles on Days 10 and 19. Theca cells of developing follicles, but not stromal cells, also demonstrated moderate sGC alpha(1) immunoreactivity. In gonadotropin- treated immature rats, intense sGC alpha(1) subunit staining was similarly observed in granulosa cells of primordial and primary follicles, but such staining was low in granulosa cells of small antral follicles and undetectable in granulosa cells of large antral and preovulatory follicles. Following ovulation, corpora lutea expressed moderate sGC alpha(1) immunoreactivity. Similar ovarian localization and expression patterns were seen for sGC beta(1), indicating regulated coexpression of sGC subunits. Immunoblot analysis revealed no change in total ovarian sGC alpha(1) and beta(1) subunit protein levels during gonadotropin treatment. Similarly, no effect of FSH on sGC subunit protein levels was apparent in cultured granulosa cells. These findings indicate regulated, cell- specific patterns of sGC expression in the ovary and are consistent with roles for cGMP in modulating ovarian functions.     

Nitric oxide activation of soluble guanylyl cyclase reveals high and low affinity sites that mediate allosteric inhibition by calcium

Cyclic GMP (cGMP) and Ca(2+) regulate opposing mechanisms in (patho)physiological processes reflected in the reciprocal regulation of their intracellular concentrations. Although mechanisms by which cGMP regulates [Ca(2+)](i) have been described, those by which Ca(2+) regulates [cGMP](i) are less well understood. In the present study, Ca(2+) inhibited purified sGC activated by sodium nitroprusside (SNP), a precursor of nitric oxide (NO), employing Mg-GTP as substrate in a concentration-dependent fashion, but was without effect on basal enzyme activity. Ca(2+) inhibited sGC stimulated by protoporphyrin IX or YC-1 suggesting that inhibition was not NO-dependent. In contrast, Ca(2+) was without effect on sGC activated by SNP employing Mn-GTP as substrate, demonstrating that inhibition did not reflect displacement of heme from sGC. Ligand activation of sGC unmasked negative allosteric sites of high (K(i) similar 10(-7) M) and low (K(i) approximately 10(-5) M) affinity for Ca(2+) that mediated noncompetitive and uncompetitive inhibition, respectively. Free Mg(2+) in excess of substrate did not alter the concentration-response relationship of Ca(2+) inhibition at high affinity sites, but produced a rightward shift in that relationship at low affinity sites. Similarly, Ca(2+) inhibition at high affinity sites was noncompetitive, whereas inhibition at low affinity sites was competitive, with respect to free Mg(2+). Purified sGC specifically bound (45)Ca(2+) in the presence of a 1000-fold excess of Mg(2+) and in the absence of activating ligands. These data suggest that sGC is a constitutive Ca(2+) binding protein whose allosteric function is conditionally dependent upon ligand activation.     

The receptor guanylyl cyclase Npr2 is essential for sensory axon bifurcation within the spinal cord

Sensory axonal projections into the spinal cord display a highly stereotyped pattern of T- or Y-shaped axon bifurcation at the dorsal root entry zone (DREZ). Here, we provide evidence that embryonic mice with an inactive receptor guanylyl cyclase Npr2 or deficient for cyclic guanosine monophosphate-dependent protein kinase I (cGKI) lack the bifurcation of sensory axons at the DREZ, i.e., the ingrowing axon either turns rostrally or caudally. This bifurcation error is maintained to mature stages. In contrast, interstitial branching of collaterals from primary stem axons remains unaffected, indicating that bifurcation and interstitial branching are processes regulated by a distinct molecular mechanism. At a functional level, the distorted axonal branching at the DREZ is accompanied by reduced synaptic input, as revealed by patch clamp recordings of neurons in the superficial layers of the spinal cord. Hence, our data demonstrate that Npr2 and cGKI are essential constituents of the signaling pathway underlying axonal bifurcation at the DREZ and neuronal connectivity in the dorsal spinal cord.     

Basal rather than induced heme oxygenase-1 levels are crucial in the antioxidant cytoprotection

Heme oxygenase-1 (HO-1) overexpression protects against tissue injury in many inflammatory processes, including ischemia/reperfusion injury (IRI). This study evaluated whether genetically decreased HO-1 levels affected susceptibility to liver IRI. Partial warm ischemia was produced in hepatic lobes for 90 min followed by 6 h of reperfusion in heterozygous HO-1 knockout (HO-1(+/-)) and HO-1(+/+) wild-type (WT) mice. HO-1(+/-) mice demonstrated reduced HO-1 mRNA/protein levels at baseline and postreperfusion. This corresponded with increased hepatocellular damage in HO-1(+/-) mice, compared with WT. HO-1(+/-) mice revealed enhanced neutrophil infiltration and proinflammatory cytokine (TNF-alpha, IL-6, and IFN-gamma) induction, as well as an increase of intrahepatic apoptotic TUNEL(+) cells with enhanced expression of proapoptotic genes (Bax/cleaved caspase-3). We used cobalt protoporphyrin (CoPP) treatment to evaluate the effect of increased baseline HO-1 levels in both WT and HO-1(+/-) mice. CoPP treatment increased HO-1 expression in both animal groups, which correlated with a lower degree of hepatic damage. However, HO-1 mRNA/protein levels were still lower in HO-1(+/-) mice, which failed to achieve the degree of antioxidant hepatoprotection seen in CoPP-treated WT. Although the baseline and postreperfusion HO-1 levels correlated with the degree of protection, the HO-1 fold induction correlated instead with the degree of damage. Thus, basal HO-1 levels are more critical than the ability to up-regulate HO-1 in response to the IRI and may also predict the success of pharmacologically induced cytoprotection. This model provides an opportunity to further our understanding of HO-1 in stress defense mechanisms and design new regimens to prevent IRI.     

The affinity of the dynein microtubule-binding domain is modulated by the conformation of its coiled-coil stalk

The microtubule-binding domain (MTBD) of dynein is separated from the AAA (ATPase with any other activity) core of the motor by an approximately 15-nm stalk that is predicted to consist of an antiparallel coiled coil. However, the structure of this coiled coil and the mechanism it uses to mediate communication between the MTBD and ATP-binding core are unknown. Here, we sought to identify the optimal alignment between the hydrophobic heptad repeats in the two strands of the stalk coiled coil. To do this, we fused the MTBD of mouse cytoplasmic dynein, together with 12-36 residues of its stalk, onto a stable coiled-coil base provided by Thermus thermophilus seryl-tRNA synthetase and tested these chimeric constructs for microtubule binding in vitro. The results identified one alignment that yielded a protein displaying high affinity for microtubules (2.2 microM). The effects of mutations applied to the MTBD of this construct paralleled those previously reported (Koonce, M. P., and Tikhonenko, I. (2000) Mol. Biol. Cell 11, 523-529) for an intact dynein motor unit in the absence of ATP, suggesting that it resembles the tight binding state of native intact dynein. All other alignments showed at least 10-fold lower affinity for microtubules with the exception of one, which had an intermediate affinity. Based on these results and on amino acid sequence analysis, we hypothesize that dynein utilizes small amounts of sliding displacement between the two strands of its coiled-coil stalk as a means of communication between the AAA core of the motor and the MTBD during the mechanochemical cycle.     

Dimerization of nitric oxide-sensitive guanylyl cyclase requires the alpha 1 N terminus

The enzyme nitric oxide-sensitive guanylyl cyclase is an obligate heterodimer consisting of an alpha and a beta subunit. Whereas the C-terminal parts of the subunits have been shown to be sufficient for catalysis, regulation was assigned to the N termini. The central domains have been postulated to be responsible for the formation of alphabeta heterodimers. Here, we have analyzed dimerization by precipitation of various N- and C-terminally truncated alpha(1) mutants with beta(1) wild type or deletion mutants thereof after coexpression in the baculovirus/Sf9 system. In contrast to the current hypothesis, our analysis revealed that an N-terminal region of the alpha(1) subunit (amino acids 61-128) is mandatory for quantitative dimerization. The central domain (amino acids 367-462) contributes but is not sufficient to mediate robust alphabeta interaction. Wild type-like binding of the identified minimum dimerization region of alpha(1) (amino acids 61-462) requires the N-terminal and central region of beta(1) (amino acids 1-385). Furthermore, we observed an unequal stability of the alpha(1) and beta(1) subunit. Whereas beta(1) forms heme containing homodimers and is stable, alpha(1) appears to be prone to misfolding and degradation when heterodimerization is impaired by deletion of important sequences.     

Inhibition of retinal guanylyl cyclase by the RGS9-1 N-terminus

Cyclic GMP plays a key role in retinal phototransduction and its photoreceptor concentration is precisely controlled by the cooperative action of cGMP phosphodiesterase (PDE) and retinal guanylyl cyclase (retGC). However, studies of the relationship between these two systems have focused only on a Ca(2+)-mediated, indirect connection. Using a retinal "regulator of G-protein signaling" (RGS9-1) and its fragments, we show that the N-terminus of RGS9-1 inhibits retGC activity. We also indicate that the GGL domain and/or the RGS domain function as an internal suppressor against the N-terminus, suggesting that proteins bound to these domains regulate the inhibitory activity of the N-terminus. Direct interaction of retGC with RGS9-1 and its N-terminus is also proved by immunoprecipitation and an overlay technique. Since RGS9-1 also controls the lifetime of transducin-activated PDE through regulating GTPase activity of transducin, this study strongly suggests that RGS9-1 mediates the direct interaction between PDE and retGC systems, and that this ingenious mechanism plays an important role in tuning of cGMP concentration in photoreceptors.     

Determination of the binding site on the extracellular domain of guanylyl cyclase C to heat-stable enterotoxin.

Guanylyl cyclase C, one of the family of membrane-bound guanylyl cyclases, consists of an extracellular domain and an intracellular domain, which are connected by a single transmembrane polypeptide. The extracellular domain binds unique small polypeptides with high specificity, which include the endogenous peptide hormones, guanylin and uroguanylin, as well as an exogenous enterotoxigenic peptide, heat-stable enterotoxin, secreted by pathogenic Escherichia coli. Information on this specific binding is propagated into the intracellular domain, followed by the synthesis of cGMP, a second messenger that regulates a variety of intracellular physiological processes. This study reports the design of a photoaffinity labeled analog of heat-stable enterotoxin (biotinyl-(AC(5))(2)-[Gly(4), Pap(11)]STp(4-17)), which incorporates a Pap residue (p-azidophenylalanine) at position 11 and a biotin moiety at the N terminus, and the use of this analog to determine the ligand-binding region of the extracellular domain of guanylyl cyclase C. The endoproteinase Lys-C digestion of the extracellular domain, which was covalently labeled by this ligand, and mass spectrometric analyses of the digest revealed that the ligand specifically binds to the region (residue 387 to residue 393) of guanylyl cyclase C. This region is localized close to the transmembrane portion of guanylyl cyclase C on the external cellular surface. This result was further confirmed by characterization of site-directed mutants of guanylyl cyclase C in which each amino acid residue was substituted by an Ala residue instead of residues normally located in the region. This experiment provides the first direct demonstration of the ligand-binding site of guanylyl cyclase C and will contribute toward an understanding of the receptor recognition of a ligand and the modeling of the interaction of the receptor and its ligand at the molecular level.     

Inhibition of deactivation of NO-sensitive guanylyl cyclase accounts for the sensitizing effect of YC-1

Many of the physiological effects of the signaling molecule nitric oxide are mediated by the stimulation of the NO-sensitive guanylyl cyclase. Activation of the enzyme is achieved by binding of NO to the prosthetic heme group of the enzyme and the initiation of conformational changes. So far, the rate of NO dissociation of the purified enzyme has only been determined spectrophotometrically, whereas the respective deactivation, i.e. the decline in enzymatic activity, has only been determined in cytosolic fractions and intact cells. Here, we report on the deactivation of purified NO-sensitive guanylyl cyclase determined after addition of the NO scavenger oxyhemoglobin or dilution. The deactivation rate corresponded to a half-life of the NO/guanylyl cyclase complex of approximately 4 s, which is in good agreement with the spectrophotometrically measured NO dissociation rate of the enzyme. The deactivation rate of the enzyme determined in platelets yielded a much shorter half-life indicating either partial damage of the enzyme during the purification procedure or the existence of endogenous deactivation accelerating factors. YC-1, a component causing sensitization of guanylyl cyclase toward NO, inhibited deactivation of guanylyl cyclase, resulting in an extremely prolonged half-life of the NO/guanylyl cyclase complex of more than 10 min. The deactivation of an ATP-utilizing guanylyl cyclase mutant was almost unaffected by YC-1, indicating the existence of a special structure within the catalytic domain required for YC-1 binding or for the transduction of the YC-1 effect. In contrast to the wild type enzyme, YC-1 did not increase NO sensitivity of this mutant, clearly establishing inhibition of deactivation as the underlying mechanism of the NO sensitizer YC-1.     

A critical role for ATP in the stimulation of retinal guanylyl cyclase by guanylyl cyclase-activating proteins

It has been believed that retinal guanylyl cyclase (retGC), a key enzyme in the cGMP recovery to the dark state, is solely activated by guanylyl cyclase-activating proteins (GCAPs) in a Ca2+-sensitive manner. However, a question has arisen as to whether the observed GCAP stimulation of retGC is sufficient to account for the cGMP recovery because the stimulated activity measured in vitro is less than the light/GTP-activated cGMP phosphodiesterase activity. Here we report that the retGC activation by GCAPs is larger than previously reported and that a preincubation with adenine nucleotide is essential for the large activation. Under certain conditions, ATP is two times more effective than adenylyl imidodiphosphate (AMP-PNP), a hydrolysis-resistant ATP analog; however, this study mainly used AMP-PNP to focus on the role of adenine nucleotide binding to retGC. When photoreceptor outer segment homogenates are preincubated with AMP-PNP (EC50 = 0.65 +/- 0.20 mM), GCAP2 enhanced the retGC activity 10-13 times over the control rate. Without AMP-PNP, GCAP2 stimulated the control activity only 3-4-fold as in previous reports. The large activation is due to a GCAP2-dependent increase in Vmax without an alteration of retGC affinity for GCAP2 (EC50 = 47.9 +/- 2.7 nM). GCAP1 stimulated retGC activity in a similar fashion but with lower affinity (EC50 = 308 nM). In the AMP-PNP preincubation, low Ca2+ concentrations are not required, and retGC exists as a monomeric form. This large activation is accomplished through enhanced action of GCAPs as shown by Ca2+ inhibition of the activity (IC50 = 178 nM). We propose that retGC is activated by a two-step mechanism: a conformational change by ATP binding to its kinase homology domain under high Ca2+ concentrations that allows large enhancement of GCAP activation under low Ca2+ concentrations.     

Mutations at the P1' position of Notch1 decrease intracellular domain stability rather than cleavage by gamma-secretase

Gamma-secretase is a unique protease which cleaves within the transmembrane domain of several substrate proteins. Among gamma-secretase substrates are members of the Notch family of receptors and the amyloid precursor protein. In this study we used a cell-free Notch-cleavage assay and specific gamma-secretase inhibitors to study the cleavage of Notch by gamma-secretase. Using this assay, we found that, in contrast to previous reports, the presence of valine at the P1(') position of Notch1 is not required for gamma-secretase cleavage. Our results suggest that the presence of valine at the N-terminus of the Notch intracellular domain cleavage product is important for its stability. Thus it appears that Notch cleavage is very similar to APP cleavage with respect to the lack of sequence specificity.