Photoreceptor guanylate cyclases: a review

Almost three decades of research in the field of photoreceptor guanylate cyclases are discussed in this review. Primarily, it focuses on the members of membrane-bound guanylate cyclases found in the outer segments of vertebrate rods. These cyclases represent a new guanylate cyclase subfamily, termed ROS-GC, which distinguishes itself from the peptide receptor guanylate cyclase family that it is not extracellularly regulated. It is regulated, instead, by the intracellularly-generated Ca2+ signals. A remarkable feature of this regulation is that ROS-GC is a transduction switch for both the low and high Ca2+ signals. The low Ca2+ signal transduction pathway is linked to phototransduction, but the physiological relevance of the high Ca2+ signal transduction pathway is not yet clear; it may be linked to neuronal synaptic activity. The review is divided into eight sections. In Section I, the field of guanylate cyclase is introduced and the scope of the review is briefly explained; Section II covers a brief history of the investigations and ideas surrounding the discovery of rod guanylate cyclase. The first five subsections of Section III review the experimental efforts to quantify the guanylate cyclase activity of rods, including in vitro and in situ biochemistry, and also the work done since 1988 in which guanylate cyclase activity has been determined. In the remaining three subsections an analytical evaluation of the Ca2+ modulation of the rod guanylate cyclase activity related to phototransduction is presented. Section IV deals with the issues of a biochemical nature: isolation and purification, subcellular localization and functional properties of rod guanylate cyclase. Section V summarizes work on the cloning of the guanylate cyclases, analysis of their primary structures, and determination of their location with in situ hybridization. Section VI summarizes studies on the regulation of guanylate cyclases, with a focus on guanylate cyclases activating proteins. In Section VII, the evidence about the localization and functional role of guanylate cyclases in other retinal cells, especially in "on-bipolar" cells, in which guanylate cyclase most likely plays a critical role in electrical signaling, is discussed. The review concludes with Section VIII, with remarks about the future directions of research on retinal guanylate cyclases.

Structural and functional characterization of a second subfamily member of the calcium-modulated bovine rod outer segment membrane guanylate cyclase, ROS-GC2

A native bovine calcium-modulated rod outer segment membrane guanylate cyclase (ROS-GC) has been cloned and reconstituted to show its linkage consistent to the process of phototransduction. In the present study, a second form of the membrane guanylate cyclase has been cloned from the bovine retina. This cyclase shares a high sequence identity with ROS-GC, is specifically expressed in the bovine retina, and, like ROS-GC, is modulated in low Ca2+ by a calmodulin-like Ca2+-binding protein, termed GCAP2. For this reason, this cyclase has now been named ROS-GC2 and the previously described ROS-GC as ROS-GC1. The tail end of ROS-GC2 contains a stretch of five amino acids, a structural feature unique to itself. These findings support the existence of a calcium-modulated subfamily of ROS-GC and indicate that ROS-GC2 embodies a five amino acid signature element at its tail end.

Membrane guanylate cyclase signal transduction system

The suspect role of the receptor-mediated cyclic GMP signaling pathway was dispelled by the discovery of a membrane guanylate cyclase that was also an atrial natriuretic factor receptor. It is now established that the membrane guanylate cyclase transduction system is linked to the signaling of natriuretic factors, guanylin/enterotoxin, and emerging evidence suggests that a new neural tissue-specific subfamily of membrane guanylate cyclases exists whose mechanism of signal transduction is different from those of the other membrane cyclases. This review will briefly discuss the fascinating, albeit turbulent, history of this signal transduction field, which will be followed by its current status and finally the direction it is heading.

Distinct inhibitory ATP-regulated modulatory domain (ARMi) in membrane guanylate cyclases

Depending upon the cofactors Mg2+ or Mn2+, ATP stimulates or inhibits the signal transduction activities of the natriuretic factor receptor guanylate cyclases, ANF-RGC and CNP-RGC: there is stimulation in the presence of Mg2+ and inhibition in the presence of Mn2+. A defined core ATP-regulated modulatory (ARM) sequence motif within the intracellular 'kinase-like' domain of the cyclases is critical for stimulation, but the mechanism of the inhibitory transduction process is not known. In addition, ATP inhibits the basal cyclase activity of a rod outer segment membrane guanylate cyclase (ROS-GC). The mechanism of this inhibitory transduction process is also not known. These issues have been addressed in the present investigation through a program of deletion mutagenesis/expression studies of the cyclases. The study shows that the ATP-mediated inhibitory transduction processes of the natriuretic factor receptor cyclases and of ROS-GC are identical. The ATP-regulated inhibitory domain of all these cyclases resides within the C-terminal segment of the cyclase. This domain is in a different location from the one representing the ATP-stimulatory ARM. The identification of the inhibitory domain in the C-terminal segment of the cyclase indicates that this segment is composed of two separate domains: one representing a catalytic cyclase domain and the other an ATP-regulated inhibitory (ARMi) domain. These findings establish a novel ATP-mediated inhibitory transduction mechanism of the membrane guanylate cyclases which is distinct from that of its counterpart, the stimulatory ATP-mediated hormonal signal transduction mechanism. Thus, they define a new paradigm of guanylate cyclase-linked signal transduction pathways.

Calcium modulation of bovine photoreceptor guanylate cyclase

Bovine photoreceptor guanylate cyclase (ROS-GC) consists of a single transmembrane polypeptide chain with extracellular and intracellular domains. In contrast to non-photoreceptor guanylate cyclases (GCs) which are activated by hormone peptides, ROS-GC is modulated in low Ca2+ by calmodulin-like Ca(2+)-binding proteins termed GCAPs (guanylate cyclase-activating proteins). In this communication we show that, like the native system, ROS-GC expressed in COS cells is activated 4-6-fold by recombinant GCAP1 at 10 nM Ca2+ and that the reconstituted system is inhibited at physiological levels of Ca2+ (1 microM). A mutant ROS-GC in which the extracellular domain was deleted was stimulated by GCAP1 indistinguishable from native ROS-GC indicating that this domain is not involved in Ca2+ modulation. Deletion of the intracellular kinase-like domain diminished the stimulation by GCAP1, indicating that this domain is at least in part involved in Ca2+ modulation. Replacement of the catalytic domain in a non-photoreceptor GC by the catalytic domain of ROS-GC yielded a chimeric GC that was sensitive to ANF/ATP and to a lesser extent to GCAP1. The results establish that GCAP1 acts at an intracellular domain, suggesting a mechanism of photoreceptor GC stimulation fundamentally distinct from hormone peptide stimulation of other cyclase receptors.

Molecular and pharmacological identity of the alpha 2D-adrenergic receptor subtype in bovine retina and its photoreceptors

The rat cA2-47 gene encodes the pharmacologically defined alpha 2D-adrenergic receptor (alpha 2D-AR) subtype. Previously, the expression of its mRNA was shown in bovine retina by amplification through the reverse transcription-polymerase chain reaction (RT-PCR) of a region corresponding to the rat alpha 2D-AR, amino acid (aa) residues 382-439, indicating the presence of this subtype in this neural tissue. In the present study, the structure of this gene has been probed and the encoded receptor subtype has been characterized in bovine retina and its photoreceptor cells. The deduced aa sequence of the two bovine gene fragments, aa residues 290-375 and aa residues 392-434, demonstrates 77% overall identity with the rat alpha 2D-AR subtype and 80% overall identity with the mouse alpha 2D-AR. The receptor encoded by the bovine gene was expressed in the retina and its photoreceptors with the typical pharmacological characteristics established for the rat alpha 2D-AR subtype: The receptor bound rauwolscine with a KD of 14 nM in the retina and with that of 19 nM in the photoreceptor cells; the binding association rate constant, k+1, for the ligand was 0.012 min-1, the dissociation rate constant, k-1, was 0.14 min-1 and the half-time for dissociation was 5 min. Oxymetazoline displaced the bound [3H]-rauwolscine with an EC50 value of 85 nM, while SK & F 104078, and prazosin displaced the bound [3H]-rauwolscine with the respective IC50 values of 900 nM and 3000 nM. The other alpha 2-AR subtypes -alpha 2A-AR, alpha 2B-AR, alpha 2C-AR-were not detected in the retina and its photoreceptors. Thus, this study shows that the bovine alpha 2D-AR gene is a structural variant of the rat and mouse genes, that the bovine gene encodes the typical pharmacologically defined alpha 2D-AR subtype, that this subtype is present in its exclusive form in the bovine retina and its photoreceptors, where it may be presynaptic in nature.

Molecular characterization of S100A1-S100B protein in retina and its activation mechanism of bovine photoreceptor guanylate cyclase

In contrast to the membrane guanylate cyclases which are stimulated by extracellular ligands, rod outer segment membrane guanylate cyclase (ROS-GC) activity is modulated intracellularly by calcium in two ways: one, where it is inhibited, and the other, where it is stimulated. The former way is linked to the phototransduction, and physiology of the second is unknown. In both ways calcium modulation of the cyclase occurs through the calcium binding proteins: through guanylate cyclase activating proteins (GCAPs) in the case of phototransduction, and through the recently discovered calcium-dependent GCAP (CD-GCAP) in the case of the other way. The kinase-like domain of ROS-GC is critical for the phototransduction-linked process. The present study shows the expression of alpha and beta chains of S100A1-S100B protein in the bovine retina and demonstrates that this protein stimulates ROS-GC activity in a dose-dependent fashion, that the stimulation is calcium dependent with an EC50 of 17 microM, and that the kinase-like domain is not involved in the calcium-modulated cyclase activation. Instead the involved domain resides at the C-terminal segment, between amino acids 731 and 1054. Thus, this S100A1-S100B protein-mediated calcium-modulated signal transduction mechanism is novel. Furthermore, this study provides the molecular understanding of the two transduction processes mediated by the same ROS-GC, one linked to the low and the other to the high calcium levels.

ATP modulation of the ligand binding and signal transduction activities of the type C natriuretic peptide receptor guanylate cyclase

The type C natriuretic peptide (CNP)-activated guanylate cyclase (CNP-RGC) is a single-chain transmembrane-spanning protein, containing both CNP binding and catalytic cyclase activities. Upon binding CNP to the extracellular receptor domain, the cytosolic catalytic domain of CNP-RGC is activated, generating the second messenger cyclic GMP. Obligatory in this activation process is an intervening signal transduction step which is regulated by ATP binding to the cyclase. This bridges the events of ligand binding and cyclase activation. A defined sequence motif (Gly499-Xa-Xa-Xa-Gly503), termed ATP regulatory module (ARM), is critical for this step. The present study shows that ATP not only amplifies the signal transduction step, it also concomitantly reduces the ligand binding activity of CNP-RGC. Reduction in the ligand binding activity is a consequence of the transformation of the high affinity receptor-form to the low affinity receptor-form. A single ARM residue Gly499 is critical in the mediation of both ATP effects, signal transduction and ligand binding activity of the receptor. Thus, this residue represents an ATP bimodal switch to turn the CNP signal on and off.

A novel calcium-dependent activator of retinal rod outer segment membrane guanylate cyclase

The membrane guanylate cyclase in retinal rod outer segments (ROS-GC) is known to be negatively regulated by calcium; when the calcium concentration is reduced below the dark-adapted level of about 500 nM, the enzyme is activated by a soluble protein. We now report that the enzyme is also positively regulated by calcium; a novel soluble protein is identified and purified from bovine retina which activates ROS-GC, with half-maximal activation occurring at 2-5 microM calcium. The activation is dose-dependent, and at its maximum, cyclase is stimulated up to 25-fold. The activator has a molecular mass of about 40 kDa and is a multimer of a 6-7 kDa peptide.

Single amino acid residue-linked signaling shifts in the transduction activities of atrial and type C natriuretic factor receptor guanylate cyclases

The type A (ANF) and the type C (CNP) natriuretic factor-activated guanylate cyclases, respectively termed as ANF-RGC and CNP-RGC, are single-chain transmembrane-spanning proteins, containing ligand binding and catalytic cyclase domains at two opposite ends of the protein. The binding activity resides at the N-terminal extracellular region and the catalytic cyclase activity at the carboxyl end. The ANF-RGC residue Leu-364, residing in the extracellular region, is critical for the ANF-binding activity; the CNP-RGC residue Glu-332 is critical for the CNP-binding activity. The counter part of CNP-RGC-Glu-332 residue is the ANF-RGC residue Gln-338 and of ANF-RGC-Leu-364 residue in CNP-RGC is the Valine-358. The present study shows a remarkable signal switching phenomenon associated with these residues. By changing the ANF-RGC residue Gln-338 to Glu, ANF-RGC switches from no to significant CNP signal transduction activity; similarly, a change from Valine-358 to Leu generates ANF signal transduction activity in CNP-RGC. These acquired signal transduction activities in the cyclases are in addition to their natural signal transduction activities. Thus, these new cyclases show both ANF and CNP signaling activities.

Regulation of bovine rod outer segment membrane guanylate cyclase by ATP, phosphodiesterase and metal ions

In vertebrate retina, rod outer segment is the site of visual transduction. The inward cationic current in the dark-adapted outer segment is regulated by cyclic GMP. A light flash on the outer segment activates a cyclic GMP phosphodiesterase resulting in rapid hydrolysis of the cyclic nucleotide which in turn causes a decrease in the dark current. Restoration of the dark current requires inactivation of the phosphodiesterase and synthesis of cyclic GMP. The latter is accomplished by the enzyme guanylate cyclase which catalyzes the formation of cyclic GMP from GTP. Therefore, factors regulating the cyclase activity play a critical role in visual transduction. But regulation of the cyclase by some of these factors--phosphodiesterase, ATP, the soluble proteins and metal cofactors (Mg and Mn)--is controversial. The availability of different types of cyclase preparations, dark-adapted rod outer segments with fully inhibited phosphodiesterase activity, partially purified cyclase without PDE contamination, cloned rod outer segment cyclase free of other rod outer segment proteins, permitted us to address these controversial issues. The results show that ATP inhibits the basal cyclase activity but enhances the stimulation of the enzyme by soluble activator, that cyclase can be activated in the dark at low calcium concentrations under conditions where phosphodiesterase activity is fully suppressed, and that greater activity is observed with manganese as cofactor than magnesium. These results provide a better understanding of the controls on cyclase activity in rod outer segments and suggest how regulation of this cyclase by ATP differs from that of other known membrane guanylate cyclases.

ATP bimodal switch that regulates the ligand binding and signal transduction activities of the atrial natriuretic factor receptor guanylate cyclase

Atrial natriuretic factor (ANF)-dependent guanylate cyclase (ANF-RGC) is a single-chain transmembrane-spanning protein, containing both ANF binding and catalytic cyclase activity. ANF binding to the extracellular receptor domain activates the cytosolic catalytic domain, generating the second messenger cyclic GMP. Obligatory in this activation process is an intervening step regulated by the ATP binding to the cyclase. This is a signal transduction step that bridges the events of ligand binding and cyclase activation. A defined structural motif (Gly503-Xa-Gly505-Xa-Xa-Xa-Gly509), termed ATP regulatory module (ARM), is critical for this step. The present study shows that the ARM-Gly505 residue acts as an ATP bimodal switch in regulating both the ligand binding and signal transduction activities of ANF-RGC, thus representing a critical site to turn the hormone signal on and off.

Structural, genetic and pharmacological identity of the rat alpha 2-adrenergic receptor subtype cA2-47 and its molecular characterization in rat adrenal, adrenocortical carcinoma and bovine retina

Subsequent to the first alpha 2-adrenergic receptor (alpha 2-AR) gene cloning of alpha 2-C10 from human platelet, cloning of the first rodent alpha 2-AR cDNA, cA2-47, was reported. Based on the structural and limited pharmacological comparison, it was concluded that the rodent receptor is a molecular and pharmacological analog of the human receptor, which is pharmacologically classified as the alpha 2A-AR. A later study slightly revised the structure of the human receptor. Thus, the precise structural comparison of the rat receptor to the human platelet receptor is no longer valid. Another rat alpha 2-AR gene, RG20, was then cloned and was also found to be a structural analog of the human alpha 2-C10. It, however, varied slightly from the alpha 2A subtype pharmacology, but matched the newly defined alpha 2D subtype pharmacology. It was, therefore, concluded that RG20 encodes the alpha 2D subtype. The structural and pharmacological relationship of RG20 with cA2-47 is not known, although it has been tacitly assumed that both are the identical alpha 2D receptor subtypes. The present study addresses this and other issues relating to the precise structural, genetic and pharmacological relationship of cA2-47 with the human platelet alpha 2-C10 receptor, and also the localization of cA2-47 transcript in certain rat tissues. The results show that the cA2-47 receptor shows a high degree of sequence identity to the alpha 2-C10 receptor, yet important differences exist between them. The sequence identity of cA2-47 receptor to the RG20 receptor is almost, but not quite complete. The cA2-47 gene is not present in the human and the human gene is not present in the rat; that cA2-47 receptor subtype is pharmacologically similar to the RG20 receptor subtype, both being of the alpha 2D subtype. The cA2-47 receptor transcript in addition to being found in the rat brain is present in the rat adrenal gland, testes, adrenocortical carcinoma and the bovine retina.

Structural and functional characterization of the rod outer segment membrane guanylate cyclase

In the vertebrate photoreceptor cell, rod outer segment (ROS) is the site of visual signal-transduction process, and a pivotal molecule that regulates this process is cyclic GMP. Cyclic GMP controls the cationic conductance into the ROS, and light causes a decrease in the conductance by activating hydrolysis of the cyclic nucleotide. The identity of the granylate cyclase (ROS-GC) that synthesizes this pool of cyclic GMP is unknown. We now report the cloning, expression and functional characterization of a DNA from bovine retina that encodes ROS-GC.

Glutamic acid-332 residue of the type C natriuretic peptide receptor guanylate cyclase is important for signaling

The type C natriuretic peptide (CNP)-activated guanylate cyclase (CNP-RGC) is a single-chain transmembrane-spanning protein, predicted to contain both ligand binding and catalytic activities. Upon binding CNP, CNP-RGC catalyzes the formation of cyclic GMP. We now show that the Glu-332 residue residing in the extracellular region of CNP-RGC plays an important role in signal transduction. Deletion of the CNP-RGC intracellular region resulted in the CNP receptor which lacked cyclase activity; deletion or substitution of Glu-332 with His or Lys resulted in almost total loss of both CNP binding and the CNP-dependent cyclase activity without affecting the basal cyclase activity of the mutant proteins. These observations support the general signal transduction model of the subfamily of natriuretic factor receptor cyclases where it is predicted that ligand binding to the extracellular receptor domain of the protein activates the cytosolic catalytic domain, generating the second-messenger cyclic GMP, and identify an amino acid residue of CNP-RGC that plays an important role in CNP signaling.

The glycine residue of ATP regulatory module in receptor guanylate cyclases that is essential in natriuretic factor signaling

Atrial natriuretic factor (ANF) and C-type natriuretic peptide (CNP)-activated guanylate cyclases are single-chain transmembrane-spanning proteins, containing both ligand binding and catalytic activities. In both proteins, ligand binding to the extracellular receptor domain activates the cytosolic catalytic domain, generating the second messenger cyclic GMP. Obligatory in this activation process is an ATP-dependent step. ATP directly binds to a defined ATP-regulatory module (ARM) sequence motif in the cyclases and through ARM bridges the events of ligand binding and signal transduction. These ARM sequence motifs are respectively represented by Gly503-Xa-Gly505-Xa-Xa-Xa-Gly509 and Gly499-Xa-Xa-Xa-Gly503 in the case of ANF receptor guanylate cyclase (ANF-RGC) and CNP receptor guanylate cyclase (CNP-RGC). Through genetic remodeling techniques, we now show that ARM-Gly505 in ANF-RGC and the corresponding ARM-Gly499 in CNP-RGC are critical for ANF and CNP signaling, and other ARM-Gly residues have minimal effect in the respective signaling processes.

Structural and biochemical identity of retinal rod outer segment membrane guanylate cyclase

Recent molecular cloning reports show that there are at least three membrane guanylate cyclases in vertebrate retina: (1) atrial natriuretic factor receptor guanylate cyclase (ANF-RGC), (2) C-type natriuretic peptide receptor guanylate cyclase (CNP-RGC), and (3) "retinal guanylate cyclase" (RetGC). The specific cellular localization of the first two cyclases is unknown, but RetGC is apparently localized in photoreceptor cells, suggesting that it participates in visual transduction. With the overall objective of identifying the guanylate cyclase that is linked to phototransduction, we compared the structural and regulatory properties of the biochemically characterized 112 kDa bovine rod outer segment membrane guanylate cyclase (ROS-GC) with those of RetGC, ANF-RGC and CNP-RGC. The N-terminal and two internal peptide sequences of purified ROS-GC had about 90% similarity with the corresponding sequences of the RetGC; the sequence identity with natriuretic peptide receptor cyclases was about 30%. A 19 amino acid long sequence from a tryptic peptide of ROS-GC had no corresponding sequence in the other three cyclases. ROS-GC was inhibited by ATP but ANF-RGC and CNP-RGC were activated by ATP in the presence of the respective peptide hormones. These results suggest that ROS-GC represents a new subtype of the membrane guanylate cyclase family that is structurally and biochemically distinct from the other retinal cyclases.

Interaction of atrial natriuretic factor and endothelin-1 signals through receptor guanylate cyclase in pulmonary artery endothelial cells

The endothelial cell has a unique intrinsic feature: it produces a most potent vasopressor peptide hormone, endothelin (ET-1), yet it also contains a signaling system of an equally potent hypotensive hormone, atrial natriuretic factor (ANF). This raises two related curious questions: does the endothelial cell also contain an ET-1 signaling system? If yes, how do the two systems interact with each other? The present investigation was undertaken to determine such a possibility. Bovine pulmonary artery endothelial (BPAE) cells were chosen as a model system. Identity of the ANF receptor guanylate cyclase was probed with a specific polyclonal antibody to the 180 kDa membrane guanylate cyclase (mGC) ANF receptor. A Western-blot analysis of GTP-affinity-purified endothelial cell membrane proteins recognized a 180 kDa band; the same antibody inhibited the ANF-stimulated guanylate cyclase activity; the ANF-dependent rise of cyclic GMP in the intact cells was dose-dependent. By affinity cross-linking technique, a predominant 55 kDa membrane protein band was specifically labeled with [125I]ET-1. ET-1 treatment of the cells showed a migration of the protein kinase C (PKC) activity from cytosol to the plasma membrane; ET-1 inhibited the ANF-dependent production of cyclic GMP in a dose-dependent fashion with an EC50 of 100 nM. This inhibitory effect was duplicated by phorbol 12-myristate 13-acetate (PMA), a known PKC-activator. The EC50 of PMA was 5 nM. A PKC inhibitor, 1-(5-isoquinolinyl-sulfonyl)-2-methyl piperazine (H-7), blocked the PMA-dependent attenuation of ANF-dependent cyclic GMP formation. These results demonstrate that the 180 kDa mGC-coupled ANF and ET-1 signaling systems coexist in endothelial cells and that the ET-1 signal negates the ANF-dependent guanylate cyclase activity and cyclic GMP formation. Furthermore, these results support the paracrine and/or autocrine role of ET-1.

Cloning and expression of an ATP-regulated human retina C-type natriuretic factor receptor guanylate cyclase

The natriuretic factors are structurally related polypeptide hormones that regulate the hemodynamics of the physiological processes of diuresis, water balance, and blood pressure. Presumably, these hormones act through the activation of guanylate cyclases which are also the specific receptors of these hormones. Two such structurally similar cell surface receptors are known; the ligand for one is atrial natriuretic factor (ANF) and for the other is C-type natriuretic peptide (CNP). Studies with ANF receptor guanylate cyclase (ANF-RGC) have indicated that its ligand binding site is extracellular and the catalytic site is intracellular, but the mere ligand binding to the receptor domain does not activate the cytosolic catalytic domain. An intervening ATP-mediated event is obligatory: ATP binds to a defined ATP-regulated module (ARM) sequence and bridges the events of ligand binding and signal transduction. The mechanism of CNP signaling is not known, although CNP in intact cells transfected with CNP receptor guanylate cyclase (CNP-RGC) stimulates the formation of cyclic GMP. Furthermore, there is no prior evidence of the presence of CNP signal transduction system in retina, although the presence of ANF-RGC has been documented. We now report the molecular cloning and expression of CNP-RGC from human retina and show that ATP is obligatory in CNP signaling also.(ABSTRACT TRUNCATED AT 250 WORDS)

Core sequence of ATP regulatory module in receptor guanylate cyclases

Atrial natriuretic factor (ANF) and C-type natriuretic peptide (CNP)-activated guanylate cyclases are single-chain transmembrane-spanning proteins, containing both ligand binding and catalytic activities. In both proteins, ligand binding to the extracellular receptor domain activates the cytosolic catalytic domain, generating the second messenger cyclic GMP. Studies with ANF receptor guanylate cyclase (ANF-RGC) have indicated that obligatory in this activation process is an ATP-dependent step. ATP directly binds to the cyclase and bridges the events of ligand binding and signal transduction. A defined ATP-regulated module (ARM) sequence (Gly503-Arg-Gly-Ser-Asn-Tyr-Gly509) in the cyclase is critical in the ATP-mediated event. Through genetic remodeling techniques, we have now identified the core ARM sequence that is essential in both ANF and CNP signaling. This sequence is Gly-Xa-Xa-Xa-Gly, represented by Gly505-Ser-Asn-Tyr-Gly509 in the case of ANF-RGC ARM and by Gly499-Ser-Ser-Tyr-Gly503 in the CNP receptor guanylate cyclase ARM.

A structural motif that defines the ATP-regulatory module of guanylate cyclase in atrial natriuretic factor signalling

Atrial natriuretic factor (ANF)-dependent guanylate cyclase is a single-chain transmembrane-spanning protein, containing an ANF receptor and having catalytic activity. ANF binding to the receptor domain activates the catalytic domain, generating the second messenger cyclic GMP. Obligatory in this activation process is an intervening step regulated by ATP, but its mechanism is not known. Through a programme of site-directed and deletion mutagenesis/expression studies, we report herein the identity of a structural motif (Gly503-Arg-Gly-Ser-Asn-Tyr-Gly509) that binds ATP and amplifies the ANF-dependent cyclase activity; this, therefore, represents an ATP-regulatory module (ARM) of the enzyme, which plays a pivotal role in ANF signalling.

Genetically tailored atrial natriuretic factor-dependent guanylate cyclase. Immunological and functional identity with 180 kDa membrane guanylate cyclase and ATP signaling site

Biochemical and immunological studies have established that one of the signal transducers of atrial natriuretic factor (ANF) is a 180 kDa membrane guanylate cyclase (180 kDa mGC), which is also an ANF receptor; obligatory in the transduction process is an intervening ATP-regulated step, but its mechanism is not known. GC alpha is a newly discovered member of the guanylate cyclase family whose activity is independent of the known natriuretic peptides, and the enzyme is not an ANF receptor. The genetically tailored GC alpha, GC alpha-DmutGln338Leu364, however, is not only a guanylate cyclase but also an ANF receptor and is structurally and functionally identical to the cloned wild-type ANF receptor guanylate cyclase, GC-A. We now report that the ANF-dependent guanylate cyclase activity in the particulate fractions of cells transfected with GC alpha-DmutGln338Leu364 was inhibited by the 180 kDa mGC polyclonal antibody, and with this antibody probe it was possible to purify the 130 kDa expressed receptor; the hormone-dependent cyclase activity of this receptor was exclusively dependent upon ATP; and through site-directed mutational studies with GC alpha mutants, the signaling sequence that defines ATP binding site was identified. We thus conclude that 180 kDa mGC and the mutant protein are immunologically similar, both proteins are linked to the ANF signal in the generation of cyclic GMP synthesis; and in both the ligand binding and catalytic activities are bridged through a defined ATP binding module.

Site-directed mutational analysis of a membrane guanylate cyclase cDNA reveals the atrial natriuretic factor signaling site

Natriuretic peptides are structurally related hormones that regulate hemodynamics of the physiological processes of diuresis, water balance, and blood pressure. One of the second messengers of these hormones is cGMP, and the type of receptor that is involved in the generation of cGMP is also a guanylate cyclase. Recent genetic evidence has revealed such a receptor family; two family members, GC-A and GC-B, have been cloned. We now describe the molecular cloning, sequencing, and expression of a cDNA clone from rat adrenal gland that encodes a membrane guanylate cyclase, GC alpha, that, with the exception of two amino acids, is structurally identical to GC-A and conforms to the purported topographical model of GC-A. The two amino acid changes are the substitutions Gln338----His338 and Leu364----Pro364, involving single nucleotide changes, CAG----CAC and CTG----CCG, respectively. Expression studies indicate that GC alpha cyclase activity is independent of the known natriuretic peptides, and direct binding studies demonstrate that GC alpha is not an ANF receptor. To determine the importance of Gln338 and Leu364 in ANF signaling, the GC alpha cDNA regions encoding amino acid residues 338 and 364 were remodeled by oligonucleotide-directed mutagenesis. A double mutant encoding Gln338 and Leu364, and a single-substitution mutant encoding Leu364 expressed both ANF binding and ANF-dependent cyclase activities, but the mutant encoding Gln338 and a deletion mutant lacking residue 364 did not express either of the above activities. These results define the critical role of Leu364 in ANF signal transduction.

Molecular cloning, sequencing and expression of an alpha 2-adrenergic receptor complementary DNA from rat brain

We have isolated a cDNA clone from rat brain using a human platelet alpha 2-adrenergic receptor genomic clone as a probe. Comparison of the deduced amino acid sequence (450 residues) corresponding to the rat brain cDNA with that of the human platelet and human kidney alpha 2-adrenergic receptors showed 84% and 44% sequence similarity, respectively. The major sequence difference between the rat brain and human platelet proteins, was a stretch of 48 amino acids within the third cytosolic loop in which the similarity was only 42%. Analysis of the 48 amino acid-region indicated that the two receptors significantly differ in terms of their primary amino acid sequence and the predicted secondary and tertiary structural features. There was no sequence similarity between the human platelet and rat brain clone over the 177 bases of 3'-noncoding sequence and a less than 50% similarity over a stretch of 210 nucleotides in the 5'-untranslated region. Southern-blot analysis with a human platelet alpha 2-adrenergic receptor probe revealed the existence of a single 5.2 kb restriction fragment (KpnI/SacI) in both human and rat genomic DNA; the rat brain alpha 2-receptor probe, however, hybridized to a single 1.9 kb band in rat DNA. Northern-blot analysis of rat brain poly(A+) RNA with the rat brain cDNA probe under stringent hybridization conditions revealed a single 4.5 kb mRNA; none was detected by the human platelet receptor probe. The rat brain 4.5 kb mRNA was not detected in any (other than brain) tested rat tissues utilizing either rat brain or human platelet DNA probes. The rat brain cDNA was expressed in a mammalian cell line (COS-2A) and found to bind the alpha 2-adrenergic antagonist [3H]yohimbine; based on the binding-affinity for prazosin, the presently cloned receptor was pharmacologically closer to the alpha 2A subclass. We conclude that the rat brain cDNA encodes a new alpha 2-adrenergic receptor subtype that may be brain-specific.

Regulation of guanylate cyclase activity by atrial natriuretic factor and protein kinase C

The putative 'second messenger' of certain atrial natriuretic factor (ANF) signal transductions is cyclic GMP. Recently, we purified a 180-kDa protein, apparently containing both ANF receptor and guanylate cyclase activities, and hypothesized that this is one of the cyclic GMP transmembrane signal transducers. The enzyme is ubiquitous and appears to be conserved. Utilizing the 180-kDa membrane guanylate cyclase, we now show that the 180-kDa guanylate cyclase is regulated in opposing fashions by two receptor signals--ANF stimulating it and protein kinase C inhibiting it. Furthermore, protein kinase C phosphorylates the 180-kDa enzyme. This suggests a novel 'switch on' and 'switch off' mechanism of the cyclic GMP signal transduction. 'Switch off' represents the phosphorylation while 'switch on' the dephosphorylation of the enzyme.