Cyclic GMP and regulation of cyclic nucleotide hydrolysis

Several of the different PDE isozyme families have the ability in vitro to hydrolyze cGMP. In particular they include the CaM-dependent PDEs, the cGMP-stimulated PDEs, and the cGMP binding, cGMP-specific PDEs. Existing evidence suggests or demonstrates that in different cell types, each of these can be important determinants for the control of cGMP steady-state levels. Each of these enzymes is differentially expressed and regulated; moreover, the amount of the enzyme expressed and the mode of regulation determine to a large extent the rate of rise, maximal level, rate of fall, and duration of the cGMP signal in the cell. In addition to enzymes that function to degrade cGMP at least two also are regulated by cGMP both in vitro and in the intact cell. The cGMP-stimulated PDE has the ability to decrease cAMP levels in response to cGMP and the cGMP-inhibited PDE can increase cAMP levels in response to cGMP. We are just beginning to define how many different isozymes of PDE exist in mammalian tissues, where they are located, and how they are regulated. Selective inhibitors to each are being developed and studies designed to define structural features that determine the mechanisms of action and regulation of the PDEs have been initiated. It is expected that in the next few years more PDEs will be discovered and the functions of the new an existing ones with be more clearly defined.

The role of protein phosphorylation in the regulation of cyclic nucleotide phosphodiesterases

The cyclic nucleotide phosphodiesterases constitute a complex superfamily of enzymes responsible for catalyzing the hydrolysis of cyclic nucleotides. Regulation of cyclic nucleotide phosphodiesterases is one of the two major mechanisms by which intracellular cyclic nucleotide levels are controlled. In many cases the fluctuations in cyclic nucleotide levels in response to hormones is due to the hormone responsiveness of the phosphodiesterase. Isozymes of the cGMP-inhibited, cAMP-specific, calmodulin-stimulated and cGMP-binding phosphodiesterases have been demonstrated to be substrates for protein kinases. Here we review the evidence that hormonally responsive phosphorylation acts to regulate cyclic nucleotide phosphodiesterases. In particular, the cGMP-inhibited phosphodiesterases, which can be phosphorylated by at least two different protein kinases, are activated as a result of phosphorylation. In contrast, phosphorylation of the calmodulin-stimulated phosphodiesterases, which coincides with a decreased sensitivity to activation by calmodulin, results in decreased phosphodiesterase activity.

Isolation and characterization of a previously undetected human cAMP phosphodiesterase by complementation of cAMP phosphodiesterase-deficient Saccharomyces cerevisiae

We have established a highly sensitive functional screen for the isolation of cDNAs encoding cAMP phosphodiesterases (PDEs) by complementation of defects in a Saccharomyces cerevisiae strain lacking both endogenous cAMP PDE genes, PDE1 and PDE2. Three groups of cDNAs corresponding to three distinct human genes encoding cAMP-specific PDEs were isolated from a human glioblastoma cDNA library using this functional screen. Two of these genes are closely related to the Drosophila dunce cAMP-specific PDE. The third gene, which we named HCP1, encoded a novel cAMP-specific PDE. HCP1 has an amino acid sequence related to the sequences of the catalytic domains of all cyclic nucleotide PDEs. HCP1 is a high affinity cAMP-specific PDE (Km = 0.2 microM) that does not share other properties of the cAMP-specific PDE family, i.e. extensive sequence homology to the Drosophila dunce cAMP PDE and sensitivity to rolipram and R020-1724. The PDE activity of HCP1 is not sensitive to cGMP or other inhibitors of the cGMP-inhibitable PDEs, such as milrinone. The biochemical and pharmacological properties of HCP1 suggest that it is a member of a previously undiscovered cyclic nucleotide PDE family. Northern blot analysis indicates that high levels of HCP1 mRNA are present in human skeletal muscle.

Immunochemical characterization of the distinct monocyte cyclic AMP-phosphodiesterase from patients with atopic dermatitis

BACKGROUND

Previous findings have suggested that the immunopathology of patients with atopic dermatitis (AD) results from altered cellular responses caused by cyclic nucleotide regulatory abnormalities. One such defect is the increased degradation of the second messenger, cyclic adenosine monophosphate (cAMP), by elevated cAMP-phosphodiesterase (PDE) activity in patients with AD.

METHODS

We used two monoclonal antibodies to identify the major PDE isoform in AD blood monocytes. We have also characterized the abnormal PDE activity by means of chromatofocusing and sucrose gradient centrifugation.

RESULTS

The chromatofocusing technique allowed the separation of a PDE-containing fraction (isoelectric point = 6.1) from AD monocytes but not from normal cells. This monocyte fraction accounted for most of the elevated leukocyte-PDE activity and was a cytosolic, cAMP-specific, low Michaelis constant, calcium-calmodulin-dependent enzyme, inhibited by the cAMP-PDE inhibitor, Ro 20-1724. The majority of the PDE activity in this chromatofocused fraction was immunoadsorbed by the solid-phase immobilized antibodies against calcium-calmodulin-dependent PDE.

CONCLUSIONS

The increased degradation of cAMP by a unique form of PDE may cause defective regulation of intracellular functions of AD monocytes, leading to the characteristic hyperreactive immune and inflammatory events. Characterization of PDE isoenzymes from different leukocyte subpopulations may allow further expansion of cell-directed therapy for inflammatory disease.

Affinities of bovine photoreceptor cGMP phosphodiesterases for rod and cone inhibitory subunits

Rods and cones have analogous phototransduction components and cycles, but differ from each other in their physiological response to light. Differences between the affinities of rod and cone phosphodiesterase (PDE) catalytic subunits for their respective inhibitory subunits could potentially contribute to these physiological differences. To test this idea, we expressed both the 13 kDa PDE subunit, unique to a subset of bovine retinal cones [(1990) J. Biol. Chem. 265, 11259-11264], and the rod PDE 11 kDa inhibitory subunit in E. coli, purified them, and compared their abilities to inhibit rod and cone PDE catalytic subunits. Rod PDE has similar Ki values (approximately 80 pM) for both the rod and cone recombinant inhibitory subunits. Activated cone PDE has Ki values of 200 pM for the cone 13 kDa subunit and 600 pM for rod PDE gamma.

Molecular cloning of a cDNA encoding the "61-kDa" calmodulin-stimulated cyclic nucleotide phosphodiesterase. Tissue-specific expression of structurally related isoforms

We have isolated a 2287-bp cDNA encoding the 61-kDa calmodulin-stimulated cyclic nucleotide phosphodiesterase (CaM PDE) from a bovine brain library. A large open reading frame within the cDNA encodes a 530-residue polypeptide which is identical to the sequence of the purified protein previously determined by direct amino acid sequencing. Moreover, COS cells transfected with the cDNA express a cAMP and cGMP hydrolytic activity that is stimulated by calcium and calmodulin, confirming that the cDNA represents a mRNA species encoding a CaM PDE isozyme. RNase protection analyses indicate that either 61-kDa CaM PDE mRNA or structurally related transcripts encoding different CaM PDE isoforms are expressed in a tissue-specific manner. Total RNA isolated from brain (cerebral cortex, basal ganglia, hippocampus, cerebellum, and medulla/spinal cord), heart, aorta, liver, kidney outer medulla, kidney papilla, trachea, and lung completely protected a 410-base antisense riboprobe corresponding to sequence encoding a portion of the catalytic domain. Little or no protection was detected using adrenal cortex, adrenal medulla, liver, kidney cortex, spleen, or T-lymphocyte total RNA. Only brain RNA completely protected a 240-base antisense riboprobe corresponding to the 61-kDa CaM PDE amino terminus encompassing a putative calmodulin-binding domain. However, heart, aorta, liver, kidney, trachea, and lung RNA protected 150 bases of this riboprobe suggesting that these tissues express an isoform structurally related to the 61-kDa CaM PDE. Northern analysis of mRNA isolated from brain, heart, aorta, liver, kidney, lung, and trachea revealed that the cDNA hybridizes with a 3.8- and a 4.4-kb (kilobase) mRNA species. Interestingly, Northern blots of bovine cerebral cortex and heart mRNA probed under stringent conditions with antisense transcripts corresponding to either the 5'- or 3'-untranslated sequence of the 61-kDa CaM PDE cDNA hybridized with only the 4.4-kb mRNA from both tissues. Since different, yet structurally similar CaM PDE isoforms are expressed in brain and in heart, this result, in addition to the RNase protection data, is consistent with the idea that the mRNAs encoding these two CaM PDE isoforms are products of an alternately spliced gene.

Molecular cloning of cDNA encoding a "63"-kDa calmodulin-stimulated phosphodiesterase from bovine brain

Partially degenerate oligonucleotides based on peptide sequence were used to isolate cDNA to a 63-kDa bovine brain calmodulin-stimulated phosphodiesterase (CaM-PDE) isozyme. A 412-base pair polymerase chain reaction fragment was obtained and used along with the oligonucleotides to isolate several cDNAs each encoding sequence identical to known peptide sequences from the 63-kDa CaM-PDE. The largest cDNA contained a full-length open reading frame (ORF) encoding a 534 amino acid, 61,005-dalton protein. It had 59% amino acid identity to the 61-kDa bovine brain CaM-PDE and included a carboxyl-terminal conserved domain containing the PDE catalytic domain consensus sequences. The NH2-terminal region fits the criteria for a calmodulin-binding domain. When its expression was driven by a cytomegalovirus promoter on a pCDM8 vector in COS-7 cells, the cDNA encoded a catalytically active, calmodulin-stimulated PDE. Northern analysis of RNA from several tissues with a probe containing much of the conserved PDE catalytic domain showed only a single band of 4.0 kilobases. Hybridization was seen in mRNA from several regions of the central nervous system with the greatest signal in basal ganglia. Strong signals also were seen in other tissues including kidney papilla and adrenal medulla. Antisense RNA probes were used in RNase-protection assays to look for evidence of multiple 63-kDa CaM-PDE transcripts. A catalytic domain probe was fully protected by RNA from cerebral cortex, basal ganglia, cerebellum, hippocampus, adrenal medulla, and kidney papilla. However, a probe to the NH2-terminal region was fully protected only by brain and adrenal medullary RNA indicating the likelihood of one or more isozyme(s) divergent in this region in the kidney papilla.

Analysis of the functional role of cGMP-dependent protein kinase in intact human platelets using a specific activator 8-para-chlorophenylthio-cGMP

8-(p-Chlorophenylthio)-cGMP (8-pCPT-cGMP) and 8-bromo-cGMP were compared with respect to their chemical and biological properties in order to evaluate their potential as selective activators of cGMP-dependent protein kinase (cGMP-PK; EC 2.7.1.37) in intact human platelets. 8-pCPT-cGMP, 8-Br-cGMP and cGMP were shown to be potent and selective activators of purified bovine lung cGMP-PK and of cGMP-PK present in human platelet membranes when compared with the activation of cAMP-dependent protein kinase (cAMP-PK; EC 2.7.1.37). 8-pCPT-cGMP was not hydrolysed by the purified cGMP-stimulated phosphodiesterase (cGS-PDE), cGMP-inhibited phosphodiesterase (cGI-PDE) and Ca(2+)-calmodulin-dependent phosphodiesterase (CaM-PDE), whereas cGMP and, to a lesser extent, 8-Br-cGMP were hydrolysed by all three types of 3',5' cyclic nucleotide phosphodiesterases (EC 3.1.4.17) examined. Also, 8-pCPT-cGMP was not hydrolysed by a human platelet homogenate which contains a high level of the cGMP-specific cGMP-binding phosphodiesterase (cGB-PDE). Additionally, 8-pCPT-cGMP did not activate the cGS-PDE or inhibit the cGI-PDE, whereas half-maximal inhibition of cGI-PDE occurred at 8 microM 8-Br-cGMP. The apparent lipophilicity of 8-pCPT-cGMP was higher than that of 8-Br-cGMP. Extracellular application of 8-pCPT-cGMP to intact human platelets reproduced the pattern of protein phosphorylation induced by sodium nitroprusside (SNP), a cGMP-elevating inhibitor of platelet activation. Quantitatively, 8-pCPT-cGMP was more effective than 8-Br-cGMP in inducing phosphorylation of the 46/50 kDa vasodilator-stimulated phosphoprotein, a major substrate of cGMP-PK in intact platelets. As observed with SNP, pretreatment of human platelets with 8-pCPT-cGMP prevented the aggregation induced by thrombin. The results suggest that 8-pCPT-cGMP is a very potent and selective activator of cGMP-PK in cell extracts and in intact human platelets and, in this respect, is superior to 8-Br-cGMP and other cGMP analogs used for intact cell studies. The data also suggest that inhibition of platelet activation in intact human platelets by nitrovasodilators is mediated by cGMP-PK.

Regulation and function of cyclic nucleotides

Recent work has greatly expanded our knowledge of the structure, regulation and diversity of enzymes involved in the synthesis and degradation of cyclic nucleotides. This review focuses on recent work that provides insight into the structure and function of the cyclases and phosphodiesterases that regulate cyclic nucleotide metabolism. Particular emphasis is given to the roles played by multiple isoforms of each enzyme system.

Structure and function studies of the cGMP-stimulated phosphodiesterase

Studies of cGMP binding to both the native cyclic GMP-stimulated phosphodiesterase and to two unique isolated chymotryptic fragments lacking the catalytic domain suggest that the enzyme contains two noncatalytic cGMP-binding sites/homodimer. In the presence of high concentrations of ammonium sulfate, 2 mol of cGMP are bound/mol of cGMP-stimulated phosphodiesterase homodimer. Under these conditions, linear Scatchard plots of binding are obtained that give an apparent Kd of approximately 2 microM. The inclusion of 3-isobutyl-1-methylxanthine produces a curvilinear plot. In the absence of ammonium sulfate, the dissociation of cGMP from the holoenzyme is rapid, having a t1/2 of less than 10 s, and addition of ammonium sulfate to the incubation greatly decreases this rate of dissociation. The native enzyme is resistant to degradation by chymotrypsin in the absence of cGMP; however, in its presence, chymotrypsin treatment produces several discrete fragments. Similarly, in the presence but not in the absence of cGMP, dicyclohexylcarbodiimide causes an irreversible activation of the enzyme without cross-linking the nucleotide to the phosphodiesterase. Both observations provide evidence that a different conformation in the enzyme results from cGMP binding. Only the conformation formed upon cGMP binding is easily attacked by chymotrypsin or permanently activated by treatment with dicyclohexylcarbodiimide. One major chymotryptic cleavage site exposed by cGMP binding is at tyrosine 553, implying that this region takes part in the conformational change. Limited proteolysis experiments indicate that these noncatalytic binding sites are located within a region of internal sequence homology previously proposed to include the cGMP-binding site(s) and that they retain a high affinity and specificity for cGMP independent of the catalytic domain of the enzyme. The products formed by partial proteolysis can be separated into individual catalytically active and cGMP-binding fractions by anion exchange chromatography. Gel filtration and electrophoresis analysis of the isolated fractions suggest that the cGMP-binding peak has a dimeric structure. Moreover, it can be further resolved by polyethyleneimine high performance liquid chromatography into two peaks (Peaks IIIA and IIIB). Peak IIIA binds 2 mol of cGMP/mol of dimer with an apparent Kd of 0.2 microM. Peak IIIB, however, has greatly reduced cGMP binding. Further digestion of these fragments with cyanogen bromide show that the differences between Peaks IIIA and IIIB are due to one or more additional proteolytic nicks in IIIB that remove a few residues near its C terminus, most probably residues 523-550 or 534-550. This in turn suggests that this region is essential for cGMP-binding activity.(ABSTRACT TRUNCATED AT 400 WORDS)

Molecular cloning of a cyclic GMP-stimulated cyclic nucleotide phosphodiesterase cDNA. Identification and distribution of isozyme variants

We have cloned a 4.2-kilobase pair (kb) cDNA that encodes the cyclic GMP-stimulated phosphodiesterase (cGS PDE) from a bovine adrenal cortex library. The 921-residue polypeptide deduced from the cDNA nucleotide sequence is nearly identical with the complete amino acid sequence of the cGS PDE purified from a soluble bovine heart extract. Moreover, PPD-S49 cells transfected with the cGS PDE cDNA express a soluble cAMP hydrolytic activity that is enhanced by cGMP. Total RNA isolated from several bovine tissues were screened for cGS PDE transcript by Northern blot analysis. The cGS PDE cDNA appears to hybridize to a single 4.5-4.6-kb mRNA species. Although the cGS PDE mRNA is most abundant in the adrenal cortex, it is also concentrated in the adrenal medulla and heart and in anatomically distinct regions of the brain and kidney. A mRNA species encoding a putative variant cGS PDE isoform was detected by RNase protection. Total RNA isolated from adrenal cortex, adrenal medulla, liver, kidney, trachea, lung, spleen, and T-lymphocytes completely protected a 452-base riboprobe encoding 100 residues of the adrenal cortex cGS PDE amino terminus. In contrast, RNAs isolated from brain (cerebral cortex, hippocampus, and basal ganglia) protected only 268 bases of this riboprobe. The RNase protection pattern of this same probe using heart RNA showed major bands at both 268 and 452 bases, suggesting that two different cGS PDE mRNA species are expressed. These results indicate that the cGS PDE is widely expressed in a variety of tissues. Moreover, these studies suggest that at least one different cGS PDE isoform having a structurally distinct amino-terminal domain is expressed in brain and heart.

Evidence for domain organization within the 61-kDa calmodulin-dependent cyclic nucleotide phosphodiesterase from bovine brain

The complete amino acid sequence of the 61-kDa calmodulin-dependent, cyclic nucleotide phosphodiesterase (CaM-PDE) from bovine brain has been determined. The native protein is a homodimer of N alpha-acetylated, 529-residue polypeptide chains, each of which has a calculated molecular weight of 60,755. The structural organization of this CaM-PDE has been investigated with use of limited proteolysis and synthetic peptide analogues. A site capable of interacting with CaM has been identified, and the position of the catalytic domain has been mapped. A fully active, CaM-independent fragment (Mr = 36,000), produced by limited tryptic cleavage in the absence of CaM, represents a functional catalytic domain. N-Terminal sequence and size indicate that this 36-kDa fragment is comprised of residues 136 to approximately 450 of the CaM-PDE. This catalytic domain encompasses a approximately 250 residue sequence that is conserved among PDE isozymes of diverse size, phylogeny, and function. CaM-PDE and its PDE homologues comprise a unique family of proteins, each having a catalytic domain that evolved from a common progenitor. A search of the sequence for potential CaM-binding sites revealed only one 15-residue segment with both a net positive charge and the ability to form an amphiphilic alpha-helix. Peptide analogues that include this amphiphilic segment were synthesized. Each was found to inhibit the CaM-dependent activation of the enzyme and to bind directly to CaM with high affinity in a calcium-dependent manner. This site is among the sequences cleaved from a 45-kDa chymotryptic fragment that has the complete catalytic domain but no longer binds CaM. These results indicate that residues located between position 23 and 41 of the native enzyme contribute significantly to the binding of CaM although the involvement of residues from additional sites is not excluded.

Sequence comparison of the 63-, 61-, and 59-kDa calmodulin-dependent cyclic nucleotide phosphodiesterases

Partial protein sequences from the 59-kDa bovine heart and the 63-kDa bovine brain calmodulin-dependent phosphodiesterases (CaM-PDEs) were determined and compared to the sequence of the 61-kDa isozyme reported by Charbonneau et al. [Charbonneau, H., Kumar, S., Novack, J. P., Blumenthal, D. K., Griffin, P. R., Shabanowitz, J., Hunt, D. F., Beavo, J. A. & Walsh, K. A. (1991) Biochemistry (preceding paper in this issue)]. Only a single segment (34 residues) at the N-terminus of the 59-kDa isozyme lacks identity with the 61-kDa isozyme; all other assigned sequence is identical in the two isozymes. Peptides from the 59-kDa isozyme that correspond to residues 23-41 of the 61-kDa protein bind calmodulin with high affinity. The C-terminal halves of these calmodulin-binding peptides are identical to the corresponding 59-kDa sequence; the N-terminal halves differ. The localization of sequence differences within this single segment suggests that the 61- and 59-kDa isozymes are generated from a single gene by tissue-specific alternative RNA splicing. In contrast, partial sequence from the 63-kDa bovine brain CaM-PDE isozyme displays only 67% identity with the 61-kDa isozyme. The differences are dispersed throughout the sequence, suggesting that the 63- and 61-kDa isozymes are encoded by separate but homologous genes.

High concentrations of a cGMP-stimulated phosphodiesterase mediate ANP-induced decreases in cAMP and steroidogenesis in adrenal glomerulosa cells

An adrenal cGMP-stimulated phosphodiesterase (cGS-PDE) has been shown to mediate atrial natriuretic peptide (ANP)-induced reductions in aldosterone secretion and cAMP levels in primary bovine glomerulosa cells. High concentrations of cGS-PDE have been localized to the zona glomerulosa cell layer of the adrenal cortex using biochemical and immunological techniques. Immunoblot analysis using an affinity-purified, isozyme-specific antiserum revealed a single band that comigrated with a purified cGS-PDE (105 kDa) (1) and that was most highly concentrated in the outermost 1-2 mm of the cortex, representing the capsule and zona glomerulosa regions. Greater than 90% of the overall phosphodiesterase activity present in tissue extracts prepared from these regions was immunoprecipitated using a solid-phase monoclonal antibody reagent, indicating the cGS-PDE as the predominant phosphodiesterase isozyme. Immunohistochemical staining experiments of frozen thin sections of intact adrenal tissue revealed that the cGS-PDE present in this region was localized in the glomerulosa cells themselves. The role of this isozyme as a mediator of ANP-induced decreases in intracellular cAMP concentrations and aldosterone production was tested in primary cultures of bovine adrenal glomerulosa cells. In cells stimulated by ACTH, ANP treatment produced dose-dependent reductions in aldosterone secretion and cellular cAMP content over the same concentration range. Increases in aldosterone production elicited by three cell-permeable cAMP derivatives (8-bromo-cAMP, 8-p-chlorophenylthio-cAMP, and N6-2'-O-dibutyryl-cAMP) were antagonized by ANP, indicating a site of action distal to adenylate cyclase for this hormone. Because the relative magnitude of the ANP effect differed depending upon the derivative used, the three derivatives were compared with respect to their relative rates of in vitro hydrolysis by adrenal cGS-PDE. A positive correlation between their rates of hydrolysis and the degree to which the steroidogenic response produced by these derivatives was antagonized by ANP was demonstrated, further suggesting an ANP-induced activation of the cGS-PDE as being responsible for this effect. The possible contribution of an additional pathway mediated by an inhibitory guanine nucleotide binding regulatory protein (Gi) acting on adenylate cyclase was tested by pretreatment of primary glomerulosa cells with pertussis toxin. Levels of pertussis toxin sufficient to inhibit subsequent in vitro ribosylation did not significantly alter the ANP effect on aldosterone production, although a partial reduction in the ANP effect on cAMP levels was observed.(ABSTRACT TRUNCATED AT 400 WORDS)

Amino acid sequence of the cyclic GMP stimulated cyclic nucleotide phosphodiesterase from bovine heart

The complete amino acid sequence of the cyclic GMP stimulated cyclic nucleotide phosphodiesterase (cGS-PDE) of bovine heart has been determined by analysis of five digests of the protein; placement of the C-terminal 330 residues has been confirmed by interpretation of the corresponding partial cDNA clone. The holoenzyme is a homodimer of two identical N alpha-acetylated polypeptide chains of 921 residues, each with a calculated molecular weight of 103,244. The C-terminal region, residues 613-871, of the cGS-PDE comprises a catalytic domain that is conserved in all phosphodiesterase sequences except those of PDE 1 from Saccharomyces cerevisiae and a secreted PDE from Dictyostelium. A second conserved region, residues 209-567, is homologous to corresponding regions of the alpha and alpha' subunits of the photoreceptor phosphodiesterases. This conserved domain specifically binds cGMP and is involved in the allosteric regulation of the cGS-PDE. This regulatory domain contains two tandem, internal repeats, suggesting that it evolved from an ancestral gene duplication. Common cyclic nucleotide binding properties and a distant structural relationship provide evidence that the catalytic and regulatory domains within the cGS- and photoreceptor PDEs are also related by an ancient internal gene duplication.

Primary sequence of cyclic nucleotide phosphodiesterase isozymes and the design of selective inhibitors

Primary sequence information has been reported for more than 15 different mammalian cyclic nucleotide phosphodiesterases. Moreover, recent observations suggest that many of these isozymes are selectively expressed in a limited number of cell types. The fact that nearly all these different phosphodiesterases have unique primary sequences in their catalytic or regulatory domains and that they are often selectively expressed implies that it may be possible to modulate individual isozymes using specific drugs. Joe Beavo and David Reifsnyder summarize much of the evidence that has led to our current understanding of multiple isozymes of phosphodiesterase, with emphasis on aspects that may be relevant to drug design. They also discuss why many previous attempts to isolate isozyme-selective inhibitors may have failed.

Identification of a noncatalytic cGMP-binding domain conserved in both the cGMP-stimulated and photoreceptor cyclic nucleotide phosphodiesterases

Partial amino acid sequence has been determined for the cone, alpha' subunit of the bovine photoreceptor cyclic nucleotide phosphodiesterase (PDE) and deduced from nucleotide sequences of a partial cDNA clone. These sequences identify the alpha' subunit as the product of a gene that is distinct from those encoding the alpha or beta subunits of the membrane-associated rod photoreceptor PDE. Comparisons between the recently determined cGMP-stimulated-PDE sequence and those of the alpha and alpha' photoreceptor PDE subunits reveal an unexpected sequence similarity. In addition to the catalytic domain conserved in eukaryotic PDEs, all three PDEs possess a second conserved segment of approximately 340 residues that contains two internally homologous repeats. Limited proteolysis and direct photolabeling studies indicate that the noncatalytic, cGMP-binding site(s) in the cGMP-stimulated PDE is located within this conserved domain, suggesting that it also may serve this function in the photoreceptor PDEs. Moreover, other PDEs that do not bind cGMP at noncatalytic sites do not contain this conserved domain. The function of the conserved segment in the photoreceptor PDEs is not known, but the homology to allosteric sites of the cGMP-stimulated PDE suggests a role in cGMP binding and modulation of enzyme activity.

Inhibition and stimulation of photoreceptor phosphodiesterases by dipyridamole and M&B 22,948

Few high affinity inhibitors of the photoreceptor phosphodiesterases have been identified. We show here that dipyridamole and M&B 22,948 (Zaprinast), potent inhibitors of the cGMP-binding, cGMP-specific phosphodiesterase (PDE), also inhibit trypsin- or transducin-activated bovine rod and cone photoreceptor phosphodiesterases at submicromolar concentrations. Dixon plots demonstrated that the inhibition of trypsin-activated rod PDE was competitive, with Ki values of 140 nM for M&B 22,948 and 380 nM for dipyridamole. Both of these drugs were much more potent than other PDE inhibitors, including isobutylmethylxanthine (IBMX). These results reinforce the suggestion that the photoreceptor and the cGMP-binding, cGMP-specific PDE are closely related. In addition, the high affinity and selectivity of these agents should make them useful for probing the regulation and function of PDE in the photoreceptor. At low substrate concentrations, the effects of these drugs on basal unactivated PDE activity were similar to those seen with trypsin- or transducin-activated PDE. At millimolar substrate concentrations, however, the effects of the drugs were biphasic; PDE activity was stimulated at drug concentrations from 1 to 10 microM and inhibited at higher concentrations. Stimulation was not observed with IBMX. This stimulation of activity apparently was not an allosteric effect caused by direct binding of the dipyridamole and M&B 22,948 to the high affinity noncatalytic cGMP binding sites on the PDEs; whereas no cooperativity of cGMP binding to this site has been demonstrated, the drugs actually stimulated the binding of low concentrations of cGMP to this site. In addition, whereas preincubation with cGMP and cGMP analogs blocked the stimulation exerted by the drugs, they did so only at much higher concentrations than those necessary for saturation of the high affinity noncatalytic cGMP site. Because the stimulation can only be seen at higher substrate levels than are thought to exist in the photoreceptor, only the inhibitory effects of the drugs are likely to be pharmacologically relevant. However, the stimulation exerted by these drugs may point to a hitherto unknown allosteric interaction between the catalytic and regulatory sites on the PDE or to a previously unrecognized regulatory site.

Direct photolabeling of the cGMP-stimulated cyclic nucleotide phosphodiesterase

cGMP-stimulated phosphodiesterase (PDE) has been directly photolabeled with [32P]cGMP using UV light. Sequence analysis of peptide fragments obtained from partial proteolysis or cyanogen bromide cleavage indicate that two different domains are labeled. One site, on a Mr = 36,000 chymotryptic fragment located near the COOH terminus, has characteristics consistent with it being close to or part of the catalytic site of the enzyme. This peptide contains a region of sequence that is highly conserved in all mammalian cyclic nucleotide PDEs and has been postulated to contain the catalytic domain of the enzyme. The other site, on a Mr = 28,000 cyanogen bromide cleavage fragment located near the middle of the molecule, probably makes up part of the allosteric site of the molecule. Labeling of the enzyme is concentration dependent and Scatchard analysis of labeling yields a biphasic plot with apparent half labeling concentrations of about 1 and 30 microM consistent with two types of sites being labeled. Limited proteolysis of the PDE by chymotrypsin yields five prominent fragments that separate by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) at Mr = 60,000, 57,000, 36,000, 21,000, and 17,000. Both the Mr = 60,000 and 57,000 apparently have blocked NH2 termini suggesting that the Mr = 57,000 fragment is a subfragment of the Mr = 60,000 fragment. Primary sequence analysis indicates that both the Mr = 21,000 and 17,000 fragments are subfragments of the Mr = 36,000 fragment. Autoradiographs of photolabeled then partially proteolyzed enzyme show labeled bands at Mr = 60,000, 57,000, and 36,000. Addition of 5 microM cAMP prior to photolabeling eliminates photolabeling of the Mr = 36,000 fragment but not the Mr = 60,000 or 57,000 fragments. The labeled site not blocked by cAMP is also contained in a Mr = 28,000 cyanogen bromide fragment of the enzyme that does not overlap with the Mr = 36,000 proteolytic fragment. Limited chymotryptic proteolysis also increases basal activity and eliminates cGMP stimulation of cAMP hydrolysis. The chymotryptic fragments can be separated by either ion exchange high performance liquid chromatography (HPLC) or solid-phase monoclonal antibody treatment. A solid-phase monoclonal antibody against the cGMP-stimulated PDE removes the Mr = 60,000 and 57,000 labeled fragments and any intact, unproteolyzed protein but does not remove the Mr = 36,000 fragment or the majority of activity. Ion exchange HPLC separates the fragments into three peaks (I, II, and III). Peaks I and II contain activity of approximately 40 and 100 units/mg, respectively. Peak II is the undigested or slightly nicked native enzyme.(ABSTRACT TRUNCATED AT 400 WORDS)

A soluble form of bovine rod photoreceptor phosphodiesterase has a novel 15-kDa subunit

A substantial fraction (20-30%) of the bovine rod outer segment phosphodiesterase (PDE) activity is not associated with outer segment membranes prepared with buffers of moderate ionic strength; this PDE activity appears to represent a distinct, soluble isozyme. Although this PDE isozyme can be demonstrated to be present in sealed rod outer segments, it is discarded from most standard rod outer segment preparations. A method was developed that allowed the rapid purification of the soluble rod PDE by 2600-fold, to apparent homogeneity, using a monoclonal antibody column (ROS-1a). The soluble rod PDE isozyme has a novel Mr = 15,000 subunit (delta) in addition to subunits of Mr = 88,000 (alpha sol), 84,000 (beta sol), and 11,000 (gamma sol). The delta subunit comigrates with and may be identical to the cone PDE 15-kDa subunit. The small subunits of the soluble rod PDE and the membrane-associated rod PDE were isolated by reverse-phase chromatography. The gamma sol subunit was a potent inhibitor of trypsin-activated rod PDE, inhibiting 50% of 1 pM PDE activity at a concentration of 11 pM. This concentration was similar to that observed for the gamma subunit of the membrane-associated rod PDE. The purified delta subunit did not appear to affect PDE activity; this subunit was, however, unusually difficult to keep in solution. All of the kinetic and physical properties of the soluble rod PDE tested thus far are similar to those of the membrane-associated form, except for the presence of the delta subunit, suggesting that this unique subunit could mediate the solubility of the soluble rod PDE and the cone PDE in the intact photoreceptor.

cGMP is tightly bound to bovine retinal rod phosphodiesterase

Although the total concentration of cGMP in rod outer segments is thought to be substantially greater than the free concentration, no quantitatively relevant site for the bound cGMP has been described in mammalian photoreceptors. We have found that preparations of purified bovine rod photoreceptor cyclic nucleotide phosphodiesterase (PDE) contain 1.8 +/- 0.3 mol of tightly bound cGMP per mol of PDE. When subunits of the purified PDE were separated by reverse-phase HPLC in 0.1% trifluoroacetic acid and acetonitrile, a peak of material having spectral properties characteristic of a guanine ring was seen. This material was identified as cGMP by comigration with authentic cGMP on HPLC, conversion to 5-GMP by trypsin-activated rod PDE, and conversion to guanosine by a combination of trypsin-activated PDE and 5'-nucleotidase-containing snake venom. When incubated with 1 microM [3H]cGMP, only 0.1 mol of [3H]cGMP bound per mol of purified PDE, presumably because nearly all binding sites were occupied by tightly bound endogenous cGMP carried through the purification. Scatchard plots of [3H]cGMP binding have indicated that two classes of binding sites are present on the rod PDE. The off-rate of cGMP from the slowly dissociating site is extremely slow; it has a t1/2 of approximately 4 hr at 37 degrees C. At lower temperatures, very little cGMP dissociates; the amount of [3H]cGMP bound to rod PDE after 2 hr at 4 degrees C was essentially the same as at the beginning of the incubation. The observation that stoichiometric amounts of cGMP are tightly bound to PDE accounts for the inability to purify the bovine rod PDE on cGMP affinity columns or to demonstrate stoichiometric high-affinity binding sites with [3H]cGMP. More significantly, the tightly bound cGMP may resolve the apparent discrepancy between the free and total cGMP concentrations of photoreceptor outer segments.

Cyclic AMP-dependent and cyclic AMP-independent actions of a novel cardiotonic agent, OPC-8212

Possible cAMP-dependent and cAMP-independent mechanisms of action for the cardiac effects of OPC-8212, a novel piperazinyl-quinolinone derivative, were evaluated. OPC-8212 was tested for in vitro potency as an inhibitor of soluble bovine cardiac phosphodiesterases using a rapid isolation and assay method involving monoclonal antibodies that distinguish among isozymes. The drug was selective for a low-Km, cGMP-inhibited phosphodiesterase (CGI-PDE) with an IC50 (half-maximal inhibition concentration) of 7.4 mumol/l when measured at a substrate level of 0.35 mumol/l cAMP. Under the conditions used, sulfolane, the solvent for OPC-8212, did not affect CGI-PDE activity. In electrophysiological measurements, OPC-8212 prolonged the action potential duration in canine Purkinje strand preparations up to 148% (APD90) at 10 mumol/l. Concomitantly, OPC-8212 produced a 100% increase in developed force. Both prolongation of the action potential duration and the positive inotropic effect were readily reversed after exposure to tetrodotoxin, 3 mumol/l. Using Na-selective microelectrodes, intracellular Na+ ion activity increased 225% upon exposure to 10 mumol/l OPC-8212. OPC-8212 represents a novel type of positive inotropic agent, possessing both cAMP-dependent (selective PDE isozyme inhibition) and cAMP-independent (activation of intracellular Na+) mechanism of action.