Functional properties of human platelets derived in vitro from CD34+ cells.

The in vitro production of blood platelets for transfusion purposes is an important goal in the context of a sustained demand for controlled products free of infectious, immune and inflammatory risks. The aim of this study was to characterize human platelets derived from CD34+ progenitors and to evaluate their hemostatic properties. These cultured platelets exhibited a typical discoid morphology despite an enlarged size and expressed normal levels of the major surface glycoproteins. They aggregated in response to ADP and a thrombin receptor agonist peptide (TRAP). After infusion into NSG mice, cultured and native platelets circulated with a similar 24 h half-life. Notably, the level of circulating cultured platelets remained constant during the first two hours following infusion. During this period of time their size decreased to reach normal values, probably due to their remodeling in the pulmonary circulation, as evidenced by the presence of numerous twisted platelet elements in the lungs. Finally, cultured platelets were capable of limiting blood loss in a bleeding assay performed in thrombocytopenic mice. In conclusion, we show here that cultured platelets derived from human CD34+ cells display the properties required for use in transfusion, opening the way to clinical trials.

Microtubule plus-end tracking Adenopolyposis Coli negatively regulates proplatelet formation.

Platelets are produced upon profound reorganization of mature megakaryocytes (MK) leading to proplatelet elongation and release into the blood stream, a process termed thrombopoiesis. This highly dynamic process requires microtubules (MT) reorganization by mechanisms that are still incompletely understood. Adenomatous polyposis coli (APC) is a microtubule plus-end tracking protein involved in the regulation of MT in a number of cell systems and its inactivation has been reported to alter hematopoiesis. The aim of our study was to investigate the role of APC in megakaryopoiesis and the final steps of platelet formation. Down-regulation of APC in cultured human MK by RNA interference increased endomitosis and the proportion of cells able to extend proplatelets (68.8% (shAPC1) and 52.5% (shAPC2) vs 28.1% in the control). Similarly an increased ploidy and amplification of the proplatelet network were observed in MK differentiated from Lin- cells of mice with APC-deficiency in the MK lineage. In accordance, these mice exhibited increased platelet counts when compared to wild type mice (1,323 ± 111 vs 919 ± 52 platelets/µL; n = 12 p 0.0033**). Their platelets had a normal size, ultrastructure and number of microtubules coils and their main functions were also preserved. Loss of APC resulted in lower levels of acetylated tubulin and decreased activation of the Wnt signaling pathway. Thus, APC appears as an important regulator of proplatelet formation and overall thrombopoiesis.

Lentiviral gene rescue of a Bernard-Soulier mouse model to study platelet glycoprotein Ibß function.

UNLABELLED: Essentials A signaling role of glycoprotein (GP)Ibß is postulated but not formally demonstrated in platelets. Lentiviral-mediated rescue in knock-out mice can be used to evaluate GPIbß function in vivo. Transduction of the native subunit corrected the main defects associated with GPIb-IX deficiency Deletion of intracellular 159-170 segment increased thrombosis, 150-160 removal increased bleeding. SUMMARY: Background The platelet glycoprotein (GP)Ib-V-IX complex is required for normal hemostasis and megakaryopoiesis. A role in GPIb-dependent responses has been ascribed to the less well characterized GPIbß subunit using a specific antibody and GPIb-IX transfected cells. Objectives Our aim was to evaluate, in vivo, the role of the GPIbß in hemostasis and thrombosis. Methods GPIbß(null) Sca-1(+) progenitors transduced with viral particles harboring hGPIbß were transplanted into lethally irradiated GPIbß(-/-) recipient mice. Results hGPIbß transplanted into the bone marrow of GPIbß(null) mice rescued GPIb-IX expression in 97% of circulating platelets. These platelets efficiently bound von Willebrand factor (VWF) and extended filopodia on a VWF matrix, demonstrating the restoration of GPIb-dependent adhesive and signaling properties. These mice exhibited less severe macrothrombocytopenia and had normal tail bleeding times as compared with GPIbß(null) mice. This strategy was employed to manipulate and evaluate the role of the GPIbß intracellular domain. Removal of the membrane proximal segment (Δ(150-160) ) decreased GPIb-IX expression by 43%, confirming its involvement in receptor assembly and biosynthesis, and resulted in increased bleeding times and decreased thrombosis in a mechanical injury model in the aorta. On the other hand, deletion of the C-flanking 159-170 segment allowed normal GPIb-IX expression, VWF-dependent responses and bleeding times, but resulted in enhanced arterial thrombosis. Conclusion This pointed to a repressor role of GPIbß in thrombus formation in vivo that was not predicted in studies of heterologous cells. These results highlight the utility of this lentiviral strategy for the structure-function evaluation of GPIb-IX in platelets.

Cdc42-dependent F-actin dynamics drive structuration of the demarcation membrane system in megakaryocytes.

UNLABELLED: Essentials Information about the formation of the demarcation membrane system (DMS) is still lacking. We investigated the role of the cytoskeleton in DMS structuration in megakaryocytes. Cdc42/Pak-dependent F-actin remodeling regulates DMS organization for proper megakaryopoiesis. These data highlight the mandatory role of F-actin in platelet biogenesis. SUMMARY: Background Blood platelet biogenesis results from the maturation of megakaryocytes (MKs), which involves the development of a complex demarcation membrane system (DMS). Therefore, MK differentiation is an attractive model for studying membrane remodeling. Objectives We sought to investigate the mechanism of DMS structuration in relationship to the cytoskeleton. Results Using three-dimensional (3D) confocal imaging, we have identified consecutive stages of DMS organization that rely on F-actin dynamics to polarize membranes and nuclei territories. Interestingly, microtubules are not involved in this process. We found that the mechanism underlying F-actin-dependent DMS formation required the activation of the guanosine triphosphate hydrolase Cdc42 and its p21-activated kinase effectors (Pak1/2/3). Förster resonance energy transfer demonstrated that active Cdc42 was associated with endomembrane dynamics throughout terminal maturation. Inhibition of Cdc42 or Pak1/2/3 severely destructured the DMS and blocked proplatelet formation. Even though this process does not require containment within the hematopoietic niche, because DMS structuration was observed upon thrombopoietin-treatment in suspension, integrin outside-in signaling was required for Pak activation and probably resulted from secretion of extracellular matrix by MKs. Conclusions These data indicate a functional link, mandatory for MK differentiation, between actin dynamics, regulated by Cdc42/Pak1/2/3, and DMS maturation.

Broader expression of the mouse platelet factor 4-cre transgene beyond the megakaryocyte lineage.

BACKGROUND: Transgenic mice expressing cre recombinase under the control of the platelet factor 4 (Pf4) promoter, in the context of a 100-kb bacterial artificial chromosome, have become a valuable tool with which to study genetic modifications in the platelet lineage. However, the specificity of cre expression has recently been questioned, and the time of its onset during megakaryopoiesis remains unknown. OBJECTIVES/METHODS: To characterize the expression of this transgene, we used double-fluorescent cre reporter mice. RESULTS: In the bone marrow, Pf4-cre-mediated recombination had occurred in all CD42-positive megakaryocytes as early as stage I of maturation, and in rare CD42-negative cells. In circulating blood, all platelets had recombined, along with only a minor fraction of CD45-positive cells. However, we found that all tissues contained recombined cells of monocyte/macrophage origin. When recombined, these cells might potentially modify the function of the tissues under particular conditions, especially inflammatory conditions, which further increase recombination in immune cells. Unexpectedly, a subset of epithelial cells from the distal colon showed signs of recombination resulting from endogenous Pf4-cre expression. This is probably the basis of the unexplained colon tumors developed by Apc(flox/flox) ;Pf4-cre mice, generated in a separate study on the role of Apc in platelet formation. CONCLUSION: Altogether, our results indicate early recombination with full penetrance in megakaryopoiesis, and confirm the value of Pf4-cre mice for the genetic engineering of megakaryocytes and platelets. However, care must be taken when investigating the role of platelets in processes outside hemostasis, especially when immune cells might be involved.

Proplatelet formation deficit and megakaryocyte death contribute to thrombocytopenia in Myh9 knockout mice.

BACKGROUND: Inactivation of the mouse Myh9 gene (Myh9Δ) or its mutation in MYH9-related diseases leads to macrothrombocytopenia. Paradoxically, previous studies using in vitro differentiated megakaryocytes showed an increased capacity for proplatelet formation when myosin was absent or inhibited. METHODS: To explore the origin of the thrombocytopenia induced by myosin deficiency, we studied proplatelet formation using bone marrow explants of wild-type (WT) and Myh9Δ mouse where megakaryocytes have matured in their native environment. RESULTS AND DISCUSSION: A dramatic decrease in the number and complexity of proplatelets was observed in megakaryocytes from Myh9Δ mice, while inhibition of myosin activity by blebbistatin increased proplatelet formation from WT mature megakaryocytes. Moreover, Myh9Δ megakaryocytes had a smaller size than the WT cells. These data indicate that myosin deficiency acts negatively on proplatelet formation, probably by impairing in situ megakaryocyte maturation, while myosin activity is dispensable at the latest stage of proplatelet formation. In addition, ultrastructural examination of Myh9Δ bone marrow revealed an increased proportion of megakaryocytes exhibiting signs of non-apoptotic cell death as compared with the WT mice. CONCLUSION: These data indicate that thrombocytopenia in Myh9Δ mice results from defective development of megakaryocyte size, impaired proplatelet formation and increased cell death.

Inhibition of adhesive and signaling functions of the platelet GPIb-V-IX complex by a cell penetrating GPIbalpha peptide.

BACKGROUND: Interaction between the platelet glycoprotein (GP)Ib-V-IX complex and von Willebrand factor (VWF) is critical for initiating platelet-vessel wall contacts, particularly under high shear conditions. This interaction also plays an important role in initiating platelet activation through the generation of intracellular signals resulting in platelet shape change and integrin alpha(IIb)beta3 activation. OBJECTIVE: A cell-penetrating peptide strategy was used to study the role of the intracellular domain of the GPIbalpha subunit in VWF/GPIb-V-IX-dependent adhesion and activation. METHODS: Peptides of 11-13 amino acids, covering the 557-610 region, were coupled to a nine-arginine permeating tag (R9) and the effects of their cell entry on VWF-dependent responses were analyzed. RESULTS: The R9alpha557 peptide corresponding to the 557-569 segment reduced platelet agglutination in response to VWF, while the other peptides had no effect. The decreased platelet agglutination appeared to be an indirect consequence of adenosine diphosphate release as a normal response was restored by apyrase or a P2Y1 receptor antagonist. A more direct effect of R9alpha557 on GPIb VWF-dependent functions was observed in adhesion studies on a VWF matrix, where it decreased platelet adhesion and profoundly inhibited filopodia formation. In addition, cell adhesion was reduced and shape change absent when Chinese hamster ovary cells expressing the GPIb-IX complex were incubated with R9alpha557. CONCLUSION: This study performed in intact platelets suggests a functional role of the 557-569 domain of GPIbalpha in controlling VWF-dependent adhesion and signaling.

The P2Y1 receptor plays an essential role in the platelet shape change induced by collagen when TxA2 formation is prevented.

ADP and TxA2 are secondary agonists which play an important role as cofactors when platelets are activated by agonists such as collagen or thrombin. The aim of the present study was to characterize the role of the ADP receptor P2Y(1) in collagen-induced activation of washed platelets. Inhibition of P2Y(1) alone with the selective antagonist MRS2179 prolonged the lag phase preceding aggregation in response to low or high concentrations of fibrillar collagen, without affecting the maximum amplitude of aggregation or secretion. A combination of MRS2179 and aspirin resulted in complete inhibition of platelet shape change at low and high collagen concentrations, together with a profound decrease in aggregation and secretion. Scanning electron microscopy showed that these platelets had conserved the discoid morphology typical of the resting state. A lack of shape change was also observed in aspirin-treated P2Y(1)- and G(alphaq)-deficient mouse platelets and in delta-storage pool-deficient platelets from Fawn Hooded rats. In contrast, when the second ADP receptor P2Y(12) was inhibited with AR-C69931MX, aspirin-treated platelets were still able to change shape and displayed only a moderate decrease in aggregation and secretion. In conclusion, this study provides evidence that collagen requires not only the TxA2 receptor Tpalpha, but also P2Y(1), to induce platelet shape change.

Lineage-specific overexpression of the P2Y1 receptor induces platelet hyper-reactivity in transgenic mice.

In order to investigate the role of the platelet P2Y1 receptor in several aspects of platelet activation and thrombosis, transgenic (TG) mice overexpressing this receptor specifically in the megakaryocytic/platelet lineage were generated using the promoter of the tissue-specific platelet factor 4 gene. Studies of the saturation binding of [33P]2MeSADP in the presence or absence of the selective P2Y1 antagonist MRS2179 indicated that wild-type (WT) mouse platelets bore 150 +/- 31 P2Y1 receptors and TG platelets 276 +/- 34, representing an 84% increase in P2Y1 receptor density. This led to a well defined phenotype of platelet hyper-reactivity in vitro, as shown by increased aggregations in response to adenosine 5'-diphosphate (ADP) and low concentration of collagen in TG as compared with WT platelets. Moreover, overexpression of the P2Y1 receptor enabled ADP to induce granule secretion, unlike in WT platelets, which suggests that the level of P2Y1 expression is critical for this event. Our results further suggest that the weak responses of normal platelets to ADP are due to a limited number of P2Y1 receptors rather than to activation of a specific transduction pathway. TG mice displayed a shortened bleeding time and an increased sensitivity to in vivo platelet aggregation induced by infusion of a mixture of collagen and epinephrine. Overall, these findings emphasize the importance of the P2Y1 receptor in hemostasis and thrombosis and suggest that variable expression levels of this receptor on platelets might play a role in thrombotic states in human, which remains to be assessed.

The P2Y(12) receptor induces platelet aggregation through weak activation of the alpha(IIb)beta(3) integrin--a phosphoinositide 3-kinase-dependent mechanism.

High concentrations of adenosine-5'-diphosphate ADP are able to induce partial aggregation without shape change of P2Y(1) receptor-deficient mouse platelets through activation of the P2Y(12) receptor. In the present work we studied the transduction pathways selectively involved in this phenomenon. Flow cytometric analyses using R-phycoerythrin-conjugated JON/A antibody (JON/A-PE), an antibody which recognizes activated mouse alpha(IIb)beta(3) integrin, revealed a low level activation of alpha(IIb)beta(3) in P2Y(1) receptor-deficient platelets in response to 100 microM ADP or 1 microM 2MeS-ADP. Adrenaline induced no such activation but strongly potentiated the effect of ADP in a dose-dependent manner. Global phosphorylation of (32)P-labeled platelets showed that P2Y(12)-mediated aggregation was not accompanied by an increase in the phosphorylation of myosin light chain (P(20)) or pleckstrin (P(47)) and was not affected by the protein kinase C (PKC) inhibitor staurosporine. On the other hand, two unrelated phosphoinositide 3-kinase inhibitors, wortmannin and LY294002, inhibited this aggregation. Our results indicate that (i) the P2Y(12) receptor is able to trigger a P2Y(1) receptor-independent inside-out signal leading to alpha(IIb)beta(3) integrin activation and platelet aggregation, (ii) ADP and adrenaline use different signaling pathways which synergize to activate the alpha(IIb)beta(3) integrin, and (iii) the transduction pathway triggered by the P2Y(12) receptor is independent of PKC but dependent on phosphoinositide 3-kinase.

Evidence for cross-talk between glycoprotein VI and Gi-coupled receptors during collagen-induced platelet aggregation.

Collagen-induced platelet aggregation is a complex process and involves synergistic action of integrins, immunoglobulin (Ig)-like receptors, G-protein-coupled receptors and their ligands, most importantly collagen itself, thromboxane A(2) (TXA(2)), and adenosine diphosphate (ADP). The precise role of each of these receptor systems in the overall processes of activation and aggregation, however, is still poorly defined. Among the collagen receptors expressed on platelets, glycoprotein (GP) VI has been identified to play a crucial role in collagen-induced activation. GPVI is associated with the FcRgamma chain, which serves as the signal transducing unit of the receptor complex. It is well known that clustering of GPVI by highly specific agonists results in platelet activation and irreversible aggregation, but it is unclear whether collagen has the same effect on the receptor. This study shows that platelets from Galphaq-deficient mice, despite their severely impaired response to collagen, normally aggregate on clustering of GPVI, suggesting this not to be the principal mechanism by which collagen activates platelets. On the other hand, dimerization of GPVI by a monoclonal antibody (JAQ1), which by itself did not induce aggregation, provided a sufficient stimulus to potentiate platelet responses to Gi-coupled, but not Gq-coupled, agonists. The combination of JAQ1 and adrenaline or ADP, but not serotonin, resulted in alpha(IIb)beta(3)-dependent aggregation that occurred without intracellular calcium mobilization and shape change in the absence of Galphaq or the P2Y(1) receptor. Together, these results provide evidence for a cross-talk between (dimerized) GPVI and Gi-coupled receptors during collagen-induced platelet aggregation. (Blood. 2001;97:3829-3835)

Differential involvement of the P2Y1 and P2YT receptors in the morphological changes of platelet aggregation.

The relative contributions of the P2Y1 and P2YT receptors to the morphological changes induced in platelets by ADP or ADP-releasing agonists were assessed using two P2 antagonists, A2P5P and AR-C67085, selective for P2Y1 and P2YT, respectively. The P2Y1 receptor was found to be involved in i) the centralization of secretory granules elicited by ADP, ii) the formation of filopodia induced by released ADP in weakly activated platelets and iii) actin polymerization and the cytoskeletal translocation of cdc42, rac1 and rhoA, in an integrin alphaIIbbeta3 dependent manner, in ADP-stimulated platelets. In contrast, the P2YT receptor was shown i) to be essential for the formation of stable macroaggregates, ii) to enhance actin polymerization and the cytoskeletal translocation of small GTPases, probably through amplification of platelet aggregation, and iii) not to be involved in the early steps of platelet activation since its blockade did not affect the cytoskeletal translocation of rhoA.

Desensitization of the platelet aggregation response to ADP: differential down-regulation of the P2Y1 and P2cyc receptors.

Platelets activated by ADP become refractory to restimulation, but the mechanism of this process is not well understood. A normal platelet response to ADP requires coactivation of the P2Y(1) receptor responsible for shape change and the P2cyc receptor, responsible for completion and amplification of the response. The aim of the present study was to characterize the desensitization of platelets to ADP and to determine whether or not these two receptors are desensitized simultaneously through identical pathways when platelets become refractory to ADP. It was found that full inhibition of platelet aggregation in response to restimulation by ADP required the presence of ADP in the medium or use of a high concentration (1 mM) of its non-hydrolysable analogue ADPbetaS. Platelets incubated for 1 h at 37 degrees C with 1 mM ADPbetaS and resuspended in Tyrode's buffer containing apyrase displayed a stable refractory state characterized by the inability to aggregate or change shape in response to ADP. ADPbetaS treated platelets loaded with fura-2/AM showed complete blockade of the calcium signal in response to ADP, whereas the capacity of ADP to inhibit PGE1 stimulated cAMP accumulation in these platelets was only diminished. Consequently, serotonin was able to promote ADP induced aggregation through activation of the Gq coupled 5HT(2A) receptor while adrenaline had no such effect. These results suggested that the refractory state of ADPbetaS treated platelets was entirely due to desensitization of the P2Y(1) receptor, the P2cyc receptor remaining functional. Binding studies were performed to determine whether the P2Y(1) and/or P2cyc binding sites were modified in refractory platelets. Using selective P2Y(1) and P2cyc antagonists (A3P5P and AR-C66096 respectively), we could demonstrate that the decrease in [33P]2MeSADP binding sites on refractory platelets corresponded to disappearance of the P2Y(1) sites with no change in the number of P2cyc sites, suggesting internalization of the P2Y(1) receptor. This was confirmed by flow cytometric analysis of Jurkat cells expressing an epitope-tagged P2Y(1) receptor, where ADPbetaS treatment resulted in complete loss of the receptor from the cell surface. We conclude that the P2Y(1) and P2cyc receptors are differently regulated during platelet activation.

ADP induces partial platelet aggregation without shape change and potentiates collagen-induced aggregation in the absence of Galphaq.

Platelets from Galphaq knockout mice are unable to aggregate in response to physiological agonists like adenosine 5'-diphosphate (ADP), thromboxane A(2), thrombin, or collagen, although shape change still occurs in response to all of these agonists except ADP. ADP-induced platelet aggregation results from simultaneous activation of the purinergic P2Y(1) receptor coupled to calcium mobilization and shape change and of a distinct P2 receptor, P2cyc, coupled through Gi to adenylyl cyclase inhibition, which is responsible for completion and amplification of the response. P2cyc could be the molecular target of the antithrombotic drug clopidogrel and the adenosine triphosphate (ATP) analogs AR-C69931MX, AR-C67085, and AR-C66096. The aim of the present study was to determine whether externally added ADP could still act through the Gi pathway in Galphaq-deficient mouse platelets and thereby amplify the residual responses to agonists such as thrombin or collagen. It was found that (1) ADP and adrenaline still inhibited cyclic AMP accumulation in Galphaq-deficient platelets; (2) both agonists restored collagen- but not thrombin-induced aggregation in these platelets; (3) the effects of ADP were selectively inhibited in vitro by the ATP analog AR-C69931MX and ex vivo by clopidogrel and hence were apparently mediated by the P2cyc receptor; and (4) high concentrations of ADP (100 micromol/L) induced aggregation without shape change in Galphaq-deficient platelets through activation of P2cyc. Since adrenaline was not able to induce platelet aggregation even at high concentrations, we conclude that the effects of ADP mediated by P2cyc are not restricted to the inhibition of adenylyl cyclase through Gi(2).

Defective platelet aggregation and increased resistance to thrombosis in purinergic P2Y(1) receptor-null mice.

ADP is a key agonist in hemostasis and thrombosis. ADP-induced platelet activation involves the purinergic P2Y(1) receptor, which is responsible for shape change through intracellular calcium mobilization. This process also depends on an unidentified P2 receptor (P2cyc) that leads to adenylyl cyclase inhibition and promotes the completion and amplification of the platelet response. P2Y(1)-null mice were generated to define the role of the P2Y(1) receptor and to determine whether the unidentified P2cyc receptor is distinct from P2Y(1). These mice are viable with no apparent abnormalities affecting their development, survival, reproduction, or the morphology of their platelets, and the platelet count in these animals is identical to that of wild-type mice. However, platelets from P2Y(1)-deficient mice are unable to aggregate in response to usual concentrations of ADP and display impaired aggregation to other agonists, while high concentrations of ADP induce platelet aggregation without shape change. In addition, ADP-induced inhibition of adenylyl cyclase still occurs, demonstrating the existence of an ADP receptor distinct from P2Y(1). P2Y(1)-null mice have no spontaneous bleeding tendency but are resistant to thromboembolism induced by intravenous injection of ADP or collagen and adrenaline. Hence, the P2Y(1) receptor plays an essential role in thrombotic states and represents a potential target for antithrombotic drugs.

The P2Y1 receptor, necessary but not sufficient to support full ADP-induced platelet aggregation, is not the target of the drug clopidogrel.

Recently we showed that the P2Y1 receptor coupled to calcium mobilization is necessary to initiate ADP-induced human platelet aggregation. Since the thienopyridine compound clopidogrel specifically inhibits ADP-induced platelet aggregation, it was of interest to determine whether the P2Y1 receptor was the target of this drug. Therefore we studied the effects of clopidogrel and of the two specific P2Y1 antagonists A2P5P and A3P5P on ADP-induced platelet events in rats. Although clopidogrel treatment (50 mg/kg) greatly reduced platelet aggregation in response to ADP as compared to untreated platelets, some residual aggregation was still detectable. In contrast, A2P5P and A3P5P totally abolished ADP-induced shape change and aggregation in platelets from both control and clopidogrel-treated rats. A2P5P and A3P5P (100 microM) totally inhibited the [Ca2+]i rise induced by ADP (0.1 microM) in control and clopidogrel-treated platelets, whereas clopidogrel treatment had no effect. Conversely, the inhibition of adenylyl cyclase induced by ADP (5 microM) was completely blocked by clopidogrel but not modified by A2P5P or A3P5P (100 microM). A3P5P (1 mM) reduced the number of [33P]2MeSADP binding sites on control rat platelets from 907 +/- 50 to 611 +/- 25 per platelet. After clopidogrel treatment, binding of [33P]2MeSADP decreased to 505 +/- 68 sites per platelet and further decreased to 55 +/- 12 sites in the presence of A3P5P (1 mM). In summary, these results demonstrate that the platelet P2Y1 receptor responsible for the initiation of aggregation in response to ADP is not the target of clopidogrel. Platelets may express another, as yet unidentified, P2Y receptor, specifically coupled to the inhibition of adenylyl cyclase and necessary to induce full platelet aggregation, which could be the target of this drug.

Species differences in localization of cardiac cAMP-phosphodiesterase activity: a cytochemical study.

The localization of the membrane-bound cyclic 3',5'-AMP phosphodiesterase in cardiac tissues of both, rat and dog was studied by cytochemical method. 40 microm thick slices from glutaraldehyde fixed heart tissue were incubated in the medium with cAMP as a substrate and Pb ions as a capture metal of the reaction product. The cAMP-PDE activity in the rat ventricle was only shown positive on the sarcolemma. Whereas, in canine ventricular tissue the cAMP-PDE activity in cardiomyocytes was shown on the sarcolemma, on the junctional sarcoplasmic reticulum and on subsarcolemmal cisternae. The results confirm differences in the localization of cAMP-PDE in dog and rat heart.

Cytochemical distribution of cyclic AMP-dependent 3',5'-nucleotide phosphodiesterase in the rat myocardium.

The cytochemical localization of cAMP-dependent phosphodiesterase was studied in the rat myocardium. Slices 40 microns thick from perfusion-fixed rat hearts were incubated in the medium with cAMP as a substrate and Pb ions as a capture metal of the reaction product. After the incubation in the basic medium the specific precipitate of cAMP phosphodiesterase was localized on the sarcolemma of cardiomyocytes. In addition, it was localized on the plasmalemma of endothelial cells of capillaries and small coronary arteries as well as on the membrane of smooth muscle cells. Using selective inhibitors SK&F 94120 for phosphodiesterase III and Rolipram for the IV isoenzyme, both isoforms were detected on the membrane of smooth muscle cell. In addition, phosphodiesterase III was localized on the sarcolemma only and phosphodiesterase IV on the sarcolemma of cardiomyocytes and the plasmalemma of endothelial cells.

Isoprenaline induces endothelium-independent relaxation and accumulation of cyclic nucleotides in the rat aorta.

The role of endothelium in isoprenaline-induced relaxation was investigated in aortic rings brought to different levels of pre-contraction. Relaxation elicited by isoprenaline decreased with increasing pre-contraction. However, relaxation was identical in rings with and without endothelium brought to the same initial tension by adjusting the noradrenaline concentration. Furthermore, isoprenaline increased cAMP and cGMP contents to the same levels whether endothelium was present or not. These results do not support an obligatory role for the endothelium in isoprenaline-induced relaxation in rat aorta. They indicate that relaxation induced by isoprenaline can be enhanced by the endothelium as a consequence of its effect on the precontraction level of the aorta.

Role of phosphodiesterases III and IV in the modulation of vascular cyclic AMP content by the NO/cyclic GMP pathway.

1. The effect on cyclic nucleotide contents of selective inhibitors of cyclic nucleotide phosphodiesterase (PDE) isoforms III and IV (respectively SK&F 94120 and rolipram) and their interactions with endothelium and NO have been studied in rat aorta in the presence of indomethacin (10 microM). The participation of NO was assessed by using either NG-nitro-L-arginine methyl ester (L-NAME) (NO synthase inhibitor: 30 microM) or 3-morpholinosydnonimine (SIN-1, NO donor: 10 microM with SOD 100 units ml-1). 2. The presence of endothelium significantly increased both adenosine 3':5'-cyclic monophosphate (cyclic AMP, 1.7 fold) and guanosine 3':5'-cyclic monophosphate (cyclic GMP, 2.2 fold) contents. Cyclic GMP was largely affected by L-NAME or SIN-1 treatment, this was not the case for cyclic AMP suggesting that the presence of endothelium modified cyclic AMP content in aorta independently of the NO production. 3. In the presence or absence of endothelium, neither SK&F 94120 nor rolipram, alone or combined, significantly modified cyclic GMP content. 4. The PDE III inhibitor significantly affected cyclic AMP content only in non treated aorta without endothelium. In contrast, the PDE IV inhibitor increased cyclic AMP in all conditions. These increases were generally about 2 fold but markedly higher in aorta treated with SIN-1 and superoxide dismutase (SOD, 6 fold). Association of a low concentration of the PDE III inhibitor (5 microM) with the PDE IV inhibitor (30 microM) potentiated the effect of the PDE IV inhibitor on cyclic AMP content, except for aorta without endothelium treated with SIN-1 plus SOD. 5. These data indicate that the presence of the endothelium could increase cyclic AMP content independently of NO and prostacyclin (PGI2) production. Furthermore, an increase in cyclic GMP content (modulated by NO production) could enhance the cyclic AMP accumulation induced by the PDE IV inhibitor. This result supports the hypothesis that PDE III inhibition by endogenous cyclic GMP may potentiate the effect of PDE IV inhibition on cyclic AMP content. Taken together with our previous studies on relaxation, these results suggest that the NO/cyclic GMP pathway could induce PDE IV-dependent regulation of cyclic AMP via PDE III inhibition.