Yasmin Shakur

Regulation and function of the cyclic nucleotide phosphodiesterase (PDE3) gene family

Publisher Summary This chapter discusses some general information about cyclic nucleotide phosphodiesterases (PDEs). It also discusses the PDE3 gene family, emphasizing the molecular biology, structure/function relationships, and cellular regulation and functional roles of PDE3s, as well as physiological/pharmacological actions, therapeutic applications, and potential benefits of PDE3 inhibitors. The major cause of concern in the use of PDE3 inhibitors as therapeutic agents is the potential for increased mortality in patients with known heart disease. Although caution is certainly warranted in this context, conclusions should not be indiscriminately applied to all PDE3 inhibitors. The pharmacological profiles of newer PDE3 inhibitors differ from those of the PDE3 inhibitors used in earlier heart failure clinical trials. Although milrinone and cilostazol are similar in potency as inhibitors of PDE3, milrinone had greater effects than cilostazol on increasing both cyclic adenosine monophosphate (cAMP) and contractility in isolated rabbit cardiomyocytes. The ability to target PDE3 inhibitors to specific isoforms in specific intracellular compartments and/or specific cells may be critical for improvement in efficacy and safety. The acute benefits and chronic adverse actions of PDE3 inhibitors in patients, with heart failure, may result from the phosphorylation of different substrates of Protein kinase A (PKA) in different intracellular compartments. Newer PDE3 inhibitors that target a specific isoform in the appropriate compartment could potentially confer beneficial hemodynamic effects without adverse effects on mortality.

Cilostazol as a unique antithrombotic agent.

Cilostazol (CLZ) was originally developed as a selective inhibitor of cyclic nucleotide phosphodiesterase 3 (PDE3). PDE3 inhibition in platelets and vascular smooth muscle cells (VSMC) was expected to provide an antiplatelet effect and vasodilation. Recent preclinical studies have demonstrated that CLZ also possesses the ability to inhibit adenosine uptake by various cells, a property that distinguishes CLZ from other PDE3 inhibitors, such as milrinone. After extensive preclinical and clinical studies, CLZ has been shown to have unique antithrombotic and vasodilatory properties based upon these novel mechanisms of action. CLZ was approved in 1988 for the treatment of symptoms related to peripheral arterial occlusive disease in Japan (Pletaal) and in 1999 in the U.S. and in 2001 in the U.K. (Pletal) for the treatment of intermittent claudication symptoms. Despite its remarkable antiplatelet properties, CLZ is not generally considered an antithrombotic agent in Western countries, perhaps due to the bulk of its antithrombotic preclinical and clinical development being conducted in Japan. In this review, the unique properties of CLZ are reviewed with the focus on CLZ as a unique antiplatelet agent targeting platelets and VSMC, demonstrating synergy with endogenous mediators and showing lowered risk of bleeding risk compared to other antiplatelet drugs.

Comparison of the Effects of Cilostazol and Milrinone on cAMP-PDE Activity, Intracellular cAMP and Calcium in the Heart

We investigated the basis for the difference in the cardiotonic effects of the PDE3 inhibitors cilostazol and milrinone in the rabbit heart. Cilostazol displayed greater selectivity than milrinone for inhibition of cAMP-PDE activity in microsomal vs cytosolic fractions from rabbit heart. This difference was due to the inhibition of significantly less cytosolic cAMP-PDE activity by cilostazol compared to milrinone. A combination of cilostazol (>15 μM) and the PDE4 selective inhibitor, rolipram (5 μM), inhibited levels of cytosolic cAMP-PDE activity similar to those inhibited by milrinone on its own. This suggested that milrinone inhibited PDE4 in addition to PDE3 activity. In isolated rabbit cardiomyocytes, milrinone (>10 μM) caused greater elevations in intracellular cAMP and calcium than cilostazol. In the presence of rolipram, however, the cAMP and calcium elevating effects of cilostazol and milrinone were similar. Therefore, in rabbit heart, partial inhibition of PDE4 by milrinone contributed to greater increases in cardiomyocyte cAMP and calcium levels than cilostazol. PDE4 activity in failing human heart was lower than in rabbit heart and there was no significant difference in the inhibition of human cytosolic cAMP-PDE by cilostazol and milrinone. Our results suggest that in normal rabbit heart inhibition of PDE4 by milrinone may partly contribute to the greater cardiotonic effect of milrinone when compared to cilostazol. However, the lower level of PDE4 activity in failing human heart suggests that factors other than inhibition of PDE4 by milrinone may contribute to differences in cardiotonic action when compared to cilostazol.

Cyclic nucleotide specific phosphodiesterases of Leishmania major

BackgroundLeishmania represent a complex of important human pathogens that belong to the systematic order of the kinetoplastida. They are transmitted between their human and mammalian hosts by different bloodsucking sandfly vectors. In their hosts, the Leishmania undergo several differentiation steps, and their coordination and optimization crucially depend on numerous interactions between the parasites and the physiological environment presented by the fly and human hosts. Little is still known about the signalling networks involved in these functions. In an attempt to better understand the role of cyclic nucleotide signalling in Leishmania differentiation and host-parasite interaction, we here present an initial study on the cyclic nucleotide-specific phosphodiesterases of Leishmania major.ResultsThis paper presents the identification of three class I cyclic-nucleotide-specific phosphodiesterases (PDEs) from L. major, PDEs whose catalytic domains exhibit considerable sequence conservation with, among other, all eleven human PDE families. In contrast to other protozoa such as Dictyostelium, or fungi such as Saccharomyces cerevisiae, Candida ssp or Neurospora, no genes for class II PDEs were found in the Leishmania genomes. LmjPDEA contains a class I catalytic domain at the C-terminus of the polypeptide, with no other discernible functional domains elsewhere. LmjPDEB1 and LmjPDEB2 are coded for by closely related, tandemly linked genes on chromosome 15. Both PDEs contain two GAF domains in their N-terminal region, and their almost identical catalytic domains are located at the C-terminus of the polypeptide. LmjPDEA, LmjPDEB1 and LmjPDEB2 were further characterized by functional complementation in a PDE-deficient S. cerevisiae strain. All three enzymes conferred complementation, demonstrating that all three can hydrolyze cAMP. Recombinant LmjPDEB1 and LmjPDEB2 were shown to be cAMP-specific, with Km values in the low micromolar range. Several PDE inhibitors were found to be active against these PDEs in vitro, and to inhibit cell proliferation.ConclusionThe genome of L. major contains only PDE genes that are predicted to code for class I PDEs, and none for class II PDEs. This is more similar to what is found in higher eukaryotes than it is to the situation in Dictyostelium or the fungi that concomitantly express class I and class II PDEs. Functional complementation demonstrated that LmjPDEA, LmjPDEB1 and LmjPDEB2 are capable of hydrolyzing cAMP. In vitro studies with recombinant LmjPDEB1 and LmjPDEB2 confirmed this, and they demonstrated that both are completely cAMP-specific. Both enzymes are inhibited by several commercially available PDE inhibitors. The observation that these inhibitors also interfere with cell growth in culture indicates that inhibition of the PDEs is fatal for the cell, suggesting an important role of cAMP signalling for the maintenance of cellular integrity and proliferation.

Therapeutic Potential of Phosphodiesterase Inhibitors in Parasitic Diseases

Protozoan parasites of the order kinetoplastida are the causative agents of three of the worlds most important neglected human diseases: African trypanosomiasis, American trypanosomiasis, and leishmaniasis. Current therapies are limited, with some treatments having serious and sometimes lethal side effects. The growing number of cases that are refractory to treatment is also of concern. With few new drugs in development, there is an unmet medical need for new, more effective, and safer medications. Recent studies employing genetic and pharmacological techniques have begun to shed light on the role of the cyclic nucleotide phosphodiesterases in the life cycle of these pathogens and suggest that these important regulators of cyclic nucleotide signaling may be promising new targets for the treatment of parasitic diseases.