PDE3 Inhibition Reduces Epithelial Mast Cell Numbers in Allergic Airway Inflammation and Attenuates Degranulation of Basophils and Mast Cells.

Epithelial mast cells are generally present in the airways of patients with allergic asthma that are inadequately controlled. Airway mast cells (MCs) are critically involved in allergic airway inflammation and contribute directly to the main symptoms of allergic patients. Phosphodiesterase 3 (PDE3) tailors signaling of cyclic adenosine monophosphate (cAMP) and cyclic guanosine monophosphate (cGMP), which are critical intracellular second messenger molecules in various signaling pathways. This paper investigates the pathophysiological role and disease-modifying effects of PDE3 in mouse bone marrow-derived MCs (bmMCs), human LAD2- and HMC1 mast cell lines, human blood basophils, and peripheral blood-derived primary human MCs (HuMCs). In a chronic house dust mite (HDM)-driven allergic airway inflammation mouse model, we observed that PDE3 deficiency or PDE3 inhibition (PDE3i) therapy reduced the numbers of epithelial MCs, when compared to control mice. Mouse bone marrow-derived MCs (bmMCs) and the human HMC1 and LAD2 cell lines predominantly expressed PDE3B and PDE4A. BmMCs from Pde3-/- mice showed reduced loss of the degranulation marker CD107b compared with wild-type BmMCs, when stimulated in an immunoglobulin E (IgE)-dependent manner. Following both IgE-mediated and substance P-mediated activation, PDE3i-pretreated basophils, LAD2 cells, and HuMCs, showed less degranulation than diluent controls, as measured by surface CD63 expression. MCs lacking PDE3 or treated with the PDE3i enoximone exhibited a lower calcium flux upon stimulation with ionomycine. In conclusion PDE3 plays a critical role in basophil and mast cell degranulation and therefore its inhibition may be a treatment option in allergic disease.

A pathophysiological role of PDE3 in allergic airway inflammation.

Phosphodiesterase 3 (PDE3) and PDE4 regulate levels of cyclic AMP, which are critical in various cell types involved in allergic airway inflammation. Although PDE4 inhibition attenuates allergic airway inflammation, reported side effects preclude its application as an antiasthma drug in humans. Case reports showed that enoximone, which is a smooth muscle relaxant that inhibits PDE3, is beneficial and lifesaving in status asthmaticus and is well tolerated. However, clinical observations also showed antiinflammatory effects of PDE3 inhibition. In this study, we investigated the role of PDE3 in a house dust mite-driven (HDM-driven) allergic airway inflammation (AAI) model that is characterized by T helper 2 cell activation, eosinophilia, and reduced mucosal barrier function. Compared with wild-type (WT) littermates, mice with a targeted deletion of the PDE3A or PDE3B gene showed significantly reduced HDM-driven AAI. Therapeutic intervention in WT mice showed that all hallmarks of HDM-driven AAI were abrogated by the PDE3 inhibitors enoximone and milrinone. Importantly, we found that enoximone also reduced the upregulation of the CD11b integrin on mouse and human eosinophils in vitro, which is crucial for their recruitment during allergic inflammation. This study provides evidence for a hitherto unknown antiinflammatory role of PDE3 inhibition in allergic airway inflammation and offers a potentially novel treatment approach.

Role of phosphodiesterase type 3A and 3B in regulating platelet and cardiac function using subtype-selective knockout mice.

Phosphodiesterase type 3 (PDE3) is an important regulator of cAMP-mediated responses within the cardiovascular system. PDE3 exists as two subtypes: PDE3A and PDE3B, with distinct cellular and subcellular locations. Due to the lack of subtype-specific pharmacological tools, the definitive role of each subtype in regulating cardiovascular function has not been determined. In this study, we investigated platelet and cardiac function, using PDE3A and PDE3B gene knockout (KO) mice. Platelet-rich-plasma was prepared from the blood of KO and age-matched wild-type (WT) mice. PGE1 (1 microg/mL) almost completely inhibited aggregation of platelets from WT, PDE3A KO and PDE3B KO mice. In platelets from WT mice, cilostamide (100 microM), a selective PDE3 inhibitor, blocked collagen- and ADP-induced aggregation. In contrast, cilostamide had no effect on aggregation of platelets from PDE3A KO mice. In PDE3B KO mice, inhibition of collagen- and ADP-induced platelet aggregation was similar to that in WT mice. The resting intra-platelet cAMP concentration in platelets from PDE3A KO mice was twice that in the WT platelets. After PGE1 (0.1 microg/mL) stimulation, intra-cellular cAMP concentration was increased significantly more in platelets from PDE3A KO mice compared to WT mice. In vivo, PDE3A KO mice were protected against collagen/epinephrine-induced pulmonary thrombosis and death, while no such protection was observed in PDE3B KO mice. The heart rate of PDE3A KO mice was significantly higher, compared with age-matched WT mice, while that of PDE3B KO mice was similar to WT. There was no difference in cardiac contractility between PDE3A or PDE3B KO mice. Heart rate and contractility were increased in a similar dose-dependent fashion by isoproterenol in both types of KO mice. Cilostamide increased heart rate and contractility in WT and PDE3B KO but not in PDE3A KO mice. Compared to WT and PDE3B KO mice, cyclic AMP-PDE activity in membrane fractions prepared from the hearts of PDE3A KO mice was lower and not inhibited by cilostamide. The data suggest that PDE3A is the main subtype of PDE3 expressed in platelets and cardiac ventricular myocytes, and is responsible for the functional changes caused by PDE3 inhibition.