Phosphodiesterase 7B regulates prostanoid‐ but not ß‐adrenergic‐stimulated cAMP levels in primary human airway smooth muscle cells

Abstract

Human airway smooth muscle (HASM) cells contain G‐protein coupled receptor (GPCR) signal transduction pathways that are organized in the plasma membrane and form cAMP signaling compartments. One such compartment contains ß2‐adrenergic receptors (ß2AR) coupled to adenylyl cyclase (AC)6 and is principally localized in lipid rafts. Another compartment expresses E prostanoid receptors 2 and 4 (EP2/4) coupled to AC2 and is restricted to non‐raft regions of the plasma membrane. Various phosphodiesterase (PDE) isozymes modulate cyclic AMP (cAMP) levels in response to these pathways. Non‐specific or PDE‐family specific PDE inhibitors have been used to treat asthma and chronic obstructive pulmonary disease with limited success, in part due to expression of these PDE isoforms throughout the body. Drugs that inhibit specific PDE isozymes might produce therapeutic effects in airways with fewer off‐target effects. RNA‐sequencing data in HASM cells indicates that PDE7B is the third most highly expressed PDE isoform and includes expression of both the PDE7B‐201 and PDE7B‐203 splice variants. We sought to characterize the role of PDE7B in the lipid raft and non‐raft cAMP signaling compartments. We used siRNA to knock down both PDE7B splice variants, confirmed protein reduction via Western Blot analysis, and then observed live cells’ real‐time cAMP levels in response to either isoproterenol (ßAR agonist) or PGE2 (EP agonist). The cADDis‐FMP biosensor, which localizes in lipid raft regions, did not report altered cAMP dynamics in response to ß2AR or EPR agonists following PDE7B knockdown. However, the cADDis‐FS15 biosensor, which reports cAMP levels in non‐raft plasma membrane regions, reported significant increases in cAMP levels stimulated by EPR agonists but no change in cAMP levels stimulated by ß2AR agonist. PDE7B may play a unique role in regulating non‐raft associated EP2/4 signaling without altering cAMP levels in other areas of the cell, thereby presenting a novel therapeutic target for pulmonary diseases.