Activation of soluble AC10 induces cytoskeletal reorganisation

Abstract

The cellular monolayer of the pulmonary endothelium forms a semi-selective barrier intersecting the vascular space, the underlying interstitium, and adjacent airspace. This endothelial barrier maintains tissue homeostasis critically regulating vessel permeability. Endothelial cAMP signals regulate endothelial permeability; however, cAMP signals are highly compartmentalized, such that cAMP signals generated by transmembrane adenylyl cyclase protect the barrier, while cAMP signals generated by soluble AC disrupt the barrier. Indeed, bicarbonate stimulation of soluble AC10 disrupts the endothelial barrier increasing permeability and is required for LPS-induced lung edema. Yet, how AC10 cAMP signals coordinate endothelial barrier regulation is unclear. The endothelial cytoskeleton alters cell shape which in turn regulates endothelial permeability. Thus, we hypothesized that bicarbonate stimulation of AC10 induces cytoskeletal remodeling. PMVECs were engineered to overexpress AC10 fused to a C-terminus hemagglutinin tag (HA). Gene and protein expression were controlled using a two-tier gene expression approach in which the doxycycline inducible promoter couples with a protein destabilizing variant of FKBP12 fused to the AC10-HA construct rendering the protein unstable in the absence of Shield1. In the presence of doxycycline and Shield1, AC10-HA protein began to appear 4-hours after induction and was absent in control cells. In this system, following addition of doxycycline and Shield1 and in the presence of elevated bicarbonate, whole cell cAMP increased over the same time course as protein expression while control cells showed no additional increase above normal bicarbonate stimulation. As cAMP increases above controls, endothelial cells begin to retract inducing inter-endothelial gaps between adjacent cells. This increase in inter-endothelial gaps was consistent with decreased resistance across the endothelial monolayer. To further address cytoskeletal mediated changes during AC10-induced endothelial barrier disruption, we examined actin cytoskeleton dynamics. Significant loss of the cortical actin rim and formation of actin stress fibers progress to complete actin cytoskeletal disruption by 24 hours. Interestingly, over the same course as the restructuring of the actin cytoskeleton, we detected phosphorylation of actin binding proteins, filamin and VASP, at PKA mediated sites. Thus, it appears that AC10 mediated pulmonary endothelial barrier disruption is coupled to actin remodeling.