Carbonic Anhydrase IX and Hypoxia Promote Rat Pulmonary Endothelial Cell Survival during Infection.

Low tidal volume ventilation protects the lung in mechanically ventilated patients. The impact of the accompanying permissive hypoxemia and hypercapnia on endothelial cell recovery from injury is poorly understood. CA (carbonic anhydrase) IX is expressed in pulmonary microvascular endothelial cells (PMVECs), where it contributes to CO2 and pH homeostasis, bioenergetics, and angiogenesis. We hypothesized that CA IX is important for PMVEC survival and that CA IX expression and release from PMVECs are increased during infection. Although the plasma concentration of CA IX was unchanged in human and rat pneumonia, there was a trend toward increasing CA IX in the bronchoalveolar fluid of mechanically ventilated critically ill patients with pneumonia and a significant increase in CA IX in the lung tissue lysates of pneumonia rats. To investigate the functional implications of the lung CA IX increase, we generated PMVEC cell lines harboring domain-specific CA IX mutations. By using these cells, we found that infection promotes intracellular (IC) expression, release, and MMP (metalloproteinase)-mediated extracellular cleavage of CA IX in PMVECs. IC domain deletion uniquely impaired CA IX membrane localization. Loss of the CA IX IC domain promoted cell death after infection, suggesting that the IC domain has an important role in PMVEC survival. We also found that hypoxia improves survival, whereas hypercapnia reverses the protective effect of hypoxia, during infection. Thus, we report 1) that CA IX increases in the lungs of pneumonia rats and 2) that the CA IX IC domain and hypoxia promote PMVEC survival during infection.

Microtubule motors regulate ISOC activation necessary to increase endothelial cell permeability.

Calcium store depletion activates multiple ion channels, including calcium-selective and nonselective channels. Endothelial cells express TRPC1 and TRPC4 proteins that contribute to a calcium-selective store-operated current, I(SOC). Whereas thapsigargin activates the I(SOC) in pulmonary artery endothelial cells (PAECs), it does not activate I(SOC) in pulmonary microvascular endothelial cells (PMVECs), despite inducing a significant rise in global cytosolic calcium. Endoplasmic reticulum exhibits retrograde distribution in PMVECs when compared with PAECs. We therefore sought to determine whether endoplasmic reticulum-to-plasma membrane coupling represents an important determinant of I(SOC) activation in PAECs and PMVECs. Endoplasmic reticulum organization is controlled by microtubules, because nocodozole induced microtubule disassembly and caused retrograde endoplasmic reticulum collapse in PMVECs. In PMVECs, rolipram treatment produced anterograde endoplasmic reticulum distribution and revealed a thapsigargin-activated I(SOC) that was abolished by nocodozole and taxol. Microtubule motors control organelle distribution along microtubule tracks, with the dynein motor causing retrograde movement and the kinesin motor causing anterograde movement. Dynamitin expression reduces dynein motor function inducing anterograde endoplasmic reticulum transport, which allows for direct activation of I(SOC) by thapsigargin in PMVECs. In contrast, expression of dominant negative kinesin light chain reduces kinesin motor function and induces retrograde endoplasmic reticulum transport; dominant negative kinesin light chain expression prevented the direct activation of I(SOC) by thapsigargin in PAECs. I(SOC) activation is an important step leading to disruption of cell-cell adhesion and increased macromolecular permeability. Thus, microtubule motor function plays an essential role in activating cytosolic calcium transitions through the membrane I(SOC) channel leading to endothelial barrier disruption.