Disintegration of cytoskeletal structure of actin filaments in energy-depleted endothelial cells.

Abstract

In a previous study [Watanabe, H., W. Kuhne, R. Spahr, P. Schwartz, and H. M. Piper. Am. J. Physiol. 260 (Heart Circ. Physiol. 29): H1344-H1352, 1991] metabolic inhibition (5 mM KCN + 5 mM 2-deoxy-D-glucose, for 2 h) was found to cause disintegration of F-actin filaments, cell retraction, and augmented paracellular macromolecule permeability in monolayer cultures of porcine aortic endothelial cells after a rapid depletion of ATP stores (90% in 5 min). These changes were reversible. In the present study, the nature of this cytoskeletal disintegration was investigated. 1) Disintegration of F-actin filaments within 2-h incubation under metabolic inhibition was accompanied by appearance of F-actin clumps in the cells, but total contents of F-actin remained unaltered. 2) Cytosolic Ca2+ levels rapidly rose in metabolically inhibited cells; after 2 h a 10-fold increase was observed. 3) Presence of the Ca2+ ionophore A23187 (10 microM) mimicked the reversible effect of metabolic inhibition on F-actin filaments and monolayer permeability but not the extensive depletion of ATP stores. 4) Existence of the Ca(2+)-activatable actin-severing protein gelsolin in endothelial cells was demonstrated. The results show that during the reversible phase of endothelial energy depletion disintegration of F-actin filaments is only partial, since it is based on their fragmentation and not depolymerization. Increase in cytosolic Ca2+ levels seems to be the primary cause for the fragmentation, possibly through the activation of gelsolin.