The assignment of the Ca2+-ATPase activity of chromaffin granules to the proton translocating ATPase

AbstractCaATP is shown to function as a substrate for the proton translocating ATPase of chromaffin granule ghosts at concentrations which are comparable to that of MgATP. Using the initial rate of the proton pump activity as the measure (ΔpH/Δt), an apparent Km-value of 139 ± 8 μM was estimated for CaATP and 59 ± 3 μM for MgATP. The maximal rate was markedly higher with MgATP than with CaATP, partly due to an inhibition of the hydrolytic activity at the higher concentrations of CaATP. The proton pump activity with CaATP was inhibited by N-ethylmaleimide and N,N'-dicyclohexylcarbodiimide at concentrations similar to that found for MgATP. No inhibition was observed with sodium vanadate in the concentration range 0–15 μM. Calmodulin and trifluoperazine had no effect on the overall ATPase activity with CaATP. These findings establish this acitivity as an intrinsic property of the chromaffin granules, i.e., linked to the H+-ATPase. No evidence was obtained for the presence of a Ca2+-translocating ATPase ((Ca2+ + Mg2+)-ATPase) in the chromaffin granules.Ca2+-ATPaseH+-ATPaseProton pumpChromaffin granuleAdrenal medull

Mural Cell Associated VEGF Is Required for Organotypic Vessel Formation

Background: Blood vessels comprise endothelial cells, mural cells (pericytes/vascular smooth muscle cells) and basement membrane. During angiogenesis, mural cells are recruited to sprouting endothelial cells and define a stabilizing context, comprising cell-cell contacts, secreted growth factors and extracellular matrix components, that drives vessel maturation and resistance to anti-angiogenic therapeutics. Methods and Findings: To better understand the basis for mural cell regulation of angiogenesis, we conducted high content imaging analysis on a microtiter plate format in vitro organotypic blood vessel system comprising primary human endothelial cells co-cultured with primary human mural cells. We show that endothelial cells co-cultured with mural cells undergo an extensive series of phenotypic changes reflective of several facets of blood vessel formation and maturation: Loss of cell proliferation, pathfinding-like cell migration, branching morphogenesis, basement membrane extracellular matrix protein deposition, lumen formation, anastamosis and development of a stabilized capillary-like network. This phenotypic sequence required endothelial-mural cell-cell contact, mural cell-derived VEGF and endothelial VEGFR2 signaling. Inhibiting formation of adherens junctions or basement membrane structures abrogated network formation. Notably, inhibition of mural cell VEGF expression could not be rescued by exogenous VEGF. Conclusions: These results suggest a unique role for mural cell-associated VEGF in driving vessel formation and maturation