Calcium uptake by isolated nerve endings: evidence for a rapid component mediated by the breakdown of phosphatidylinositol

Several physiological stimuli, including neuronal depolarization, increase the production of phosphatidate (PA) from phosphatidylinositol (PI) and increase calcium fluxes across cell membranes. To determine if breakdown of PI is required for neuronal calcium uptake, we tested inhibitors of PI-specific phospholipase C on depolarization-dependent uptake of calcium by isolated brain synaptosomes. At a concentration of 0.1 mM these inhibitors reduced calcium uptake produced by depolarization for 1 to 3 sec, but did not affect uptake due to more prolonged depolarization. Exogenous PA also stimulated calcium accumulation by synaptosomes and this uptake was not reduced by the enzyme inhibitors. These results suggest that the rapid calcium influx produced by neuronal depolarization may be mediated by the breakdown of PI.     

Isolation and properties in culture of human adrenal capillary endothelial cells

The isolation of human adrenal capillary endothelial (HACE) cells without resort to fluorescence activated cell sorting is described, together with their properties in culture. HACE cells were isolated by plating collagenase digests at high dilution in the presence of endothelial cell growth supplement, followed by clonal selection of endothelial colonies. HACE cells exhibit a typical endothelial 'cobblestone' morphology at confluence and formed 'tubes' when seeded onto 'Matrigel'. They are positive for human MHC1, and the endothelial markers ENDOCAM (CD31) and weakly CD34, they also take up dil-acetyl low density lipoprotein but are negative for Factor VIII. Their growth is strongly stimulated by FGF and inhibited by TGF-beta I. Like their much studied bovine counterparts they are robust in culture, retaining the properties described up to senescence. HACE cells provide a readily available alternative to human umbilical vein endothelial cells in that they are easily isolated pure and in quantity. They should be particularly useful in studies where human capillary, as opposed to large vessel endothelium, is required.     

The activation of the decapping enzyme DCP2 by DCP1 occurs on the EDC4 scaffold and involves a conserved loop in DCP1

The removal of the 5′-cap structure by the decapping enzyme DCP2 and its coactivator DCP1 shuts down translation and exposes the mRNA to 5′-to-3′ exonucleolytic degradation by XRN1. Although yeast DCP1 and DCP2 directly interact, an additional factor, EDC4, promotes DCP1–DCP2 association in metazoan. Here, we elucidate how the human proteins interact to assemble an active decapping complex and how decapped mRNAs are handed over to XRN1. We show that EDC4 serves as a scaffold for complex assembly, providing binding sites for DCP1, DCP2 and XRN1. DCP2 and XRN1 bind simultaneously to the EDC4 C-terminal domain through short linear motifs (SLiMs). Additionally, DCP1 and DCP2 form direct but weak interactions that are facilitated by EDC4. Mutational and functional studies indicate that the docking of DCP1 and DCP2 on the EDC4 scaffold is a critical step for mRNA decapping in vivo. They also revealed a crucial role for a conserved asparagine–arginine containing loop (the NR-loop) in the DCP1 EVH1 domain in DCP2 activation. Our data indicate that DCP2 activation by DCP1 occurs preferentially on the EDC4 scaffold, which may serve to couple DCP2 activation by DCP1 with 5′-to-3′ mRNA degradation by XRN1 in human cells.