Plasma membrane Ca(2+) pumps (PMCA) that expel Ca(2+) from cells are encoded by four genes (PMCA1-4). In this study, we show that aortic endothelium and smooth muscle differ in their PMCA isoform mRNA expression: endothelium expressed predominantly PMCA1, and smooth muscle expressed PMCA4 and a lower level of PMCA1. In this study, we report a novel peptide (caloxin 1b1, obtained by screening for binding to extracellular domain 1 of PMCA4), which inhibited PMCA extracellularly, selectively, and had a higher affinity for PMCA4 than PMCA1. It inhibited the PMCA Ca(2+)-Mg(2+)-ATPase activity in leaky erythrocyte ghosts (mainly PMCA4) with a K(i) value of 46 +/- 5 microM, making it 10x more potent than the previously reported caloxin 2a1. It was isoform selective because it inhibited the PMCA1 Ca(2+)-Mg(2+)-ATPase in human embryonic kidney-293 cells with a higher K(i) value (105 +/- 11 microM) than for PMCA4. Caloxin 1b1 was selective in that it did not inhibit other ATPases. Because caloxin 1b1 had been selected to bind to an extracellular domain of PMCA, it could be added directly to cells and tissues to examine its effects on smooth muscle and endothelium. In de-endothelialized aortic rings, caloxin 1b1 (200 microM) produced a contraction. It also increased the force of contraction produced by a submaximum concentration of phenylephrine. In aortic rings with endothelium intact, precontracted with phenylephrine and relaxed partially with a submaximum concentration of carbachol, caloxin 1b1 increased the force of contraction rather than potentiating the endothelium-dependent relaxation. In cultured cells, caloxin 1b1 increased the cytosolic [Ca(2+)] more in arterial smooth muscle cells than in endothelial cells. Thus caloxin 1b1 is the first highly selective extracellular PMCA inhibitor that works better on vascular smooth muscle than on endothelium.
Highlights d Chromosomes from early embryos resemble a barbell d Lamina interactions stretch chromosomes and separate compartments d Conventional compartments arise during gastrulation via long-distance associations d Single-chromosome clustering uncovers prevalent conformations
Hundreds of cell types form the vertebrate brain, but it is largely unknown how similar these cellular repertoires are between or within species, or how cell type diversity evolves. To examine cell type diversity across and within species, we performed single-cell RNA sequencing of ~130,000 hypothalamic cells from zebrafish ( Danio rerio ) and surface-and cave-morphs of Mexican tetra ( Astyanax mexicanus ). We found that over 75% of cell types were shared between zebrafish and Mexican tetra, which last shared a common ancestor over 150 million years ago. Orthologous cell types displayed differential paralogue expression that was generated by sub-functionalization after genome duplication. Expression of terminal effector genes, such as neuropeptides, was more conserved than the expression of their associated transcriptional regulators. Species-specific cell types were enriched for the expression of species-specific genes, and characterized by the neo-functionalization of members of recently expanded or contracted gene families. Within species comparisons revealed differences in immune repertoires and transcriptional changes in neuropeptidergic cell types associated with genomic differences between surface-and cave-morphs. The single-cell atlases presented here are a powerful resource to explore hypothalamic cell types, and reveal how gene family evolution and the neo-and sub-functionalization of paralogs contribute to cellular diversity.
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