Angiogenesis is a key process in various physiological and pathological conditions in the nervous system and in the retina during postnatal life. Although an increasing number of studies have addressed the role of endothelial cells in this event, the astrocytes contribution in angiogenesis has received less attention. This review is focused on the role of astrocytes as a scaffold and in the stabilization of the new blood vessels, through different molecules release, which can modulate the angiogenesis process in the brain and in the retina. Further, differences in the astrocytes phenotype are addressed in glioblastoma, one of the most devastating types of brain cancer, in order to provide potential targets involved in the cross signaling between endothelial cells, astrocytes and glioma cells, that mediate tumor progression and pathological angiogenesis. Given the relevance of astrocytes in angiogenesis in physiological and pathological conditions, future studies are required to better understand the interrelation between endothelial and astrocyte signaling pathways during this process.
In resistance arteries, smooth muscle cells (SMCs) and endothelial cells (ECs) are communicated through gap junctions (i.e. myoendothelial gap junctions), which provide a signaling pathway for control of vasomotor tone. In this context, the Ca2+ signaling associated to smooth muscle contraction might also be transmitted via myoendothelial gap junctions and activate a regulatory feedback mechanism (myoendothelial feedback) by the production of endothelium‐dependent vasodilators. It is thought that IP3 is the main Ca2+‐related signaling transmitted from smooth muscle cells to endothelial cells, but the direct contribution of Ca2+ to the myoendothelial feedback is not clear. We investigated the temporal pattern of vasoconstriction in mesenteric resistance arteries, and their temporal relationship with the increase of Ca2+ in SMC and EC. We used intact mesenteric resistance arteries of Sprague dawley male rats (≤ 10 mm in length) to measure the vasoconstriction and changes in [Ca2+]i of smooth muscle cells and endothelial cells observed in response to phenylephrine (PE) or KCl using the fluorescent indicators of Ca2+, Fluo‐4 and X‐Rhod‐1.Changes in [Ca2+]i were also evaluated in primary cultures of mesenteric endothelial cells. All procedures were approved by the local Bioethical Committee (ID:180806005). The vasoconstriction induced by PE and KCl was not only associated with an increase of [Ca2+]i in smooth muscle cells, but also in endothelial cells, which was prevented by the blockade of L‐type voltage‐dependent Ca2+ channels with 10 μM nifedipine or the inhibition of gap junctions with 50 μM 18‐b‐Glycyrrhetenic acid. Although the stimulation with PE or KCl did not evoke an increment of [Ca2+]i in primary cultures of endothelial cells, the response induced by these vasoconstrictors was larger after blocking nitric oxide (NO) production with NG‐nitro‐L‐arginine (100 μM). These results suggest that the direct diffusion of Ca2+ contributes to the NO‐mediated component of the myoendothelial feedback. Support or Funding Information Conicyt 21171840
Endothelial cell migration is a key process in angiogenesis. Progress of endothelial cell migration is orchestrated by coordinated generation of Ca2+ signals through a mechanism organized in caveolae. Connexins (Cx) play a central role in coordination endothelial cell function, directly by cell-to-cell communication via gap junction and, indirectly, by the release of autocrine/paracrine signals through Cx-formed hemmichannels. However, Cx hemichannels are also permeable to Ca2+ and Cx43 can be associated with caveolin-1, a structural protein of caveolae. We proposed that endothelial cell migration relies on Cx43 hemichannel opening. Here we show a novel mechanism of Ca2+ signaling in endothelial cell migration. The Ca2+ signaling that mediates endothelial cell migration and the subsequent tubular structure formation depended on Cx43 hemichannel opening and is associated with the translocation of Cx43 with caveolae to the rear part of the cells. These findings indicate that Cx43 hemichannels play a central role in endothelial cell migration and provide new therapeutic targets for the control of deregulated angiogenesis in pathological conditions such as cancer.
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