Robin Looft‐Wilson scite author profile

Rationale The coordination of vascular smooth muscle cell (VSMC) constriction plays an important role in vascular function such as regulation of blood pressure. However, the mechanism responsible for VSMC communication is not clear in the resistance vasculature. Pannexins (Panx) are purine releasing channels permeable to the vasoconstrictor ATP and thus may play a role in the coordination of VSMC constriction. Objective We investigated the role of pannexins in phenylephrine (PE) and KCl mediated constriction of resistance arteries. Methods and Results Western blot, immunohistochemistry and immunogold labeling coupled to scanning and transmission electron microscopy revealed the presence of Panx1 but not Panx2 or Panx3 in thoracodorsal resistance arteries (TDA). Functionally, the contractile response of pressurized TDA to PE was significantly decreased by multiple Panx inhibitors (mefloquine, probenecid and 10Panx1), ectonucleotidase (apyrase) and purinergic receptor inhibitors (suramin and reactive-blue-2). Electroporation of TDA with either Panx1-GFP or Panx1 siRNA showed enhanced and decreased constriction respectively in response to PE. Lastly, the Panx inhibitors did not alter constriction in response to KCl. This result is consistent with co-immunoprecipitation experiments from TDA, which suggested an association between Panx1 and α1D-adrenoreceptor. Conclusions Our data demonstrate for the first time a key role for Panx1 in resistance arteries, by contributing to the coordination of VSMC constriction and possibly regulation of blood pressure.

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Compartmentalized Connexin 43 S -Nitrosylation/Denitrosylation Regulates Heterocellular Communication in the Vessel Wall

Straub

Billaud

Johnstone

et al. 2011

ATVB

158

177

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Objective-To determine whether S-nitrosylation of connexins (Cxs) modulates gap junction communication between endothelium and smooth muscle. Methods and Results-Heterocellular communication is essential for endothelium control of smooth muscle constriction; however, the exact mechanism governing this action remains unknown. Cxs and NO have been implicated in regulating heterocellular communication in the vessel wall. The myoendothelial junction serves as a conduit to facilitate gap junction communication between endothelial cells and vascular smooth muscle cells within the resistance vasculature. By using isolated vessels and a vascular cell coculture, we found that Cx43 is constitutively S-nitrosylated on cysteine 271 because of active endothelial NO synthase compartmentalized at the myoendothelial junction. Conversely, we found that stimulation of smooth muscle cells with the constrictor phenylephrine caused Cx43 to become denitrosylated because of compartmentalized S-nitrosoglutathione reductase, which attenuated channel permeability. We measured S-nitrosoglutathione breakdown and NO x concentrations at the myoendothelial junction and found S-nitrosoglutathione reductase activity to precede NO release. Key Words: NO Ⅲ GSNO-R Ⅲ connexin Ⅲ myoendothelial junction Ⅲ nitrosylation W ithin the vessel wall of resistance arteries, coordinated vascular smooth muscle cell (SMC) and endothelial cell (EC) function is integrated by complex intercellular signaling to regulate the constriction and dilation of the artery. The anatomic structures that facilitate direct SMC and EC communication within the resistance artery are myoendothelial junctions (MEJs), which are cellular extensions from ECs or SMCs that project through the internal elastic lamina [1][2][3] and link the plasma membranes of the 2 different cell types together. The gap junctions (GJs) at the MEJ provide a conduit for second messenger and electric signaling between the 2 cell types. 2,4,5 For example, phenylephrine (PE) stimulation of SMCs induces inositol 1,4,5-triphosphate (IP 3 ) generation and an increase in [Ca 2ϩ ] i concentrations, constricting the artery. It is thought that the IP 3 progresses to the adjacent EC through GJs at the MEJ, initiating an increase in [Ca 2ϩ ] i and the release of NO to modulate the magnitude of vasoconstriction, thereby regulating the tone of the artery. 6 -8 Elucidation of the mechanisms regulating this process could provide novel insight into blood pressure regulation; however, the process remains uncharacterized. Conclusion-This study provides evidence for compartmentalized S-nitrosylation/denitrosylationGJs are intracellular signaling channels formed by 2 hexameric hemichannels, with each adjacent cell contributing 1 hemichannel. Connexin (Cx) proteins compose the channels, of which 4 different Cxs have been identified in the vasculature, with multiple studies demonstrating a potentially important role for Cx43 at the MEJ. 9 Recent studies have demonstrated that GJ communication and trafficking of Cx43 are mod...

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Robin Looft‐Wilson

Pannexin1 Regulates α1-Adrenergic Receptor– Mediated Vasoconstriction

Compartmentalized Connexin 43 S -Nitrosylation/Denitrosylation Regulates Heterocellular Communication in the Vessel Wall

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