Smooth muscle gap-junctions allow propagation of intercellular Ca2+ waves and vasoconstriction due to Ca2+ based action potentials in rat mesenteric resistance arteries

The Journal of Physiology and Experimental Physiology have always used UK legislation as the basis of their policy on ethical standards in experiments on non-human animals. However, for international journals with authors, editors and referees from outside the UK the policy can lack transparency and is sometimes cumbersome, requiring the intervention of a Senior Ethics Reviewer or advice from external experts familiar with UK legislation. The journals have therefore decided to set out detailed guidelines for how authors should report experimental procedures that involve animals. As well as helping authors, this new clarity will facilitate the review process and decision making where there are questions regarding animal ethics.

Although the chemical nature of endothelium-derived hyperpolarizing factor (EDHF) remains elusive, electrophysiological evidence exists for electrical communication between smooth muscle cells and endothelial cells suggesting that electrotonic propagation of hyperpolarization may explain the failure to identify a single chemical factor as EDHF. Anatomical evidence for myoendothelial gap junctions, or the sites of electrical coupling, is, however, rare. In the present study, serial-section electron microscopy and reconstruction techniques have been used to examine the incidence of myoendothelial gap junctions in the proximal and distal mesenteric arteries of the rat where EDHF responses have been reported to vary. Myoendothelial gap junctions were found to be very small in the mesenteric arteries, the majority being <100 nm in diameter. In addition, they were significantly more common in the distal compared with the proximal regions of this arterial bed. Pentalaminar gap junctions between adjacent endothelial cells were much larger and were common in both proximal and distal mesenteric arteries. These latter junctions were frequently found near the myoendothelial gap junctions. These results provide the first evidence for the presence of sites for electrical communication between endothelial cells and smooth muscle cells in the mesenteric vascular bed. Furthermore, the relative incidence of these sites suggests that there may be a relationship between the activity of EDHF and the presence of myoendothelial gap junctions.

To investigate mechanisms underlying the transmission of spontaneous Ca2+ signals in the bladder, changes in intracellular concentrations of Ca2+ ([Ca2+]i) were visualized in isolated detrusor smooth muscle bundles of the guinea-pig urinary bladder loaded with a fluorescent Ca2+ indicator, fura-PE3 or fluo-4. Spontaneous increases in [Ca2+]i (Ca2+ transients) preferentially originated along the boundary of muscle bundles and then spread to the other boundary (Ca2+ waves). The synchronicity of Ca2+ waves across the bundles was disrupted by 18beta-glycyrrhetinic acid (18beta-GA, 40 microm), carbenoxolone (30 microm) or 2-aminoethoxydiphenylborate (2-APB, 50-100 microm), while CPA (10 microm), ryanodine (100 microm), xestospongin C (3 microm) and U-73122 (10 microm) had no effect. Intracellular recordings using two independent microelectrodes demonstrated that 2-APB (100 microm) blocked electrical coupling between detrusor smooth muscle cells. Nifedipine (10 microm) but not nominal Ca2+-free solution diminished the synchronicity of Ca2+ waves before preventing their generation. Staining for c-kit identified interstitial cells (IC) located along both boundaries of muscle bundles. IC were also scattered amongst smooth muscle cells and were more dominantly distributed in connective tissue between muscle bundles. IC generated nifedipine-resistant spontaneous Ca2+ transients, which occurred independently of those of smooth muscles. In conclusion, the propagation of Ca2+ transients in the bladder appears to be exclusively mediated by the spread of action potentials through gap junctions being facilitated by the regenerative nature of L-type Ca2+ channels, without significant contribution of intracellular Ca2+ stores. IC in the bladder may modulate the transmission of Ca2+ transients originating from smooth muscle cells rather than being the pacemaker of spontaneous activity.