Thomas Hartig Braunstein

Phosphorylation of connexin43 on serine 306 regulates electrical coupling

BACKGROUND Phosphorylation is a key regulatory event in controlling the function of the cardiac gap junction protein connexin43 (Cx43). Three new phosphorylation sites (S296, S297, S306) have been identified on Cx43; two of these sites (S297 and S306) are dephosphorylated during ischemia. The functional significance of these new sites is currently unknown. OBJECTIVE The purpose of this study was to examine the role of S296, S297, and S306 in the regulation of electrical intercellular communication. METHODS To mimic constitutive dephosphorylation, serine was mutated to alanine at the three sites and expressed in HeLa cells. Electrical coupling and single channel measurements were performed by double patch clamp. Protein expression levels were assayed by western blotting, localization of Cx43, and phosphorylation of S306 by immunolabeling. Free hemichannels were assessed by biotinylation. RESULTS Macroscopic conductance in cells expressing S306A was reduced to 57% compared to wild type (WT), whereas coupling was not significantly changed in cells expressing either S296A or S297A. S306A-expressing cells displayed similar protein and free hemichannel abundance compared to WT Cx43, whereas the fractional area of plaques in cell-to-cell interfaces was increased. However, single channel measurements showed a WT Cx43 main state conductance of 119 pS, whereas the main state conductance of S306A channels was reduced to 95 pS. Furthermore, channel gating was affected in S306A channels. CONCLUSION Lack of phosphorylation at serine 306 results in reduced coupling, which can be explained by reduced single channel conductance. We suggest that dephosphorylation of S306 partly explains the electrical uncoupling seen in myocardial ischemia.

The Role of L- and T-Type Calcium Channels in Local and Remote Calcium Responses in Rat Mesenteric Terminal Arterioles

Background/Aims: The roles of intercellular communication and T-type versus L-type voltage-dependent Ca2+ channels (VDCCs) in conducted vasoconstriction to local KCl-induced depolarization were investigated in mesenteric arterioles. Methods: Ratiometric Ca2+ imaging (R) using Fura-PE3 with micro-ejection of depolarizing KCl solution and VDCC blockers, and immunohistochemical and RT-PCR techniques were applied to isolated rat mesenteric terminal arterioles (n = 71 from 47 rats; intraluminal diameter: 24 ± 1 μm; length: 550–700 μm). Results: Local application of KCl (at 0 μm) led to local (ΔR = 0.54) and remote (ΔR = 0.17 at 500 μm) increases in intracellular Ca2+. Remote Ca2+ responses were inhibited by the gap junction uncouplers carbenoxolone and palmitoleic acid. CaV1.2, CaV3.1 and CaV3.2 channels were immunolocalized in vascular smooth muscle cells and CaV3.2 in adjacent endothelial cells. Local and remote Ca2+ responses were inhibited by bath application of L- and T-type blockers [nifedipine, NNC 55-0396 and R(–)-efonidipine]. Remote Ca2+ responses (500 μm) were not affected by abolishing Ca2+ entry at an intermediate position on the arterioles (at 200–300 μm) using micro-application of VDCC blockers. Conclusion: Both L- and T-type channels mediate Ca2+ entry during conducted vasoconstriction to local KCl in mesenteric arterioles. However, these channels do not participate in the conduction process per se.

Distinct permeation profiles of the connexin 30 and 43 hemichannels

Connexin 43 (Cx43) hemichannels may form open channels in the plasma membrane when exposed to specific stimuli, e.g. reduced extracellular concentration of divalent cations, and allow passage of fluorescent molecules and presumably a range of smaller physiologically relevant molecules. However, the permeability profile of Cx43 hemichannels remains unresolved. Exposure of Cx43‐expressing Xenopus laevis oocytes to divalent cation free solution induced a gadolinium‐sensitive uptake of the fluorescent dye ethidium. In spite thereof, a range of biological molecules smaller than ethidium, such as glutamate, lactate, and glucose, did not permeate the pore whereas ATP did. In contrast, permeability of glutamate, glucose and ATP was observed in oocytes expressing Cx30. Exposure to divalent cation free solutions induced a robust membrane conductance in Cx30‐expressing oocytes but none in Cx43‐expressing oocytes. C‐terminally truncated Cx43 (M257) displayed increased dye uptake and, unlike wild type Cx43 channels, conducted current. Neither Cx30 nor Cx43 acted as water channels in their hemichannel configuration. Our results demonstrate that connexin hemichannels have isoform‐specific permeability profiles and that dye uptake cannot be equaled to permeability of smaller physiologically relevant molecules in given settings.

Activation, permeability, and inhibition of astrocytic and neuronal large pore (Hemi)channels

Background: The permeability and physiological role of several large pore (hemi)channels are unresolved. Results: Large pore (hemi)channels, when heterologously expressed, display isoform-specific permeability and gating for ions and fluorescent dyes. Conclusion: Large pore channels have isoform-specific transport characteristics that can be used for their identification. Significance: Although large pore channels have characteristic properties in overexpression systems, these properties may be undetectable in native cells. Astrocytes and neurons express several large pore (hemi)channels that may open in response to various stimuli, allowing fluorescent dyes, ions, and cytoplasmic molecules such as ATP and glutamate to permeate. Several of these large pore (hemi)channels have similar characteristics with regard to activation, permeability, and inhibitor sensitivity. Consequently, their behaviors and roles in astrocytic and neuronal (patho)physiology remain undefined. We took advantage of the Xenopus laevis expression system to determine the individual characteristics of several large pore channels in isolation. Expression of connexins Cx26, Cx30, Cx36, or Cx43, the pannexins Px1 or Px2, or the purinergic receptor P2X7 yielded functional (hemi)channels with isoform-specific characteristics. Connexin hemichannels had distinct sensitivity to alterations of extracellular Ca2+ and their permeability to dyes and small atomic ions (conductance) were not proportional. Px1 and Px2 exhibited conductance at positive membrane potentials, but only Px1 displayed detectable fluorescent dye uptake. P2X7, in the absence of Px1, was permeable to fluorescent dyes in an agonist-dependent manner. The large pore channels displayed overlapping sensitivity to the inhibitors Brilliant Blue, gadolinium, and carbenoxolone. These results demonstrated isoform-specific characteristics among the large pore membrane channels; an open (hemi)channel is not a nonselective channel. With these isoform-specific properties in mind, we characterized the divalent cation-sensitive permeation pathway in primary cultured astrocytes. We observed no activation of membrane conductance or Cx43-mediated dye uptake in astrocytes nor in Cx43-expressing C6 cells. Our data underscore that although Cx43-mediated transport is observed in overexpressing cell systems, such transport may not be detectable in native cells under comparable experimental conditions.

Role of vascular potassium channels in the regulation of renal hemodynamics

K(+) conductance is a major determinant of membrane potential (V(m)) in vascular smooth muscle (VSMC) and endothelial cells (EC). The vascular tone is controlled by V(m) through the action of voltage-operated Ca(2+) channels (VOCC) in VSMC. Increased K(+) conductance leads to hyperpolarization and vasodilation, while inactivation of K(+) channels causes depolarization and vasoconstriction. K(+) channels in EC indirectly participate in the control of vascular tone by several mechanisms, e.g., release of nitric oxide and endothelium-derived hyperpolarizing factor. In the kidney, a change in the activity of one or more classes of K(+) channels will lead to a change in hemodynamic resistance and therefore of renal blood flow and glomerular filtration pressure. Through these effects, the activity of renal vascular K(+) channels influences renal salt and water excretion, fluid homeostasis, and ultimately blood pressure. Four main classes of K(+) channels [calcium activated (K(Ca)), inward rectifier (K(ir)), voltage activated (K(V)), and ATP sensitive (K(ATP))] are found in the renal vasculature. Several in vitro experiments have suggested a role for individual classes of K(+) channels in the regulation of renal vascular function. Results from in vivo experiments are sparse. We discuss the role of the different classes of renal vascular K(+) channels and their possible role in the integrated function of the renal microvasculature. Since several pathological conditions, among them hypertension, are associated with alterations in K(+) channel function, the role of renal vascular K(+) channels in the control of salt and water excretion deserves attention.

Closure of multiple types of K+ channels is necessary to induce changes in renal vascular resistance in vivo in rats

Inhibition of K+ channels might mediate renal vasoconstriction. As inhibition of a single type of K+ channel caused minor or no renal vasoconstriction in vivo in rats, we hypothesized that several classes of K+ channels must be blocked to elicit renal vasoconstriction. We measured renal blood flow (RBF) in vivo in anesthetized Sprague–Dawley rats. Test agents were infused directly into the renal artery to avoid systemic effects. Inhibition of BKCa and Kir channels (with TEA and Ba2+, respectively) caused small and transient reductions in RBF (to 93 ± 2% and 95 ± 1% of baseline, respectively). KATP, SKCa or Kv channel blockade (with glibenclamide, apamin and 4-aminopyridine, respectively) was without effect. However, a cocktail of all blockers caused a massive reduction of RBF (to 15 ± 10% of baseline). Nifedipine and mibefradil abolished and reduced, respectively, this RBF reduction. The effect of the cocktail of K+ channel blockers was confirmed in mice using the isolated blood-perfused juxtamedullary nephron preparation. A cocktail of K+ channel openers (K+, NS309, NS1619 and pinacidil) had only a minor effect on baseline RBF in vivo in rats, but reduced the vasoconstriction induced by bolus injections of norepinephrine or angiotensin II (by 33 ± 5% and 60 ± 5%, respectively). Our results indicate that closure of numerous types of K+ channels could participate in the mediation of agonist-induced renal vasoconstriction. Our results also suggest that renal vasoconstriction elicited by K+ channel blockade is mediated by nifedipine-sensitive Ca2+ channels and partly by mibefradil-sensitive Ca2+ channels.

Connexin mimetic peptides fail to inhibit vascular conducted calcium responses in renal arterioles

Vascular conducted responses are believed to play a central role in controlling the microcirculatory blood flow. The responses most likely spread through gap junctions in the vascular wall. At present, four different connexins (Cx) have been detected in the renal vasculature, but their role in transmission of conducted vasoconstrictor signals in the preglomerular arterioles is unknown. Connexin mimetic peptides were previously reported to target and inhibit specific connexins. We, therefore, investigated whether conducted vasoconstriction in isolated renal arterioles could be blocked by the use of mimetic peptides directed against one or more connexins. Preglomerular resistance vessels were microdissected from kidneys of Sprague-Dawley rats and loaded with fura 2. The vessels were stimulated locally by applying electrical current through a micropipette, and the conducted calcium response was measured 500 mum from the site of stimulation. Application of connexin mimetic peptides directed against Cx40, 37/43, 45, or a cocktail with equimolar amounts of each, did not inhibit the propagated response, whereas the nonselective gap junction uncoupler carbenoxolone completely abolished the propagated response. However, the connexin mimetic peptides were able to reduce dye coupling between rat aorta endothelial cells shown to express primarily Cx40. In conclusion, we did not observe any attenuating effects on conducted calcium responses in isolated rat interlobular arteries when exposed to connexin mimetic peptides directed against Cx40, 37/43, or 45. Further studies are needed to determine whether conducted vasoconstriction is mediated via previously undescribed pathways.

Na+-independent, nifedipine-resistant rat afferent arteriolar Ca2+ responses to noradrenaline: possible role of TRPC channels.

Aim:  In rat afferent arterioles we investigated the role of Na+ entry in noradrenaline (NA)‐induced depolarization and voltage‐dependent Ca2+ entry together with the importance of the transient receptor potential channel (TRPC) subfamily for non‐voltage‐dependent Ca2+ entry.

Norepinephrine inhibits intercellular coupling in rat cardiomyocytes by ubiquitination of connexin43 gap junctions

Abstract Gαq-stimulation reduces intercellular coupling within 10 min via a decrease in the membrane lipid phosphatidylinositol-4,5-bisphosphate (PIP2), but the mechanism is unknown. Here we show that uncoupling in rat cardiomyocytes after stimulation of α-adrenergic Gαq-coupled receptors with norepinephrine is prevented by proteasomal and lysosomal inhibitors, suggesting that internalization and possibly degradation of connexin43 (Cx43) is involved. Uncoupling was accompanied by increased Triton X-100 solubility of Cx43, which is considered a measure of the non-junctional pool of Cx43. However, inhibition of the proteasome and lysosome further increased solubility while preserving coupling, suggesting that communicating gap junctions can be part of the soluble fraction. Ubiquitination of Cx43 was also increased, and Cx43 co-immunoprecipitated with the ubiquitin ligase Nedd4. Conclusions: Norepinephrine increases ubiquitination of Cx43 in cardiomyocytes, possibly via Nedd4. We suggest that Cx43 is subsequently internalized, which is preceded by acquired solubility in Triton X-100, which does not lead to uncoupling per se.

Connexin abundance in resistance vessels from the renal microcirculation in normo- and hypertensive rats.

The expression of connexins in renal arterioles is believed to have a profound impact on conducted responses, regulation of arteriolar tonus and renal blood flow. We have previously shown that in renal preglomerular arterioles, conducted vasomotor responses are 40% greater in spontaneously hypertensive rats (SHR) than in normotensive Sprague–Dawley (SD) rats. Because conducted vasomotor responses depend on the cell–cell communication mediated through gap junctions, we hypothesized that the increased magnitude of conducted vasomotor response in SHR is associated with an increased amount of connexins in renal arterioles. To test this hypothesis, the amount of connexin 37 (Cx37), Cx40 and Cx43 was assessed in renal arterioles from normo‐ and hypertensive rats using quantitative immunofluorescence laser confocal miscroscopy. To account for differences in genetic background, we included both normotensive Wistar–Kyoto (WKY) and SD rats in the study. In all three strains of rats, and for all three isoforms, the expression of connexins was predominantly confined to the endothelial cells. We found a significantly increased abundance (240 ± 17.6%, p<0.05) of Cx37 in arterioles from WKY compared with SD and SHR. This high abundance of Cx37 was not related to blood pressure because normotensive SD demonstrated a level of Cx37 similar to that of SHR. Additionally, we found no evidence for an increased abundance of Cx40 and Cx43 in renal arterioles of SHR when compared with normotensive counterparts.