Involvement of myoendothelial gap junctions in the actions of endothelium-derived hyperpolarizing factor

The nature of the vasodilator endothelium-derived hyperpolarizing factor (EDHF) is controversial, putatively involving diffusible factors and/or electrotonic spread of hyperpolarization generated in the endothelium via myoendothelial gap junctions (MEGJs). In this study, we investigated the relationship between the existence of MEGJs, endothelial cell (EC) hyperpolarization, and EDHF-attributed smooth muscle cell (SMC) hyperpolarization in two different arteries: the rat mesenteric artery, where EDHF-mediated vasodilation is prominent, and the femoral artery, where there is no EDHF-dependent relaxation. In the rat mesenteric artery, stimulation of the endothelium with acetylcholine (ACh) evoked hyperpolarization of both ECs and SMCs, and characteristic pentalaminar MEGJs were found connecting the two cell layers. In contrast, in the femoral artery, ACh evoked hyperpolarization in only ECs but not in SMCs, and no MEGJs were present. Selective hyperpolarization of ECs or SMCs evoked hyperpolarization in the other cell type in the mesenteric artery but not in the femoral artery. Disruption of gap junctional coupling using the peptide Gap 27 markedly reduced the ACh-induced hyperpolarization in SMCs, but not in ECs, of the mesenteric artery. These results show that transfer of EC hyperpolarization or of a small molecule to SMCs through MEGJs is essential and sufficient to explain EDHF.     

Ca2+ and inositol 1,4,5-trisphosphate-mediated signaling across the myoendothelial junction

Second messenger signaling between endothelial cells (ECs) and vascular smooth muscle cells (VSMCs) is poorly understood, but intracellular Ca2+ concentrations ([Ca2+]i) in the 2 cells are coordinated, possibly through gap junctions at the myoendothelial junction. To study heterocellular calcium signaling, we used a vascular cell coculture model composed of monolayers of ECs and VSMCs. Stimulation of either cell type leads to an increase in [Ca2+]i in the stimulated cell and a secondary increase in [Ca2+]i in the other cell type that was blocked by gap junction inhibitors. To determine which second messengers are involved, we initially depleted Ca2+ stores in the endoplasmic reticulum Ca2+ with thapsigargin in ECs or VSMCs, but this had no effect on heterocellular calcium signaling. Alternatively, we loaded ECs or VSMCs with 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA) to buffer changes in [Ca2+]i. BAPTA loading of ECs inhibited agonist-induced increases in intracellular calcium concentration ([Ca2+]i), in both ECs and VSMCs. In contrast, BAPTA loading of the VSMCs blunted the VSMC response but did not alter the secondary increase in EC [Ca2+]i. Xestospongin C (an inositol 1,4,5-trisphosphate receptor inhibitor) had no effect on the secondary Ca2+ response, but when xestospongin C or thapsigargin was loaded into ECs and BAPTA into VSMCs, intercellular Ca2+ signaling was completely blocked. We conclude that 1,4,5-trisphosphate and Ca2+ originating in the VSMCs induces the secondary increase in EC [Ca2+]i but stimulation of the ECs generates a Ca2+ dependent response in the VSMCs.     

Proton permeation through the myocardial gap junction

Although protons can directly or indirectly gate solute permeability of the myocardial gap junction, there is little information regarding their own permeation, despite their importance in the regulation of myocardial contractility and rhythm. By pipette-loading of acid into guinea pig isolated, ventricular myocyte pairs while imaging pH(i) confocally using SNARF fluorescence, we have observed that protons permeate the junctional region. Permeation is inhibited by glycyrrhetinic acid, an agent that also increases intercellular electrical resistance, suggesting H+ permeation via gap junctions. The rate of spread of acid between cells appears to be limited by junctional permeation rather than by cytoplasmic diffusion. Mathematical analyses, combined with experiments using SNARF as a proton carrier, suggest that gap junctional H+ transmission may be accomplished physiologically by the permeation of intrinsic "proton-porter" molecules. We propose that proton flux through gap junctions will contribute to the dissipation of regional acid loads within the myocardium. This represents a mechanism for the local control of myocardial pH(i).     

Trafficking of gap junction channels at a vertebrate electrical synapse in vivo

Trafficking and turnover of transmitter receptors required to maintain and modify the strength of chemical synapses have been characterized extensively. In contrast, little is known regarding trafficking of gap junction components at electrical synapses. By combining ultrastructural and in vivo physiological analysis at identified mixed (electrical and chemical) synapses on the goldfish Mauthner cell, we show here that gap junction hemichannels are added at the edges of GJ plaques where they dock with hemichannels in the apposed membrane to form cell-cell channels and, simultaneously, that intact junctional regions are removed from centers of these plaques into either presynaptic axon or postsynaptic dendrite. Moreover, electrical coupling is readily modified by intradendritic application of peptides that interfere with endocytosis or exocytosis, suggesting that the strength of electrical synapses at these terminals is sustained, at least in part, by fast (in minutes) turnover of gap junction channels. A peptide corresponding to a region of the carboxy terminus that is conserved in Cx36 and its two teleost homologs appears to interfere with formation of new gap junction channels, presumably by reducing insertion of hemichannels on the dendritic side. Thus, our data indicate that electrical synapses are dynamic structures and that their channels are turned over actively, suggesting that regulated trafficking of connexons may contribute to the modification of gap junctional conductance.     

心脏缝隙连接和心房颤动

在心脏中,缝隙连接(gap junction,GJ)是存在于相临心肌细胞间的一种由特殊膜蛋白通道组成的具有亲水性的特殊低阻抗区域,它的主要功能是介导细胞间电和化学信号的传导.心房颤动(atrial fibrillation,AF)是临床上最常见的持续性快速心律失常,近年来随着对AF发病机制研究的深入,GJ与AF的关系正日益受到关注,本文就此作一综述.     

异型缝隙连接通道和磷酸化对心脏缝隙连接的调变

目的 检测由缝隙连接蛋白(connexin，Cx)43和Cx45组成的多种异型缝隙连接通道(her—eromultimeric gap junction channels，HGJC)和磷酸化对缝隙连接(gap junction，GJ)的调变作用。方法 将转染了编码为Cx43或Cx45的DNA后的Hela细胞放置在一起共同培养组成双侧和单侧异型GJ通道。显微注射若丹明123(rhodamine123，Rh)检测经200nmol／L十四(烷)酰佛波醇乙酸酯(12-0-tetrade—canoylphorbol-13-acetae，TPA)处理前后，在紫外光显示下由Cx43和Cx45所组成的不同GJ通道对荧光染料的偶联率(coupling ratio)。结果 在不同的GJ中，同型GJ通道Cx43(homotypie Cx43，HoCx43)偶联率最高。从Cx45侧注入荧光染料的单侧异型GJ通道45(mono-heteromeric Cx45-Cx43／45，MH45)偶联率较之从Cx43／45侧注入荧光染料的MH45、双侧异型GJ通道Cx43／45(bi-heteromeric Cx43／45，BH43／45)及同型GJ通道Cx45(homotypic Cx45，HoCx45)等的偶联率是最低的。根据HoCx43或HoCx45通道的偶联率对各型通道偶联率进行标准化处理。BH43／45和MH43通道的偶联率均较HoCx43降低。对MH45通道来说，从Cx43／45侧注射的通道偶联率大于从Cx45侧注射的偶联率。TPA处理后HoCx43的偶联率降低，而当Cx43和Cx45组合成BH43／45和MH43通道后其偶联率下降更显著。结论 Cx43和Cx45共同表达可构成BH43／45、MH43和MH45等异型通道，而这些通道可降低细胞间的通讯并对磷酸化的作用不敏感。单侧异型GJ通道的偶联率取决于染料注射的方向。     

缝隙连接在大鼠缺血预适应心肌保护中的作用

目的探讨心肌缝隙连接在缺血预适应中的调控机制以及在预适应信号传导通路中的地位和作用。方法Sprague—Dawley大鼠进行30min的冠状动脉缺血和4h再灌注,根据是否使用缺血预适应、二氮嗪、18β-甘草次酸和5-羟基奎酸分为7组,即对照组（单纯缺血再灌注）、缺血预适应组、缺血预适应和5-羟基奎酸合用组、二氮嗪组、二氮嗪和5-羟基奎酸合用组、甘草次酸组、甘草次酸和5-羟基奎酸合用组。测量各组的血流动力学指标、心肌梗死面积以及缝隙连接蛋白43的磷酸化和内化。结果与对照组相比,缺血预适应、二氮嗪、18β-甘草次酸能降低心肌梗死面积（P〈0．001）,5-羟基奎酸可以阻断缺血预适应和二氮嗪的心肌保护作用（P〉0．05）,但是对缝隙连接失耦联剂甘草次酸没有影响（P〈0．001）。缺血预适应和线粒体三磷酸腺苷敏感性钾通道开放剂二氮嗪能促进缝隙连接蛋白43磷酸化,抑制去磷酸化和内化（P〈0．001,P〈0．001）,线粒体三磷酸腺苷敏感性钾通道阻断剂5-羟基奎酸能阻断该作用（P〉0．05,P〉0．0051）。结论缺血预适应通过开放线粒体三磷酸腺苷敏感性钾通道来调节缝隙连接蛋白43的磷酸化和内化,进而调控缝隙连接的化学转运,减少心肌梗死面积。     

Quinine blocks specific gap junction channel subtypes

We demonstrate that the antimalarial drug quinine specifically reduces currents through gap junctions formed by some connexins (Cx) in transfected mammalian cells, but does not affect other gap junction types. Quinine blocked Cx36 and Cx50 junctional currents in a reversible and concentration-dependent manner with half maximal blocking concentrations of 32 and 73 microM, respectively; Hill coefficients for block by quinine were about 2 for both connexins. In contrast, quinine did not substantially block gap junction channels formed by Cx26, Cx32, Cx40, and Cx43, and only moderately affected Cx45 junctions. To determine the location of the binding site of quinine (pKa = 8.7), we investigated the effect of quinine at various external and internal pH values and the effect of a permanently charged quaternary derivative of quinine. Our results indicate that the binding site for quinine is intracellular, possibly within the pore. Single-channel studies indicated that exposure to quinine induced slow transitions between open and fully closed states that decreased open probability of the channel. Quinine thus offers a potentially useful method to block certain types of gap junction channels, including those between neurons that are formed by Cx36. Moreover, quinine derivatives that are excluded from other types of membrane channels may provide molecules with connexin-specific as well as connexin-selective blocking activity.     

Endothelial feedback and the myoendothelial projection

The endothelium plays a critical role in controlling resistance artery diameter, and thus blood flow and blood pressure. Circulating chemical mediators and physical forces act directly on the endothelium to release diffusible relaxing factors, such as NO, and elicit hyperpolarization of the endothelial cell membrane potential, which spreads to the underlying smooth muscle cells via gap junctions (EDH). It has long been known that arterial vasoconstriction in response to agonists is limited by the endothelium, but the question of how contraction of smooth muscle cells leads to activation of the endothelium (myoendothelial feedback) has, until recently, received little attention. Initial studies proposed the permissive movement of Ca(2+) ions from smooth muscle to endothelial cells to elicit release of NO. However, more recent evidence supports the notion that flux of IP(3) leading to localized Ca(2+) events within spatially restricted myoendothelial projections and activation of EDH may underlie myoendothelial feedback. In this perspective, we review recent data which supports the functional role of myoendothelial projections in smooth muscle to endothelial communication. We also discuss the functional evidence supporting the notion that EDH, as opposed to NO, is the primary mediator of myoendothelial feedback in resistance arteries.     

Vascular influences on the dynamic stability of the choledochoduodenal junction

Alterations of arterial, hepatic portal, and central venous pressures are shown to be associated with changes in the same direction of the opening pressures of the canine choledochoduodenal junction. Increases in opening pressures subsequent to increases in vascular pressures could be abolished by the intraductal administration of norepinephrine. Experiments employing the systematic intraductal administration of various pharmacological agents produced data that are interpreted to indicate that alterations in ductal opening pressures are preponderantly dependent in the dog upon local vascular effects.