Gap junctions

Electrical coupling through gap junctions constitutes a mode of signal transmission between neurons (electrical synaptic transmission). Originally discovered in invertebrates and in lower vertebrates, electrical synapses have recently been reported in immature and adult mammalian nervous systems. This has renewed the interest in understanding the role of electrical synapses in neural circuit function and signal processing. The present review focuses on the role of gap junctions in shaping the dynamics of neural networks by forming electrical synapses between neurons. Electrical synapses have been shown to be important elements in coincidence detection mechanisms and they can produce complex input-output functions when arranged in combination with chemical synapses. We postulate that these synapses may also be important in redefining neuronal compartments, associating anatomically distinct cellular structures into functional units. The original view of electrical synapses as static connecting elements in neural circuits has been revised and a considerable amount of evidence suggests that electrical synapses substantially affect the dynamics of neural circuits.     

Gap junctions between pinealocytes

Summary The intercellular junctions between the pinealocytes of male rats were investigated by freeze-fracture and conventional electron microscopy.Our findings reveal that the intercellular contacts between pineal cells, formerly described as zonulae adhaerentes or zonulae occludentes, are in fact gap junctions which are difficult to characterize in thin sections due to their peculiar geometrical arrangement, which is in the form of fenestrated communicating zonules.The arrangement of these communicating zonules around rudimentary lumina of pineal clusters and rare transitions between tight and gap junctions may point to phylogenetic transformations of occluding into communicating zonules, corresponding with the change of the pineal gland from a sensory to a secretory organ. Alternatively, these tight-to-gap junctional transitions may reflect the periodic (circadian or seasonal) activity of the pineal gland.These Studies were supported by the German Research Foundation within the SFB 90 Cardiovasculäres System     

Gap junctions and tumour progression

Gap junctional intercellular communication has been implicated in growth control and differentiation. The mechanisms by which connexins, the gap junction proteins, act as tumor suppressors are unclear. In this review, several different mechanisms are considered. Since transformation results in a loss of the differentiated state, one mechanism by which gap junctions may control tumour progression is to promote or enhance differentiation. Processes of differentiation and growth control are mediated at the genetic level. Thus, an alternative or complimentary mechanism of tumour suppression could involve the regulation of gene expression by connexins and gap junctional coupling. Finally, gap junction channels form a conduit between cells for the exchange of ions, second messengers, and small metabolites. It is clear that the sharing of these molecules can be rather selective and may be involved in growth control processes. In this review, examples will be discussed that provide evidence for each of these mechanisms. Taken together, these findings point to a variety of mechanims by which connexins and the gap junction channels that they form may control tumour progression.     

Gap junctions as electrical synapses

Gap junctions are the morphological substrate of one class of electrical synapse. The history of the debate on electrical vs. chemical transmission is instructive. One lesson is that Occam’s razor sometimes cuts too deep; the nervous system does its operations in a number of different ways and a unitarian approach can lead one astray. Electrical synapses can do many things that chemical synapses can do, and do them just as slowly. More intriguing are the modulatory actions that chemical synapses can have on electrical synapses. Voltage dependence provides an important window on structure function relations of the connexins, even where the dependence may have no physiological role. The new molecular approaches will greatly advance our knowledge of where gap junctions occur and permit experimental manipulation with high specificity.     

Gap junctions between guinea-pig pinealocytes

Summary In accordance with previous results in rats, belt-like arrangements of fenestrated gap junctions have been found around the collicular segments of pineal cells in the guinea pig. In addition, macular interpinealocyte gap junctions have been observed in this species.S.-K. Huang was a recipient of a Humboldt Foundation fellowship.     

Gap junctions in excitable cells

Gap junction channels are an integral part of the conduction or propagation of an action potential from cell to cell. Gap junctions have rather unique gating and permeability properties which permit the movement of molecules from cell to cell. These molecules may not be directly linked to action potentials but can alter nonjunctional processes within cells, which in turn can affect conduction velocity. The data described in this review reveal that, for the majority of excitable cells, there are two limiting factors, with respect to gap junctions, that affect the conduction/propagation of action potentials. These are (1) the total number of channels and (2) the selective permeability of the channels. Interestingly, voltage dependence and the time course of voltage inactivation (kinetics) are not rate limiting steps under normal physiological conditions for any of the connexins studied so far. Only specialized rectifying electrical synapses utilize strong voltage dependence and rapid kinetics to permit or deny the continued propagation of an action potential.     

细胞缝隙连接与心血管疾病

目录一、细胞缝隙连接的形态和结构二、细胞缝隙连接的功能　 (一 )参与信息的传递及神经冲动的传导　 (二 )协调细胞间活动的一致性　 (三 )参与细胞的分化生长与发育　 (四 )缓冲毒性化学物质的毒害作用　 (五 )通过周围细胞滋养受损细胞　 (六 )参与局部的代谢功能三、细胞缝隙连接蛋白功能的调节四、缝隙连接和心血管疾病　 (一 )心律失常　 (二 )动脉粥样硬化　 (三 )先天性心脏病　 (四 )缺血性心脏病　 (五 )心肌病细胞间通讯是一个在进化上很古老的功能 ,细胞间的通讯方式可分为间接与直接方式。以体循环远程分泌、旁分泌或自分泌方…     

神经组织缝隙连接

近年来神经组织中缝隙连接的分布和功能研究取得了一些显著进展。分子生物学方法的应用促进了ＧＪ结构,亚型及生物物理特性的揭示,染料偶联实验和Ｃａ＾２＋成像技术为ＧＪ的功能研究提供了直观有效的手段。ＧＪ的调控涉及ＧＪ的表达,导通性的改变等环节。ＧＪ胞间通讯的基本形式是交换第二信使和电偶联。     

Gap junctions in human sebaceous glands

Summary An examination of human sebaceous glands by transmission electron microscopy has revealed the presence of gap junctions. The junctions are found in abundance between differentiating cells, and annular forms are also seen. The possible significance of this new finding is briefly discussed.We thank the ENT consultant staff of Royal Prince Alfred Hospital, Sydney, for making tissue available. The co-operation of the director, Dr. D.J.H. Cockayne, and staff of the University of Sydney Electron Microscope Unit is gratefully acknowledged. Mr. E. Foster provided excellent assistance with the photography. -The project was supported by the Consolidated Medical Research Funds, University of Sydney, and the National Health and Medical Research Council of Australia. One of us (N.K.) was the recipient of the Phyllis Anderson Medical Research Fellowship awarded by the Faculty of Medicine, University of Sydney     

Role of Gap junctions in bone tissue

Gap junctions are transmembrane channels, that connect the membranes of adjacent cells and are involved in the direct signal transmission between the cells. The intercellular communication involving this type of channels provides the proper functioning of tissues and organs. Gap junctions formation and synthesis of connexins is regulated by hormones, growth factors and signaling molecules. Gap junctions, located between osteoblasts, osteoclasts, and osteocytes, play a key role in the process of bone turnover, and therefore in the modeling and bone tissue regeneration. They also mediate the regulation of proliferation, differentiation and maturation of osteoblasts, as well as formation and activity of osteoclasts. This paper presents the current state of knowledge on the role of intercellular connections via Gap junctions in bone cells, with particular emphasis on the involvement of connexin 43, in the regulation of osteogenesis.     

Gap junctions in hemodichorial and hemotrichorial placentae

Summary Gap junctions were found to be a constant feature of chorioallantoic placentae with two or three trophoblastic layers. The gap junctions connect layers I and II in hemodichorial and layers II and III in hemotrichorial placentae. Although the gap junctions vary in form and in the packing density of membrane-associated particles, they cover an extensive surface area in all species examined. The gap junctions always connect adjacent membranes of two trophoblastic layers, which show no evidence of micropinocytotic activity; at least one of these trophoblastic layers is syncytial. It is therefore concluded that the gap junctions play an important role in diaplacental transport. We consider that gap junctions act as molecular sieves, resulting in limitations in the transport of large molecules. The passage of small molecules, on the contrary, would be facilitated by the gap junctions.With the support of the Deutsche ForschungsgemeinschaftDedicated to Prof. Wolfgang Bargmann on his 70. birthdayWe are very grateful to Mrs. B. Brühl, I. Stenull and cand. med. P. Zahn for technical assisstence.We also gratefully acknowledge Prof. Dr. R. Taugner for helping us with freeze-fracturing     

Gap junctions in the rabbit sinoatrial node

In comparison to the cellular basis of pacemaking, the electrical interactions mediating synchronization and conduction in the sinoatrial node are poorly understood. Therefore, we have taken a combined immunohistochemical and electrophysiological approach to characterize gap junctions in the nodal area. We report that the pacemaker myocytes in the center of the rabbit sinoatrial node express the gap junction proteins connexin (Cx)40 and Cx46. In the periphery of the node, strands of pacemaker myocytes expressing Cx43 intermingle with strands expressing Cx40 and Cx46. Biophysical properties of gap junctions in isolated pairs of pacemaker myocytes were recorded under dual voltage clamp with the use of the perforated-patch method. Macroscopic junctional conductance ranged between 0.6 and 25 nS with a mean value of 7.5 nS. The junctional conductance did not show a pronounced sensitivity to the transjunctional potential difference. Single-channel recordings from pairs of pacemaker myocytes revealed populations of single-channel conductances at 133, 202, and 241 pS. With these single-channel conductances, the observed average macroscopic junctional conductance, 7.5 nS, would require only 30-60 open gap junction channels.     

Gap junctions in skeletal development and function

Gap junctions play a critical role in the coordinated function and activity of nearly all of the skeletal cells. This is not surprising, given the elaborate orchestration of skeletal patterning, bone modeling and subsequent remodeling, as well as the mechanical stresses, strains and adaptive responses that the skeleton must accommodate. Much remains to be learned regarding the role of gap junctions and hemichannels in these processes. A common theme is that without connexins none of the cells of bone function properly. Thus, connexins play an important role in skeletal form and function.     

Gap junctions: towards a molecular structure

Gap junctions are ubiquitous plasma membrane specializations that allow cells to exchange small molecules and ions directly. The isolation, biochemical characterization and molecular cloning of the major protein of rat liver gap junctions lead to a clearer view of these membrane zones that allow cells to ‘talk’ to each other and co-ordinate their activities in tissues and organs.     

Gap junctions in several tissues share antigenic determinants with liver gap junctions.

Using affinity-purified antibodies against mouse liver gap junction protein (26 K), discrete fluorescent spots were seen by indirect immunofluorescence labelling on apposed membranes of contiguous cells in several mouse and rat tissues: pancreas (exocrine part), kidney, small intestine (epithelium and circular smooth muscle), Fallopian tube, endometrium, and myometrium of delivering rats. No reaction was seen on sections of myocardium, ovaries and lens. Specific labelling of gap junction plaques was demonstrated by immunoelectron microscopy on ultrathin frozen sections through liver and the exocrine part of pancreas after treatment with gold protein A. Weak immunoreactivity was found on the endocrine part of the pancreas (i.e., Langerhans islets) after glibenclamide treatment of mice and rats, which causes an increase of insulin secretion and of the size as well as the number of gap junction plaques in cells of Langerhans islets. Furthermore, the affinity purified anti-liver 26 K antibodies were shown by immunoblot to react with proteins of similar mol. wt. in pancreas and kidney membranes. Taken together these results suggest that gap junctions from several, morphogenetically different tissues have specific antigenic sites in common. The different extent of specific immunoreactivity of anti-liver 26 K antibodies with different tissues is likely due to differences in size and number of gap junctions although structural differences cannot be excluded.     

Gap junctions. Structural changes after uncoupling procedures

The freeze-fracture appearance of rat stomach and liver gap junctions changes after uncoupling procedures such as inhibition of the metabolism of perfusion with hypertonic sucrose. In control stomach, either fixed immediately or kept for 1 h in a well-oxygenated Tyrode's solution at 37 degrees C, most gap junctions between mucous cells contain particles irregularly packed at an average center-to-center spacing of 10.3-10.5 nm. After 1-h treatment with 2,4-dinitrophenol (DNP), at the same temperature and oxygenation, most particles aggregate hexagonally at an average spacing of approximately 8.5 nm. Similar changes are seen in hypoxic specimens. In control liver, fixed by perfusion, most junctional particles are irregularly packed at an average center-to-center spacing of approximately 10 mm. Small areas of fairly regular hexagonal packing are occasionally seen, where the average particle spacing is 9.2-9.5 nm. In hypoxic liver, the junctional particles form regular hexagonal packings in which the average center-to-center particle spacing is approximately 8.5 nm. In liver perfused with hypertonic sucrose-calcium solutions, following EDTA solutions, most junctions are pulled apart. The separated junctional membranes, expected to be highly impermeable, contain particles regularly and tightly packed as in hypoxic or DNP-treated junctions. Preliminary measurements indicate also a possible change in particle diameter, from approximately 8.6 nm (control) to approximately 7.7 nm (treated). The structural changes are similar to those previously reported in crayfish and may reflect conformational changes in particle subunits resulting in functional uncoupling.