Biophysical properties of gap junctions between freshly dispersed pairs of mouse pancreatic beta cells.

Coupling between beta cells through gap junctions has been postulated as a principal mechanism of electrical synchronization of glucose-induced activity throughout the islet of Langerhans. We characterized junctional conductance between isolated pairs of mouse pancreatic beta cells by whole-cell recording with two independent patch-clamp circuits. Most pairs were coupled (67%, n = 155), although the mean junctional conductance (gj) (215 +/- 110 pS) was lower than reported in other tissues. Coupling could be recorded for long periods, up to 40 min. Voltage imposed across the junctional or nonjunctional membranes had no effect on gj. Up to several hours of treatment to increase intracellular cAMP levels did not affect gj. Electrically coupled pairs did not show transfer of the dye Lucifer yellow. Octanol (2 mM) reversibly decreased gj. Lower concentrations of octanol (0.5 mM) and heptanol (0.5 mM) than required to uncouple beta cells decreased voltage-dependent K+ and Ca2+ currents in nonjunctional membranes. Although gj recorded in these experiments would be expected to be provided by current flowing through only a few channels of the unitary conductance previously reported for other gap junctions, no unitary junctional currents were observed even during reversible suppression of gj by octanol. This result suggests either that the single channel conductance of gap junction channels between beta cells is smaller than in other tissues (less than 20 pS) or that the small mean conductance is due to transitions between open and closed states that are too rapid or too slow to be resolved.     

Formation of gap junctions by expression of connexins in Xenopus oocyte pairs

RNAs coding for connexins 32, 43, and the putative lens gap junction protein MP26 were tested for their ability to induce cell-cell coupling in Xenopus oocyte pairs. Large, voltage-insensitive conductances developed when connexin32 and 43 RNA-injected oocytes were paired both with themselves and with each other. Oocyte pairs injected with water manifested small conductances, which were symmetrically voltage-dependent. MP26 RNA-injected pairs displayed no conductances above control values. Unexpectedly, connexin43/water oocyte pairs developed high, asymmetrically voltage-dependent conductances, a property not displayed by the connexin32/water pairs. In single oocytes, these proteins remained intracellular until pairing, at which time the connexins, but not MP26, concentrated at the appositional areas.     

Hepatic gap junctions in the hepatocarcinogen-resistant DRH rat

Although the gap junction or connexin (Cx) is considered to be a tumor-suppressor, it is also required for tumor promotion. Therefore, we examined hepatic gap junctions in hepatocarcinogen-resistant (DRH) rats. Specifically, we investigated gap junction structure and Cx32 expression during normal conditions and in response to a hepatocarcinogen, 3'-methyl-4-dimethylaminoazobenzene (3'-MeDAB). On a basal diet without 3'-MeDAB, hepatic gap junctions and Cx32 protein expression were greater in DRH rats than in control Donryu rats, as evidenced by morphometry, immunohistochemistry and immunoblotting. On a diet containing 3'-MeDAB, gap junctions and expressed Cx32 were increased significantly in Donryu rats, but not in DRH rats. In this condition, Donryu rats lost weight but DRH rats increased relative liver weight. After 3'-MeDAB treatment, cathepsin D expression in hepatocytes was significantly increased only in Donryu rats, indicating that DRH rats were less susceptible to 3'-MeDAB. The abundance of mitogen-activated protein kinase, some constituent of which might be associated with the degree of Cx protein phosphorylation, was reduced to a greater extent in Donryu than in DRH rats after 3'-MeDAB treatment. The resistance of DRH rats to carcinogenesis may be due partially to their stabilized gap junctions, which could coordinate metabolic coupling to evade 3'-MeDAB toxicity.     

Electrophysiological properties and gap junction coupling of striatal astrocytes

The striatum is the biggest nucleus of the basal ganglia and receives input from almost all cortical regions, substantia nigra and the thalamus. Striatal neuronal circuitry is well characterized, but less is known about glial physiology. To this end, we evaluated astrocyte electrophysiological properties using whole-cell patch-clamp recording in dorsal striatal brain slices from P15 to P21 rat. The majority of cells (95%) were passive astrocytes that do not express any detectable voltage-gated channels. Passive astrocytes were subcategorized into three groups based on time-dependent current properties. The observed proportion of the different astrocyte subtypes did not change within the age range evaluated here, but was modulated during reduction of specific conductances and gap junction coupling. Striatal astrocytes were extensively interconnected and closure of gap junctions with octanol (1 mM), carbenoxolone (100 μM) or increased intracellular calcium (2 mM), significantly altered intrinsic properties. When simultaneously blocking potassium channels and gap junction coupling almost no passive conductance was detected, implying that the major currents in striatal astrocytes derive from potassium and gap junction conductance. Uncoupling of the syncytium reduced currents activated in response to a hyperpolarizing pulse, suggesting that changes in gap junction coupling alters astrocyte electrophysiological responses. Our findings indicate that the prevalent gap junction coupling is vital for astrocyte function in the striatum, and that whole-cell recordings will be distorted by currents activated in neighboring cells.     

Alterations of tight and gap junctions in mouse hepatocytes following administration of colchicine

Summary Mature columnar cells of the midgut of Cubitermes contain a prominent secretion product observed at light- and electron-microscopic levels. At the ultrastructural level the product is resolved as an electron dense material contained in vesicles up to 1 m diameter that accumulate in the apical cytoplasm. The vesicles are composite, apparently formed by coalescence of at least two types of precursor vesicle both of which originate from the Golgi apparatus. Discharge of the product takes place by exocytosis into intercellular space at or in the vicinity of the apical septate junction complex. Augmentation of apical surface area by microvilli is less prominent in Cubitermes than in other termites for which data are available. This and other evidence suggests that absorptive functions are reduced in the midgut of this insect.     

Hormonal modulation of gap junctions in rat ovarian follicles

Summary Homocellular gap junctions between granulosa cells and between theca interna cells, and heterocellular gap junctions between granulosa cells and oocytes persist in rat ovarian follicles for as long as 90 days following hypophysectomy. Gonadotrophic and/or steroid hormones are therefore not required for the maintenance of gap junctions between these cells during early follicular growth. However, replacement therapy with estrogen and human chorionic gonadotrophin results in amplification of gap junctions in granulosa and theca interna cells respectively. Within 24 h following hormonal stimulation, growth of gap junctions is characterized by the appearance of formation plaques as observed in freeze-fracture replicas and by the association of microfilamentous material located subadjacent to gap junction membrane observable in thin-sectioned cells.     

Electrophysiological properties of human oviduct smooth muscle cells in dissociated cell culture.

Intracellular recordings were made from human oviduct smooth muscle maintained in cell culture. Solitary cells isolated from one another and cells in contact with one another retained electrical properties of smooth muscle in vivo. Membrane potential of solitary cells and connected cells was -35 mV. Connected cells formed electrotonic junctions which transmitted current from one cell to another. This current spread was responsible for differences in input resistance and time constant in solitary cells, 66 Momega and 96 msec, compared to connected cells, 26 Momega and 56 msec. All cells expressed delayed rectification to depolarizing current pulses. Some cells generated action potentials spontaneously or in response to intracellular current pulses. Action potentials were abolished by cobalt or by EGTA. Slow wave potentials, 5 . 20 mV in amplitude, occurred continuously once every 15 to 45 seconds in connected cells.     

Morphometric analysis of gap junctions in rat myocardium after hyperkalemia

The effect of membrane depolarization was investigated on gap junctions from isolated rat hearts perfused with a modified Krebs-Henseleit solution containing 16 mM K+. After freeze-fracturing, the configuration of the junctional particles in the ventricular myocardium was analysed by measurements of connexon densities and centre-to-centre distances between neighbouring particles. Both in control and hyperkalemic tissue, the gap junctions occur on the intercalated discs as round or oval aggregates of connexons which are closely and regularly packed in small, criss-cross-oriented arrays separated by particle-free aisles. Within the arrays, the mean (+/- SD) centre-to-centre distances between particles from control and hyperkalemic tissue, i.e. 9.17 +/- 1.52 and 9.15 +/- 1.51 mm, respectively, are not significantly different. Similarly, comparison of particle densities after control and high-K+ perfusion, i.e. 8,490 +/- 600 and 8,420 +/- 620 particles/microns 2, respectively, reveals no difference in the proportion of the particle arrays to the empty aisles. The apparently unaltered gap junctional morphology after depolarization of the sarcolemma by high-K+ perfusion provides support for the electrophysiological finding that the conductance of cardiac gap junctions is insensitive to membrane potential.     

Internalized gap junctions in ciliary epithelium of rabbit and rat

Summary Transmission electron microscopy was used to examine internalized gap junctions (IGJ) in rabbit and rat ciliary epithelial cells. A prominent feature of all the specimens studied was the presence of different images of IGJ membrane that entrapped a portion of an adjoining cell. We documented and analyzed more than 500 gap junction (GJ) vacuoles and invaginations, the latter comprising less than 20% of all the structures examined. With ten exceptions found in non-pigmented cells, all the IGJ were unidirectionally internalized within the cytoplasm of pigmented epithelial cells. Morphological signs of autophagic degradation of GJ vacuoles were observed. An essential finding was that once a GJ membrane started to invaginate, a lucidation of a part of the protruding cytoplasm occurred; no planar GJ membranes exhibited such an alteration. The present findings suggest that IGJ derived from the epithelium of ciliary processes arise through an invagination-endocytosis mechanism and are degraded autophagically. This phenomenon may be relevant to aqueous humor production.     

Organization of connexons in isolated rat liver gap junctions.

Gap junction plaques from rat liver plasma membranes have been subjected to a range of detergent treatments in order to evaluate systematically the influence of different isolation procedures on their structure. The separation of the connexons was found to vary depending on the conditions used. In the absence of detergent the center-to-center separation of the connexons is, on average, approximately 90 A, and they are arranged on a hexagonal lattice so that the symmetry of the double-layered structure approximates to p6m in projection (or p622 in three-dimensions). Exposure to increasing concentration of detergent reduces the connexon separation to values below 80 A. More severe detergent treatment leads to disintegration of the gap junction plaques. Specimens with center-to-center separations smaller than 86 A show progressively larger deviation from p6m symmetry, seen as apparent rotations of the connexon assemblies within the crystal lattice. This reorganization occurs with both ice-embedded and negatively-stained specimens, using ionic or nonionic detergents, and therefore is probably a packing readjustment caused by depletion of intervening lipid molecules.     

An ultrastructural and electrophysiological study of the development of neuro-muscular junctions between previously dissociated foetal rat cells in vitro

Summary The development of neuro-muscular junctions between previously dissociated foetal rat spinal cord and somatic muscle has been investigated. The first indications of junction formation, both ultrastructurally and electrophysiologically, were observed after circa 18 days in vitro. The junctions contained numerous vesicles, but no secondary folds were developed even after 6 weeks in culture, and synaptic densities were not well marked. Functional endplates were found, and action potentials, endplate potentials and miniature endplate potentials recorded.The authors wish to thank Mr. D. Fraser, B. Sc., for valued technical help, and Mr. S. Waterman for photographic printing.