Adhesion and cytosolic dye transfer between macrophages and intestinal epithelial cells

Activated macrophages (M phi) found in the intestinal lesions of patients with inflammatory bowel disease (IBD) secrete many inflammatory mediators which can regulate intestinal epithelial cell (IEC) function. However, little is known about direct M phi-IEC interactions. Two potential mechanisms by which cells may interact are through specific receptor-ligand binding of adhesion molecules, such as integrins or cadherins, and by exchange of cytoplasmic substances through transmembraneous channels called gap junctions. We investigated whether M phi could adhere to epithelial cells in culture and form transmembrane communication channels as defined by dye transfer. Primary cultures of murine M phi and a M phi cell line, P388D1, adhered to Mode-K and IEC6, but not CMT-93 IEC. Antibody blocking studies determined that P388D1-Mode-K binding was partially dependent on beta 2 integrin (CD18) function, Mode-K constitutively expressed CD106 (VCAM-1) and cell associated fibronectin, while P388D1 expressed low levels of CD49d/CD29 (VLA4) but blocking antibodies to these surface molecules did not inhibit P388D1-Mode-K adherence. Transfer of calcein dye from M phi to IEC was quantitated by flow cytometry and was dependent on M phi-IEC adhesion. Dye transfer was concentration dependent in that the fluorescence intensity of Mode-K was proportional to the number of adherent P388D1 cells as well as the dye load of the M phi. These results indicate that M phi interact with IEC by adhesion and possibly through gap junctions and may thus regulate IEC function by direct cell-cell communication.     

A pre-loading method of evaluating gap junctional communication by fluorescent dye transfer

We describe a simple method for evaluating gap junctional communication (GJC) between cells in culture. The procedure involves pre-loading cells with two fluorescent dyes: calcein and DiI. Calcein is able to pass through gap junctions, while DiI is not. These pre-loaded cells are then plated with unlabeled cells. The number of cells receiving calcein from each pre-loaded cell can then be quantified after the cells settle on the plate. Potent and reversible inhibitors of GJC can be used in this system to evaluate dye transfer within a given period of time.     

Neurotransmitter modulation of gap junctional communication in the rat hippocampus

Increasing experimental evidence indicates that gap junctions can be modulated by neurotransmitters, in particular dopamine. To examine possible modulation of gap junctional communication in the rat hippocampus by neurotransmitters, we studied dye coupling and electrotonic transmission in the CA1 area in the presence of carbachol, a cholinergic agonist, and dopamine agonists. Carbachol markedly reduced dye coupling and the frequency of electrotonic potentials (spikelets). Spikelet amplitudes were decreased in the presence of carbachol. These effects were reversed by the cholinergic antagonist atropine, suggesting a muscarinic action of carbachol on gap junctional function. The non-specific dopamine agonist apomorphine, and the specific D1 receptor agonist SKF 38393, reduced dye coupling between pyramidal cells. Spikelet frequency was also decreased in the presence of dopamine agonists, but less than with carbachol. The specific D1 receptor antagonist, SCH 23390, reversed the effects of both dopamine agonists. These observations indicate that cholinergic and dopaminergic transmission can affect electrical and chemical (dye coupling) communication through gap junctions, and could therefore alter properties of neuronal assemblies, in addition to their effects on intrinsic membrane properties.     

In vitro studies of cochlear excitation

Cells in tissues coordinate their activity by sharing ions, second messengers, and small metabolites through clusters of intercellular channels called gap junctions. The thyroid hormones 3,3',5-triiodo-L-thyronine (T3) and L-thyroxine (T4) are capable of modulating gap junctional communication (GJC) as are 1,25-dihydroxyvitamin D3, retinoic acid, and other nuclear receptor ligands. T3 and T4 were found to stimulate GJC in WB-F344 rat liver epithelial cells dose-dependently at concentrations between 1 nM and 0.1 microM, assayed by the dye transfer method using Lucifer Yellow CH. The stimulation of cell-cell communication was preceded by an increase in connexin43 mRNA levels and was accompanied by an accumulation of connexin43 protein measurable 2 days after incubation with these compounds. These observations establish a novel role of thyroid hormones in the regulation of gap junctional intercellular communication via connexin43 gene expression.     

Effects of general anesthetics on intercellular communications mediated by gap junctions between astrocytes in primary culture

BACKGROUND: Astrocytes represent a major nonneuronal cell population in the central nervous system (CNS) and are actively involved in several brain functions. These cells are coupled by gap junctions (GJ) into a syncytial-like network resulting in cellular communication through ionic and metabolic exchange between adjacent astrocytes. Whether anesthetics affect astrocyte function is not known. In the present study, the effects of general anesthetics on GJ permeability were investigated in primary cultures of mouse striatal astrocytes. METHODS: Junctional permeability was determined by using the fluorescent probe Lucifer yellow and the scrape loading/dye transfer technique. Confluent cells were preincubated 5 min with various concentrations of anesthetic agents and GJ permeability was estimated by measuring the area occupied by the dye from digitalized images taken 8 min after cell loading. RESULTS: Of the intravenous anesthetics tested, only propofol (P: 10(-4) M, P < 0.01 and 10(-5) M, P < 0.05) and etomidate (ET: 10(-4) M, P < 0.05, but not 10(-5) M) induced a significant reduction of GJ permeability. In contrast, diazepam (10(-5) M), morphine (10(-4) M), ketamine (10(-4) M), thiopental (10(-4) M), and clonidine (10(-7) M) did not affect junctional permeability. In addition, the halogenated anesthetics halothane, enflurane, and isoflurane induced a dose-dependent closure of GJ. For halothane, enflurane, and isoflurane, the maximum effect was achieved with a 10(-4) M, 1.6 x 10(-3) M, and 10(-3) M anesthetic concentration, respectively. Removal of volatile anesthetics resulted in the restoration of the control fluorescence area between 15 and 45 min. The time course of recovery of GJ permeability was examined more precisely for shorter periods of halothane administration (5 min, 1 mM). Under these conditions, the rate of dye spread returned to control values following anesthetic washout, while, during the same period of time, complete uncoupling of GJ was still observed in the presence of a 1 mM halothane concentration. CONCLUSIONS: These results indicate that general anesthetics differentially affect GJ permeability in cultured astrocytes. This uncoupling effect (closure of gap junctions) may contribute to the mechanisms of action of some anesthetic agents (primarily volatile anesthetics) at the level of the CNS by altering astrocyte communication.     

Gap junctions mediate intercellular calcium signalling in cultured articular chondrocytes

Gap junction-mediated intercellular communication has been implicated in a variety of cellular functions. Among these, signal transduction can be coordinated among several cells due to gap junctional permeability to intracellular second messengers. Chondrocytes from articular cartilage in primary culture respond to extracellular ATP by rhythmically increasing their cytosolic Ca2+ concentration. Digital imaging fluorescence microscopy of Fura-2 loaded cells was used to monitor Ca2+ in confluent and semi-confluent cell layers. Under these conditions, Ca2+ spikes propagate from cell to cell giving rise to intercellular Ca2+ waves. The functional expression of gap junctions was assessed, in confluent chondrocyte cultures, by the intercellular transfer of Lucifer yellow dye in scrape-loading experiments. Intercellular dye transfer was blocked by the gap junction inhibitor 18 alpha-glycyrrhetinic acid. In imaging experiments, the inhibitor caused the loss of synchrony of ATP-induced Ca2+ oscillations, and blocked the intercellular Ca2+ propagation induced by mechanical stimulation of a single cell in a monolayer. It is concluded that gap junctions mediate intercellular signal transduction in cartilage cells and may provide a mechanism for co-ordinating their metabolic activity.     

Emergence of undifferentiated rat tracheal cell carcinomas, but not squamous cell carcinomas, is associated with a loss of expression of E-cadherin and of gap junction communication

A series of cells representing normal, non-tumorigenic cell lines, as well as differentiating neoplastic and undifferentiated neoplastic rat tracheal epithelial cell populations were evaluated for their ability to establish homologous and/or heterologous cell-cell gap junction communication in culture. Gap junction communication was evaluated by flow cytometric quantitation of the transfer of the fluorescent dye calcein from a donor to a recipient cell population via gap junctions. The data indicate that normal primary cultures of rat tracheal epithelial cells, as well as non-tumorigenic cell lines and squamous cell carcinomas cell populations, retain the ability to establish both homologous and heterologous gap junction communication. In all cases an average of >48% of recipient cells had acquired calcein label during a 5-h interval of co-culture of donor and recipient cells at confluent densities. Cells harvested directly from squamous cell carcinoma tumors exhibited similar levels of cell-cell communication. In contrast, cells giving rise to undifferentiated carcinomas, as well as cells harvested from undifferentiated carcinomas, exhibited very low levels or no homologous or heterologous cell-cell communication. Cell populations exhibiting distinctly different communication phenotypes were evaluated by Northern blot analysis for expression of connexins (Cx 26, 32 and 43) and E-cadherin. Neither communicating nor non-communicating cells expressed connexin 32. Those cell populations, which established functional gap junctions, expressed E-cadherin as well as connexin 26 and/or 43. In contrast, those cell populations that lacked the ability to communicate universally lacked expression of E-cadherin, and a quarter also lacked expression of detectable levels of connexin.     

Prolonged QT interval in hypertrophic and dilated cardiomyopathy in children

We investigated whether the growth state of NRK cells (proliferating or quiescent by serum deprivation) affected the ability of oncogenic Ki-ras p21 and the protein kinase C activator, 12-O-tetradecanoylphorbol-13-acetate (TPA), to alter gap junctional communication. We evaluated gap junctional permeance by rate analysis of the transfer of a fluorescent dye, Lucifer Yellow, between cell pairs. We found that while the gap junctions of proliferating NRK cells were unresponsive to both TPA and to Ki-ras p21, junctional communication in quiescent cells was significantly inhibited by brief exposures to 100 ng/ml TPA. Furthermore, activity of Ki-ras p21 2 h prior to TPA exposure enhanced the inhibitory effect of TPA in quiescent cells. Junctional sensitivity to TPA was transient, with inhibition of junctional communication detected at 10 min and refractory after 60 min of continuous exposure. The suppression of junctional communication by TPA was completely prevented if the oncogenic p21 had been active for a longer period of time (48 h). The application of a phorbol ester derivative (4 alpha-PDD), which does not activate protein kinase C, did not affect the ability of quiescent cells to communicate. From these results we conclude that there is a cell-state dependence of junctional sensitivity to TPA in NRK cells and that ras p21 activity potentiates the junctional response to TPA. One interesting possibility is that this involved a cell-cycle effect.     

ATP- and gap junction-dependent intercellular calcium signaling in osteoblastic cells

Many cells coordinate their activities by transmitting rises in intracellular calcium from cell to cell. In nonexcitable cells, there are currently two models for intercellular calcium wave propagation, both of which involve release of inositol trisphosphate (IP3)- sensitive intracellular calcium stores. In one model, IP3 traverses gap junctions and initiates the release of intracellular calcium stores in neighboring cells. Alternatively, calcium waves may be mediated not by gap junctional communication, but rather by autocrine activity of secreted ATP on P2 purinergic receptors. We studied mechanically induced calcium waves in two rat osteosarcoma cell lines that differ in the gap junction proteins they express, in their ability to pass microinjected dye from cell to cell, and in their expression of P2Y2 (P2U) purinergic receptors. ROS 17/2.8 cells, which express the gap junction protein connexin43 (Cx43), are well dye coupled, and lack P2U receptors, transmitted slow gap junction-dependent calcium waves that did not require release of intracellular calcium stores. UMR 106-01 cells predominantly express the gap junction protein connexin 45 (Cx45), are poorly dye coupled, and express P2U receptors; they propagated fast calcium waves that required release of intracellular calcium stores and activation of P2U purinergic receptors, but not gap junctional communication. ROS/P2U transfectants and UMR/Cx43 transfectants expressed both types of calcium waves. Gap junction-independent, ATP-dependent intercellular calcium waves were also seen in hamster tracheal epithelia cells. These studies demonstrate that activation of P2U purinergic receptors can propagate intercellular calcium, and describe a novel Cx43-dependent mechanism for calcium wave propagation that does not require release of intracellular calcium stores by IP3. These studies suggest that gap junction communication mediated by either Cx43 or Cx45 does not allow passage of IP3 well enough to elicit release of intracellular calcium stores in neighboring cells.     

Reticulospinal actions on primary afferent depolarization of cutaneous and muscle afferents in the isolated frog neuraxis

The disposition and orientation of mouse ductin (the subunit c of the vacuolar H(+)-ATPase) in gap junctions has been examined. Like the Nephrops norvegicus (arthropod) form, mouse ductin in the intact junctional structure is resistant to high levels of nonspecific proteinase, suggesting that it is for the most part buried in the bilayer. Antisera to an octapeptide near the N-terminus cross-react with ductins in gap junction preparations from four different mouse tissues, from chicken and Xenopus laevis liver, and from N. norvegicus hepatopancreas. The antisera and antibodies, affinity purified against the octapeptide, agglutinate isolated gap junctions, suggesting that the N-terminus is located on the exposed surface, equivalent to the cytoplasmic face of an intercellular gap junction. The antibodies also block dye coupling when injected into cells in culture, confirming the cytoplasmic location of the epitope. The lipophylic reagent dicylohexyl carbodiimide (DCCD), which targets carboxyl groups within the membrane and selectively reacts with ductin in N. norvegicus gap junction preparations, rapidly inhibits junctional communication. Bafilomycin A1, which inhibits V-ATPase and stops vacuolar acidification, does not affect dye coupling, showing that the inhibition seen with antibodies and DCCD is not an indirect consequence of their action on the ductin of V-ATPase. Consistent with this interpretation the anti-peptide antibodies do not bind to intact chromaffin granules or inhibit their V-ATPase activity, but do bind to osmotically disrupted granule membrane. This suggests that ductin has an orientation (N-terminus pointing away from the cytoplasm) in the vacuolar membrane opposite to that in the gap junction membrane.     

Gap junctions and growth control in liver regeneration and in isolated rat hepatocytes

The hepatocytes in the mature normal liver are tightly coupled through gap junctions, except during compensatory hyperplasia (regeneration) after partial hepatectomy when the gap junctions become down-regulated. The significance of this down-regulation has been a long-standing enigma. The present study of hepatocytes in primary culture and in the regenerating liver aimed at defining the relationship, if any, between hepatocyte gap junctional communication and proliferation. Gap junctional down-regulation in the regenerating liver appeared to be a specific phenomenon because desmosomes and the surface contact area between neighboring hepatocytes remained constant. All agents and conditions (dexamethasone in vivo; dexamethasone, cyclic adenosine monophosphate, serum, and high cell density in vitro) delaying gap junctional down-regulation also increased the lag before the cells reached competence to enter S phase. This raised the possibility that hepatocyte DNA replication was inhibited through preservation of gap junctions. However, we disproved this assumption by showing that the DNA replication (more specifically the G1/S transition rate constant) was inhibited even in hepatocytes completely devoid of gap junctional communication. The teleological advantage of linking gap junctional down-regulation to hepatocyte G1 progression therefore may not be to trigger DNA replication but to ensure that proliferating hepatocytes and hepatocytes responsible for liver-specific metabolic functions maintain separate pools of metabolites and signaling molecules.     

Nitric oxide production in mouse peritoneal macrophages enhanced with glycyrrhizin

The enhancement of nitric oxide (NO) production in glycyrrhizin (GL)-induced macrophages (M phi) in response to lipopolysaccharide (LPS) was investigated. No production in GL-induced macrophage culture supernatants was stimulated in response to LPS (10 micrograms/ml) for 24- or 48- h cultures, and these levels were compared three times with the levels in saline-induced peritoneal exudate cell cultures. Furthermore, M phi induced with proteose peptone (PP) containing GL could generate greater NO production than M phi induced with PP alone. However, no stimulation of NO production was observed by addition of GL in the cultures of M phi induced with thioglycollate or Bacillus Calmette Guerin. Moreover, GL-induced M phi showed cytostasis against such tumor target cells as L 1210 and P 388 lymphoma cell lines. These observations indicate that GL can activate the M phi in vivo system and stimulate NO production in response to LPS.     

Gap junctional communication between vascular cells. Induction of connexin43 messenger RNA in macrophage foam cells of atherosclerotic lesions

The structure and function of blood vessels depend on the ability of vascular cells to receive and transduce signals and to communicate with each other. One means by which vascular cells have been shown to communicate is via gap junctions, specifically connexin43. In atherosclerosis, the normal physical patterns of communication are disrupted by the subendothelial infiltration and accumulation of blood monocytes, which in turn can differentiate into resident foam cells. In this paper we report that neither freshly isolated human peripheral blood monocytes nor differentiated monocytes/macrophages exhibit functional gap junctional dye transfer in homo-cellular culture or in co-culture with endothelial cells or smooth muscle cells. By Northern analysis, neither freshly isolated blood monocytes nor pure cultures of differentiated monocyte/macrophages expressed gap junction messenger RNA. However, immunohistochemical staining followed by in situ hybridization on sections of human atherosclerotic carotid arteries revealed strong expression of gap junction connexin43 messenger RNA by macrophage foam cells. These results suggest that tissue-specific conditions present in atherosclerotic arteries induce expression of connexin43 messenger RNA in monocyte/macrophages.     

Cell-junctional and cytoskeletal organization in mouse blastocysts lacking E-cadherin

Trophectoderm epithelium formation, the first visible differentiation process during mouse embryonic development, is affected in embryos lacking the cell adhesion molecule E-cadherin. Here we analyze the developmental potential of such E-cadherin-negative embryos, focusing on the organization of cell junctions and the cytoskeleton. To do this we used antibodies directed against alpha-, beta-, or gamma-(plakoglobin)-catenin and junctional and cytoskeletal proteins including ZO-1 and occludin (tight junctions), desmoglein1 (desmosomes), connexin43 (gap junctions), and EndoA (cytokeratin intermediate filaments). Membrane localization of alpha- and beta-catenin, and ZO-1, as well as cortical actin filament organization were abnormal in E-cadherin-negative embryos, and the expression levels of alpha- and beta-catenin were dramatically reduced, all suggesting a regulatory role for E-cadherin in forming the cadherin-catenin complex. In contrast, the membrane localization of plakoglobin, occludin, desmoglein1, connexin43, and cytokeratin filaments appeared unaltered. The unusual morphogenesis in E-cadherin-negative embryos apparently reflects defects in the molecular architecture of a supermolecular assembly involving zonulae adherens, tight junctions, and cortical actin filament organization, although the individual structures still appeared normal in electron microscopical analysis.     

Effects of antiarrhythmic agents on junctional resistance of guinea pig ventricular cell pairs

Modulation of intercellular coupling through gap junctions can lead to a decrease in conduction velocity and conduction block. Previous studies have suggested that antiarrhythmic agents alter the internal resistance (sum of cytoplasmic and gap junctions resistances) of cardiac fibers. The objective of this study was to directly assess the effect of antiarrhythmic agents on junctional resistance between two isolated cells using the double whole-cell patch-clamp technique. The experimental protocol consisted in holding the membrane potential of each guinea pig ventricular myocyte of a coupled cell pair at 0 mV. Then, a junctional voltage gradient was created by changing membrane potential in only one cell. Voltage gradients were varied between -50 to +50 mV in steps of 20 mV. The extracellular medium was set to minimize trans-sarcolemmal currents and the junctional current was recorded in the cell maintained at 0 mV. Drugs tested were quinidine, lidocaine, procainamide, flecainide, propranolol, sotalol, amiodarone and verapamil. Drugs were superfused after a control period of 5 min. during which junctional resistance was observed to be stable. None of the antiarrhythmic agents tested in this study directly affected junctional resistance, although procainamide slightly increased junctional resistance 110 +/- 8% after 10 min of exposure. In conclusion, drugs tested in this study, chosen among all classes of antiarrhythmic agents, did not affect junctional resistance of cardiac myocyte cell pairs. However, long-term modulation or indirect effects of antiarrhythmic agents on gap junctions under physiological conditions cannot be excluded.     

The L-arginine-nitric oxide system regulates platelet aggregation in pregnancy

Methylmercury (MeHg) causes renal injury in addition to central and peripheral neuropathy. To clarify the mechanism of nephrotoxicity by MeHg, we investigated the effect of this compound on intercellular communication through gap junction channels in primary cultures of rat renal proximal tubular cells. Twenty minutes after exposure to 30 microM MeHg, gap junctional intercellular communication (GJIC), which was assessed by dye coupling, was markedly inhibited before appearance of cytotoxicity. When the medium containing MeHg was exchanged with MeHg-free medium, dye coupling recovered abruptly. However, the dye-coupling was abolished again 30 min after replacement with control medium, and the cells were damaged. Intracellular calcium concentration, [Ca2+]i, which modulates the function of gap junctions, significantly increased following exposure of the cells to 30 microM MeHg and returned to control level following replacement with MeHg-free medium. These results suggest that the inhibiting effect of MeHg on GJIC is related to the change in [Ca2+]i, and may be involved in the pathogenesis of renal dysfunction.     

Mechanisms of electrical coupling between pyramidal cells

Direct electrical coupling between neurons can be the result of both electrotonic current transfer through gap junctions and extracellular fields. Intracellular recordings from CA1 pyramidal neurons of rat hippocampal slices showed two different types of small-amplitude coupling potentials: short-duration (5 ms) biphasic spikelets, which resembled differentiated action potentials and long-duration (>20 ms) monophasic potentials. A three-dimensional morphological model of a pyramidal cell was employed to determine the extracellular field produced by a neuron and its effect on a nearby neuron resulting from both gap junctional and electric field coupling. Computations were performed with a novel formulation of the boundary element method that employs triangular elements to discretize the soma and cylindrical elements to discretize the dendrites. An analytic formula was derived to aid in computations involving cylindrical elements. Simulation results were compared with biological recordings of intracellular potentials and spikelets. Field effects produced waveforms resembling spikelets although of smaller magnitude than those recorded in vitro. Gap junctional electrotonic connections produced waveforms resembling small-amplitude excitatory postsynaptic potentials. Intracellular electrode measurements were found inadequate for ascertaining membrane events because of externally applied electric fields. The transmembrane voltage induced by the electric field was highly spatially dependent in polarity and wave shape, as well as being an order of magnitude larger than activity measured at the electrode. Membrane voltages because of electrotonic current injection across gap junctions were essentially constant over the cell and were accurately depicted by the electrode. The effects of several parameters were investigated: 1) decreasing the ratio of intra to extracellular conductivity reduced the field effects; 2) the tree structure had a major impact on the intracellular potential; 3) placing the gap junction in the dendrites introduced a time delay in the gap junctional mediated electrotonic potential, as well as deceasing the potential recorded by the somatic electrode; and 4) field effects decayed to one-half of their maximum strength at a cell separation of approximately 20 micron. Results indicate that the in vitro measured spikelets are unlikely to be mediated by gap junctions and that a spikelet produced by the electric field of a single source cell has the same waveshape as the measured spikelet but with a much smaller amplitude. It is hypothesized that spikelets are a manifestation of the simultaneous electric field effects from several local cells whose action potential firing is synchronized.     

Lack of restriction at the blood-brain interface in Limulus despite atypical junctional arrangements

Tracer and freeze-fracture techniques are used to evaluate the capacity of the central and peripheral nervous system of the horseshoe crab, Limulus polyphemus to admit or exclude molecular or ionic constituents of the blood intercellularly. Both the peripheral and central nervous systems are contained within blood sinuses so there is intimate contact between the haemolymph and the neural lamella. No discrete perineurium exists so any protection afforded to the nerve cells must be provided by the ensheathing glial cells and any junctions between them. Using ionic lanthanum as a pre-fixation incubation medium the system is seen to be completely "open', with the tracer gaining access to all regions of the nervous tissue. Cellular association in the peripheral nervous system, as revealed by thin-section and freeze-fracture, consist only of small scattered gap junctions between glial cells which afford no restriction to tracer entry. Gap junctions are again present between glial cells in the C.N.S. but here they are far more numerous, sometimes forming extensive sheets of almost continuous gap junctional plaques. Between certain glial cells there also exists a junctional system of linear PF ridges and complementary EF grooves; these may associate with or surround, often discontinuous arrays, the gap junctional plaques. Given their characteristics and the freedom of tracer entry, they seem unlikely to represent either typical occluding tight junctions or septate junctions.