Is the nexus necessary for cell-to-cell coupling of smooth muscle?

Connexins: key mediators of endocrine function

The appearance of multicellular organisms imposed the development of several mechanisms for cell-to-cell communication, whereby different types of cells coordinate their function. Some of these mechanisms depend on the intercellular diffusion of signal molecules in the extracellular spaces, whereas others require cell-to-cell contact. Among the latter mechanisms, those provided by the proteins of the connexin family are widespread in most tissues. Connexin signaling is achieved via direct exchanges of cytosolic molecules between adjacent cells at gap junctions, for cell-to-cell coupling, and possibly also involves the formation of membrane "hemi-channels," for the extracellular release of cytosolic signals, direct interactions between connexins and other cell proteins, and coordinated influence on the expression of multiple genes. Connexin signaling appears to be an obligatory attribute of all multicellular exocrine and endocrine glands. Specifically, the experimental evidence we review here points to a direct participation of the Cx36 isoform in the function of the insulin-producing β-cells of the endocrine pancreas, and of the Cx40 isoform in the function of the renin-producing juxtaglomerular epithelioid cells of the kidney cortex.

Fifty-eight years in science--a commentary

After 58 years in science, mostly in pharmacology, one gains perspective. Mine is that there have been important changes over this time, some good and some questionable. In this commentary, I try to reveal how I got to this stage, partially explaining my biases, and possibly helping others learn from my experiences including mistakes. Changing from seeking an M.D. to cellular biology and then to pharmacology early in my career were the best moves I made. The next best move was migration to Canada, away from the McCarthy-McCarran hysteria. Arriving at a time after the end of World War II when science in Canada was expanding was very good luck. I had an excellent opportunity to enjoy both the administration (as Chair of the first independent Department of Pharmacology at the University of Alberta) and the practice of pharmacology (as a practitioner of research on smooth muscle in health and disease). For me, the practice of research has always won over administration when a choice had to be made. Early on, I began to ask questions about educational practices and tried to evaluate them. This led me to initiate changes in laboratories and to seek nondidactic educational approaches such as problem-based learning. I also developed questions about the practice of anonymous peer review. After moving to McMaster in 1975, I was compelled to find a solution for a failed "Pharmacology Program" and eventually developed the first "Smooth Muscle Research Program". Although that was a good solution for the research component, it did not solve the educational needs. This led to the development of "therapeutic problems", which were used to help McMaster medical students educate themselves about applied pharmacology. Now these problems are being used to educate pharmacology honours and graduate students at the University of Alberta. The best part of all these activities is the colleagues and friends that I have interacted with and learned from over the years, and the realization that many of them have collaborated with me again in this volume.

Coupling among interstitial cells of Cajal in the human ileum

Current knowledge on the morphology and physiology of interstitial cells of Cajal (ICC) is mostly based on animal studies, and information about the function of these cells in humans is scarce. There is ultrastructural evidence that ICC in the myenteric region (ICC-MP) of the small intestine of several species are connected by gap junctions, but these were not observed in the human small intestine. The aim of the present study was to determine whether functional coupling also exists among ICC-MP in the human ileum. We visualized ICC-MP in live tissues using Nomarski optics, and verified their identity by staining for c-Kit. ICC were injected intracellularly with the fluorescent dye Lucifer yellow, which crosses gap junctions. In most cases the labelled cells had oval somata with two primary processes. At normal pH (7.3-7.4) only 20.2% (21/104) of the injected ICC were coupled to other ICC. However, at pH 7.8-7.9 coupling incidence increased to 74.5% (35/47, P < 0.0001). The injected cells were coupled to one to 35 other ICC. Octanol blocked coupling in all cases. Apparently, gap junctions interconnect ICC in the human small intestine. Coupling was enhanced by a small increase in pH, suggesting that it may be under physiological control.

Does ICC pacing require functional gap junctions between ICC and smooth muscle in mouse intestine?

We tested the hypothesis that interstitial cells of Cajal (ICC) pace longitudinal and circular muscle of mouse intestine through gap junctions. Carbenoxolone (10(-6), 10(-5), 10(-4) mol L(-1)), an inhibitor of gap junction conductance, was applied to segments of longitudinal or circular muscle with contractions driven by ICC after inhibition of nerve function by tetrodotoxin (10(-6) mol L(-1)) and L-NOARG (10(-4) mol L(-1)). Carbenoxolone concentration- and time-dependently inhibited the amplitude of contraction (0.2-1.5 g in controls) of segments of longitudinal muscle, but had no effect on the frequency of contractions (from 36-54 min). It also inhibited the amplitude of contractions of circular muscle segments and reduced the frequency slightly at 10(-4) mol L(-)1. Carbenoxolone inhibited tonic contractions of longitudinal but not circular segments to 60 mmol L(-1) KCl, suggesting that it directly inhibited contractions of longitudinal muscle. The responses to pacing by electrical field stimulation (40 V cm(-1), 50-100 ms, 1 Hz) after block of nerve function were reduced insignificantly in amplitude, and not in frequency in both longitudinal and circular segments. We conclude that it is likely that only gap junctions within circular muscle are involved in pacing of muscle by ICC. Carbenoxolone also has effects on muscle contractility in longitudinal muscle.

Do gap junctions couple interstitial cells of Cajal pacing and neurotransmission to gastrointestinal smooth muscle?

Interstitial cells of Cajal (ICC) pace gastrointestinal phasic activity and transmit nerve activity. Gap junctions may couple these cells to smooth muscle, but no functional evidence exists. The objective of this study was to use uncouplers of gap junctions, 18 alpha-glycyrrhetenic acid and its water-soluble analogue carbenoxolone, to evaluate if gap junctions function in pacing and neurotransmission. After inhibition of nerve function with tetrodotoxin (TTX) and N(G)-nitro-L-arginine (L-NOARG), ionomycin- or carbachol-initiated regular phasic activities of circular muscle strips from canine colon and ileum. In some cases, the primary ICC network responsible for pacing was removed. The effects of inhibitors of gap junction conductance (10(-5)-10(-4) mol L(-1)) on frequencies and amplitudes of contraction were compared to appropriate time controls. Lower oesophageal sphincter (LOS) relaxations to nerve stimulation were studied before and after inhibition of gap junction functions. No major changes in LOS relaxations or frequencies of colonic or ileal contractions occurred, but amplitudes of contractions decreased from these agents. Similar results were obtained when the myenteric plexus-ICC network of ileum was removed. Regular phasic activity was not obtained after removal of the colon submuscular plexus ICC. These findings suggest that mechanisms other than gap junctions couple gut pacemaking activity and nerve transmission.

Gap junctions in gastrointestinal muscle contain multiple connexins

In the canine gastrointestinal tract, the roles that gap junctions play in pacemaking and neurotransmission are unclear. Using antibodies to connexin (Cx)43, Cx45, and Cx40, we determined the distribution of these connexins. Cx43 was present in all locations where structural gap junctions occur. Cx40 was also widely distributed in the circular muscle of the lower esophageal sphincter (LES), stomach, and ileum. Cx45 was sparsely distributed in circular muscle of the LES. In the interstitial cells of Cajal (ICC) networks of myenteric plexus, in the deep muscular and submuscular plexuses, sparse Cx45 and Cx40 immunoreactivity was present. In colon, immunoreactivity was found only in the myenteric and submuscular plexus and nearby circular muscle cells. No immunoreactivity was found in sites lacking structural gap junctions (longitudinal muscle, inner circular muscle of the intestine, and most circular muscle of the colon). Studies of colocalization of connexins suggested that in the ICC networks, some colocalization of Cx43 with Cx40 and/or Cx45 occurred. Thus gap junctions in canine intestine may be heterotypic or heteromeric and have different conductance properties in different regions based on different connexin compositions.

Intercellular coupling mediated by potassium accumulation in peg-and-socket junctions

Coupling of smooth muscle cells is important for coordination of gastrointestinal motility. Small structures called peg-and-socket junctions (PSJs) have been found between muscle cells and may play a role in electrical coupling due to extracellular potassium accumulation in the narrow cleft between the muscle cells. A model was developed in which an electrical boundary element model of the cell morphology is used in conjunction with a finite difference model which described ionic fluxes and diffusion of extracellular potassium in the PSJ. The boundary element model used a combination of triangular and cylindrical elements to reduce computational demand while ensuring accuracy. Barrier kinetics were used to model the underlying ionic transport mechanisms. Seven ionic transport mechanisms were used to create the transmembrane voltage waveform. Results indicate that PSJs may produce significant coupling between smooth muscle cells under appropriate conditions. Coupling increased exponentially with increasing length and with decreasing intercellular gap.

Gap junctions in intestinal smooth muscle and interstitial cells of Cajal

This manuscript reviews gap junctions' roles in control of intestinal motility. Gap junctions (GJs) of small intestine (SmIn) are found between circular muscle (CM) cells, between interstitial cells of Cajal (ICC) of deep muscular plexus (DMP) and between them and adjacent outer circular muscle (OCM). GJs between longitudinal muscle (LM) cells or between cells of inner circular muscle (ICM) have not been reported. Occasional GJs have been reported between ICC of the myenteric plexus (MyP) and rarely between these ICC and adjacent LM or CM cells, or between ICC within CM and smooth muscle cells. In the colon (Co) of several species a special network of ICC lines the inner border of CM, the submuscular plexus (SP). GJs are found between ICCs and between them and CM cells. The ICC of MyP of Co are associated with LM and CM; occasional GJs exist between ICC and each muscle layer. Small GJs are missed by electron microscopy or light microscopic Immunocytochemistry. Therefore, GJ coupling may exist without demonstrated GJs. The consequences for the pacemaking functions of ICC networks of varied densities of GJ between ICC and between ICC of MyP or DMP or of SP and CM are considered. Connexins (Cxs) that compose intestinal GJs may affect coupling, but are incompletely known. Understanding of the role of GJs in coordinating intestinal motility requires knowing: (1) what passes through gap junctions to couple ICC to smooth muscle cells; (2) what Cx with what conductances and what modulatory controls connect ICC and smooth muscle cells; (3) whether smooth muscles can generate slow waves independent of ICC networks; and (4) what happens to motility, slow waves, and IJPs when GJs are selectively uncoupled.

The connexin43 gene is responsive to oestrogen

Connexin43 is the major protein of gap junctions in heart and smooth muscle including the myometrium. Molecular cloning of the connexin43 gene reveals a similar organization to that exhibited by other connexin genes: the 5' untranslated region is interrupted by an 8.5 kilobase intron. The promoter region preceding the first exon contains a TATA box and AP-1 and AP-2 sites. In addition, a series of half-palindromic oestrogen response elements is present in this region. When this promoter is linked to the reporter gene luciferase, it drives the expression of luciferase constitutively in HeLa cells transfected with this luciferase-connexin43 promoter fusion construct. When the same cells are cotransfected with oestrogen receptor cDNA, an upregulation of luciferase expression by oestrogen occurs in a cell-specific manner.

Immunohistochemical localization of a gap junction protein (connexin43) in the muscularis externa of murine, canine, and human intestine

Electron-microscopic studies have revealed a heterogeneous distribution of gap junctions in the muscularis externa of mammalian intestines. This heterogeneity is observed at four different levels: among species; between small and large intestines; between longitudinal and circular muscle layers; and between subdivisions of the circular muscle layer. We correlated results obtained with two immunomethods, using an antibody to the known gap-junctional protein (connexin43) with ultrastructural findings, and further evaluated the respective sensitivity of these two approaches. For comparative reasons we also included the vascular smooth muscle of coronary arteries into our study. Two versions of the immunotechnique (peroxidase-antiperoxidase and fluorescence methods) were applied to frozen sections of murine, canine, and human small and large intestines, as well as to pig coronary artery. In the small intestine of all three species a very strong reactivity marked the outer main division of the circular muscle layer, while the longitudinal muscle layer as well as the inner thin division of the circular muscle layer were negative. In murine and human colon both muscle layers were negative, while in canine colon the border layer between the circular muscle and the submucosa reacted strongly, and scattered activity was found in the portion of the circular muscle layer (one tenth of its thickness) closest to the submucosa. The remainder of the circular muscle layer and the entire longitudinal muscle layer were negative in the canine colon. In the coronary artery we could not confirm the positive, specific labeling reported by other investigators (l.c.).(ABSTRACT TRUNCATED AT 250 WORDS)

Intercellular communication in smooth muscle

The functioning of a group of cells as a tissue depends on intercellular communication; an example is the spread of action potentials through intestinal tissue resulting in synchronized contraction. Recent evidence for cell heterogeneity within smooth muscle tissues has renewed research into cell coupling. Electrical coupling is essential for propagation of action potentials in gastrointestinal smooth muscle. Metabolic coupling may be involved in generation of pacemaker activity. This review deals with the role of cell coupling in tissue function and some of the issues discussed are the relationship between electrical synchronization and gap junctions, metabolic coupling, and the role of interstitial cells of Cajal in coupling.

An electron-microscopic study of smooth muscle cell dye coupling in the pig coronary arteries. Role of gap junctions

Arterial smooth muscles behave like a syncytium, since they are electrically coupled. It is generally assumed that electrical coupling and dye coupling are mediated by gap junctions. No gap junctions could be detected by transmission electron microscopy in media of coronary arteries. We looked for the presence of gap junction protein in vascular smooth muscle by immunohistochemistry with light microscopy. Immunohistologically detectable connexin is expressed by smooth muscle cells of the media of pig coronary arteries, where staining occurs as a discrete punctation. We investigated the dye coupling in strips of pig coronary artery. The fluorescent dye lucifer yellow was microiontophoretically injected into a smooth muscle cell through an intracellular microelectrode. The dye was visualized on the entire strip, then on semithin sections with a fluorescence microscope, and at the ultrastructural level by using an anti-lucifer yellow antibody revealed by the protein A-gold technique. In all the tissues examined, the cells were dye-coupled. We conclude that in arterial media the smooth muscle cells are dye-coupled, despite the absence of detectable gap junctions by transmission electron microscopy, and suggest that dye coupling could occur via isolated gap junction channels.

Impedance analysis applicable to cardiac muscle and smooth muscle bundles

An electrical equivalent circuit was constructed to represent a chain of five myocardial cells in a cardiac muscle bundle with various degrees of cell-to-cell coupling, and an impedance analysis was performed. The impedance across the entire network was measured at frequencies ranging from 10(1) to 10(6) Hz. The Bode plots were nearly superimposable for 1, 10, and 100 tunnels; for 10(3), 10(4), and 10(5) tunnels, the absolute zeta at 10 Hz was lower: e.g., 9.82 M omega for 1 tunnel compared to 6.64 M omega for 10(5) tunnels. The delta zeta 1/2 values were shifted to the left in the well-coupled cases: e.g., for 1 tunnel, f1/2 was 37.8 kHz, and for 10(5) tunnels, f1/2 was 1.2 kHz. For high coupling, the Bode plots contained a double component due to the end membranes. When Ro was increased by eight times, zeta increased by 7.47 fold (for 1 tunnel, 10 Hz), and by 3.72 fold (for 10(5) tunnels, 10 Hz). Raising Ro to x 12, x 100, and x 1000 produced a further and further shift to the left of the Bode plots. The total tissue resistivity (Rt) increased as a function Ro. Thus, in low coupling cases, almost all of the applied current passes through the interstitial space; e.g., at 1 tunnel (10 Hz), 1.0% of the current passes through the cell pathway (Rcell). The ratio of impedances at 10 kHz to 10 Hz (zeta 10kHz/zeta 10Hz) decreased with increasing tunnels (for Ro x 1). The ratio of resistivities at Ro x 8 to Ro x 1 (Rt'/Rt) was 7.47 for 1 tunnel. In contrast, the ratio at 10(5) tunnels was 3.73. It is concluded that it is difficult to determine the degree of cell coupling from such impedance analysis, unless the same tissue can be used for its own control, i.e., before and after a large change in cell coupling is introduced.

Intercellular dye-coupling in intestinal smooth muscle. Are gap junctions required for intercellular coupling?

The dye Lucifer Yellow was injected into single smooth muscle cells in the guinea pig small intestine in order to study intercellular coupling. Dye-coupling was observed in both the circular and longitudinal muscle layers and was markedly reduced when the intercellular pH was lowered. These results suggest the presence of gap junctions among intestinal muscle cells, but are inconsistent with previous ultrastructural studies that failed to demonstrate such junctions in the longitudinal muscle.

Urinary bladder of rat: fine structure of normal and hypertrophic musculature

The fine structure of the muscle of the urinary bladder in female rats is similar to that of other visceral muscles, although it is arranged in bundles of variable length, cross-section and orientation, forming a meshwork. When distended, the musculature is 100-120 microns thick, with some variation and occasional discontinuity. Extended areas of cell-to-cell apposition with uniform intercellular space occur between muscle cells, whereas attachment plaques for mechanical coupling are less common than in other visceral muscles. There are no gap junctions between muscle cells. Many bundles of microfilaments and small elastic fibres run between the muscle cells. After chronic partial obstruction of the urethra, the bladder enlarges and is about 15 times heavier, but has the same shape as in controls; the growth is mainly accounted for by muscle hypertrophy. The outer surface of the hypertrophic bladder is increased 6-fold over the controls; the muscle is increased 3-fold in thickness, and is more compact. Mitoses are not found, but there is a massive increase in muscle cell size. There is a modest decrease in percentage volume of mitochondria, an increase in sarcoplasmic reticulum, and no appreciable change in the pattern of myofilaments. Gap junctions between hypertrophic muscle cells are virtually absent. Intramuscular nerve fibres and vesicle-containing varicosities appear as common in the hypertrophic muscle as in controls. There is no infiltration of the muscle by connective tissue and no significant occurrence of muscle cell death.

Contact relationships between vascular smooth muscle cells: an in vivo and in vitro study

Cell/cell contacts in the intact media of the rat thoracic aorta and inferior vena cava, and in cultured smooth muscle cells from these vessels have been quantified in order to determine whether their density and their type can be correlated with the differences in load at these two sites. The type and number of contacts per 100 microns of cell perimeter and per 100 cells were determined with a semi-automatic image analysis system. In all cases there was a predominance of simple appositions; intermediate junctions, interdigitations, and nexus junctions were less frequently observed. There were more cell contacts of each type in the intact arteries than in the intact veins. In cell cultures, all types of cell contacts were increased but the proportion of load bearing types was reduced.

Functional characterization of cell-to-cell coupling in cultured rat aortic smooth muscle

Gap junction (GJ) occurrence and function was studied in cultured rat aortic smooth muscle cells, since cell-to-cell coupling is proposed to coordinate smooth muscle function but is difficult to study in the intact tissue. Cell proliferation in vitro formed a multilayered structure 10-15 cells thick. GJs connected cells to lateral and vertical neighbors, appearing in freeze fracture as P-face particles aggregated into circular plaques but also as linear arrays. The membrane potential was 58 +/- 3 mV. From quantification of the spread of electrotonic potentials according to a two-dimensional model, the intercellular resistivity was 900-1,400 omega X cm, whereas the nonjunctional membrane resistivity was 10(4) omega X cm2. Intercellular spread of 5(6)-carboxyfluorescein (CF; mol wt 376) in aortic cultures suggests that metabolic coupling is an important consequence of GJs in smooth muscle. CF transfer was not blocked by A23187 (10(-5) M), although rat fibroblasts became uncoupled by 10(-6) M. Ultimately uncoupled by the more potent ionophore ionomycin (10(-5) M), aortic cells seem more able to maintain GJ permeability during challenge from increased intracellular Ca than cells of noncontractile origin.

Intrinsic reflexes underlying peristalsis in the small intestine of the domestic fowl

Peristalsis in the chicken small intestine was studied using either a modified Trendelenburg method or a technique in which changes in circular muscle activity were recorded in response to application of a localized radial distension. A localized radial distension had no effect on either the resting tension or the spontaneous activity of the circular muscle on the oral side of distension. On the aboral side of the distension a transient contraction was recorded in the ileum and jejunum after a mean delay of 2.74 s at 37 degrees C. In about a third of the preparations a tonic contraction was also present which persisted for as long as distension was maintained. The transient contraction was blocked by hyoscine (0.6-2.3 microM) and hexamethonium (275 microM); whereas the tonic contraction persisted in the presence of hyoscine. Both types of contraction were blocked by tetrodotoxin (0.31 microM). No such responses were recorded in the duodenum. The descending excitatory reflex responses were followed in all preparations by a fall in the amplitude and frequency of spontaneous contractions and in a few preparations by a concomitant fall in the tone of the circular muscle lasting for up to 3 min. This inhibitory component of the descending reflex was not blocked by guanethidine (3-10 microM). The transient contraction, which originated most frequently at the site of distension, always propagated aborally at a mean speed of 14.2 mm s-1. Surgical interruption of the longitudinal muscle and myenteric plexus effectively blocked the transmission of the excitatory and inhibitory components of the descending reflex past the site of the lesion. In the modified Trendelenburg apparatus raising the intraluminal pressure elicited peristalsis in the isolated ileum. Peristaltic contractions never started at the most oral end of the preparation but appeared instead at any other point on the ileum. This resulted in several contractions contributing to each emptying cycle. Peristalsis was blocked by tetrodotoxin (0.31 microM). These results are discussed in the terms of the organization of the descending reflex. It is suggested that within the enteric nervous system of the ileum and jejunum of the chicken, there are cholinergic and non-cholinergic excitatory neurones and non-adrenergic inhibitory neurones. The results of this study demonstrate that neurogenic peristalsis in the avian small intestine does not conform to the 'law of the intestine' as originally postulated by Bayliss & Starling (1899).

Control of human colonic motor function

Human colonic motility is governed by control mechanisms involving the electrical activity of the smooth muscle cell membranes, the intrinsic and extrinsic nervous activity, and hormonal action. The structural bases for neural and myogenic control have not been demonstrated. However, gap junctions are lacking between muscle cells, and nerves are not close to smooth muscle cells. The myogenic control, as observed in vitro, is described and compared with results obtained from different in vivo techniques. In vitro and in vivo measurements are critically evaluated, and a reconciliation between them attempted. No appropriate animal model is available to help resolve different findings and interpretations. Neural control of colon motility is exerted probably through modulation of myogenic activity as well as directly. The activities of extrinsic nerves, intrinsic motor nerves and afferent nerves are integrated within the colon, at prevertebral ganglia and in the spinal cord in animals, but similar data are not available for the human. There is a lack of studies directly relating transit to motility and conventional beliefs need reexamination.

Passive and active membrane properties of canine gastric antral circular muscles

Experiments were performed to determine the mechanisms responsible for the gradient of electrical activity within circular muscle of the canine gastric antrum. Cable properties of canine gastric antral circular muscles were determined using the partitioned chamber technique of Abe and Tomita (J. Physiol. Lond. 196: 87-100, 1968). The length constant of the circular muscle near the myenteric plexus was 2.4 mm. This was significantly greater than the length constant of the circular muscle near the submucosa (1.7 mm). Membrane time constants were determined by two techniques. Although the time constant of the circular muscle near the myenteric plexus tended to be greater than that of the circular muscle near the submucosa, this difference was not statistically significant. The two regions of circular muscle also differed in their relative levels of excitability. Submucosal circular muscles demonstrated considerably more outward rectification on depolarization and were difficult to bring to threshold for slow waves. This study demonstrates that significant differences exist in the passive and active membrane properties of myenteric and submucosal circular muscle cells. The data help explain the gradient of electrical activity through the thickness of antral circular muscle.

Ultrastructural studies on the neuromuscular control of human tracheal and bronchial muscle

This study presents an ultrastructural analysis of neural and myogenic control of smooth muscle in human trachea, in small (approximately fourth to seventh order) bronchi. A moderate frequency of gap junctions between smooth muscle cells and a sparse innervation was observed in trachea. In contrast, small junctions without identifiable gaps were identified in bronchi along with a dense, sometimes close innervation of muscle. Most profiles of nerve varicosities in both types of airways were of two types: (1) those containing mostly small agranular and few or no large granular vesicles; and (2) nerves (probably adrenergic) with some small granular vesicles along with other vesicles present in bronchi. In the bronchi some mast cells were found near nerve profiles and in close proximity to smooth muscle. These morphological findings suggest that tracheal muscle may be organized for more neural and less myogenic control of activity. Interactions between mast cells, nerves and muscles in bronchi could influence airway function. These findings imply that a single type of airway muscle may not adequately represent the structural and functional properties of human airway.

Slow wave heterogeneity within the circular muscle of the canine gastric antrum

A cross-sectional preparation was designed in which multiple micro-electrodes can be precisely positioned to impale smooth muscle cells anywhere from the serosa to the submucosa. Intracellular electrical recordings were obtained from gastric antral circular muscle cells from the myenteric plexus to the submucosa. The resting membrane potential changed linearly as a function of distance from the myenteric plexus to the submucosa. Slow wave upstroke dV/dt, upstroke potential amplitude, and plateau potential amplitude changed linearly as a function of distance from the myenteric plexus to the submucosa. When slow waves were recorded simultaneously from a circular cell near the myenteric plexus and from a cell near the submucosa, the event always occurred first in the cell near the myenteric plexus. Electrical differences did not appear to be caused by electrotonic decay of slow waves as they propagated through the circular muscle. Electrical differences could not be explained on the basis of differences in intrinsic neural activity or prostaglandin synthesis. Membrane polarization could not explain the differences in slow waves between myenteric and submucosal circular muscle cells. The conclusion of this paper is that fundamental differences exist between the excitability mechanisms and/or passive membrane properties of cells near the myenteric plexus and the submucosa. These differences might be manifest in different motor performance of these two muscle cell populations.

Description of the structural control systems of ovum transport in the quail oviduct

Some electron microscropic and light microscopic aspects of the quail oviduct have been studied in relation to ovum transport. Previously it has been shown that in this smooth muscle there exist spontaneous coordinated electrical and mechanical activity which suggests a good electrical and mechanical coupling of the muscle cells. The structural basis for this coupling is not known. The majority of muscle cell contacts observed were simple appositions and intermediate junctions. Less numerous were attachments of the interdigitation type. No nexuses or tight junctions were seen. Mechanical stretching or contraction of cells induced with 10(-4)M carbachol did not affect the contacts. The fine structure of the muscle cells did not differ from that described for other smooth muscles. Electronmicroscopically the muscle cell bundles could not be distinguished into separate layers, in the light microscope the cell bundles were spirally arranged. Stretching of the oviductal strips to the length to which the ovum stretches the muscular wall during ovum transport caused re-orientation of the muscle cell bundles. One-directional stretching turned the axes of the muscle cells and the collagen bundles parallel, while stretching in two direction made the tissue look like a network. The re-orientation of muscle cell bundles may be of importance in producing forces in the muscular tunic during ovum transport. The nerve supply to the muscle cells was negligible. These and previous results show that structurally the muscular wall of the quail oviduct is a dynamic unity in which the ovum via stretch induces the electrical and mechanical activity throughout the tissue. Innervation may play a minor role in controlling the contractions.

Biological implications of gap junction structure, distribution and composition: a review

Traditionally, all gap junctions have been considered to be identical in structure and function throughout the animal kingdom. Functions ascribed to these membrane specializations have been fundamental and have not been thought to differ significantly with respect to their mechanism of action. More recent studies support the view, however, that structural and compositional diversity may reflect significant functional differences between gap junctions in different classes of tissue but no clear and definitive patterns have yet emerged. This review does not attempt to comprehensively analyze the totality of the vast gap junction and coupling literature but focuses instead upon those recent observations which raise new questions related to the biological activities of gap junctions in different tissues.

Improved electrical coupling in uterine smooth muscle is associated with increased numbers of gap junctions at parturition

We have studied some passive electrical properties of uterine smooth muscle to determine whether a change in electrical parameters accompanies gap junction formation at delivery. The length constant of the longitudinal myometrium increased from 2.6 +/- 0.8 mm (X +/- SD) before term to 3.7 +/- 1 mm in tissues from delivering animals. The basis of the change was a 33% decrease in internal resistance and a 46% increase in membrane resistance. Axial current flow in an electrical syncytium such as myometrium is impeded by the cytoplasm of individual cells plus the junctions between cells. Measurement of the longitudinal impedance indicated that the specific resistance of the myoplasmic component was constant at 319 +/- 113 omega . cm before term and 340 +/- 93 omega . cm at delivery. However, a decrease in junctional resistance was apparent from 323 +/- 161 omega . cm to 134 +/- 64 omega . cm at delivery. 1.5-2 d after delivery, the junctional resistance was increased, as was the myoplasmic resistance. Thin-section electron microscopy of some of the same muscle samples showed that gap junctions were present in significantly greater numbers in the delivering tissues. Therefore, our results support the hypothesis that gap junction formation at delivery is associated with improved electrical coupling of uterine smooth muscle.

Intercellular communication in normal and regenerating rat liver: a quantitative analysis

We have compared intercellular communication in the regenerating and normal livers of weanling rats. The electrophysiological studies were conducted at the edge of the liver, and we have found that here as elsewhere in the liver there is a dramatic decrease in the number and size of gap junctions during regeneration. The area of hepatocyte membrane occupied by gap junctions is reduced 100-fold 29-35 h after hepatectomy. By combining observations made with the scanning electron microscope with our freeze fracture data we have estimated the number of "communicating interfaces" (areas of contact between hepatocytes that include at least one gap junction) formed by hepatocytes in normal and regenerating liver. In normal liver a hepatocyte forms gap junctions with every hepatocyte it contacts (approximately 6). In regenerating liver a hepatocyte forms detectable gap junctions with, on average, only one other hepatocyte. Intercellular spread of fluorescent dye and electric current is reduced in regenerating as compared with normal liver. The incidence of electric coupling is reduced from 100% of hepatocyte pairs tested in control liver to 92% in regenerating liver. Analysis of the spatial dependence of electronic potentials indicates a substantial increase in intercellular resistance in regenerating liver. A quantitative comparison of our morphological and physiological data is complicated by tortuous pattern of current flow and by inhomogeneities in the liver during regeneration. Nevertheless we believe that our results are consistent with the hypothesis that gap junctions are aggregates of channels between cell interiors.

Gap junctions of the muscles of the small and large intestine

The distribution of gap junctions (nexuses) in various parts of the small and large intestines of the guinea-pig was studied using the freeze-fracture technique and in thin sections. The percentage area of smooth muscle cell surface occupied by gap junctions varies from 0.50% in the circular muscle of the duodenum to zero in the longitudinal muscle of the ileum. In the circular muscle of the jejunum and ileum the area occupied by nexuses is 0.22% (or about 11 micrometers 2 per cell). The sizes of junctions range from less than 0.01 micrometer 2 to 0.20 micrometer 2, with two-thirds of them being smaller than 0.05 micrometer 2. In the colon, gap junctions are rare, very small and confined to the circular muscle layer. Even the smallest aggregates of intramembrane particles correspond to areas of close apposition between the membranes of adjacent cells; it is therefore justified to interpret them as being gap junctions. Some gap junctions are formed between a smooth muscle cell and an interstitial cell. Gap junctions are not found in the longitudinal muscle of the small intestine; this is in sharp contrast to the abundance of gap junctions in the adjacent circular layer. In the small intestine of cats and rabbits, gap junctions are abundant in the circular muscle layer, whereas they are very small in size and very few in number in the longitudinal muscle layer.

Electrical coupling among heart cells in the absence of ultrastructurally defined gap junctions

Cells from the ventricles of 7-day chick embryos were aggregated into spheroidal clusters by 48 hr of culture on a gyratory platform. All aggregates beat spontaneously and rhythmically. Microelectrode impalement of widely separated cells within aggregates indicated that they were coupled, as evidenced by a mean coupling ratio (delta V2/ delta V1) of 0.81 +/- 0.09, and by simultaneity of intrinsic electrical activity (action potentials and subthreshold voltage fluctuation). In freeze-fracture preparations, the cell surfaces contained numerous small groups of intramembrane protein (IMP) particles, arranged in macular clusters, and linear and circular arrays. Using the criterion of 4 clustered IMP particles to defined a minimal gap junction, 0.27% of the total P-face examined was devoted to gap junctional area. Within such clusters particles were packed at about 8200/micrometer2; in nonjunctional regions, particles were scattered at a density of about 2000/micrometer2. When exposed to cycloheximide (CHX: 50 micrograms/ml) for 24--48 hr, coupling ratio declined to 0.44. This decrease could be attributed largely to leakiness of the nonjunctional membrane. Aggregates continued to beat rhythmically and in a coordinated fashion even after 72 hr in inhibitor. However, between 3--21 hr in CHX gap junctional area declined to 0.10%, and all particle clusters disappeared from the P-faces of aggregates in CHX for 24 or 48 hr. Neither macular nor linear particle arrays were seen. We conclude that organized gap junctions are unnecessary for electrotonic coupling between embryonic heart cells. These findings support the idea that low-resistance cell-to-cell pathways may exist as isolated channels scattered throughout the area of closely apposed plasma membranes.

The role of junctional communication in animal tissues

Permeable intercellular junctions are a common feature of most animal tissues. These junctions allow the free exchange of small ions and molecules between all the cells in coupled populations. Such limited syncytial interaction contributes to the integration of individual cells into organized tissues.

Hypertrophic smooth muscle. III. Increase in number and size of gap junctions

The smooth muscle cells of the circular musculature of the guinea pig ileum are connected by gap junctions (nexuses) which occupy about 0.21% of the cell surface. When the muscle hypertrophies in the portions of the ileum oral to an experimental stenosis, the muscle cells increase in size and number. Gap junctions become markedly larger than in control muscles and occupy 0.49% of the cell surface. While the cells double their surface area, the number of nexuses per unit surface remains unchanged (47--48 per 1000 microns2). The packing density of intramembrane particles (or pits) in the nexuses of hypertrophic muscle cells is 6700 . microns-2, which is slightly less than in control muscle cells (7200 . microns-2). A characteristic grouping of the particles (or the pits) within the nexus is often observed. Nexuses between two processes originating from the same cell are common. Nexuses do not occur in the longitudinal muscle.

Ultrastructural basis for maintenance and termination of pregnancy

Myometrial tissues from guinea pigs, sheep, and human subjects at various stages of gestation and postpartum were quantitatively examined in the electron microscope for the presence of gap junctions between muscle cells. Gap junctions were found in tissues from guinea pigs and sheep which were being delivered or ready to be delivered and in tissues taken immediately post partum. Gap junctions were also present in 19 tissues obtained from 69 women undergoing elective or emergency cesarean section for a variety of reasons. The frequency of their occurrence varies in relation to the presence or absence of labor and other conditions. We propose that gap junctions are required for effective muscle contractions leading to termination of pregnancy in all animals, including human beings. The absence of gap junctions throughout gestation may be necessary for maintenance of pregnancy and the premature appearance of the cell contacts may lead to premature labor.

Possible role of gap junctions in activation of myometrium during parturition

Gap junctions between smooth muscle cells of the myometrium of pregnant rats were found only immediately prior to, during and immediately after parturition by quantitative thin-section and freeze-fracture microscopy. Ovariectomy of 16- to 17-days-pregnant rats resulted in premature termination of pregnancy and the appearance of gap junctions. Methods that prolonged normal pregnancy in rats or maintained pregnancy in ovariectomized animals (progesterone treatment) prevented the appearance of gap junctions. Gap junctions formed in tissues incubated for 24--96 h in vitro without any hormonal influence. We propose that gap junctions are essential for normal labor and delivery for synchronous contraction of the muscle of the uterus. We present a model for control of parturition that may apply to other animals including humans. The model proposes: 1) the possible roles progesterone, prostaglandins, or estrogens may play in initiating gap-junction formation; 2) that the formation of gap junctions is a necessary step in activation of the myometrium leading to labor; and 3) that agents used to stimulate or inhibit labor may do so by affecting gap junctions.