Intercellular communication and some structural aspects of membrane junctions in a simple cell system

Intercellular communication and tissue growth : V. A cancer cell strain that fails to make permeable membrane junctions with normal cells

A method is described for testing communication between a normal and a cancerous cell in culture without inserting microprobes into either cell; microprobes are put into other normal cells coupled to the normal cell in question. It is shown with this method that a cell strain (class-A), of epithelial morphology, isolated from Morris' liver tumor (H-5123) fails to make communicative junctions with several types of normal cells; small inorganic ions and fluorescein do not pass from the normal cells to the class-A cells (they do pass from the normal cells to normal cells, even between normal cells of different type). The class-A cells also appear incapable of junctional communication among themselves. The cells of class-A are cancerous: they are not 'contact inhibited' by each other or by the normal cells and they form malignant tumors when injected into test animals. Another cell strain (class-B), of fibroblastic morphology, derived from the same liver tumor as class-A makes communicative junctions readily. This strain is 'contact inhibited' and does not produce tumors when injected into the animals.

A weak electrical current enhances intracellular delivery of therapeutic substances

Cell membranes have electrical properties which can be measured and modified. Administering a weak electrical signal across a tissue is a technique which can be used to determine the quantity of water in the intracellular and extracellular compartments. Using this real-time method of bioelectrical impedance, it was found that a variety of stimuli (including an electrical current) can enhance the passage of water and other substances into the cell. We propose an inexpensive and safe technique which could be utilized to enhance delivery of a wide variety of therapeutic agents into cells for the enhanced delivery of antibiotics, chemotherapy or other therapeutic agents.

Structure--function relationships in gap junctions

Gap junctions are metabolic and electrotonic pathways between cells and provide direct cooperation within and between cellular nets. They are among the cellular structures most frequently investigated. This chapter primarily addresses aspects of the assembly of the gap junction channel, considering the insertion of the protein into the membrane, the importance of phosphorylation of the gap junction proteins for coupling modulation, and the formation of whole channels from two hemichannels. Interactions of gap junctions with the subplasmalemmal cytoplasm on the one side and with tight junctions on the other side are closely considered. Furthermore, reviewing the significance and alterations of gap junctions during development and oncogenesis, respectively, including the role of adhesion molecules, takes up a major part of the chapter. Finally, the literature on gap junctions in the central nervous system, especially between astrocytes in the brain cortex and horizontal cells in the retina, is summarized and new aspects on their structure-function relationship included.

Evidence for intercellular cohesion in the septate junction of the protozoon Gregarina

Injection of Lucifer Yellow dye was used to establish whether septate junctions formed a permeability barrier between primite and satellite gamonts in the syzygy of the protozoon Gregarina. The fluorescent dye did not pass from one cell to the other, thus suggesting that the septate junction served only for mechanical adhesion. Later on in development, when the gametocyst had formed, the septate junction vanished and interruptions were observed between opposing cell membranes. At this stage the fluorescent dye was able to pass freely into the conjugated cells.

Cell-to-cell coupling assayed by means of electrical measurements

The importance of electrical measurements in the evaluation of cell-to-cell coupling in heart muscle was discussed. The presence of gap junctions in heart and smooth muscle, and the implications of this for electrical synchronization and healing-over, was emphasized. Moreover, the modulation of junctional resistance by Ca, protons and cAMP was reviewed.

Permeability properties of cell-to-cell channels: kinetics of fluorescent tracer diffusion through a cell junction

We have analyzed the intracellular and cell-to-cell diffusion kinetics of fluorescent tracers in the Chironomus salivary gland. We use this analysis to investigate whether membrane potential-induced changes in junctional permeability are accompanied by changes in cell-to-cell channel selectivity. Tracers of different size and fluorescence wavelength were coinjected into a cell, and the fluorescence was monitored in this cell and an adjacent one. Rate constants, kj, for cell-to-cell diffusion were derived by compartment model analysis, taking into account (i) cell-to-cell diffusion of the tracers; (ii) their loss from the cells; (iii) their binding (sequestration) to cytoplasmic components; and (iv) their relative mobility to cytoplasm, as determined separately on isolated cells. In cell pairs, we compared a tracer's kj with the electrical cell-to-cell conductance, gj. At cell membrane resting potential, the kj's ranged 3.8-9.2 X 10(-3) sec-1 for the small carboxyfluorescein (mol wt 376) to about 0.4 X 10(-3) sec-1 for a large fluorescein-labeled sugar (mol wt 2327). Cell membrane depolarization reversibly reduced gj and kj for a large and a small tracer, all in the same proportion. This suggests that membrane potential controls the number of open channels, rather than their effective pore diameter or selectivity. From the inverse relation between tracer mean diameter and relative kj we calculate an effective, permeation-limiting diameter of approximately 29 A for the insect cell-to-cell channel. Intracellular diffusion was faster than cell-to-cell diffusion, and it was not solely dependent on tracer size. Rate constants for intracellular sequestration and loss through nonjunctional membrane were large enough to become rate-limiting for cell-to-cell tracer diffusion at low junctional permeabilities.

Ultrastructure of gap junctions in the central nervous system of Lymnaea stagnalis with particular reference to electrotonic coupling between the neuroendocrine caudodorsal cells

Presence and structure of gap junctions have been studied at the ultrastructural level in the central nervous system of the freshwater snail Lymnaea stagnalis. Gap junctions are clearly visible in thin sections of glutaraldehyde-fixed and phosphotungstic acid-stained material as well as in freeze-fracture preparations. Various types can be distinguished on the basis of junctional size and shape, and numerical density, diameter, spacing and arrangement of junctional particles. Junctions are present between neurones and between glial cells. The neuroendocrine ovulation-hormone-producing caudodorsal cells show gap junctions at four sites, viz. between somata, between axons in the "loop area" and in the intercerebral commissure and between neurohaemal axon terminals. These junctions show common characteristics as to numerical density, diameter, spacing and arrangement of junctional particles, but morphometry reveals different mean values for junctional size and numerical density. Values are the highest for axons in the loop area, intermediate for axons crossing the commissure, and the lowest for somata and axon terminals. It is proposed that the gap junctions particularly play a role in electrotonic intercellular coupling. The results strongly suggest that the gap junctions between the caudodorsal cells--especially those in the loop area and between the crossing axons--are the morphological correlates of the previously demonstrated electrotonic coupling between these cells. This coupling may enable all cells of the network to act synchronously so that a large amount of ovulation-hormone can be released within a short period of electrical activity (the discharge).

Gap junctions and septate-like junctions between neurons of the opisthobranch mollusc Navanax inermis

The buccal ganglia of Navanax inermis were studied by thin section, lanthanum infiltration and freeze fracture. Freeze fracture clearly demonstrates small gap junctions between neuronal processes in the neuropil, many of which are known to be electrotonically coupled. Junctional particles cleave with the P-face. In thin section, gap junctions appeared as small blurred contacts, presumably because of the small size of the junctions. Lanthanum infiltration was poor and failed to aid in identifying gap junctions. However, it did reveal septate-like junctions whose septa were not osmiophilic. Corresponding E-face grooves and ridges were seen in freeze fracture, sometimes adjacent to gap junctions. The septate-like junctions have parallel membranes and may have been mistaken for gap junctions in several other thin section studies of invertebrate neurons.

Intercellular communication in the supporting cells of the organ of Corti

We have directly tested the concept that the supporting cells of the organ of Corti are functionally coupled through gap junctions. In vitro and in vivo preparations were evaluated. Electrical measurements clearly show that the cells are coupled ionically. Voltage drops measured in neighboring cells in response to intracellular current injections indicate that current spread decays rapidly. Despite the existence of electrical coupling, fluorescent dye injection studies revealed no dye spread into adjacent cells, other than a few instances which were clearly artifactual. However, it is possible that dye spread is very slow and that dye in adjacent cells is diluted below visual detectability. In any case, dye coupling is remarkably poor compared to other electrically coupled tissues. The role of coupling in the supporting cells may be nutritive, considering the avascular nature of Corti's organ.

Cell-to-cell channels with two independently regulated gates in series: analysis of junctional conductance modulation by membrane potential, calcium, and pH

We study cell-to-cell channels, in cell pairs isolated from Chironomus salivary gland, by investigating the dependence of junctional conductance (gj) on membrane potentials (E1, E2), on Ca2+, and on H+, and we explore the interrelations among these dependencies; we use two separate voltage clamps to set the membrane potentials and to measure gj. We find gj to depend on membrane potentials whether or not a transjunctional potential is present. The pattern of gj dependence on membrane potentials suggests that each channel has two closure mechanisms (gates) in series. These gates pertain, respectively, to the two cell faces of the junction. By treating the steady-state gj as the resultant of two simultaneous but independent voltage-sensitive open/closed equilibria, one within each population of gates (i.e., one on either face of the junction), we develop a model to account for the steady-state gj vs. E relationship. Elevation of cytosolic Ca2+ or H+ at fixed E lowers gj, but at moderate concentrations of these ions this effect can be completely reversed by clamping to more negative E. Overall, the effect of a change in pCai or pHi takes the form of a parallel shift of the gj vs. E curve along the E axis, without change in slope. We conclude (1) that the patency of a cell-to-cell channel is determined by the states of patency of its two gates; (2) that the patency of the gates depends on membrane potentials (not on transjunctional potential), on pCai, and on pHi; (3) that pCai and pHi determine the position of the gj vs. E curve on the E axis; and (4) that neither Ca2+ nor H+ at moderate concentrations alters the voltage sensitivity of gj.

Cell-to-cell tracer movement in cardiac muscle. Ruthenium red vs. lanthanum

An attempt was made to label injured cardiac muscle cells by exposing them to two electron-opaque tracers, ruthenium red and lanthanum nitrate. To do this, false tendons of sheep hearts containing strands of Purkinje fibers were sectioned, allowed to heal, and then exposed to the tracer during fixation. After this treatment, a group of cells near the cut end were found to be labelled intracellularly with the tracers while the remaining cells in the strand were unlabelled. For comparison, several false tendons were fixed briefly in glutaraldehyde before being cut and then exposed to the tracer. With lanthanum, the results were similar to those obtained when the cells had been damaged prior to fixation. However, when ruthenium red was used as the tracer, it penetrated much further into the cellular strand, its intensity gradually diminishing with distance from the cut end. This finding of apparent dye-coupling in fixed tissue was surprising since it has been suggested that glutaraldehyde fixation converts all communicating junctions to be uncoupled state. Dye-coupling of fixed tissue with ruthenium red as a tracer was seen also in frog atrial trabeculae. Gap junctions between injured (and presumably uncoupled) sheep heart Purkinje cells were compared to gap junctions between uninjured control cells in thin sections. No difference was detected.

Nurse cell-oocyte interaction in the telotrophic ovarioles of an insect, Rhodnius prolixus

Microinjection of intracellular tracers fluorescein, Procion Yellow, Lucifer Yellow and horseradish peroxidase unequivocally showed the syncytial structure of the tropharium and its interaction with the oocytes. The tropharium tip is a separate isolated compartment. Finger-like nurse cell projections comprising the syncytial tropharium interact via gap junctions along their abutting membranes and also via large cytoplasmic continuities at the central trophic core. The trophic cords connecting the tropharium to oocyte vary in diameter relative to oocyte stage. Continuity of the tropharium with the oocytes is lost at approximately 1000 micron oocyte length and the severed cords then regress from the oocyte to the tropharium base. Variation in cord diameters and timing of cord closure may account for the highly regulated sequential oocyte growth.

A clarification of the two types of invertebrate pleated septate junction

It is confirmed that there are two distinct variations septate junction. The first of these, the 'lower invertebrate pleated septate junction', is described fully using conventional thin section, lanthanum tracer and freeze-fracture techniques. The second type, the well-known pleated septate junction characteristic of the molluscs and arthropods, is renamed the 'mollusc-arthropod pleated septate junction', and is described briefly to allow easier comparison between the two variations. As both types have not been studied in a range of invertebrate phyla the results can be used as a basis for discussing their respective phylogenetic positions. The lower invertebrate pleated septate junction occurs in several groups in the minor phyla immediately above the Coelenterata and in the lower phyla of both the deuterostome and proterostome lineages. The mollusc-arthropod pleated septate junction is restricted to the Mollusca and Arthropoda as its name implies.

Asymmetrically permeable membrane channels in cell junction

Asymmetric membrane junctions were formed in culture by pairing two cell types which, in their respective homologous junctions, have cell-cell channels of different permselectivities. The channels in the asymmetric junction, presumably made of unequal channel precursors, displayed directional permselectivity; fluorescent labeled glutamic acid (700 daltons), but not smaller and less polar permeant molecules, traversed the junction more readily in one direction than in the other. The favored direction was the one where the permeant passed first through the cell membrane that would have the less restrictive channels in a homologous junction. This directional selectivity requires no electric field across the junction and is thus distinct from a rectifying junction. The physiological potential of such directional molecular sieving for partitioning communication between tissue cells of different function and developmental fate are discussed.

Focal laminate segments in cytoplasmic processes of mouse myocardial fibroblasts

In mouse ventricular myocardium, we have found unusual fibroblasts whose cellular processes in some regions are particularly flattened and which contain linearly-arranged, electron-opaque structures ('central laminae"). The morphology of these focal laminate segments of fibroblast processes suggests that the intracellular laminae are adhesive entities which hold the plasmalemmata above and below them in close parallel apposition for short distances.

The morphology and coupling of Aplysia bag cells within the abdominal ganglion and in cell culture

The bag cells in the abdominal ganglion of Aplysia californica control egg-laying behavior by releasing a polypeptide (ELH) during an afterdischarge of synchronous action potentials. We have used intracellular injection of Lucifer Yellow to study the morphology and interconnections of the bag cells. These neurosecretory cells are typically multipolar and their processes extend in all directions out from the bag cell clusters into the surrounding connective tissue, where they branch in a complex manner. In some of the dye injection experiments, dye transfer from the injected cell to neighboring cells was observed. Freeze fracture of the bag cell clusters and their surrounding connective tissue revealed numerous gap junctions on bag cell processes within the clusters as well as on more distal processes. We have also examined the morphology and coupling between bag cells in primary culture. As in the intact ganglion, bag cells in culture were found to be multipolar. All pairs of bag cells whose somata or processes had formed contacts in culture were electrically coupled. The strongest coupling was observed between pairs of cells whose somata appeared closely apposed. In these cases transfer of Lucifer Yellow between cells could also be observed. It is therefore likely that the synchrony of bag cell action potentials during a bag cell afterdischarge is a result of coupling between individual cells in the bag cell cluster.

Gap junctions coupling photoreceptor axons in the first optic ganglion of the fly

The first optic ganglion of the fly, the lamina ganglionaris, was investigated with the transmission electron microscope for the purpose of demonstrating possible electronic junctions. Within a cartridge, the six short receptor cell axons R1--R6 are extensively coupled by symmetrical gap junctions. This is mainly seen in the distal third of the first synaptic region where none or only a few lateral branches of the centrally lying L-fibres (L1, L2) penetrate the ring of six short receptor fibre endings. Gap junctions as found between R1--R6 are distinguished morphologically from chemically-mediated synapses by the closely apposed cell membranes. They exhibit only a 2--4 nm extracellular cleft. Unlike the chemical synapse the gap junction in the neuropile of the fly appears structurally symmetrical. No such gap junctions are found either between R-fibres and glial cells, interneurons and glial cells, between glial cells and between interneurones themselves, nor between the parallel long receptor axons R7/8, which bypass the lamina outside the cartridge. In accordance with electrophysiological data, it can now be argued that the six short receptor axons R1--R6 are electrically interconnected by symmetrical gap junctions.

Intramembraneous particles and transmembraneous ionic channels in the epidermal cell membrane. A cytochemical study with the alcian blue-lanthanum technique

Normal skin was investigated with the Alcian blue-lanthanum technique. Nexus (gap junctions) were found in the stratum Malpighii. They were less numerous in the basal layer, increasing to the upper layers of the epidermis and lacking in the stratum corneum. They were five-layered, about 20 nm thick and showed a 5-7 nm broad lanthanum positive intercellular dense line. Transitional forms between the narrow intercellular space and the real nexus were observed. These "nearly nexus" were broader, the intercellular dense line measured 6-15 nm, and sometimes they were seven-layered. Both, nexus and "nearly nexus" revealed a specific distribution of lanthanum in their membranes. Lanthanum ions seemed to penetrate the membranes forming electron-dense transversal channels branching off from the central dense line with a periodicity of 3 nm. The tangential sections suggested that this distribution was based on the aggregation of intramembraneous particles 1.5-2.0 nm in diameter, which in some areas may be gathered to greater subunits. The nexus may play a role in the control of epidermal proliferation.

Permeability of a cell junction and the local cytoplasmic free ionized calcium concentration: a study with aequorin

A technique is devised to determine the spatial distribution of the free ionized cytoplasmic calcium concentration ([Ca2+]i) inside a cell: Chironomus salivary gland cells are loaded with aequorin, and hte Ca2+-dependent light emission of the aequorin is scanned with an image-intensifier/television system. With this technique, the [Ca2+]i is determined simultaneously with junctional electrical coupling when Ca2+ is microinjected into the cells, or when the cells are exposed to metabolic inhibitors, Ca-transporting ionophores, or Ca-free medium. Ca microinjections elevating the [Ca2+]i in the junctional locale produce depression of junctional membrane conductance. When the [Ca2+]i elevation is confined to the vicinity of one cell junction, the conductance of that junction alone is depressed; other junctions of the same cell are not affected. The depression sets in as the [Ca2+]i rises in the junctional locale, and reverses after the [Ca2+]i falls to baseline. When the [Ca2+]i elevation is diffuse throughout the cell, the conductances of all junctions of the cell are depressed. The Ca injections produce no detectable [Ca2+]i elevations in cells adjacent to the injected one; the Ca-induced change in junctional membrane permeability seems fast enough to block appreciable transjunctional flow of Ca2+. Control injections of Cl- or K+ do not affect junctional conductance. The Ca injections that elevate [Ca2+]i sufficiently to depress junctional conductance also produce under the usual conditions an increase in nonjunctional membrane conductance and, hence, depolarization. But injections that elevate [Ca2+]i at the junction while largely avoiding nonjunctional membrane cause depression of junctional conductance with little or no depolarization. Moreover, elevations of [Ca2+]i in cells clamped near resting potential produce the depression, too. On the other hand, complete depolarization in K medium does not produce the depression, unless accompanied by [Ca2+]i elevation. Thus, the depolarization is neither necessary nor sufficient for depression of junctional conductance. Treatment with cyanide, dinitrophenol and ionophores X537A or A23187 produces diffuse elevation of [Ca2+]i associated with depression of junctional conductance. Prolonged exposure to Ca-free medium leads to fluctuation in [Ca2+]i where rise and fall of [Ca2+]i correlate respectively with fall and rise in junctional conductance.

New membrane formation and intercellular communication in the early Xenopus embryo

The ionic permeability of the nonjunctional and newly formed junctional membranes was investigated in embryos of Xenopus laevis up to the onset of the fifth cleavage. Continuous measurements were made of the equivalent nonjunctional (R'o) and junctional resistances (R'i) in different pairs of adjacent cells separated by one of the four cleavage membranes formed in that period. The specific resistance of the nonjunctional membranes (ro) and of each cleavage membrane (ri) as a function of time were derived using a generally applicable computer simulation model. ro decreased from about 40 komega cm2 in the in the uncleaved egg to about 10 komega cm2 at the 16-cell stage, due to the insertion of a small fraction of the relatively permeable newly formed cleavage membranes into the outer surface. Superimposed on this overall decline, a transient decrease of ro was observed during each cycle, caused by a temporary partial separation of the peripheral parts of adjacent blastomeres. The changes in followed the same pattern. R'1 increased stepwise during each cleavage cycle. At the onset of each cleavage there were no significant differences in R'i as measured between different pairs of cells. After an initial phase of membrane formation ri of all cleavage membranes remained constant at about 400 omega cm2. In the states investigated the coupling ratio ranged from 0.8 to 1. It is argued that this close coupling could be the result of the highly impermeable outer surface even in the absence of specialized junctions in the intercellular membranes.

Fine structure of the rectum in cockroaches (Dictyoptera): general organization and intercellular junctions

The organization of the rectal pads is described in cockroaches belonging to the Groups Blattoidea (Periplaneta americana, Blatta orientalis) and Blaberoidea (Supella supellectillu, Blaberus craniifer). In the Blattoidea, each pad is composed of two layers (principal and basal cells) and is surrounded by very narrow junctional cells supporting the sclerotized cuticle of the pad frame; basally, the junctional cells abut on to the basal cells. In the Blaberoidea, the basal cell layer is discontinuous, the basal cells being interspersed between extensions of the junctional cells beneath the pad. The ultrastructural features of each cell type is described, with special reference to the intercellular junctions, which exhibit unusual complexity. Four types of junction are recognized: desmosomes (belt and spot desmosomes), gap junctions, septate junctions and scalariform (ladder-like) junctions. The last are usually closely associated with mitochondria, forming mitochondrial-scalariform junction complexes (MS). The distribution of these junctions is examined in relation to the partitioning of extracellular spaces, and to the problem of fluid transport.

Calcium ion distribution in cytoplasm visualised by aequorin: diffusion in cytosol restricted by energized sequestering

The distribution of Ca2+ in the cytoplasm following a local rise in Ca2+ concentration is visualized by means of aequorin luminescence and a television system with an image intensifier. Diffusion of Ca2+ through the cytosol is so constrained that a rise in cytoplasmic Ca2+ concentration produced by local Ca2+ entry through cell membrane or by local Ca2+ injection is confined to the immediate vicinity of these sites. The diffusion constraints are lifted by treatment with cyanide or ruthenium red. Thus, energized calcium sequestering, probably by mitochondria, is the dominant factor in the constraints. In cell regions where the sequestering machinery is sufficiently dense, different Ca2+ message functions inside a cell may be effectively segregated, permitting private-line intracellular communication.

Luteinizing hormone, progesterone and the morphological development of normal and superovulated corpora lutea in sheep

The development of granulosa-lutein cells was studied in 27 normal and 32 superovulated ewes between days 0-4(day 0 began with the preovulatory LH peak in normal animals and the HCG injection in superovulated ewes). The pattern of differentiation was similar in both groups. Following initial hormonal stimulation (0-12 hours after LH or HCG), granulosa cells were approximately 100 mu2 and contained small, pleomorphic nuclei with large amounts of clumped chromatin. Elongate cells lining the basement membrane possessed large, heterogeneous dense bodies, and a well-developed Golgi apparatus. Mitotic figures were observed up to 6 hours prior to ovulation. Sixteen to 20 hours following the LH surge or HCG injection, hypertrophy of granulosa cells was evident. Nuclei contained definitive nucleoli. Blood vessels in the theca interna were abundant and highly dilated. Ovulation occurred approximately 24 hours after the LH peak or HCG injection. Visible signs of luteinization were evident 6-12 hours after ovulation. A slight increase in serum progesterone levels was detected. The second post-ovulatory day was characterized by continuing hypertrophy of granulosa cells and extensive proliferation of smooth endoplasmic reticulum and mitochondria. Nuclei of granulosa cells were larger and possessed extremely large nucleoli. Numerous mitotic figures were apparent within the corpus luteum. Serum progesterone concentrations began increasing at 60-72 hours after hormone stimulation. By the end of the third post-ovulatory day, the corpus luteum consisted of large, pleomorphic, parenchymal cells, interspersed between capillaries and connective tissue elements. Only an occasional mitotic figure was apparent within the corpus luteum at 100 hours. Light microscopic autoradiography of 5, 10, and 15 day corpora lutea taken from ewes pulsed with 3H thymidine at specific times before and after ovulation revealed that granulosa cells did not undergo secondary mitoses following ovulation. In contrast, thecal, mesenchymal and endothelial cells did mitose on day 3.

Absence of cell communication for fluorescein and dansylated amino acids in an electrotonic coupled cell system

Quantitative evaluation of the diffusion process of sodium fluorescein and dansylated amino acids in the salivary gland of the larvae of Drosophila hydei reveals that the differences in specific permeability between the junctional and nonjunctional membranes, as found for small ions, do not apply to the fluorescent probes. There are no significant differences between the permeability properties for the different dansylated amino acids tested, and the same properties are found for sodium fluorescein.

Intercellular communication in a positional field. Ultrastructural correlates and tracer analysis of communication between insect epidermal cells

The junctional membrane in the epidermal cells of the larval beetle (Tenebrio molitor L.) is comprised of macular gap junctions embedded in septate junctions. Ultrastructural and morphometric analysis of the distribution of gap junctions within the segmental epidermis suggests that this junction alone could account for the high electrotonic coupling recorded for the epidermal sheet. Analysis of the lanthanum-impregnated septate junction makes it doubtful that this junction serves as a communicating channel between beetle cells. A new model for the septate junction is presented in which pleated septa, less than 30 A thick, connect adjacent plasma membranes; the septa themselves are interconnected by two interseptal platforms that are coplanar with the plasma membranes. Iontophoretic injection of organic tracers into single epidermal cells suggests that only molecules of less than MW 1000 can transfer between cells through low-resistance junctions.

A freeze-fracture study of adult Calliphora salivary glands

A freeze-fracture study of adult Calliphora salivary glands has revealed a high density (approx. 4500/mu2) of intramembraneous particles (80-110 A) in both the apical and basal membranes. Most of the particles were associated with the A face. The density of the stalked surface particles which coat the cytoplasmic surface of the apical membrane. The possible significance of these particles in ion transport is discussed.