Change of form of septate and gap junctions during development of the insect midgut

In insects, smooth septate junctions join cells derived from the embryonic midgut, and pleated septate junctions are found in all other tissues. Relatively little is known about either type of septate junction or the relationship between them, but they have been treated as two different junctions in the literature. The gap junctions which are associated with these septate junctions also differ. Crystalline gap junctions are found in the midgut, associated with smooth septate junctions, and irregular gap junctions are found in tissues where pleated septate junctions are located. We have examined the development of smooth septate junctions and crystalline gap junctions and the relationship between them, by studying the embryogenesis of the midgut in Manduca sexta (tobacco hornworm). At 56 hr of development (hatching is at 104 hr) pleated septate junctions and irregular gap junctions joined the midgut epithelial cells. At 65 hr, the septate junctions had disappeared, but gap junctions persisted. At 70 hr, smooth septate junctions had replaced the earlier pleated septate junctions and gap junctions associated with these smooth septate junctions were often of the crystalline form. In later embryos, the smooth septate junctions matured and enlarged, while all gap junctions became crystalline in form.     

Further studies on the junctional complex in the intestine of Sagitta setosa

Summary The intramembrane structures of the pleated septate junction which occur in the junctional complex of the intestine of the chaetognath Sagitta setosa have been investigated.The pleated septate junction is made up of linear rows of irregularly shaped and sized particles, often fused into short rods, and pits which can be fused into furrows. The distribution of these structures on E and P faces depends upon the preparative methods used. Many of the morphological characteristics are the same as those of the lower invertebrate pleated septate junction type defined by Green (1981a). The physiological significance of this junction is obscure.On the basis of the presence of septate junctions (both of the paired septate junction and pleated septate junction types) which have mainly morphological characteristics of the lower invertebrate pleated septate junction we can add to the hypothesis that chaetognaths are not related to the molluscs and arthropods.     

Glial cell contacts in insects: Effects of feeding on intercellular junctions

The intercellular junctions associated with the modified glial cells of the perineurium have been examined in the ganglia and main abdominal nerves of the blood-sucking bug Rhodnius prolixus, both before and and after feeding, by means of freeze-fracture and tracer studies. It was found that the pleated septate junctions found in the main abdominal nerve have many fewer septa than those found in the ganglion. These junctions appear to provide the flexibility needed for the movement of cells which occurs to accommodate the tremendous increase in body size that takes place after a bloodmeal. On feeding and during the subsequent period of digestion the nerves stretch to double their length, yet the blood-brain barrier is maintained throughout. In the same manner as loosely interconnected tight junctions, septate junctions with fewer septa seem to form a junction which is able to respond readily to the stress of stretching. With feeding and afterwards the septate junctions become disorganized and disassemble, while the gap junctions and tight junctions remain intact. It is envisaged, therefore, that the primary function of the septate junction is adhesive.     

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.     

Junctional complexes between the Sertoli cells in the testis of the crayfish,Procambarus paeninsulanus

The testis of the crayfish,Procambarus paeninsulanus, was prepared for light and electron microscopic study. It is composed of tubules containing germ-spermatogenic and somatic-Sertoli cells. In sections of tubules lacking sperm, the Sertoli cells rest on the basement membrane. A desmosome-like junction is found near the luminal surface between two adjacent Sertoli cells. It is closely associated with a long, septate junction. Between Sertoli cells which have surrounded numerous spermatids, the undulating membranes exhibit profiles of pleated septate junctions in tangential sections. The morphology of the pleated septate junctions between adjacent Sertoli cells suggests a possible role as a permeability barrier.     

The fine structure of polychaete septate junctions

Summary Epidermal septate junctions of Nereis sp. and Cirriformia sp. fixed with OsO₄ or glutaraldehyde/OsO₄ display variable structure in electron micrographs. In transverse section the septa are often indistinct and obscured by opaque material that fills the junctional cleft. Septa (spaced at 180–280 Å) are more clearly defined in slightly oblique transverse section; they exhibit an electron lucent center and appear to be linked by arms. En face views of the junction show a honeycomb pattern. Cytoplasmic faces of junctional membranes are backed with plaques opposite the septa. Lanthanum used as a tracer delineates junctional structure in negative contrast. In transverse section a chain-like lattice is present in the junctional cleft. En face views show parallel rows of pleated elements often linked by arms into honeycomb arrays. Oblique sections demonstrate that these pleated elements are continuous with the chain-like lattice seen in transverse sections. Lanthanum does not pass entirely through the junction. Lanthanum reveals that the septa have a very intricate substructure, but it is difficult to visualize the architecture that could generate the various images presented by these junctions when seen in different orientations. However, it is clear that these junctions possess some features that are diagnostic of several supposedly different types of septate junctions in invertebrates.Supported by USPHS grants NIH 5 P01 NS-07512, NIH 2701 GM-00102, and NB-00840, and by a grant from the Pomona College Research CommitteeI thank Sarah Wurzelmann, Stanley Brown, Nancy Kelly, and Gerhard Ott for excellent technical assistance. Portions of this study were carried out while I was a Postdoctoral Fellow in the Department of Anatomy, Albert Einstein College of Medicine. I dedicate this article to Berta Scharrer as a token of appreciation and affection for her guidance, encouragement, inspiration, and example of excellence     

A clarification of the two types of invertebrate pleated septate junction

It is confirmed that there are two distinct variations of invertebrate 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 athropods, is renamed the ‘mollusc-arthropod pleated septate junction’, and is described briefly to allow easier comparison between the two variations. As both types have now 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.     

The terminal bar in the larval midgut epithelium ofAeshna cyanea

Summary Thin section and freeze-fracture electron microscopy revealed that the terminal bars of the larval midgut epithelium ofAeshna cyanea consisted of extended smooth septate junctions (SSJ), multiple adhesive junctions and rare gap junctions. Freeze-fractures of native tissue suggested that the septal building units were anchored only in the external membrane leaflet by partially integrated proteins while the interseptal pegs were anchored partly in both leaflets by completely integrated proteins and partly by presumed peripheral proteins.Reversible depletion of the physiological Ca⁺⁺ concentration had no apparent structural effect on the SSJ of the terminal bars, but led to a reversible formation of junctional septa between the foot processes concomitant with a rearrangement of IMPs in the basolateral plasma membranes. The basolateral SSJ assembly and disassembly induced by reversible Ca⁺⁺ deprivation was interpreted as exaggerated response of an intrinsic capability normally related to the apical growth of regenerative cells and to the extrusion of degenerating cells. Lanthanum tracer ingested with hyperosmotic drinking solution was always found excluded from the basolateral intercellular spaces underneath the terminal bar, but there was a dual effect on the SSJ structure. Part of the junctions remained structurally intact, part was dissociated in the apical portion and invaded by tracer.Abbreviations EF exoplasmic fracture face - EGTA ethylenglycol-bis(2-aminoethylether)-N,N-tetraacetic acid - IMP intramembrane particle - PAS periodic acid Schiff reagent - PF protoplasmic fracture face - PSJ pleated septate junction - SDS sodium dodecyl sulphate - SSJ smooth septate junction Dedicated to Prof. Dr. E.Scholtyseck in honour of his 65th birthday.     

Organization and function of septate junctions

In most cell types, distinct forms of intercellular junctions have been visualized at the ultrastructural level. Among these, the septate junctions are thought to seal the neighboring cells and thus to function as the paracellular barriers. The most extensively studied form of septate junctions, referred to as the pleated septate junctions, is ultrastructurally distinct with an electron-dense ladder-like arrangement of transverse septa present in invertebrates as well as vertebrates. In invertebrates, such as the fruit fly Drosophila melanogaster, septate junctions are present in all ectodermally derived epithelia, imaginal discs, and the nervous system. In vertebrates, septate junctions are present in the myelinated nerves at the paranodal interface between the myelin loops and the axonal membrane. In this review, we present an evolutionary perspective of septate junctions, especially their initial identification across phyla, and discuss many common features of their morphology, molecular organization, and functional similarities in invertebrates and vertebrates.     

Evidence for high molecular weight proteins in arthropod gap and smooth septate junctions

The proteins that make up arthropod gap and septate junctions have not been identified with any certainty. Several candidate proteins for both types of junctions have been proposed in the literature, but there has been no agreement on any of these. Arthropod gap junctions do not label with antibodies to vertebrate gap junction connexins; it thus appears that unrelated proteins form these rather similar structures. Gap junctions inManduca sextamidgut epithelium are unusual since they function only during the molt and are non-functioning during the larval instars. We have developed a preparation from this tissue that is highly enriched in both gap and smooth septate junctions when examined by electron microscopy. SDS-PAGE gels of this preparation have two major protein bands, at 75 and 90 kDa. The presence of gap junctions correlates best with the 75 kDa protein and smooth septate junctions with the 90 kDa protein. Further, the 75 kDa band is stained by an antibody to a putative gap junction protein fromC. elegans. We propose that the 75 kDa protein is a major structural component of gap junctions inManduca sextamidgut epithelium and that the 90 kDa protein forms the smooth septate junctions.     

Sealing junctions in a number of arachnid tissues

The junctions present in the central nervous system (CNS), midgut, silk gland and venom gland of arachnids have been investigated. Special care was taken to try to locate tight junctions in tissue other than CNS but they were not found in any of the other tissues. The detailed structure of the junctions present are discussed. The tight junctions present in CNS are somewhat different in appearance and fracturing behaviour to most vertebrate tight junctions and closely resemble only those found in Urochordates (a non-vertebrate chordate). The two types of septate junctions found in the other tissues belong to the pleated septate and smooth septate classes but show some interesting differences. It appears probable that the septate junctions in Arachnida, Merostomata and Myriopoda have different fracturing properties from those found in other arthropods. The finding that only septate junctions are present in most arachnid tissues, although tight junctions are present in CNS, is discussed in the context of the sealing function of septate junctions in invertebrate tissues.     

Septate junctions in the cephalic epidermis of turbellarians (Bipalium)

Summary In the epidermis of turbellarians septate junctions of the pleated sheet type have been demonstrated in conventional thin sections and freeze fractured preparations. The structure of these junctions entirely agrees with that found in molluscs and arthropods.Financially supported by DFG (Sto 75/3,4; We 380/5)     

COEXISTENCE OF GAP AND SEPTATE JUNCTIONS IN AN INVERTEBRATE EPITHELIUM

The intercellular junctions of the epithelium lining the hepatic caecum of Daphnia were examined. Electron microscope investigations involved both conventionally fixed material and tissue exposed to a lanthanum tracer of the extracellular space. Both septate junctions and gap junctions occur between the cells studied. The septate junctions lie apically and resemble those commonly discerned between cells of other invertebrates. They are atypical in that the high electron opacity of the extracellular space obscures septa in routine preparations. The gap junctions are characterized by a uniform 30 A space between apposed cell membranes. Lanthanum treatment of gap junctions reveals an array of particles of 95 A diameter and 120 A separation lying in the plane of the junction. As this pattern closely resembles that described previously in vertebrates, it appears that the gap junction is phylogenetically widespread. In view of evidence that the gap junction mediates intercellular electrotonic coupling, the assignment of a coupling role to other junctions, notably the septate junction, must be questioned wherever these junctions coexist.     

A novel adhering junction in the apical ciliary apparatus of the rotifer Brachionus plicatilis (Rotifera, Monogononta)

Cultures of the rotifer Brachionus plicatilis were examined with regard to their interepithelial junctions after infiltration with the extracellular tracer lanthanum, freeze-fracturing or quick-freeze deepetching. The lateral borders between ciliated cells have an unusual apical adhering junction. This apical part of their intercellular cleft looks desmosome-like, but it is characterized by unusual intramembranous E-face clusters of particles. Deep-etching reveals that these are packed together in short rows which lie parallel to one another in orderly arrays. The true membrane surface in these areas features filaments in the form of short ribbons; these are produced by projections, possibly part of the glycocalyx, emerging from the membranes, between which the electron-dense tracer lanthanum permeates. These projections appear to overlap with each other in the centre of the intercellular cleft; this would provide a particularly flexible adaptation to maintain cell-cell contact and coordination as a consequence. The filamentous ribbons may be held in position by the intramembranous particle arrays since both have a similar size and distribution. These contacts are quite different from desmosomes and appear to represent a distinct new category of adhesive cell-cell junction. Beneath these novel structures, conventional pleated septate junctions are found, exhibiting the undulating intercellular ribbons typical of this junctional type, as well as the usual parallel alignments of intramembranous rows of EF grooves and PF particles. Below these are found gap junctions as close-packed plaques of intramembranous particles on either the P-face or E-face. After freeze-fracturing, the complementary fracture face to the particles shows pits, usually on the P-face, arrayed with a very precise hexagonal pattern.     

Junctional structures in digestive epithelia of a cephalopod

Intercellular junctions have been studied in the epithelia of digestive organs of Sepia officinalis (digestive gland, digestive duct appendages and caecum) by conventional staining, lanthanum tracer and freeze-fracturing techniques. In the three organs studied the same junctional complex occurs, consisting of a belt desmosome, a septate junction and gap junctions. The septate junction is of pleated-sheet type and the gap junction has its particles on the P face of the fracture. Circular structures have been found in the digestive gland septate junctions. Neither continuous nor tight junctions have been found. These results show that Cephalopods have junctional structures very close to those of other Molluscs and of Annelids. Some small differences between the septate junctions of the three organs could be related to their different physiology.     

The coincident time-space patterns of septate junction development in normal and exogastrulated sea urchin embryos

Earlier studies have shown that two types of septate junction are formed during early sea urchin morphogenesis. One type is the straight, unbranched, double septum septate (SUDS) which is found in the ectodermal layer throughout early development. The second type is formed only in cells which invaginate to become endoderm and to form the digestive tract. This junction is characterized by pleated, anastomosing, single septum septates (PASS). In order to ascertain in which parts of the digestive tract these junctions are formed, we studied exogastrulae because the endoderm is everted and forms constricted areas of the gut which are easily recognizable. Our results show that, in control embryos, SUDS septates are found in the mouth, esophagus and coelom and that PASS septates are found in the stomach, intestine and anus. These junctional types are also found in the same areas in exogastrulae; SUDS septates are found in the stomadeum, esophagus and coelom, and PASS septates are found in the stomach and intestine. The transition from SUDS to PASS junctions takes place within the same time period in exogastrulae as in normal embryos, i.e., from the time of mid-gastrulation through the pluteus stage. These results indicate that septate junction formation in the sea urchin embryo digestive tract may be genetically programmed in terms of both time and spatial location. This program is not altered either by the major dislocation of cells from their normal position within the embryo or from normal contacts with neighboring cells.     

The role of cytoskeletal components in the maintenance of intercellular junctions in an insect

Summary Accessory glands of the cockroach are composed of secretory and supportive cells, the latter providing a skeleton-like framework of attentuated cytoplasmic processes into which the former are positioned. These two cell types are associated with one another laterally by adhaering, pleated septate, and gap junctions. Hemi-adhaerens junctions are also found on both luminal and basal surfaces of the gland; the former are associated with the cuticular lining of the lumen and the latter with extracellular matrix. The adhering and septate junctions are flanked by both filaments and microtubules; the former insert into the junctional membranes and are actin-like, binding both rhodamine-conjugated phalloidin and the S₁ subfragment of rabbit heavy meromyosin. The role of this cytoskeletal protein with the cellular junctions has been explored by treatment with a disruptive agent, cytochalasin D. Dissociation of actin leads to changes in septate junctions and in microtubular distribution. This suggests that the latter act as anchors for the actin filaments which, in turn, appear bound to certain of the intramembranous junctional components.Supported by a Conicet/Royal Society Visiting Fellowship     

Analog of vertebrate anionic sites in blood-brain interface of larval Drosophila

The blood-brain barrier ensures brain function in vertebrates and in some invertebrates by maintaining ionic integrity of the extraneuronal bathing fluid. Recent studies have demonstrated that anionic sites on the luminal surface of vascular endothelial cells collaborate with tight junctions to effect this barrier in vertebrates. We characterize these two analogous barrier factors for the first time on Drosophila larva by an electron-dense tracer and cationic gold labeling. Ionic lanthanum entered into but not through the extracellular channels between perineurial cells. Tracer is ultimately excluded from neurons in the ventral ganglion mainly by an extensive series of (pleated sheet) septate junctions between perineurial cells. Continuous junctions, a variant of the septate junction, were not as efficient as the pleated sheet variety in blocking tracer. An anionic domain now is demonstrated in Drosophila central nervous system through the use of cationic colloidal gold in LR White embedment. Anionic domains are specifically stationed in the neural lamella and not noted in the other cell levels of the blood-brain interface. It is proposed that in the central nervous system of the Drosophila larva the array of septate junctions between perineurial cells is the physical barrier, while the anionic domains in neural lamella are a charge-selective barrier for cations. All of these results are discussed relative to analogous characteristics of the vertebrate blood-brain barrier.     

THE STRUCTURAL ORGANIZATION OF THE SEPTATE AND GAP JUNCTIONS OF HYDRA

The septate junctions and gap junctions of Hydra were studied utilizing the extracellular tracers lanthanum hydroxide and ruthenium red. Analysis of the septate junction from four perspectives has shown that each septum consists of a single row of hexagons sharing common sides of 50–60 A. Each hexagon is folded into chair configuration. Two sets of projections emanate from the corners of the hexagons. One set (A projections) attaches the hexagons to the cell membranes at 80–100-A intervals, while the other set (V projections) joins some adjacent septa to each other. The septate junctions generally contain a few large interseptal spaces and a few septa which do not extend the full length of the junction. Basal to the septate junctions the cells in each layer are joined by numerous gap junctions. Gap junctions also join the muscular processes in each layer as well as those which connect the layers across the mesoglea. The gap junctions of Hydra are composed of rounded plaques 0.15–0.5 µ in diameter which contain 85-A hexagonally packed subunits. Each plaque is delimited from the surrounding intercellular space by a single 40-A band. Large numbers of these plaques are tightly packed, often lying about 20 A apart. This en plaque configuration of the gap junctions of Hydra contrasts with their sparser, more widely separated distribution in many vertebrate tissues. These studies conclude that the septate junction may possess some barrier properties and that both junctions are important in intercellular adhesion. On a morphological basis, the gap junction appears to be more suitable for intercellular coupling than the septate junction.     

The arthropod gap junction and pseudo-gap junction: Isolation and preliminary biochemical analysis

Summary The hepatopancreas of the crayfish, Procambarus clarkii, contains an unusual abundance of gap junctions, suggesting that this tissue might provide an ideal source from which to isolate the arthropod-type of gap junction. A membrane fraction obtained by subcellular fractionation of this organ contained smooth septate junctions, zonulae adhaerentes, gap junctions and pentalaminar membrane structures (pseudo-gap junctions) as determined by electron microscopy. A further enrichment of plasma membranes and gap junctions was achieved by the use of linear sucrose gradients and extraction with 5 mM NaOH. The enrichment of gap junctions correlated with the enrichment of a 31 Kd protein band on polyacrylamide gels. Extraction with 20 mM NaOH or 0.5% (w/v) Sarkosyl NL97 resulted in the disruption and/or solubilization of gap junctions. Negative staining revealed a uniform population of 9.6 nm diameter subunits within the gap junctions with an apparent sixfold symmetry. Using antisera to the major gap junctional protein of rat liver (32 Kd) and to the lens membrane protein (MP 26), we failed to detect any homologous antigenic components in the arthropod material by immunoblotting-enriched gap junction fractions or by immunofluorescence on tissue sections. The enrichment of another membrane structure (pseudo-gap junctions), closely resembling a gap junction, correlated with the enrichment of two protein bands, 17 and 16Kd, on polyacrylamide gels. These structures appeared to have originated from intracellular myelin-like figures in phagolysosomal structures. They could be distinguished from gap junctions on the basis of their thickness, detergent-alkali insolubility, and lack of association with other plasma membrane structures, such as the septate junction. Pseudo-gap junctions may be related to a class of pentalaminar contacts among membranes involved in intracellular fusion in many eukaryotic cell types. We conclude that pseudo-gap junctions and gap junctions are different cellular structures, and that gap junctions from this arthropod tissue are uniquely different from mammalian gap junctions of rat liver in their detergentalkali solubility, equilibrium density on sucrose gradients, and protein content (antigenic properties).