A blood-brain barrier without tight junctions in the fly central nervous system in the early postembryonic stage

Summary The anatomical basis of the vertebrate blood-brain barrier is a series of tight junctions between endothelial cells of capillaries in the central nervous system. Over two decades ago, tight junctions were also proposed as the basis of the blood-brain barrier in insects. Currently there is a growing understanding that septate junctions might possess barrier properties in various invertebrate epithelial cells. We now examine these two views by studying the blood-brain barrier properties of the early postembryonic larva of a dipteran fly (Delia platura) by transmission electron microscopy. Newly hatched larvae possess a functioning blood-brain barrier that excludes the extracellular tracer, ionic lanthanum. This barrier is intact throughout the second instar stage as well. The ultrastructural correlate of this barrier is a series of extensive septate junctions that pervade the intercellular space between adjacent perineurial cells. No tight junctions were located in either nerve, glial or perineurial cell layers. We suggest that the overall barrier might involve septate junctions within extensive, meandering intercellular clefts.     

X-ray microanalysis with transmission electron microscopy determined presence and movement of tracer (lanthanum chloride) at blood-neuron barrier of Drosophila melanogaster (Diptera : Drosophilidae) larva

In studying the larval Drosophila (Diptera : Drosophilidae) blood-brain barrier, it was important to determine if even minute amounts of tracer ultimately seeped through the septate junctions between perineurial cells to reach the neuronal region. Concurrent TEM with X-ray microanalysis was undertaken to resolve that issue. Ultrathin sections of Drosophila nervous tissue in LR White embedment were exposed to ionic tracer (lanthanum chloride) and assayed for presence or absence of lanthanum extracellular to the perineurium and glia making up the nerve sheath. Tracer filled the distal interseptal lattice of pleated sheet-septate junctions, but was contained prior to reaching the proximal paracellular space. No detectable tracer passed through septate junctions to enter the glial-neuronal domain. Based on our present data and the research of others, septate junctions in immature Drosophila are multifunctional structures that enforce spatial relationships between cells, seal intercellular spaces, and control cell proliferation in the epithelia. Septate junctions in Drosophila with the (dlg) gene also exhibit protein homologies to the Z0–1 human tight junction component.     

Perineurium in the Drosophila (Diptera : Drosophilidae) embryo and its role in the blood-brain/nerve barrier

A monolayer of perineurial cells overlies glia and neurons, and this stratum of the central nervous system is the principal site of the Drosophila (Diptera : Drosophilidae) blood-brain barrier. Perineurial cells are bonded together by pleated-sheet septate junctions that are the anatomical correlate of the vertebrate tight junction. The blood-brain barrier maintains the ionic homeostasis necessary for proper nerve function. It was known that a functioning blood-brain barrier is present in mature (Stage 17) Drosophila embryos, but the genesis of this barrier was not known. We surveyed the central nervous system of late stage embryos (15 through 17) to determine when perineurial cells could first be detected. These cells take their place in (on) the central nervous system and are joined together by pleated-sheet septate junctions, during Stage 17. Those septate junctions are quickly occlusive to lanthanum tracer. This development step occurs during the same time as when chemical synapses first become functional. Such concurrent maturation is far from coincidental, because partitioning nerves and their synapses from hemolymph (with its variable ionic constitution) are essential for normal electrophysiology. We discuss details of the germ line derivation of perineurial cells, their first detection in the embryonic central nervous system, their functional properties, and the polygonal cell-packing pattern seen in the larval central nervous system.     

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.     

The perineurium of the adult housefly: Ultrastructure and permeability to lanthanum

Summary The ultrastructure of the perineurial cells of Musca overlying the first optic neuropile was examined by transmission electron microscopy. These cells are somewhat similar to those of other insects but cytoplasmic flanges seem to be absent, and mitochondria are relatively large and sinuous. The intercellular channel system on the lateral border of the cells is relatively spacious and highly meandering. Perineurial cells are joined by septate, gap, and tight junctions, hemidesmosomes, and desmosomes. Tight and septate junctions bond perineurial cells and glial cells. These data are evaluated on the basis of tracer studies with lanthanum. This material penetrates the extracellular space between perineurium and underlying glial and nerve cells, between epithelial glial cells and retinular axon terminals (capitate projections), and between the - fiber pair in the optic cartridge (gnarls). If no damage occurs to the perineurial cells during tissue preparation, this passage of lanthanum to neuronal surfaces indicates that the blood brain barrier is incomplete in this restricted area. Supportive evidence for such permeance is based on electrophysiological data, considerations of membrane specializations in the optic neuropile, and Na⁺/K⁺ ratios of dipteran hemolymph.We gratefully acknowledge support from the N.I.H., National Eye Institute, EYO 1686 and from the College of Agricultural and Life Sciences, Hatch Project 2100. Richard L. St. Marie and Professor Stanley D. Beck, Department of Entomology, UW, Madison read early drafts of this paper and provided constructive comments     

The Ly6 protein coiled is required for septate junction and blood brain barrier organisation in Drosophila

Background

Genetic analysis of the Drosophila septate junctions has greatly contributed to our understanding of the mechanisms controlling the assembly of these adhesion structures, which bear strong similarities with the vertebrate tight junctions and the paranodal septate junctions. These adhesion complexes share conserved molecular components and have a common function: the formation of paracellular barriers restraining the diffusion of solutes through epithelial and glial envelopes.

Methodology/Principal Findings

In this work we characterise the function of the Drosophila cold gene, that codes for a protein belonging to the Ly6 superfamily of extracellular ligands. Analysis of cold mutants shows that this gene is specifically required for the organisation of the septate junctions in epithelial tissues and in the nervous system, where its contribution is essential for the maintenance of the blood-brain barrier. We show that cold acts in a cell autonomous way, and we present evidence indicating that this protein could act as a septate junction component.

Conclusion/Significance

We discuss the specific roles of cold and three other Drosophila members of the Ly6 superfamily that have been shown to participate in a non-redundant way in the process of septate junction assembly. We propose that vertebrate Ly6 proteins could fulfill analogous roles in tight junctions and/or paranodal septate junctions.     

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.     

The ultrastructural organization of peripheral nerves in two insect species (Periplaneta americana and Schistocerca gregaria)

The ultrastructural organization of various peripheral nerves, including the crural nerve, has been investigated in the locust and cockroach. In some cases the larger nerves are ensheathed by a fat body layer which is not always complete. However, like many nervous connectives, they do possess a continuous acellular neural lamella and a perineurial cell layer which surround the glial-axonal mass. Adjacent perineurial cells are associated with one another by septate desmosomes, gap junctions and tight junctions. These last may represent the morphological basis of the ‘blood-brain barrier’ observed electrophysiologically in these peripheral nerves in another report. Very small nerves of the cockroach, however, although lying embedded in a neural lamella, do not possess a specialized perineurial layer displaying junctional complexes, unless they contain one or more large axons. If they have only one or more small axons, these small nerves may either appear naked, or display a single glial cell process loosely enveloping them; in either case there is no structural basis for a ‘barrier’ system. Various comparisons have been made between locust crural nerve and the cockroach central nervous connectives in an attempt to correlate some aspects of their ultrastructural organization with relevant electrophysiological information.     

Changes in the blood-brain barrier of the central nervous system in the blowfly during development, with special reference to the formation and disaggregation of gap and tight junctions. I. Larval development

In the central nervous system (CNS) of full-grown larvae of the blowfly Calliphora erythrocephala, the glial-ensheathed nerve cells are completely surrounded by a layer of perineurial cells which form a “blood-brain barrier” between the circulating haemolymph and the CNS. A variety of intercellular junctions, including gap and tight junctions, are found between adjacent perineurial cells and some also between apposing glial cells; these have been characterized by freeze-fracturing as well as by tracer studies and analysis of thin sections. They are found not to be present between such cells in the undifferentiated CNS in the newly hatched larvae, nor are the nerve cells encompassed by glial cells; ionic lanthanum can penetrate to the axonal surfaces at this stage. However, over the 5 days of larval growth and development the glial cells produce attentuated cytoplasmic processes that ensheath the nerve cells, and the perineurium is formed; junctional complexes are assembled and a larval blood-brain barrier is produced which excludes tracers. Freeze-fracture preparations suggest that the inverted gap junctions which develop have done so by migration of individual intramembranous EF particles to form, at first, linear arrays and small clusters and, ultimately, macular aggregations in the perineurium; these lie between the undulating rows of PF particles forming the septate junctions. These septate junctions are formed by the organization of arrays of PF particles into multiple rows. Extensive PF particles fusing into ridges with EF grooves to form perineurial “tight” junctions are also observed, seemingly in the process of development; entry of exogenous lanthanum followed by its exclusion parallels the completion of ridge formation. These ridges are simple linear arrays of particles which may be discontinuous, lying in parallel with one another and the surface. Clustered particle arrays as well as scattered short ridges on the axonal PF, however, appear to be present unchanged throughout larval life; their role may therefore be associated with neural membrane function although there are suggestions that some may form axo-glial junctions. This is the first report on the lateral migration of intramembranous particles as the mode of formation of gap junctions in the nervous system of an invertebrate.     

Studies on perineural junctional complexes and the sites of uptake of microperoxidase and lanthanum in the cockroach central nervous system

The perineurial junctional complexes in the nerve cord of Periplaneta americana have been shown to consist of septate desmosomes, extensive gap junctions and relatively limited regions of tight junctions. Microperoxidase (M.W. 1,900) undergoes limited intercellular penetration into the septate desmosomes. Lanthanum penetrates both the septate desmosomes and gap junctions. It is concluded that the restricted access of these substances to the underlying extracellular spaces results from the presence of the perineurial tight junctions. These results contrast with those for small peripheral nerves, which lack equivalent junctional complexes, and in which the extracellular spaces are found to be accessible to externally applied lanthanum. The results are discussed in relation to current concepts of the insect blood-brain barrier.     

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.     

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.     

Pleated septate junctions in leech photoreceptors: ultrastructure, arrangement of septa, gate and fence functions

The leech photoreceptor forms a unicellular epithelium: every cell surrounds an extracellular “vacuole” that is connected to the remaining extracellular space via narrow clefts containing pleated septate junctions. We analyzed the complete structural layout of all septa within the junctional complex in elastic brightfield stereo electron micrographs of semithin serial sections from photoreceptors infiltrated with colloidal lanthanum. The septa form tortuous interseptal corridors that are spatially continuous, and open ended basally and apically. Individual septa seem to be impermeable to lanthanum; interseptal corridors form the only diffusional pathway for this ion. The junctions form no diffusion barrier for the electron-dense tracer Ba²⁺, but they hinder the diffusion of various hydrophilic fluorescent dyes as demonstrated by confocal laser scanning microscopy (CLSM) of live cells. Even those dyes that penetrate gap junctions do not diffuse beyond the septate junctions. The aqueous diffusion pathway within the septal corridors is, therefore, less permeable than the gap-junctional pore. Our morphological results combined with published electrophysiological data suggest that the septa themselves are not completely tight for small physiologically relevant ions. We also examined, by CLSM, whether the septate junctions create a permeability barrier for the lateral diffusion of fluorescent lipophilic dyes incorporated into the peripheral membrane domain. AFC₁₆, claimed to remain in the outer membrane leaflet, does not diffuse beyond the junctional region, whereas DiIC₁₆, claimed to flip-flop, does. Thus, pleated septate junctions, like vertebrate tight junctions, contribute to the maintenance of cell polarity.     

Freeze-fracture analysis of gap and septate junctions in embryos of a moth

Gap and septate junctions were examined in embryos of Manduca sexta (tobacco hornworm). The junctions observed were similar in structure to those reported for adult insect tissues. In the epidermis typical pleated septate junctions were found. Associated with the pleated septate junctions were inverted gap junctions which had irregularly arranged particles and pits. In the midgut typical smooth septate junctions were found. Associated with these septate junctions were gap junctions which had a regular hexagonal packing pattern. This codistribution of gap and septate junction types is discussed in light of current theories that the gap junction types are alternative forms of the same structure in different metabolic environments. In addition to these gap and septate junctions a new junction, perhaps a modified pleated septate junction, is described.     

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.     

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.     

Glial cells in peripheral nerves of the cockroach, Periplaneta americana

The ultrastructural organization and the junctional complexes of peripheral nerves have been investigated in the cockroach Periplaneta americana. Nerve 5 is surrounded by a layer of connective tissue, the neural lamella, beneath which is a layer of perineurial glial cells wrapping the axons. Adjacent perineurial cells are joined to one another by septate, gap and tight junctions. Septate and gap junctions were observed in freeze-fracture replicas of main trunk nerve 5. Septate junctions were found as rows of PF particles mainly in perineurial cell membranes. Gap junctions exhibited EF macular aggregates in perineurial and subperineurial glial cells. During incubations in vivo with extracellularly applied ionic lanthanum, the lanthanum did not penetrate beyond the perineurium. Where nerve 5 branches and contacts the muscle, lanthanum penetrated freely between the muscle fibres and the nerve branches. In small peripheral branches where the axons are surrounded by single a glial layer, lanthanum is unable to penetrate to the axolemma.     

The lateral mobility of cell adhesion molecules is highly restricted at septate junctions in <Emphasis Type="Italic">Drosophila</Emphasis>

Background  

A complex of three cell adhesion molecules (CAMs) Neurexin IV(Nrx IV), Contactin (Cont) and Neuroglian (Nrg) is implicated in the formation of septate junctions between epithelial cells in Drosophila. These CAMs are interdependent for their localization at septate junctions and e.g. null mutation of nrx IV or cont induces the mislocalization of Nrg to the baso-lateral membrane. These mutations also result in ultrastructural alteration of the strands of septate junctions and breakdown of the paracellular barrier. Varicose (Vari) and Coracle (Cora), that both interact with the cytoplasmic tail of Nrx IV, are scaffolding molecules required for the formation of septate junctions.     

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.     

Cell junctions in the cyst envelope in the silkworm testis,Bombyx mori linné

Summary The cell junctions of the cyst envelope in the testes of Bombyx mori were examined by electron microscopy utilizing a thin-sectioning technique following conventional fixation, tannic acid fixation and lanthanum tracer study, and also using a freeze-fracture technique. There are three kinds of junctions; septate junctions, gap junctions and tight junctions. Septate junctions are of the pleated type. Gap junctions are characterized by four electron-dense lines and three electronlucent lines in the reduced intercellular spaces seen by thin-sectioning. They are of the E type, having clusters of intramembraneous particles on the E-fracture face. The most striking finding is the frequent presence of tight junctions on the fracture planes, while focally fused outer leaflets of the junctional unit membranes are rarely detected on thin-sectioned preparations. Tight junctions are characterized by branching zigzag ridges on the P-fracture face and complementary grooves on the E-fracture face. It is proposed that tight junctions are new morphological evidence of blood-germ cell barrier in an insect. Acknowledgements: For helpful assistance the authors are indebted to their colleagues Miss N. Minemoto, Miss H. Kiyotake and Mr. Y. Goto