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

In the central nervous system (CNS) of pupal Calliphora, dramatic alterations occur in the perineurial and glial gap junctions. Having formed macular plaques by late larval stages, in early pupae cell migration causes the EF intramembranous junctional particles to disaggregate and move apart into linear and then disorganised arrays as shown by freeze-fracture. After nerve and glial cell reorganisation into the adult pattern, the gap junctions begin to reform in the late pupae, again seemingly by particle migration into linear arrays and clusters. Ultimately the particles form numerous macular plaques between both perineurial and glial cells. Statistical analyses support the contention that these are performed EF particles which undergo translateral movement from macular larval junctions into the disaggregated particles of early pupae and that the same particles appear to undergo realignment and reclustering in late pupae to form the mature gap junctions of adults. This is the first report to indicate breakdown and reformation of gap junctions in vivo involving reutilisation of the same intramembranous particles. Perineurial “tight” junctions are not to be found in early pupal stages and their absence can be correlated with the free entry of ionic lanthanum into the CNS observed during that period. In late pupae, when the tight junctional moniliform ridges have apparently reformed, the entry of the tracer lanthanum becomes restricted to the level of the perineurium, penetrating no deeper. This is also the case in the adult, where the blood-brain barrier is maintained. PF particles in the form of short linear ridges and clustered particle arrays in nerve cell membranes are present throughout pupal and adult stages; their continued presence throughout the whole of development suggests some role in neuronal function, as yet unclear.     

The Sertoli cell occluding junctions and gap junctions in mature and developing mammalian testis.

Special occluding junctions between Sertoli cells near the base of the seminiferous epithelium are the structural basis of the blood-testis permeability barrier. In micrographs of thin sections, multiple punctate pentalaminar contacts between apposed membranes are observed in the junctional regions.In freeze-fractured mature testis, the junctional membranes exhibit up to 40 parallel circumferentially oriented rows of intramembrane particles preferentially associated with the B-fracture face, but with complementary shallow grooves on the A-face. Short rows of particles may remain with the A-face resulting in discontinuities in the B-face particle rows. In addition, elongate aggregations of particles of uniform size (～70 A) arranged in one or more closely packed rows are occasionally found adjacent to the linear depressions on the A-face of the Sertoli junction. These are interpreted as atypical gap junctions.In immature testis, occluding junctions are absent but typical gap junctions are common. These gradually disappear. In the second postnatal week, linear arrays of particles appear on the B-face. Initially meandering and highly variable in direction, these gradually adopt a consistent orientation parallel to the cell base. The establishment of the blood-testis barrier appears to be correlated with this reorganization of the intramembrane particle rows. Sertoli junctions were shown to be resistant to hypertonic solutions that rapidly dissociate junctions of other epithelia.Sertoli junctions thus differ from other occluding junctions in their (1) basal location, (2) large number of parallel particle rows, (3) absence of anastomosis between rows, (4) preferential association of the particles with the B-face, (5) intercalation of atypical gap junctions, (6) unusual resistance to dissociation by hypertonic solutions.     

Freeze-fracture studies of frog atrial fibres.

The freeze-fracturing technique was used to characterize the junctional devices involved in the electrical coupling of frog atrial fibres. These fibres are connected by a type of junction which can be interpreted as a morphological variant of the "gap junction" or "nexus". The most characteristic features are rows of 9-nm junctional particles forming single or anastomosed circular profiles on the inner membrane face, and corresponding pits on the outer membrane face. Very seldom aggregates consisting of few geometrically disposed 9-nm particles are found. The significance of the junctional structures in the atrial fibres is discussed, with respect to present knowledge about junctional features of gap junctions in various tissues, including embryonic ones.     

ASSEMBLY OF GAP JUNCTIONS DURING AMPHIBIAN NEURULATION

Sequential thin-section, tracer (K-pyroantimonate, lanthanum, ruthenium red, and horseradish peroxidase), and freeze-fracture studies were conducted on embryos and larvae of Rana pipiens to determine the steps involved in gap junction assembly during neurulation. The zonulae occludentes, which join contiguous neuroepithelial cells, fragment into solitary domains as the neural groove deepens. These plaque-like contacts also become permeable to a variety of tracers at this juncture. Where the ridges of these domains intersect, numerous 85-Å participles apparently pile up against tight junctional remnants, creating arrays recognizable as gap junctions. With neural fold closure, the remaining tight junctional elements disappear and are replaced by macular gap junctions. Well below the junctional complex, gap junctions form independent of any visible, preexisting structure. Small, variegated clusters, containing 4–30 particles located in flat, particle-free regions, characterize this area. The number of particles within these arrays increases and they subsequently blend together into a polygonally packed aggregate resembling a gap junction. The assembly process in both apical and basal regions conforms with the concept of translational movement of particles within a fluid plasma membrane.     

THE APPEARANCE AND STRUCTURE OF INTERCELLULAR CONNECTIONS DURING THE ONTOGENY OF THE RABBIT OVARIAN FOLLICLE WITH PARTICULAR REFERENCE TO GAP JUNCTIONS

Lanthanum tracer and freeze-fracture electron microscope techniques were used to study junctional complexes between granulosa cells during the differentiation of the rabbit ovarian follicle. For convenience we refer to cells encompassing the oocyte, before antrum and gap junction formation, as follicle cells. After the appearance of an antrum and gap junctions we call the cells granulosa cells. Maculae adherentes are found at the interfaces of oocyte-follicle-granulosa cells throughout folliculogenesis. Gap junctions are first detected in follicles when the antrum appears. In early antral follicles typical large gap junctions are randomly distributed between granulosa cells. In freeze-fracture replicas, they are characterized by polygonally packed 90-Å particles arranged in rows separated by nonparticulate A-face membrane. A particle-sparse zone surrounds gap junctions and is frequently occupied by small particle aggregates of closely packed intramembranous particles. The gap junctions of granulosa cells appear to increase in size with further differentiation of the follicle. The granulosa cells of large Graafian follicles are adjoined by small and large gap junctions; annular gap junctions are also present. The large gap junctions are rarely surrounded by a particle-free zone on their A-faces, but are further distinguished by particle rows displaying a higher degree of organization.     

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.     

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.     

Cell contacts between follicle cells and the oocyte of Helisoma (Mollusca,Pulmonata)

The cell contacts between follicle cells, and follicle cells and oocytes of egg-laying populations of Helisoma duryi and non-egg-laying populations of H. trivcolvis have been studied. Scanning electron microscopy reveals that four to six follicle cells envelop a single developing oocyte. Thin sections and lanthanum impregnations demonstrate apical zonulae adherentes followed by winding pleated-type septate junctions between follicle cells. Gap junctions and septate junctions have been found between follicle cells and vitellogenic oocytes. Freeze-fracture replicas show relatively wide sinuous rows of septate junctional particles, and nemerous large gap junctional particle aggregates on the P-face between vitellogenic oocytes and follicle cells. Septate and gap junctions between immature or nonvitellogenic oocytes and follicle cells are fewer compared to those in vitellogenic oocytes. Similarly, the junctional complexes are less developed in non-egg-laying H. trivolvis compared to those in egg-laying H. duryi. It is possible that intimate interaction between follicle cells and a developing oocyte is necessary for the maturation of the oocyte. The junctional complexes could be involved in the interaction of the follicle cells and the oocyte, and they must disassemble at the onset of ovulation. Rhombic particle arrays and nonjunctional ridges of particles have been found in the basal part of the oolemma.     

Formation of tight and gap junctions in the inner enamel epithelium and preameloblasts in human fetal tooth germs

Human fetal primary tooth germs in the cap stage were fixed with a glutaraldehyde-formaldehyde mixture, and formative processes of tight and gap junctions of the inner enamel epithelium and preameloblasts were examined by means of freeze-fracture replication. Chains of small clusters of particles on the plasma membrane P-face of the inner enamel epithelium and preameloblasts were the initial sign of tight junction formation. After arranging themselves in discontinuous, linear arrays in association with preexisting or forming gap junctions, these particles later began revealing smooth, continuous tight junctional strands on the plasma membrane P-face and corresponding shallow grooves of a similar pattern on the E-face. Although they exhibited evident meshwork structures of various extents at both the proximal and distal ends of cell bodies, they formed no zonulae occludentes. Small assemblies of particles resembling gap junctions were noted at points of cross linkage of tight junctional strands; but large, mature gap junctions no longer continued into the tight junction meshwork structure. Gap junctions first appeared as very small particle clusters on the plasma membrane P-face of the inner enamel epithelium. Later two types of gap junctions were recognized: one consisted of quite densely aggregated particles with occasional particle-free areas, and the other consisted of relatively loosely aggregated particles with particle-free areas and aisles. Gap junction maturation seemed to consist in an increase of particle numbers. Fusion of gap junctions in the forming stage too was recognized. The results of this investigation suggest that, from an early stage in their development, human fetal ameloblasts possess highly differentiated cell-to-cell interrelations.     

In vitro assembly of gap junctions

Gap junction structures were assembled in vitro from octyl-β- -glucopyranoside-solubilized components of lens fiber cell membranes. Individual pore structures (connexons), short double-membrane structures, and other amorphous material were evident in the solubilized mixture. Following the removal of the detergent by dialysis, these connexons associated to form single- and double-layered, two-dimensional hexagonal arrays (unit cell size a = B = 8.5 nm). The formation of larger arrays was dependent on the lipid-to-protein ratio and the presence of Mg²⁺ ions. Crystallographic analysis of electron micrographs revealed that lens junctional connexons consisted of six subunits surrounding a stain-filled channel. Upon further detergent treatment, in vitro assembled gap junctions were insoluble and formed three-dimensional stacks while other components were solubilized. SDS-PAGE and mass data from scanning transmission electron microscopy strongly suggest that a 38-kDa polypeptide, which is a processed form of the lens specific gap junction protein MP70, is a major component of the arrays. The in vitro assembly of gap junctions opens new avenues for the structural analysis of gap junctions and for the study of the intermolecular interactions of connexons during junctional assembly.     

Conditional gene targeting of connexin43: exploring the consequences of gap junction remodeling in the heart

Abnormalities in cardiac gap junction expression have been postulated to contribute to arrhythmias and ventricular dysfunction. We investigated the role of cardiac gap junctions by generating a heart-specific conditional knock-out (CKO) of connexin43 (Cx43), the major cardiac gap junction protein. While the Cx43 CKO mice have normal heart structure and contractile function, they die suddenly from spontaneous ventricular arrhythmias. Because abnormalities in gap junction expression in the diseased heart can be focal, we also generated chimeric mice formed from Cx43-null embryonic stem (ES) cells and wildtype recipient blastocysts. Heterogeneous Cx43 expression in the chimeric mice resulted in conduction defects and depressed contractile function. These novel genetic murine models of Cx43 loss of function in the adult mouse heart define gap junctional abnormalities as a key molecular feature of the arrhythmogenic substrate and an important factor in heart dysfunction.     

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.     

THE SPLITTING OF HEPATOCYTE GAP JUNCTIONS AND ZONULAE OCCLUDENTES WITH HYPERTONIC DISACCHARIDES

Mouse livers were perfused in situ through the portal vein with the disaccharides sucrose, lactose, maltose, and cellobiose in hypertonic concentrations (0.5 M). This treatment resulted in plasmolysis of the hepatocytes and splitting of the gap junctions and zonulae occludentes. The junctions split symmetrically, leaving a half-junction on each of the two separated cells. The process of junction splitting is followed using the freeze-fracture technique, since the junctional membranes are indistinguishable from the nonjunctional membranes in thin sections once the splitting occurs. The split junctions are also studied using the freeze-etch technique, allowing a view of the gap junction extracellular surface normally sequestered within the 2-nm "gap." The monosaccharides sorbitol and mannitol did not split the junctions during the times studied (2 min), but substitution of the chloride ion with propionate in the perfusion mixture did result in junction splitting. An envelope of morphologically distinct particles surrounding freeze-fractured gap junctions is also described.     

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 supellectilium, 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.     

MYONEURAL JUNCTIONS OF TWO ULTRASTRUCTURALLY DISTINCT TYPES IN EARTHWORM BODY WALL MUSCLE

The longitudinal muscle of the earthworm body wall is innervated by nerve bundles containing axons of two types which form two corresponding types of myoneural junction with the muscle fibers Type I junctions resemble cholinergic neuromuscular junctions of vertebrate skeletal muscle and are characterized by three features: (a) The nerve terminals contain large numbers of spherical, clear, ~500 A vesicles plus a small number of larger dense-cored vesicles (b) The junctional gap is relatively wide (~900 A), and it contains a basement membrane-like material, (c) The postjunctional membrane, although not folded, displays prominent specializations on both its external and internal surfaces The cytoplasmic surface is covered by a dense matrix ~200 A thick which appears to be the site of insertion of fine obliquely oriented cytoplasmic filaments The external surface exhibits rows of projections ~200 A long whose bases consist of hexagonally arrayed granules seated in the outer dense layer of the plasma membrane The concentration of these hexagonally disposed elements corresponds to the estimated concentration of both receptor sites and acetylcholinesterase sites at cholinergic junctions elsewhere. Type II junctions resemble the adrenergic junctions in vertebrate smooth muscle and exhibit the following structural characteristics: (a) The nerve fibers contain predominantly dense-cored vesicles ~1000 A in diameter (b) The junctional gap is relatively narrow (~150 A) and contains no basement membrane-like material, (c) Postjunctional membrane specialization is minimal. It is proposed that the structural differences between the two types of myoneural junction reflect differences in the respective transmitters and corresponding differences in the mechanisms of transmitter action and/or inactivation.     

Intramembrane organization of specialized contacts in the outer plexiform layer of the retina. A freeze-fracture study in monkeys and rabbits

Freeze-fracture analysis of the neural connections in the outer plexiform layer of the retina of primates (Macaca mulatta and Macaca arctoides) demonstrates a remarkable diversity in the internal structure of the synaptic membranes. In the invaginating synapses of cone pedicles, the plasma membrane of the photoreceptor ending contains an aggregate of A-face particles, a hexagonal array of synaptic vesicle sites, and rows of coated vesicle sites, which are deployed in sequence from apex to base of the synaptic ridge. The horizontal cell dendrites lack vesicle sites and have two aggregates of intramembrane A-face particles, one at the interface with the apex of the synaptic ridge, the other opposite the tip of the invaginating midget bipolar dendrite. Furthermore, the horizontal cell dendrites are interconnected by a novel type of specialized junction, characterized by: (a) enlarged intercellular cleft, bisected by a dense plate and traversed by uniformly spaced crossbars; (b) symmetrical arrays of B-face particles arranged in parallel rows within the junctional membranes; and (c) a layer of dense material on the cytoplasmic surface of the membranes. The plasmalemma of the invaginating midget bipolar dendrite is unspecialized. At the contact region between the basal surface of cone pedicles and the dendrites of the flat midget and diffuse cone bipolar cells, the pedicle membrane has moderately clustered A-face particles, but no vesicle sites, whereas the adjoining membrane of the bipolar dendrites contains an aggregate of B-face particles. The invaginating synapse of rod spherules differs from that of cone pedicles, because the membrane of the axonal endings of the horizontal cells only has an A-face particle aggregate opposite the apex of the synaptic ridge. Specialized junctions between horizontal cell processes, characterized by symmetrical arrays of intramembrane B-face particles, are also present in the neuropil underlying the photoreceptor endings. Small gap junctions connect the processes of the horizontal cells; other gap junctions probably connect the bipolar cell dendrites which make contact with each cone pedicle. Most of the junctional specializations typical of the primate outer plexiform layer are also found in the rabbit retina. The fact that specialized contacts between different types of neurons interacting in the outer plexiform layer have specific arrangements of intramembrane particles strongly suggests that the internal structure of the synaptic membranes is intimately correlated with synaptic function.     

Presynaptic active zones at neuromuscular junctions of larval frogs

Freeze-fracturing presynaptic membranes at tadpole neuromuscular junctions display small clusters of large P-face particles, including short double linear arrays. Short pairs of double particle rows are randomly oriented at some junctions. At others, presynaptic membranes are crossed at regular intervals by long pairs of double rows indistinguishable from those characterizing the active zones of adult amphibian neuromuscular junctions. Formation of double particles rows, pairing of the double rows, and transverse alignments of the pairs are shown to be independent processes.     

Morphogenesis of tight junctions in the peritoneal mesothelium of the mouse embryo

The peritoneal mesothelium of mouse embryos (12 to 18 day of gestation) was studied by freeze-fracture and in sections in order to reveal the initial formation of the tight junctions. Freeze-fracture observations showed three types of tight junctions. Type I consists of belt-like meshworks of elevations on the P face and of shallow grooves on the E face. No tight junctional particle can be seen either on the elevations or in the grooves. Type II shows rows of discontinuous particles on the elevations on the P face. Type III consists of strands forming ridges on the P face. On the E face, the grooves of Type II and III appear to be narrower and sharper than those of Type I. Quantitatively, Type I junctions are most numerous during the early stages (day 12-13) of embryonic development, while Type III junctions become more common in the later stages, and are the only type seen by day 18. Observations on sections, however, fail to distinguish between the three types. The results suggest that an initial sign of tight junction formation is close apposition of the two cell membranes in the junctional domain, without tight junctional particles. Later, the particles appear to be incorporated in the tight junctions and the strands form by fusion of the particles.     

STUDIES OF EXCITABLE MEMBRANES : I. Macromolecular Specializations of the Neuromuscular Junction and the Nonjunctional Sarcolemma

The neuromuscular junctions and nonjunctional sarcolemmas of mammalian skeletal muscle fibers were studied by conventional thin-section electron microscopy and freeze-fracture techniques. A modified acetylcholinesterase staining procedure that is compatible with light microscopy, conventional thin-section electron microscopy, and freeze-fracture techniques is described. Freeze-fracture replicas were utilized to visualize the internal macromolecular architecture of the nerve terminal membrane, the chemically excitable neuromuscular junction postsynaptic folds, and the electrically excitable nonjunctional sarcolemma. The nerve terminal membrane is characterized by two parallel rows of 100–110-Å particles which may be associated with synpatic vesicle fusion and release. On the postsynpatic folds, irregular rows of densely packed 110–140-Å particles were observed and evidence is assembled which indicates that these large transmembrane macromolecules may represent the morphological correlate for functional acetylcholine receptor activity in mammalian motor endplates. Differences in the size and distribution of particles in mammalian as compared with amphibian and fish postsynaptic junctional membranes are correlated with current biochemical and electron micrograph autoradiographic data. Orthogonal arrays of 60-Å particles were observed in the split postsynaptic sarcolemmas of many diaphragm myofibers. On the basis of differences in the number and distribution of these "square" arrays within the sarcolemmas, two classes of fibers were identified in the diaphragm. Subsequent confirmation of the fiber types as fast- and slow-twitch fibers (Ellisman et al. 1974. J. Cell Biol. 63[2, Pt. 2]:93 a. [Abstr.]) may indicate a possible role for the square arrays in the electrogenic mechanism. Experiments in progress involving specific labeling techniques are expected to permit positive identification of many of these intriguing transmembrane macromolecules.     

Development of an apical plasma membrane domain and tight junctions during histogenesis of the mammalian pancreas

The role of tight junctions (zonula occludens) in the formation of apical plasma membrane (PM) domains was investigated in the embryonic rat pancreas. In the present study, lectin-rhodamine (WGA-TRITC and RCAII-TRITC) and lectin-gold (WGA-Au and RCAII-Au) conjugates were used to monitor apical PM domain formation and freeze-fracture analysis was used to monitor tight junction formation in the pancreatic epithelium of embryonic, neonatal, and adult rats. Fluorescent and TEM analysis of WGA and RCAII binding indicated that an apical PM domain is formed as early as Day 13 of gestation in the pancreatic epithelium. While apical WGA binding remained into adult life, RCAII binding was lost by 1 day after birth. In contrast, tight junctions were not observed until Day 14 of gestation. At this time, tight junctions were found to be incomplete in formation and typically consisted of linear arrays of IMPs or discontinuous arrays of sealing strands (focal adherens). Continuous tight junctions were not completely formed until Day 15 of gestation. Continued development of tight junctions during gestation was characterized by (1) an increase in the number of sealing strands and (2) a more parallel arrangement of sealing strands within each junctional complex. By 8 weeks after birth, tight junctions were more loosely organized and contained fewer sealing strands as compared to that observed in the fetus. These results suggest that lateral diffusion of apical PM glycoconjugates may be restricted even in the absence of complete tight junctional complexes during development of the rat pancreas.