Segmental differentiations of cell junctions in the vascular endothelium. Arteries and veins

A systematic survey of endothelial junctions in elastic (aorta) and muscular (mesenteric) arteries and in medium (renal and mesenteric) and large (cava inferior) size veins has been carried out in the rat using freeze-cleaved preparations. The arterial endothelium is provided with a complex of occluding and communicating junctions (gap junctions) comparable to, though less elaborate than, that described in arterioles. The particles of the occluding junctions behave like "single unit" particles and have the tendency to remain on B faces upon membrane cleavage. In the venous endothelium the junctions take the form of long occluding junctions with few associated communicating junctions (maculae communicantes). As in arterial endothelium, the junctional particles appear preferentially on B faces in cleaved preparations. These structures, although continuous over long distances, are interrupted focally by areas in which the junctional elements are similar to those found in venules: the ridges and grooves are short, discontinuous, randomly distributed along the general line of cell contact, and often particle-free. In muscular arteries two unusual types of junctions are encountered. Both are disposed in loops over short distances along the perimeter of the cell. One type appears to be a strectched-out version of the usual combination of occluding and communcating junctions of the arterial endothelium (this type is also occasionally encountered in the venous endothelium). The other type is reminiscent of the septate junctions found in the epithelia of invertebrates but the apparent similarity remains to be checked by further work.     

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.     

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.     

Cyclic modulation of Sertoli cell junctional complexes in a seasonal breeder: the mink (Mustela vison)

The development and modulation of Sertoli cell junctions was studied in newborn and adult mink during the active and inactive spermatogenic phases. The techniques used were electron microscopy of freeze-fractured replicas and thin sections of tissues infused with horseradish peroxidase as a junction permeability tracer. In the newborn, freeze-fractured developing junctions had either spherical or fibrillar particles. In addition, junctional domains where particles were associated preferentially with the E-face, and others where particles were associated preferentially with the P-face, were found developing either singly or conjointly within a given membrane segment, thus yielding a heterogeneous junctional segment. Coincidently with the development of a tubular lumen and the establishment of a competent blood-testis barrier, junctional strands were composed primarily of particulate elements associated preferentially with the E-face. In adult mink during active spermatogenesis, cell junctions were found on the entire lateral Sertoli cell plasma membrane from the basal to the luminal pole of the cell. In the basal third of the Sertoli cell, membranous segments that faced a spermatogonium or a migrating spermatocyte displayed forming tight, gap, and adherens junctions. In the middle third, abutting membrane segments localized above germ cells were involved in continuous zonules and in adherens junctions. In the apical or luminal third, the zonules were discontinuous, and the association of junctional particles with the E-face furrow was lost. Gap junctions increased in both size and numbers. Junctional vesicles that appeared as annular gap and tight-junction profiles in thin sections or as hemispheres in freeze-fracture replicas were present. Reflexive tight and gap junctions were formed through the interaction of plasma membrane segments of the same Sertoli cell. Internalized junctional vesicles were also present in mature spermatids. During the inactive spermatogenic phase, cell junctions were localized principally in the basal third of the Sertoli cell; junctional strands resembled those of the newborn mink. During the active spermatogenic phase, continuous zonules were competent in blocking passage of the protein tracer. During the inactive phase the blood-testis barrier was incompetent in blocking entry of the tracer into the seminiferous epithelium. It is proposed that modulation of the Sertoli cell zonules being formed at the base and dismantled at the apex of the seminiferous epithelium follows the direction of germ cell migration and opposes the apicobasal direction of junction formation reported for most epithelia.(ABSTRACT TRUNCATED AT 400 WORDS)     

Fate of annular gap junctions in the papillary cells of the enamel organ in the rat incisor

Summary To investigate the mechanisms whereby annular gap junctions in the papillary cells of the enamel organ are degraded intracellularly, continuously growing rat incisors were examined by electron microscopy of routine thin sections as well as for the cytochemical localization of inorganic trimetaphosphatase activity. Routine thin-section analysis revealed small flat or undulated gap junctions, hemi-annular gap junctions between an invaginated cell process and a cell body, and fully internalized cytoplasmic annular gap junctions. Both hemi-annular and annular gap junctions usually contain various organelles and/or inclusions, such as mitochondria, endoplasmic reticulum, ribosomes, vesicles, and lysosomes in the cytoplasm confined by the junctional membranes. Annular gap junctions are sometimes fused with vesicular or tubulovesicular structures. Cytochemistry of inorganic trimetaphosphatase activity revealed an intense enzymatic reaction within a system of tubular structures and round or oval dense bodies. Both structures are believed to correspond to primary lysosomes. A part of the Golgi apparatus also shows a weak reaction. Although hemi-annular gap junctions never show enzymatic reaction, annular gap junctions sometimes contain reaction products throughout their interior cytoplasm and inclusions. Fusion of annular gap-junctional membranes with reaction-positive tubular structures is also observed. In one instance, revealed in serial sections, an annular gap junction was encircled entirely by a reaction-positive structure. These results suggest that cytoplasmic annular gap junctions are formed by endocytosis of hemi-annular gap junctional membranes from the cell surface and then degraded intracellularly by lysosomal enzymes.     

Loss and reappearance of gap junctions in regenerating liver

Changes in intercellular junctional morphology associated with rat liver regeneration were examined in a freeze-fracture study. After a two-thirds partial hepatectomy, both gap junctions and zonulae occludentes were drastically altered. Between 0 and 20 h after partial hepatectomy, the junctions appeared virtually unchanged. 28 h after partial hepatectomy, however, the large gap junctions usually located close to the bile canaliculi and the small gap junctions enmeshed within the strands of the zonulae occudentes completely disappeared. Although the zonulae occludentes bordering the bile canaliculi apparently remained intact, numerous strands could now be found oriented perpendicular to the canaliculi. In some instances, the membrane outside the canaliculi was extensively filled with isolated junctional strands, often forming very complex configurations. About 40 h after partial hepatectomy, very many small gap junctions reappeared in close association with the zonulae occludentes. Subsequently, gap junctions increased in size and decreased in number until about 48 h after partial hepatectomy when gap junctions were indistinguishable in size and number from those of control animals. The zonulae occludentes were again predominantly located around the canalicular margins. These studies provide further evidence for the growth of gap junctions by the accretion of particles and of small gap junctions to form large maculae.     

The Sertoli cell junctional complex: structure and permeability to filipin in the neonatal and adult guinea pig

The development and maintenance of the Sertoli cell junctional complex were investigated in prepubertal and adult guinea pigs. To correlate the structure of the blood-testis barrier with its permeability, the polyene antibiotic filipin (a cholesterol-binding agent of low molecular weight: 570.70) was added to the fixative as a tracer visible in freeze-fracture replicas. Discontinuous zonules, intermediate junctions (i.e., adhering fasciae) and gap junctions all proved permeable to filipin in the two age groups. Only the continuous occluding zonules characteristic of the adult guinea pig's testis were impermeable to the tracer. In pubertal animals, the establishment of the blood-testis barrier coincided with the completion of the junctional strands in occluding zonules. The formation of occluding zonules was similar in the newborn and the adult. In the adult, the Sertoli cell junctional complexes contained three types of cell junctions: occluding, adhering, and gap junctions. The sequence of occluding and adhering junctions from the base to the apex of the epithelium was the reverse of that demonstrated in most epithelia. The impermeable continuous occluding zonules at the base showed parallel patterns of uninterrupted junctional strands, whereas the permeable discontinuous zonules found higher in the epithelium showed a meandering pattern of broken strands. Our observations indicate that (1) Sertoli cell junctional complexes form near the young germinal cells at the base of the seminiferous epithelium and break down near the older germinal cells toward the apex; (2) the various patterns and orientations of the junctional strands reflect, respectively, the different stages of disintegration of the occluding zonules and the conformation of the mature Sertoli cell to the irregular contours of the germinal cells; (3) there is no relationship between permeability and junctional strand orientation; and (4) the cellular contacts between Sertoli cells and germinal cells situated below the blood-testis barrier may represent the early stages of formation of junctional elements which ultimately become incorporated into the Sertoli cell junctional complex.     

Cell junctions in the early chick embryo--a freeze etch study

Cell junctions in the early chick embryo have been examined in freeze-etch specimen. Well developed zonulae occludentes are found in the epiblast as early as stage 4. Large gap junctions are also found in the epiblast at this stage. In those cells which have left the surface to form mesenchymal structures (Hensen's node, juxtanodal mesenchyme, primitive streak mesenchyme), one finds not only gap, but also tight, junctions. These junctions do not form continuous belts, but appear as fragments, often reduced to single strands, of typical tight junctions. They probably correspond to the focal tight junctions described earlier in sectioned material. The origin and possible significance of these contacts is discussed, and it is suggested that they represent remnants of junctions between neighboring cells in the epiblast. These junctional remnants slowly disappear by “dilution,” either through cell division and/or cell movement. The appearance of newly formed gap junctions is also described.     

Morphological variations in gap junctions of ovarian granulosa cells.

Granulosa cells in ovarian follicles of rat, mouse, rabbit and hamster were studied by lanthanum tracer and freeze-fracture techniques. Abundant gap junctions exhibited striking intraspecific variation in size and pattern of particle aggregation. The smaller gap junctions showed close packing of the intramembranous A face particles. In large gap junctions, ranging up to 6 mu in diameter, particles were packed in rectilinear arrays separated by a labyrinthine network of particle-free 'aisles'. Small clusters of particles in a particle-poor circumferential zone suggested enlargement of junctions by peripheral accretion. Linear intramembranous structures, resembling those of occluding junctions, occasionally bounded large gap junctions. Spherical intracytoplasmic structures limited by gap junctional membranes were shown by tracer studies to arise by invagination of the cell surface. These were intrepreted as a means of disposal of junctions by interiorization.     

A quantitative study of intramembrane changes during cell junctional breakdown in the dystrophic rat retinal pigment epithelium

Previous electron microscope freeze-fracture and tracer studies have revealed that intercellular junctions in the retinal pigment epithelium (RPE) of Royal College of Surgeons (RCS) rats with inherited retinal dystrophy [5] break down between three and six postnatal weeks [6, 7]. In this study quantitative computer techniques were used to analyze the freeze-fracture changes in the dystrophic RPE. The following parameters were measured: length of tight junctional strands/micron2; number of tight junctional strand anastomoses/micron2; number of gap junctional aggregates/micron2; area of gap junctional aggregates/micron2; and density of background intramembrane particles/micron2. At three postnatal weeks, the dystrophic junctional complex membrane is similar to normal, but at 10 weeks and later there are dramatic decreases in tight junctional strand length/micron2 and number of anastomoses/micron2, as well as in the number/micron2 and area of gap junctions/micron2, while the density of background particles/micron2 is dramatically increased. Correlational analysis revealed that changes in gap and tight junctions were significantly related to each other and to the increase in background particle density. The diameter of background particles within the normal and post-breakdown dystrophic junctions was measured in order to see whether the dispersal of gap and tight junctional particles (8-10 nm) into the surrounding membrane contributes to the increased particle density. These measures showed that background particles in all size ranges were more numerous in the dystrophic RPE, but that the largest increase was in the smallest diameter particles (6-7 nm). Thus, while gap and tight junctional sized particles contribute to the increase, particles from other sources may also be involved. Particle density of apical and basal membranes in the normal and in the 10 week and older dystrophic RPE was analyzed to study the effects of tight junctional breakdown on the distribution of intramembrane particles. These measures showed that particle density was greater basally than apically in the normal RPE and that particle density in both membranes decreased slightly in the dystrophic RPE, but that their ratio remained unchanged. It has been shown previously that even a single intact tight junctional strand is sufficient to maintain differences in particle density between apical and basal surfaces [14, 15] and in the majority of abnormal dystrophic junctional complexes at least one tight junctional strand remains intact.(ABSTRACT TRUNCATED AT 400 WORDS)     

Regulation of connexin‐ and pannexin‐based channels by post‐translational modifications

Connexin (Cx) and pannexin (Panx) proteins form large conductance channels, which function as regulators of communication between neighbouring cells via gap junctions and/or hemichannels. Intercellular communication is essential to coordinate cellular responses in tissues and organs, thereby fulfilling an essential role in the spreading of signalling, survival and death processes. The functional properties of gap junctions and hemichannels are modulated by different physiological and pathophysiological stimuli. At the molecular level, Cxs and Panxs function as multi‐protein channel complexes, regulating their channel localisation and activity. In addition to this, gap junctional channels and hemichannels are modulated by different post‐translational modifications (PTMs), including phosphorylation, glycosylation, proteolysis, N‐acetylation, S‐nitrosylation, ubiquitination, lipidation, hydroxylation, methylation and deamidation. These PTMs influence almost all aspects of communicating junctional channels in normal cell biology and pathophysiology. In this review, we will provide a systematic overview of PTMs of communicating junction proteins and discuss their effects on Cx and Panx‐channel activity and localisation.     

Gap junctions in the rabbit sinoatrial node

In comparison to the cellular basis of pacemaking, the electrical interactions mediating synchronization and conduction in the sinoatrial node are poorly understood. Therefore, we have taken a combined immunohistochemical and electrophysiological approach to characterize gap junctions in the nodal area. We report that the pacemaker myocytes in the center of the rabbit sinoatrial node express the gap junction proteins connexin (Cx)40 and Cx46. In the periphery of the node, strands of pacemaker myocytes expressing Cx43 intermingle with strands expressing Cx40 and Cx46. Biophysical properties of gap junctions in isolated pairs of pacemaker myocytes were recorded under dual voltage clamp with the use of the perforated-patch method. Macroscopic junctional conductance ranged between 0.6 and 25 nS with a mean value of 7.5 nS. The junctional conductance did not show a pronounced sensitivity to the transjunctional potential difference. Single-channel recordings from pairs of pacemaker myocytes revealed populations of single-channel conductances at 133, 202, and 241 pS. With these single-channel conductances, the observed average macroscopic junctional conductance, 7.5 nS, would require only 30-60 open gap junction channels.     

Electron microscopical investigations of the intercellular contacts during the early cleavage stages ofLymnaea stagnalis (Mollusca,Gastropoda)

Summary In early cleavage stages ofLymnaea stagnalis, three kinds of intercellular junctions could be distinguished up to the sixth cleavage: intermediate, septate and gap junctions. The first two form junctional belts located on the cell border at the periphery of the embryo. For the purpose of our study we were most interested in gap junctions as they are alleged to be structures that allow cell-to-cell communication. Gap junctions first appear at the four cell stage. Up to the sixth cleavage no difference in the distribution pattern could be found between and within each of the four quadrants of the embryo. Some of the cell tiers along the animal-vegetal axis lack gap junctions either between the blastomeres within the tier or between the blastomeres from adjacent tiers. All gap junctions observed in freeze fracture replicas show plaques with an irregular IMP pattern. The average IMP diameter measures 12 nm (SD±2 nm). In stages fixed after the fifth cleavage, gap junctions are found between micromeres at the animal pole and the central 3D macromere. This is in agreement with the presumed interaction between these cells at this stage. The possibility of a transition of non-functional into functional gap junctions after the fifth cleavage is discussed.     

Segmental differentiations of cell junctions in the vascular endothelium. The microvasculature

Small vascular units consisting of an arteriole, its capillaries, and the emerging venule (ACV units) were identified in the rat omentum and mesentery. They were fixed in situ and processed for electron microscopy either as whole units or as dissected segments. Systematic examination of the latter (in thin sections, as well as in freeze-cleaved preparations) showed that the intercellular junctions of the vascular endothelium vary characteristically from one segment to another in the microvasculature. In arterioles, the endothelium has continuous and elaborate tight junctions with interpolated large gap junctions. The capillary endothelium is provided with tight junctions formed by either branching or staggered strands; gap junctions are absent at this level. The pericytic venules exhibit loosely organized endothelial junctions with discontinuous low-profile ridges and grooves, usually devoid of particles. No gap junctions were found in these vessels. The endothelium of muscular venules has the same type of junctions (discontinuous ridges and grooves of low profile); in addition, it displays isolated gap junctions of smaller size and lower frequency than in arterioles. The term communicating junction (macula communicans) is proposed as a substitute for gap junctions, since the latter is inappropriate, in general, and confusing in the special case of the vascular endothelium.     

PCC4azal teratocarcinoma stem cell differentiation in culture: II. Morphological characterization

The ultrastructural morphology of the PCC4azal embryonal carcinoma cells and their differentiated counterparts, endoderm-like cells and giant cells, was characterized and compared with that of the cells of embryoid bodies. The ultrastructure of the PCC4azal embryonal carcinoma cells is similar to that of the embryonal carcinoma cells of the embryoid body. These cells are small, with a large nucleus and relatively few cytoplasmic organelles. Gap junctions and modified adherens junctions are formed at some areas of intercellular contact between the embryonal carcinoma cells. The differentiated PCC4azal endoderm-like cells have a more developed cytoplasm, containing an extensive endoplasmic reticulum with large Golgi regions. Most striking is the de novo appearance of epithelial-like junctional complexes which join the apical borders between the endoderm-like cells, thus polarizing the cell monolayer. The zonula occludens junctions of the junctional complex are extensive, consisting of six or more strands of tight junctional ridges. Terminal webs are present in the apical regions that are inserted into the zonula adherens region of the junctional complex. Gap junctions continue to join neighboring cells, and some gap junctions are intercalated within tight junctional ridges. The ultrastructure of the differentiated endodermal cells of the embryoid bodies is very similar to that of the PCC4azal endoderm-like cells. The embryoid body endodermal cells form similar junctional complexes which also contain continuous belts of tight junctions that are intercalated with gap junctions. As the PCC4azal endoderm-like cells are transformed to giant cells, a massive cytoskeleton is formed, consisting of a large complex system of 10-nm filaments, microtubules, and 7-nm microfilaments. The junctional complexes that were present during the endodermal stage are partially disassembled as the giant cells migrate apart. Thus, the differentiation process in this system is characterized by significant and distinctive morphological changes.     

Cells and intercellular contacts in glomeruli and tubules of the frog kidney

Summary By the use of thin sections and freeze-fracture replicas the glomerular and tubular structures of the kidney of the frog (Rana esculenta) were studied with special reference to intercellular junctions.In the glomerulus the filtration barrier is of very variable thickness, and frequent tight and gap junctional contacts occur between podocyte processes.Although structurally less elaborate, the proximal tubule resembles its mammalian counterpart. In the initial part the tight junctions are relatively shallow but become very broad in the mid and distal portions of the proximal tubule. The proximal tubular cells are extensively linked by gap junctions. In some animals the shapes of the cells in the proximal and distal portions of the proximal tubule were markedly different.The distal tubule consists of two segments which differ mainly in the pattern of interdigitations and the structure of the zonulae occludentes. Similarities with the tight junctional morphology of the mammalian distal tubule are striking. In the first part of the distal tubule (diluting segment) a narrow band of parallel tight junctions is found closely resembling that found in the mammalian straight distal tubule; in the more distal part of the distal tubule, however, a broad band of anastomosing tight junctional strands exists, like the zonula occludens of the mammalian convoluted distal tubule.The connecting tubule displays cellular dimorphism: its wall contains a mixture of light and dark (flask) cells. The luminal and basolateral membranes of the flask cells are covered with numerous rod-shaped particles. The tight junctions of the connecting tubule are broad and increase in depth and number of strands along its length; they are typical of a very tight epithelium.In spite of several dissimilarities with phylogenetically younger kidneys our findings suggest that many structural principles of the mammalian kidney are also represented in the kidneys of amphibians. The structural-functional relationships are discussed.     

Carbon tetrachloride induced proliferation of tight junctions in the rat liver as revealed by freeze-fracturing

Application of carbon tetrachloride produced a progressive proliferation of tight junctions in the rat liver. This system proved to be rapid and highly reproducable and affords the opportunity for tracing the fate of tight junctions in freeze-fracture replicas, facilitating investigations on their formation and function. Beginning on day one carbon tetrachloride treatments resulted in the progressive loosening and fragmentation of the junctional meshwork. After three to four days the membrane outside the zonulae occludentes was extensively filled with proliferated discrete junctional elements often forming complex configurations. From the fifth day on the zonulae occludentes were restricted again predominantly around the bile canaliculus margins. But the junctional meshwork of the zonulae occludentes remained loosened in comparison to those in the control rats. It could be shown that tight junction proliferation on the lateral surface of the plasmalemma occurred both through de novo formation from discrete centers of growth by addition of intramembranous particles and through reorganization of preexistent junctional strands of the fragmented zonulae occludentes bodies. Whereas the large gap junctions close associated with the zonulae occludentes remained more or less unaffected during the experiments, small gap junctions increased in number after five days and were located at the margin or in the tight junction domain. It is assumed that the degeneration of the tight junctions served as a pool for intramembranous particles which form the gap junctions. The results of these observations are discussed in relation to those obtained in other systems.     

Freeze-fracture studies of gap junctions in the developing and adult amphibian cardiac muscle.

The freeze-fracture technique has been used to characterize the junctional devices involved in the electrical coupling of Ambystoma cardiac tissue. These cells are connected by junctions formed by either linear or circular arrays of particles. Such structures can be interpreted as a special type of gap junction. Gap junctions have also been investigated during the growth and differentiation of two amphibians, Rana and Xenopus. In both genera the earliest stage of junctional assembly is characterized by linear rows of particles. Later, a gradual transformation of these linear rows into circles was found. Finally, in the fully formed gap junctions, these circles appeared to join together into clusters. In summary, in the adult amphibian myocardial cells, three different types of gap junctions can be described. The first type, which has been observed in all embryonic stages and in adults in all three genera, consists of linear or circular arrays of particles: this is the only type of gap junction seen at any age in Xenopus. The second type, consisting of a variable number of anastomosing circles forming regular networks, is never observed in embryonic cells. It is typical of the adult frog heart and may also be seen in Ambystoma. The third type is characteristic only of adult Ambystoma heart and consists of geometrically packed particles identifiable with classic communicating macula. The fact that only the first class of structure is observed in Xenopus heart strongly supports the conclusion that such linear arrays of intramembranous particles really represent true functional electrical junctions.     

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.     

Cell-matrix interrelation and cell-to-cell connection in the secretory ameloblast layer of kitten teeth

To investigate the cell-matrix interrelation and the structure and permeability of the junctional complexes of secretory ameloblasts, molar tooth germs from kittens were examined by means of scanning electron microscopy, routine thin sections and freeze-fracture replication. Scanning electron microscopy showed remarkably dissolved growth fronts of enamel in materials that had been fixed with glutaraldehyde and then subjected to EDTA perfusion for 10 min. By the action of EDTA, intercrystallite spaces in rod and interrod enamel were prominently widened, and their longitudinal ends of crystallites displayed irregular and extremely sparse structures. In enamel rods surrounded entirely by interrod enamel, and in enamel rods of the typical key hole shape with successive interrod enamel participation, the most striking dissolution of crystallites occurred at the boundaries between rod and interrod enamel, where broad expanses of rod-sheath spaces were observed. In thin sections, the Tomes processes of secretory ameloblasts occupying the above rods were rectangular or variations of a rectangular shape, respectively; and interameloblast spaces opened to the enamel growth fronts, which corresponded to the junction between rod and interrod enamel. In enamel rods standing in regular rows and showing the typical arcade shape, the centers of the rods were drastically dissolved and exhibited single and deep slits, whereas the boundaries between rod and interrod enamel showed no wide furrows. The Tomes processes occupying such arcade-shaped rods were typically triangular, and the interameloblast space always joined the type-1 face of process, which is responsible for enamel rod formation. Secretory ameloblast possessed two sets of junctional complexes at the proximal and distal ends of the cell body. The distal one was situated proximally to the Tomes process. Freeze-fracture replication demonstrated the functional structures of these junctions: the proximal junction was fascia occludens, and the distal one incomplete zonula occludens with many free-ending tight junctional strands and interstrand spaces or a less developed irregular junction.