Morphological and functional changes in the tight junctions of the bile canaliculi induced by bile duct ligation

Summary Thin sections after bile duct ligation showed that the depth of tight junctions appeared to increase and that the distance between individual punctate contacts appeared to become irregular and wider than in controls. The freeze fracture replicas clearly demonstrated these changes in the tight junction morphology. Changes were noted most conspicuously in the tight junction three weeks after ligation. Measurements of the junctional morphology in control and ligated specimens showed that the junctional depth had increased two fold in the latter, whereas the number of strands had scarcely changed. Lanthanum tracer experiments showed that the tight junctions did not permit the passage of the tracer in normal nor ligated rats. It was concluded that the mechanism of obstructive jaundice could not be related to changes in junctional morphology causing increased junctional permeability.Tight junction depth in this paper is synonymously used with Tight junction width or Tight junction thickness     

Alterations in intercellular junctions of the uterine epithelium during the preimplantation phase in the rabbit

Summary In the rabbit, the pseudopregnant uterus has been used as a model for studying alterations characteristic of the preimplantation phase. Alterations in intercellular junctions of the uterine epithelium were investigated during early pseudopregnancy (day 0 to day 6) by means of the freeze-fracture technique.In the uterine epithelium of oestrous females the zonula occludens belongs to the tight type of tight junctions. During pseudopregnancy an impressive proliferation of tight junctional belts can be observed. The basal strands proliferate, forming loops perpendicular to the luminal surface, whereas the more or less parallel arrangement of the luminal strands is maintained. At day 4 of pseudopregnancy macular tight junctions begin to develop on the lower portions of the lateral plasmalemma and are extensive by day 6 post hCG.Small gap junctions are infrequent between cells of the uterine epithelium and show no significant changes during the preimplantation phase.The physiological significance of the present morphological observations is discussed in the light of changes occurring during the preimplantation period.Supported by grant Kü 210/9 from the Deutsche Forschungsgemeinschaft     

Protamine alters structure and conductance ofNecturus gallbladder tight junctions without major electrical effects on the apical cell membrane

Summary Protamine is a naturally occurring basic protein (pI; 9.7 to 12.0). We have recently reported that protamine dissolved in the mucosal bath (2 to 20 m), induces about a twofold increase in transepithelial resistance inNecturus gallbladder within 10 min. Conductance decreased concomitantly with cation selectivity.In this leaky epithelium, where >90% of an applied current passes between cells, an increment in resistance of this magnitude suggests a paracellular actiona priori. To confirm this, ionic conductance across the apical cell membrane was studied with microelectrodes. Protamine increased transepithelial resistance without changing apical cell membrane voltage or fractional membrane resistance. Variation in extracellular K concentration (6 to 50mm) caused changes in apical membrane voltage not different from control.To determine if protamine-induced resistance changes were associated with structural alteration of tight junctions, gallbladders were fixedin situ at peak response and analyzed by freeze-fracture electron microscopy. According to a morphometrical analysis, the tight junctional intramembranous domain expands vertically due to incorporation of new strands (fibrils) into the main compact fibrillar meshwork.Since morphologic changes are complete within 10 min, strands are probably recycled into and out of the tight junctional membrane domain possibly by the cytoskeleton either from cytoplasmic vesicles or from intramembranous precursors. Regulation of tight junctional permeability by protamine and other perturbations may constitute a common mechanism by which leaky epithelia regulate transport, and protamine, in concentrations employed in this study, seems reasonably specific for the tight junction.     

Interendothelial junctions in kidney vessels

Summary The interendothelial junctions of all segments of the renal vasculature have been studied in eight species using the freeze-fracture technique. Three types of junctions have been found. Combinations of tight and gap junction elements are characteristic for interlobular arteries and proximal afferent arterioles. Continuous tight junction strands not subdivided into individual particles are typical for the glomerular arterioles close to the glomerulus and the vasa recta. The interendothelial junctions of glomerular and peritubular capillaries and cortical veins are characterized by slight elevations decorated with sparse arrays of particles on the P-face of the endothelial cell plasma membrane.These studies were supported by the German Research Foundation within the SFB 90 Cardiovascular System.     

The thin limbs of Henle's loop in the rabbit

Summary The thin limbs of short and long loops of Henle of the rabbit kidney were studied by freeze fracture techniques. According to TEM studies of thin sections four segments are discernible: descending thin limbs of short loops, descending thin limbs of long loops, subdivided into an upper and a lower part, and ascending thin limbs (Kaissling and Kriz 1979). This division is supported by findings obtained with the freeze fracture technique and based on differences in the organization of the junctional complexes as well as on differences in the internal morphology of the cell membranes. The descending thin limbs of short loops have junctional complexes established by several closely arranged junctional strands and numerous desmosomes. The upper parts of the long descending thin limbs have tight junctions consisting of a variable number of strands; their outstanding characteristic after freeze fracture is a high density of intramembrane particles in both luminal and baso-lateral membranes. The tight junctions of the lower part of the long descending thin limbs consist of several anastomosing junctional strands, which are, in contrast, loosely arranged; the cell membranes contain only a sparse population of intramembrane particles. The ascending thin limbs are characterized by shallow tight junctions (frequently consisting of only one single junctional strand). Moreover, the epithelial cells of this segment are heavily interdigitated; thereby the tight junctions are correspondingly lengthened.In addition, this study presents further evidence that remarkable species differences occur among thin limb epithelia. The junctional complexes of the long descending thin limbs of the rabbit are organized quite differently from those of small rodents (e.g., rat, Psammomys).The data of this study support the concept that the tight junctions are the main determinant of ionic conductances of the paracellular pathway. However, with reference to recent findings from microperfusion studies, it becomes obvious that a correlation of the junctional morphology with the transepithelial water permeability is lacking, at least for the thin limbs.This investigation was supported by the Deutsche Forschungsgemeinschaft; project Kr 546 Henlesche Schleife     

Relationship of sertoli-sertoli tight junctions to ectoplasmic specialization in conventional and en face views

Ectoplasmic specializations are actin filament-endoplasmic reticulum complexes that occur in Sertoli cells at sites of intercellular attachment. At sites between inter-Sertoli cell attachments, near the base of the cells, the sites are also related to tight junctions. We studied the characteristics of ectoplasmic specializations from six species using conventional views in which thin sections were perpendicular to the plane of the membranes, we used rare views in which the sections were in the plane of the membrane (en face views), and we also used the freeze-fracture technique. Tissues postfixed by osmium ferrocyanide showed junctional strands (fusion points between membranes) and actin bundles, actin sheets, or both, which could be visualized simultaneously. En face views demonstrated that the majority of tight junctional strands ran parallel to actin filament bundles. Usually, two tight junctional strands were associated with each actin filament bundle. Parallel tight junctions were occasionally extremely close together ( approximately 12 nm apart). Tight junctional strands were sometimes present without an apparent association with organized actin bundles or they were tangential to actin bundles. En face views showed that gap junctions were commonly observed intercalated with tight junction strands. The results taken together suggest a relationship of organized actin with tight junction complexes. However, the occasional examples of tight junction complexes being not perfectly aligned with actin filament bundles suggest that a precise and rigidly organized actin-tight junction relationship described above is not absolutely mandatory for the presence or maintenance of tight junctions. Species variations in tight junction organization are also presented.     

Fine structure of ependymal cells in the median eminence of the frog and mouse revealed by freeze-etching

Summary Freeze-etched preparations of the ventricular surfaces of ependymal cells clearly reveal the presence of pinocytotic vesicles opening into the third ventricle and large vacuoles formed by broad cell projections. The density of the vesicular openings is approximately 20 per m². The ependymal cells in the median eminence of the frog are adjoined by tight junctions comprised of five to eight interconnected junctional strands, whereas near the median eminence in the mouse only one to two such strands form the tight junction of the ependymal cells. Gap junctions between the adjacent ependymal cells are detected near the median eminence in the mouse but not in the frog.This study was supported in part by a grant from the Japanese Ministry of Education (No. 067670)     

The intercellular junctions of guinea-pig placental capillaries: a possible structural basis for endothelial solute permeability

The endothelial cell junction in guinea-pig placental capillaries consists of a continuous ribbon desmosome (zonula adherens) within which lies a particulate tight junction consisting of between one and five anastomosing strands. The intercellular space at these tight junctions is narrowed and is subdivided by junctional bars which are probably continuous with the intramembrane particle rows seen in freeze-fracture replicas of the junctions. Perfusion with lanthanum salts shows the gaps between the junctional bars to be lanthanum-filled and the entire junction to be lanthanum permeable. The estimated size of the spaces between the junctional bars is consistent with the junctional pore size indicated by previous ultrastructural tracer studies. The wider lateral intercellular space of the ribbon desmosome is spanned by more widely spaced "linkers" which may act as a coarser three-dimensional filter in series with size-limiting pores between the tight junctional bars.     

A model for de novo synthesis and assembly of tight intercellular junctions. Ultrastructural correlates and experimental verification of the model revealed by freeze-fracture

The structure and function of intercellular tight (occluding) junctions, which constitute the anatomical basis for highly regulated interfaces between tissue compartments such as the blood-testis and blood-brain barriers, are well known. Details of the synthesis and assembly of tight junctions, however, have been difficult to determine primarily because no model for study of these processes has been recognized. Primary cultures of brain capillary endothelial cells are proposed as a model in which events of the synthesis and assembly of tight junctions can be examined by monitoring morphological features of each step in freeze-fracture replicas of the endothelial cell plasma membrane. Examination of replicas of non-confluent monolayers of endothelial cells reveals the following intramembrane structures proposed as 'markers' for the sequential events of synthesis and assembly of zonulae occludentes: development of surface contours consisting of elongate terraces and furrows (valleys) orientated parallel to the axis of cytoplasmic extensions of spreading endothelial cells, appearance of small circular PF face depressions (or volcano-like protrusions on the EF face) that represent cytoplasmic vesicle-plasma membrane fusion sites, which are positioned in linear arrays along the contour furrows, appearance of 13-15 nm intramembrane particles at the perimeter of the vesicle fusion sites, and alignment of these intramembrane particles into the long, parallel, anastomosed strands characteristic of mature tight junctions. These structural features of brain endothelial cells in monolayer culture constitute the morphological expression of: reshaping the cell surface to align future junction-containing regions with those of adjacent cells, delivery and insertion of newly synthesized junctional intramembrane particles into regions of the plasma membrane where tight junctions will form, and aggregation and alignment of tight junction intramembrane particles into the complex interconnected strands of mature zonulae occludentes. The distribution of filipin-sterol complex-free regions on the PF intramembrane fracture face of junction-forming endothelial plasmalemmae corresponds precisely to the furrows, aligned vesicle fusion sites and anastomosed strands of tight junctional elements.(ABSTRACT TRUNCATED AT 400 WORDS)     

Experimental modulation of occluding junctions in a cultured transporting epithelium

The experimental opening and resealing of occluding junctions in monolayers of cultured MDCK cells (epithelioid of renal origin) was explored by measuring changes in the electrical resistance across the monolayer and by freeze-fracture electron microscopy. As in natural epithelia, the function of occluding junctions as permeability barriers specifically depends on extracellular Ca++ concentration and fails if this ion is replaced by Mg++ or Ba++. The removal of Ca++ and the addition of EGTA to the bathing medium opened the junctions and reduced the transepithelial resistance. Resealing was achieved within 10-15 min by restoring Ca++. Quantitative freeze-fracture electron microscopy showed that junctional opening, caused by lack of Ca++, was accompanied by simplification of the pattern of the membrane strands of the occluding junction without disassembly or displacement of the junctional components. Resealing of the cellular contacts involved the gradual return to a normal junctional pattern estimated as the average number of strands constituting the junction. The occluding junctions were also opened by the addition of the ionophore {"type":"entrez-nucleotide","attrs":{"text":"A23187","term_id":"833253","term_text":"A23187"}}A23187, suggesting that the sealing of the contacts requires high Ca++ on the extracellular side and low Ca++ concentration of the cytoplasmic compartment. The opening process could be blocked by low temperature (7.5 degrees C). Resealing did not depend on serum factors and did not require protein synthesis; therefore, it seems to be caused by reassembly of preexisting membrane junctional components. The restoration of the junctions occurred simultaneously with the establishment of ion-selective channels; the Na+/Cl- and the cation/cation selectivity were recovered with the same time-course as the electrical resistance. The role of the cytoskeleton in the process of junctional reassembly is reported in the companion article.     

Cholestasis-induced alterations of the trans- and paracellular pathways in rat hepatocytes

Bile secretion depends on the vectorial transport of solutes from blood to bile and involves three different pathways: transcellular pathways mediated by transport proteins distributed asymmetrically in the basolateral and canalicular plasma membrane and by transcytotic vesicles, and a paracellular pathway allowing selective diffusion through tight junctions. All three pathways are impaired differentially by extrahepatic (bile duct ligation) or intrahepatic (ethinyloestradiol) cholestasis. Ethinyloestradiol treatment leads to tight junctional defects that are less severe than those induced by bile duct ligation. Junctional impairment is reflected functionally in increased permeability for horseradish peroxidase and structurally by decreased strand numbers and increased junctional length, but not by alterations at the level of the individual strands. The parallelism of physiophical and morphological perturbations indicates a structure-function relationship in hepatocellular tight junctions. In addition, impaired functional integrity of tight junctions following bile duct ligation is reflected in a partial loss of hepatocellular surface polarity owing to redistribution of some, but not all, domain-specific plasma membrane antigens, which might mimic the behaviour of transport systems. After ethinyloestradiol treatment no alterations of surface polarity were observed. Thus, immunohistochemistry supports the view that ethinyloestradiol results in less severe impairment of the tight junctions than bile duct ligation. Finally, bile duct ligation, but not ethinyloestradiol, affects the transcytotic vesicular pathway; severe impairment of this is reflected in the absence of a late horseradish peroxidase peak in bile and also in the accumulation of pericanalicular vesicles that are immunopositive for canalicular membrane proteins and accessible for bulk phase endocytic markers. This view is supported by the disappearance of the pericanalicular vesicles simultaneously with the resumption of transcytotic horseradish peroxidase transport following release of ligation, a finding that indicates rapid restoration of this defect.This paper was presented at the symposium Metabolic Zonation of the Liver: New Answers to Old Questions, held in honour of Prof. Dr. D. Sasse's 60th birthday, 26 August 1994, in Basel     

Gap junctions and intercellular communication in the hepatopancreas of the crayfish (Orconectes propinquus) during molt

Summary The crustacean hepatopancreas is a major metabolic center intimately involved in molting and vitellogenesis. Cells of the hepatopancreas exhibit one of the richest endowments of gap junctions known and are thus presumed to be linked for intercellular communication. In order to monitor hepatopancreatic activity during the molt cycle of crayfish (Orconectes propinquus), the electrical coupling between cells of the hepatopancreatic tubules was measured during postmolt, intermolt and premolt. Samples of hepatopancreas from each of these stages were fixed and freeze-fractured to correlate morphologic features of gap junctions with electrophysiological data. Analysis of the data revealed that ionic coupling was greater in postmolt and premolt tubule cells than in cells of intermolt animals. Platinum replicas of hepatopancreatocyte plasmalemmata revealed that in postmolt, gap junction plaques were smaller and more numerous than those in intermolt and premolt; however, the total area of gap junction plaques per unit membrane area analyzed was approximately the same for hepatopancreatocytes from all molt stages. Although the hepatopancreatic gap junctions exhibited no quantitative differences, those from post- and premolt animals were rounded with tightly packed particles, while plaques from intermolt animals were generally pleomorphic with loosely packed particles. Results of this study suggest that cells of the crayfish hepatopancreas are more coupled in pre- and postmolt, with macular plaques of tightly packed particles, perhaps as a response to the increased metabolic demands of molt, and less well coupled, with irregular plaques of loosely packed junctional particles, during intermolt. The only recognizable morphological correlates of increased cell coupling were tight packing of junctional particles into rounded plaques, while decreased coupling corresponded to junctions with loosely packed irregular aggregates of particles.Supported by the Natural Sciences and Engineering Research Council of Canada (RRS)     

Correlation of tight junction morphology with the expression of tight junction proteins in blood-brain barrier endothelial cells

Endothelial cells of the blood-brain barrier form complex tight junctions, which are more frequently associated with the protoplasmic (P-face) than with the exocytoplasmic (E-face) membrane leaflet. The association of tight junctional particles with either membrane leaflet is a result of the expression of various claudins, which are transmembrane constituents of tight junction strands. Mammalian brain endothelial tight junctions exhibit an almost balanced distribution of particles and lose this morphology and barrier function in vitro. Since it was shown that the brain endothelial tight junctions of submammalian species form P-face-associated tight junctions of the epithelial type, the question of which molecular composition underlies the morphological differences and how do these brain endothelial cells behave in vitro arose. Therefore, rat and chicken brain endothelial cells were investigated for the expression of junctional proteins in vivo and in vitro and for the morphology of the tight junctions. In order to visualize morphological differences, the complexity and the P-face association of tight junctions were quantified. Rat and chicken brain endothelial cells form tight junctions which are positive for claudin-1, claudin-5, occludin and ZO-1. In agreement with the higher P-face association of tight junctions in vivo, chicken brain endothelia exhibited a slightly stronger labeling for claudin-1 at membrane contacts. Brain endothelial cells of both species showed a significant alteration of tight junctions in vitro, indicating a loss of barrier function. Rat endothelial cells showed a characteristic switch of tight junction particles from the P-face to the E-face, accompanied by the loss of claudin-1 in immunofluorescence labeling. In contrast, chicken brain endothelial cells did not show such a switch of particles, although they also lost claudin-1 in culture. These results demonstrate that the maintenance of rat and chicken endothelial barrier function depends on the brain microenvironment. Interestingly, the alteration of tight junctions is different in rat and chicken. This implies that the rat and chicken brain endothelial tight junctions are regulated differently.     

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.     

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.     

Tight junctions in the choroid plexus epithelium. A freeze-fracture study including complementary replicas

The tight junctions of the choroid plexus epithelium of rats were studied by freeze-fracture. In glutaraldehyde-fixed material, the junctions exhibited rows of aligned particles and short bars on P-faces, the E-faces showing grooves bearing relatively many particles. A particulate nature of the junctional strands could be established by using unfixed material. The mean values of junctional strands from the lateral, third, and fourth ventricles of Lewis rats were 7.5 +/- 2.6, 7.4 +/- 2.2, and 7.5 +/- 2.4; and of Sprague-Dawley rats 7.7 +/- 3.4, 7.4 +/- 2.3, and 7.3 +/- 1.6. Examination of complementary replicas (of fixed tissue) showed that discomtinuities are present in the junctional strands: 42.2 +/- 4.6% of the length of measured P-face ridges were discontinuities, and the total amount of complementary particles in E-face grooves constituted 17.8 +/- 4.4% of the total length of the grooves, thus approximately 25% of the junctional strands can be considered to be discontinuous. The average width of the discontinuities, when corrected for complementary particles in E-face grooves, was 7.7 +/- 4.5 nm. In control experiments with a "tighter" tight junction (small intestine), complementary replicas revealed that the junctional fibrils are rather continuous and that the very few particles in E-face grooves mostly filled out discontinuities in the P-face ridges. Approximately 5% of the strands were found to be discontinuous. These data support the notion that the presence of pores in the junctional strands of the choroid plexus epithelium may explain the high transepithelial conductance in a "leaky" epithelium having a high number of junctional strands. However, loss of junctional material during fracturing is also considered as an alternative explanation of the present results.     

The ultrastructural basis of the permeability of arterial endothelium to horseradish peroxidase

The thoracic aorta and basilar artery, in which the incidence of atherosclerosis is known to be different, were examined to elucidate the correlation between the structure of the intercellular cleft junction between adjacent endothelial cells and its permeability to HRP. Tannic acid or HRP in the vessel lumen passed through the intercellular clefts of the thoracic aorta into the subendothelial space, whereas in the basilar artery they were unable to penetrate beyond the tight junction of the intercellular clefts. Freeze-fracture replicas revealed that the tight junctions of the thoracic aorta consisted of one to two junctional strands in most areas of the cleaved planes, with discontinuities in some places, whereas those of the basilar artery consisted of a continuous belt-like meshwork of six anastomosing junctional strands on average. These observations confirm that the structure of endothelial junctions in arteries has a close correlation with the permeability of the intercellular clefts to HRP.     

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.     

The tight junctions of renal tubules in the cortex and outer medulla

Summary Quantitative aspects of tight junction morphology were systematically studied in the cortical and outer medullary segments of the distal urinary tubules of rat, hamster, rabbit, cat, dog and the primitve primate Tupaia belangeri.Only minor differences in junctional architecture were found between straight and convoluted portions of the distal tubule. In contrast, the collecting duct in cortex and outer medulla, in all species, exhibits the most elaborate tight junctions observed along the uriniferous tubule.The present and previous findings from this laboratory indicate that increasing tightness of the junctional complexes is apparent along the course of the nephron in all species studied.The proposed relationship between quantitative aspects of the zonula occludens and presently available values for transepithelial electrical resistance was re-examined for the renal tubules. It was found that for the mammalian kidney a satisfactory correlation exists between the tight junction morphology and presently known functional parameters. This relationship is the more evident the more additional dimensional characteristics of the intercellular clefts are taken into consideration.It may therefore be concluded that, at least for the mammalian kidney, the assumption of differences in the molecular organization of the tight junctions is not needed to explain so far unresolved discrepancies between tubular morphology and function.Parts of these findings were presented at the 72nd Meeting of the Anatomical Society, Aachen; April 1977 (see Verh. Anat. Ges. 72:229–234 [1978])Supported by the Deutsche Forschungsgemeinschaft     

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.