Adherens junctions in the ocular lens of various species: ultrastructural analysis with an improved fixation

Summary The ultrastructure and distribution of adherens junctions in the intact adult lens of human, chicken, dove, rat, and rainbow trout were studied with thin-section electron microscopy, using an improved fixation containing a mixture of glutaraldehyde, lysine, and tannic acid. The nature of adherens junctions in the fiber-cells of the lens was also verified by immunofluorescence and rhodamine-phalloidin labelings for vinculin and actin. Electron microscopy revealed that adherens junctions of the lens were different ultrastructurally from the desmosomes found only between the lateral epithelial cells of the lens. The adherens junctions had the same structural characteristics as the zonulae adherentes, except that they were macular contacts, not belts. However, cross bridges were evident within the interspace of the junctions. Adherens junctions were located between the fiber-cells, between the epithelial cells and fiber-cells, and between the epithelial cells. They had a characteristic distribution in the intersections where three hexagonal fiber-cells met, as seen in cross-sections in all species studied. In addition, adherens junctions and associated actin were found distributed randomly along the entire cell membranes of both wide and narrow sides of cortical fiber-cells in the human, chicken, and dove lenses which have good accomodating capability. However, in the poorly-accomodating lenses of rat and fish, these junctions were seen predominantly on the narrow sides and at the regions of the wide sides that were very close to the intersections. It is suggested that adherens junctions and associated actin microfilaments are involved in stabilizing the structural integrity of lens cells during accomodation and in preserving a specific lens shape.     

In vitro assembly of gap junctions.

Gap junction structures were assembled in vitro from octyl-beta-D-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.     

Junctional diversity in two regions of the epidermis of Oikopleura dioica (Tunicata,Larvacea)

Summary A simple continuous epithelium surrounds the body of the pelagic larvacean. It consists of two zones of cells: oikoplast cells and flattened cells. The oikoplast cells are columnar and produce a thick extracellular house that ensheathes the body of the organism. These cells are joined laterally by wide tight junctions (zonulae occludentes). The tail of the animal is surrounded by exceedingly thin cells which are joined by narrow tight junctions under which lie intermediate junctions (zonulae adhaerentes) and gap junctions. A web of fibrous material inserts into the intermediate junctions. The transitional cells between the two epithelial zones have one lateral border with a wide tight junction, and the other lateral border with a narrow tight junction and a wide intermediate junction. In freeze-fracture replicas, the wide tight junction has a number of anastomosing ridges, in comparison with the narrow tight junction, which usually consists of only a single row of intramembranous particles. In replicas, the thin epithelial cells show unusual parallel arrays of particles in clusters on their apical plasma membranes. This simple epithelium, therefore, exhibits striking differences between the two cellular zones, in the structural characteristics of both the lateral borders and the apical membrane.     

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.     

Reconstitution of native-type noncrystalline lens fiber gap junctions from isolated hemichannels

Gap junctions contain numerous channels that are clustered in apposed membrane patches of adjacent cells. These cell-to-cell channels are formed by pairing of two hemichannels or connexons, and are also referred to as connexon pairs. We have investigated various detergents for their ability to separately solubilize hemichannels or connexon pairs from isolated ovine lens fiber membranes. The solubilized preparations were reconstituted with lipids with the aim to reassemble native-type gap junctions and to provide a model system for the characterization of the molecular interactions involved in this process. While small gap junction structures were obtained under a variety of conditions, large native-type gap junctions were assembled using a novel two-step procedure: in the first step, hemichannels that had been solubilized with octylpolyoxyethylene formed connexon pairs by dialysis against n-decyl-beta-D-maltopyranoside. In the second step, connexon pairs were reconstituted with phosphatidylcholines by dialysis against buffer containing Mg2+. This way, double-layered gap junctions with diameter < or = 300 nm were obtained. Up to several hundred channels were packed in a noncrystalline arrangement, giving these reconstituted gap junctions an appearance that was indistinguishable from that of the gap junctions in the lens fiber membranes.     

Gap junctions are non-randomly distributed inDrosophila wing discs

Summary The distribution of gap junctions in mature larvalDrosophila melanogaster wing discs was analyzed by means of quantitative electron microscopy. Gap junctions are non-randomly distributed in the proximal-distal disc axis and in the apical-basal cell axis of the epithelium. In the epithelial cells, the surface density, number and length of gap junctions are greatest in the apical cell region and distal disc region. The average gap junction surface density is 0.0572 m^–1 and 2.77% of the lateral cell surface is composed of gap junctions. In the adepithelial cells, the gap junction surface density is 0.0005 m^–1 and 0.06% of the cell surface is composed of gap junctions. No gap junctions were observed between epithelial cells and adepithelial cells. The absolute area of gap junctions was estimated in a proximal-distal strip of cells in the disc and is considerably less in the folded regions of the epithelium compared to the flat notum and wing pouch regions. The results are discussed with respect to pattern formation and growth control in imaginal discs.     

The supramolecular architecture of junctional microdomains in native lens membranes

Gap junctions formed by connexons and thin junctions formed by lens-specific aquaporin 0 (AQP0) mediate the tight packing of fibre cells necessary for lens transparency. Gap junctions conduct water, ions and metabolites between cells, whereas junctional AQP0 seems to be involved in cell adhesion. High-resolution atomic force microscopy (AFM) showed the supramolecular organization of these proteins in native lens core membranes, in which AQP0 forms two-dimensional arrays that are surrounded by densely packed gap junction channels. These junctional microdomains simultaneously provide adhesion and communication between fibre cells. The AFM topographs also showed that the extracellular loops of AQP0 in junctional microdomains adopt a conformation that closely resembles the structure of junctional AQP0, in which the water pore is thought to be closed. Finally, time-lapse AFM imaging provided insights into AQP0 array formation. This first high-resolution view of a multicomponent eukaryotic membrane shows how membrane proteins self-assemble into functional microdomains.     

Coexistence of bombesin and 5-hydroxytryptamine in the cutaneous gland of the frog,Bombina orientalis

Summary Impulse generation and propagation was previously shown to occur in skin epithelium of newt (Cynops orientalis) embryos during certain stages of development and to be correlated with morphological changes of gap junctions. These properties are not detected in embryonic epithelia explanted and grown in culture. However, early explants when transplanted to a host embryo develop conductivity, and relatively large gap junctions with loose arrangement of connexons occur as soon as the host embryo reaches the stage when conductivity is at its maximum. In contrast, morphological and physiological characteristics of impulse propagation are lost when the transplanted epithelium is extirpated from the host embryo and returned to in-vitro conditions. Therefore, it appears that impulse propagation is dependent not solely on the differentiation of epithelial cells but upon signals from non-epithelial (possibly mesodermal) tissue as well.     

Intercellular junctions in the water-blood barrier of the gill lamella in the adult lamprey (Geotria australis,Lampetra fluviatilis)

Thin sections and freeze-fracture replicas of the water-blood barrier in the gill lamellae of adult lampreys (Geotria australis, Lampetra fluviatilis) demonstrate that the occluding junctions between epithelial pavement cells differ markedly from those between endothelial pillar cells in the structure and arrangement of their strands. The zonulae occludentes between pavement cells typically consist of complex networks of 4–6 strands, the mean number of which undergoes a small but significant decline when the animal is acclimated to seawater. In comparison, the occluding junctions between pillar cells are less elaborate and may represent maculae or fasciae, rather than zonulae occludentes. They do not apparently undergo a change when the animal enters saltwater. The results indicate that the main part of the paracellular diffusion barrier to proteins and ions is located in the epithelium rather than the endothelium. Communicating (gap) junctions are present between adjacent pavement cells, between pavement and basal cells and between pillar cells. These findings suggest that the epithelial cells and the pillar cells in the water-blood barrier of lampreys both form functional syncytia. The results are discussed in the context of ion-transporting epithelia in other aquatic vertebrates.This paper is dedicated to Professor H. Leonhardt on the occasion of his 75^th birthday     

Gap junctions and the propagation of cell survival and cell death signals

Gap junctions are a unique type of intercellular channels that connect the cytoplasm of adjoining cells. Each gap junction channel is comprised of two hemichannels or connexons and each connexon is formed by the aggregation of six protein subunits known as connexins. Gap junction channels allow the intercellular passage of small (< 1.5 kDa) molecules and regulate essential processes during development and differentiation. However, their role in cell survival and cell death is poorly understood. We review experimental data that support the hypothesis that gap junction channels may propagate cell death and survival modulating signals. In addition, we explore the hypothesis that hemichannels (or unapposed connexons) might be used as a paracrine conduit to spread factors that modulate the fate of the surrounding cells. Finally, direct signal transduction activity of connexins in cell death and survival pathways is addressed.These authors share senior authorship.This study was supported by Ghent University GOA grant no. 12050502.This revised version was published online in May 2005 with corrections to one authors email address.     

家兔晶状体纤维的超微结构:纤维细胞的间隙连接

本文报道晶状体纤维细胞间间隙连接的形态结构。我们利用冰冻断裂技术,在不同部位的球-和-凹连结的头部以及在纤维细胞和纤维细胞之间都观察到间隙连接的存在。通过极其丰富的上述连接,可实现细胞间代谢物和离子的传递。作者认为:对正常晶状体纤维细胞之间的间隙连接的深入了解,将会为晶状体发病机制的研究提供新的线索。     

Ultrastructure of the ocular ciliary epithelium of the common frog

The ultrastructure of the adult frog ciliary epithelium cells has definite regional differences. Cells of ciliary epithelium folds near the iris display morphological features characterizing its barrier and secretory functions which lead to the formation of aqueous humor. These are junctional complexes with tight junctions (zonula occludents) in the apical parts of contacting sides of cells of the inner leaf: a great quantity of mitochondria, ribosomes and various vesicles, well developed endoplasmic reticulum in the cytoplasm, much folded basal surface, gap junctions between cells of external and internal leaflets. In the mammalian inner epithelial layer different cell junctions are known to be arranged in a fixed spatial fashion. Unlike, in the frog's epithelium both zonula adherent and desmosomes may be found in any sequence. Tight junctions are formed during metamorphosis, on the place of focal junctions, whereas gap junctions, referred to earlier as "extended", start functioning between cells just on the very early stages of eye morphogenesis (Dabagyan et al., 1979). The epithelium of the posterior part of the ciliary fold and pars plana of the ciliary body have, in addition, the number of morphological sign indicating the cell involvement in the accomodational function of any eye (i. e. a majority of desmosomes binding all cells together and of zonulae adherentes, well developed intracellular skeleton of tonofilament bundles). These features are characteristic of the whole distal part of ciliary epithelium rather than of the place of attachment of zonula fiber only.     

A freeze-fracture study of the papillary layer of the rat incisor enamel organ

After tooth enamel has been secreted it undergoes maturation or hardening. This process is mediated by ruffled and smooth-ended ameloblasts and associated papillary layer cells. The cells of the papillary layer are characterized by large numbers of mitochondria, coated vesicles, microvilli, and gap junctions. These features have led numerous investigators to speculate that the papillary layer is an ion-transporting epithelium. We have conducted freeze-fracture studies of the rat papillary layer in order to better characterize the surface features of these cells. The cell membranes of the papillary cells contained large numbers of intramembrane particles of various sizes ranging from 4 to 9 nm in diameter. Gap junctions were present at the cell surface and in the cytoplasm in the form of annular gap junctions. The intramembrane particles or connexons of both types of gap junctions were about 8-9 nm wide and were either packed randomly or present in the so-called 'crystallized' state. At the interface between smooth-ended ameloblasts and papillary layer cells, a well-developed zonula occludens was present along the basal surfaces of the ameloblasts and several large gap junctions were formed between the two cell types. The capillary network associated with the papillary layer was characterized by a thin endothelium containing large numbers of fenestrations.     

Structure of rapidly frozen gap junctions

The structure of gap junctions in the rabbit ciliary epithelium, corneal endothelium, and mouse stomach and liver was studied with the freeze-fracturing technique after rapid freezing to near 4 degrees K from the living state. In the ciliary epithelium, the connexons were randomly distributed, separated by smooth membrane matrix. In the corneal endothelium, both random and crystalline arrangements of the connexons were observed. In the stomach and liver, the connexons were packed but not crystalline. Experimental anoxia or lowered pH caused crystallization of the connexons within 20-30 min. In the ciliary epithelium, the effects of prolonged anoxia or low pH could not be reversed . In addition, invaginated or annular gap junctions increased in number, but their connexons were usually distributed at random. Rapid freezing thus demonstrates that gap junctions of different tissues are highly pleiomorphic in the living state, and this may explain their variations in structure after chemical fixation. The slow time-course and irreversibility of the morphological changes induced by prolonged anoxia or low pH suggest that connexon crystallization may be a long-term consequence rather than the morphological correlate of the switch to high resistance.     

Biochemical and genetic investigations on gap junctions from mammalian cells

Gap junction protein (26K) in mouse or rat liver has been studied using a rabbit antiserum directed against the sodium dodecylsulfate denatured 26K protein from mouse liver. The liver 26K protein has been localized in gap junction plaques of hepatic plasma membranes by immuno electron microscopy. Affinity purified anti-26K antiserum showed weak cross reactivity with mouse or bovine lens gap junction protein (MIP26). This result suggests some structural homology between the different gap junction proteins in liver and lens. After partial hepatectomy of young rats the liver 26K protein appears to be degraded and later resynthesized. A variant of established Chinese hamster fibroblastoid cells has been isolated and shown to be defective in metabolic cooperation via gap junctions.Based on material presented at the Symposium Intercellular Communication Stuttgart, September 16–17, 1982     

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)     

Desmosomes: Their occurrence between adjacent primary oocytes in polyovular follicles in the rabbit

Summary In polyovular, primordial follicles in the rabbit, desmosomes are found between apposing oocyte surfaces. Morphologically these desmosomes correspond closely to those described in epithelia of vertebrates. The desmosomes alternate with other junctions which are probably gap junctions.This work was supported in part by the G.R.S.T. Grant n 75.7.1313     

The major polypeptide (MIP) of lens fiber junctions and its synthesis in cultured differentiating lens epithelial cells

Lens and liver contain many gap junctions, which for a long time have been considered to be very similar. Recent results, however, point to differences on morphological and biochemical levels, especially when the liver gap junction polypeptide (26,000 Daltons) is compared with the main intrinsic polypeptide (MIP) from lens junctions. The lens fiber specific MIP, which represents a marker molecule for lens cell differentiation could be detected by indirect immunofluorescence as well as by immunodiffusion in lens epithelial cells, which differentiated in vitro under distinct culture conditions. The fine structure of these differentiated cells is presented.Based on material presented at the Symposium Intercellular Communication Stuttgart, September 16–17, 1982     

SPECIALIZED MEMBRANE JUNCTIONS BETWEEN NEURONS IN THE VERTEBRATE CEREBELLAR CORTEX

"Gap" junctions, the morphological correlate for low-resistance junctions, are demonstrated between some mossy fiber terminals and granule cell dendrites in some lower vertebrate cerebella (gymnotid and frog). Most of the gap junctions (GJs) seen in the gymnotid-fish cerebellum exhibit an asymmetrical configuration, the electron-opaque cytoplasmic material underlying the junction being more extensive in the dendritic than in the axonal side. In the frog cerebellum, the GJs have a symmetrical distribution of such electron-opaque material. In both species the GJs are encountered at the same synaptic interface as the conventional synaptic zone (CSZ), constituting "mixed synapses" in a morphological sense. The axonal surface covered by CSZs is larger than that covered by GJs. In mammalian cerebellum, GJs are observed only in the molecular layer, between perikarya, dendrites, or perikarya and dendrites of the inhibitory interneurons. These GJs are intermixed with attachment plates and intermediary junctions interpreted as simply adhesive. In the mammalian cerebellum, a new type of junction which resembles the septate junctions (SJs) of invertebrate epithelia is observed between axonal branches forming the tip of the brush of basket fibers around the initial segment of the Purkinje cell axon. It is suggested that such junctions may be modified forms of septate junctions. The physiological implications of the possible existence of high-resistance cross-bridges between basket cell terminals, which may compartmentalize the extracellular space and thus regulate extracellular current flow, must be considered.     

Gap and tight junctions in tunicates. Study in conventional and freeze-fracture techniques

Intercellular junctions have been investigated in epidermis and pharyngeal epithelium of larvae and adults of various species of tunicates with conventional and freeze-fracture techniques. Gap and tight junctions were found, similar to those observed in vertebrate tissues. Gap junctions were frequent in glandular epithelia and in larval tissues. They were interpreted as ways of intercellular communication in these developing tissues. They were also particularly numerous in Phallusia pharyngeal cells. Tight junctions were found preferentially in adult pharyngeal and epidermal epithelia, where they were arranged in strands of distinct particles forming a belt-like network at the apical part of cells. These junctions were interpreted as providing a tight barrier between the internal medium and the external environment. In larvae, tight junctions were found only between epidermal cells of the tail. These junctions thus characterized completely differentiated tissues, where they might play, in tunicates and in vertebrates, the same role as septate junctions do in invertebrates.