Fine structure of the rectal pads in the desert locust Schistocerca gregaria with reference to the mechanism of water uptake

The rectal pads of Schistocerca gregaria are composed of three different cell types: epithelial, secondary and junctional cells. The rectal pads are interconnected by simple rectal cells and both are lined internally by a articular intima. The epithelial cells exhibit extensive infoldings of the apical plasma membranes that are closely associated with mitochondria. Their lateral plasma membranes are highly folded around large mitochondria and enclose intercellular channels and spaces. They are united by belt and spot desmosomes, septate junctions, gap junctions and scalariform junctions, but terminate in a basal syncytium without contacting the basal plasma membranes. The apical and basal cytoplasm contain coated vesicles, dense tubular elements, multivesicular bodies and lysosomes, suggesting receptor-mediated endocytosis of small peptide molecules into the epithelial cells. The apical membrane infoldings of the secondary cells are also associated with large mitochondria. Their basal plasma membranes are covered by connective cell processes and connected with them by spot desmosomes which may be involved in solute recycling. The presence of neurosecretory-like axons near the secondary cells suggests that they exert local control on the function of these cells. The ultrastructural details are examined in relation to their role in solute and water transport.     

Formation of desmosomes and other contact specializations in cultured skin of the frog (Rana esculenta)

Summary Small trypsinized explants from ventral skin of frogs (Rana esculenta) were maintained in culture for 4 days during which a newly formed epithelium differentiated along the cut edges of the dermis. During the first 6 h adjacent cells produced numerous interdigitating lamellipodia. After 2 days, epithelial polarity was restored by the formation of zonulae occludentes and the epithelial cells were joined by a few small newly formed desmosomes and by numerous interdigitations. Bipartite junctional complexes consisting of a zonula occludens, followed by a series of typical desmosomes, and characteristic of adult frog epidermis were formed only after 4 days. When cultured in the presence of an inhibitor of protein synthesis (cycloheximide) the trypsinized epidermis no longer formed desmosomes. Therefore pools of one or more crucial desmosomal proteins must be very low or non-existent. However, cycloheximide did not prevent the formation of cell contact specializations, consisting of a highly developed system of complex lamellar interdigitations, between adjacent cells.     

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

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

Fine structure of the rectum in cockroaches (Dictyoptera): General organization and intercellular junctions

The organization of the rectal pads is described in cockroaches belonging to the Groups Blattoidea (Periplaneta americana, Blatta orientalis) and Blaberoidea (Supella supellectilium, Blaberus craniifer). In the Blattoidea, each pad is composed of two layers (principal and basal cells) and is surrounded by very narrow junctional cells supporting the sclerotized cuticle of the pad frame; basally, the junctional cells abut on to the basal cells. In the Blaberoidea, the basal cell layer is discontinuous, the basal cells being interspersed between extensions of the junctional cells beneath the pad. The ultrastructural features of each cell type is described, with special reference to the intercellular junctions, which exhibit unusual complexity. Four types of junction are recognized: desmosomes (belt and spot desmosomes), gap junctions, septate junctions and scalariform (ladder-like) junctions. The last are usually closely associated with mitochondria, forming mitochondrial-scalariform junction complexes (MS). The distribution of these junctions is examined in relation to the partitioning of extracellular spaces, and to the problem of fluid transport.     

Culture of human endometrial cells under polarizing conditions

Glandular epithelial and stromal cells were isolated from human endometrial biopsies and cultured in a dual-chambered system (Millicell; Millipore, Bedford, Ma., USA) that provides access of the medium to both sides of a membrane coated with reconstituted basement membrane material (Matrigel; Collaborative Research Inc., Bedford, Ma., USA). Examination by electron microscopy revealed that the epithelial cells formed a polarized cuboidal-columnar monolayer on the Matrigel surface. The cells exhibited apical microvilli, basal nuclei, and numerous cytoplasmic structures consistent with a well-differentiated cytoplasm; they were joined basally by interdigitating processes and apically by tight junctions and desmosomes. In contrast, epithelial cells cultured in parallel on plastic dishes were flattened, had fewer microvilli and cytoplasmic structures, and no junctional complexes.     

Control of desmosome formation in aggregating embryonic chick cells

Corneal epithelial cells have been used to study cell surface changes during cell aggregation. Tissue was taken from developmental stages in which desmosomes were forming rapidly. When corneal cells are dispersed, adjacent desmosome plaques are separated and single plaques are left on the cell surface. As cells aggregate, changes in the frequency of single plaques or of full desmosomes (double plaques) per micrometer of cell surface cross section can be followed. Single plaques are lost from the surface by endocytosis. Quantitative studies show a loss of single plaques beginning in the first hour of culture and formation of double plaques at 2 to 3 hr. In cells treated with cytochalasin B or D, single plaques are not lost during the first 2 hr and double plaques form with a higher frequency. Formation of double plaques is suppressed by actinomycin D, cycloheximide, and dinitrophenol. Thus desmosome formation requires de novo protein synthesis. In addition, inhibition of cell surface turnover by drugs which modify the cytoskeleton will enhance the rate at which desmosomes form.     

Differentiation of normal human mammary epithelial cells in culture: an ultrastructural study.

An ultrastructural and cytochemical study of normal human mammary epithelial cells cultured from post-weaning breast fluids is described. Cells were examined at the time of plating and at intervals up to 28 days in culture. Three different stages in the morphological differentiation of these cells in vitro were observed: (1) the first stage was the formation of a monolayer of single cells, which occurred between days 1 and 10 in culture. The cells in this stage were not interconnected by junctional complexes and lacked Mg++- dependent ATPase activity in the plasma membranes, but did contain a large quantity of lipid and exhibited some secretory characteristics. (2) The second stage, occurring at 10 to 16 days in culture, was characterized by the formation of junctional complexes, the appearance of Mg++-dependent ATPase in the plasma membrane and a decrease in the number of dense bodies with peroxidase activity. (3) The third stage, occurring at 16 to 28 days in culture, was characterized by the formation of stratified layers of epithelial cells, which were interconnected by a larger number of desmosomes with numerous pleomorphic microfilaments. The Mg++-dependent ATPase activity in the plasma membrane was retained and the dense bodies with peroxidase activity were rarely observed at this stage. During the last seven days were prominent in the cells of the stratified layer. After 28 days in the culture, the cells began to round up and slough off the culture plate.     

Junctional complexes in fetal rat small intestine during morphogenesis

During the 7 days prior to birth (Days 15–22), the small-intestinal epithelium of the fetal rat changes from primitive stratified to simple columnar epithelium which lines villi at 19 days. As seen in thin sections, this remodeling involves rapid formation of new junctional complexes and secondary lumens between epithelial cells deep in the stratified epithelium. We have examined the formation and reorganization of junctional complexes in proximal small intestine of 15- to 19-day fetal rats using freeze-fracture techniques. On Days 15 and 16 the epithelial cells surrounding the primary lumen are joined by conventional apical junctional complexes. Additionally, macular junctional complexes are located on deeper epithelial cells. These display no polarity and consist of tight-junction strands intermixed with gap junction-like arrays and desmosomes. On Days 17 and 18 nonluminal, macular junctional complexes enlarge and secondary lumens develop within their centers. As the secondary lumens expand, microvilli appear and the junctional complex polarizes about the secondary lumen; tight-junction strands become parallel to the luminal surface, desmosomes migrate basolaterally, and gap junction-like arrays disappear. By Day 19, secondary lumens have fused with the primary lumen; concomitant loss of apical cells results in formation of villi lined by simple columnar epithelium with polarized apical tight junctions. The observed pattern of junctional complex formation may play a role in maintaining barrier function and establishing epithelial cell polarity as the epithelium is remodeled.     

Tissue culture of human epithelial cells from benign colonic tumors

Summary Human colonic epithelial cells from three classes of benign tumors have been reproducibly cultured free of fibroblasts for 8 wk using a supplemented Medium 199 (M 199S). The cultured colonic cells were identified as epithelial by the presence of junctional complexes (tight junctions, gap junctions, and desmosomes), a brush border on the apical surface, keratin fibrils, and by both a close-packed columnar or cuboidal morphology and the capability to transport water and ions to form hemicysts. Colony formation was initiated by groups of epithelial cells, not by single cells, and was inhibited by cocultivation with either lethally irradiated 3T3 cells or human diploid fibroblasts. Enhancement of epithelial colony formation was observed following culture on nonadherent, “floating” substrates compared with substrates attached directly to the bottom of the culture dish. Replication of epithelial cells in M 199S from the class of benign colonic tumors least prone to malignancy, the tubular, was significantly enhanced by epidermal growth factor (EGF). In contrast, EGF did not stimulate the growth of cells in M 199S from the other classes of benign tumors, the villotubular and the villous, which exhibit more malignant potential. These data imply that premalignant colonic epithelial cells lose responsiveness to growth modulation by EGF as they progress toward frank carcinoma. This study was supported by NCI Contract N01-CP43366 to M. L. and NCI Grant 1-R26-CA 28822 to E. F.     

Isoenzymes de l'anhydrase carbonique d'un poisson euryhalin: Variations en relation avec l'osmoregulation

A chemical study of carbonic anhydrase (EC 4.2.1.1) from the red blood cells and the gills of an euryhaline fish (Anguilla anguilla) is presented. Animals adapted to fresh water were compared to those adapted to sea water.The physicochemical constants of the various molecular forms isolated by chromatograhy and isoelectric focusing were determined; isoeleletric pH, molecular weight, and the K_m and V/E of the enzyme dehydration activity were compared.In both red cells and gills of fish adapted in either media various forms were isolated, characterized by different enzymatic kinetics (high- and low-activity forms) but having the same molecular weight (27 250). Some isoenzymes isolated from the gills differed significantly from those isolated from the red cells.Adaptation to fresh water or sea water is accompanied by modifications in the distribution of yhe isoenzymes in both red cells and gills: adaptation to sea water is characterized by a shift of the molecular forms towards an isoelectric pH higher than pH = 6.The role of these enzymes is discussed under both a physiological and biochemical point of view in relation to the electrolyte exchange across fish gill. The origin of the different molecular forms of the carbonic anhydrase is discussed in relation to the prevailing theories on this subject.     

Sec3-containing Exocyst Complex Is Required for Desmosome Assembly in Mammalian Epithelial Cells

The Exocyst is a conserved multisubunit complex involved in the docking of post-Golgi transport vesicles to sites of membrane remodeling during cellular processes such as polarization, migration, and division. In mammalian epithelial cells, Exocyst complexes are recruited to nascent sites of cell–cell contact in response to E-cadherin–mediated adhesive interactions, and this event is an important early step in the assembly of intercellular junctions. Sec3 has been hypothesized to function as a spatial landmark for the development of polarity in budding yeast, but its role in epithelial cells has not been investigated. Here, we provide evidence in support of a function for a Sec3-containing Exocyst complex in the assembly or maintenance of desmosomes, adhesive junctions that link intermediate filament networks to sites of strong intercellular adhesion. We show that Sec3 associates with a subset of Exocyst complexes that are enriched at desmosomes. Moreover, we found that membrane recruitment of Sec3 is dependent on cadherin-mediated adhesion but occurs later than that of the known Exocyst components Sec6 and Sec8 that are recruited to adherens junctions. RNA interference-mediated suppression of Sec3 expression led to specific impairment of both the morphology and function of desmosomes, without noticeable effect on adherens junctions. These results suggest that two different exocyst complexes may function in basal–lateral membrane trafficking and will enable us to better understand how exocytosis is spatially organized during development of epithelial plasma membrane domains.     

Fine structure of cultured epithelial cells derived from voided urine of normal adults

Cultures of epithelial cells can be initiated with the sediment of voided urine of normal adults. Tightly or loosely packed colonies were formed by cells of diverse morphologic configuration. Ultrastructural studies revealed that the proliferating cells formed abundant desmosomes, imperfectly formed tight junctions and lamina densa, all typical of epithelial cells. Some cells were lined by the characteristic asymmetric unit membrane, thus confirming the urothelial derivation of the cultures. Peculiar, apparently hitherto not described multivesicular bodies, seemingly of cytoplasmic origin, were observed near the surfaces of some cells. The urinary cell culture system is a potentially useful tool for diagnostic and research purposes.     

Microampullary organs of a freshwater eel-tailed catfish,Plotosus (tandanus) tandanus

Whole body studies of Plotosus tandanus revealed that ampullary pores occur over the entire body of the fish, but are in higher concentrations in the head region. These pores give rise to a short canal (50-60 microm) produced by columnar epithelial cells bound together by tight junctions and desmosomes. At the junction of the canal and the ampulla, cuboidal epithelial cells make up the wall. The ampulla consists of layers of collagen fibers that surround flattened epithelial cells in the lateral regions and give rise to supportive cells that encase a small number of receptor cells (10-15). The ampullary wall comprises several types of cells that are adjoined via tight junctions and desmosomes between cell types. The ovoid receptor cells possess microvilli along the luminar apical area. Beneath this area, the cells are rich in mitochondria and rough endoplasmic reticulum. An unmyelinated neuron adjoins with each receptor cell opposite multiple presynaptic bodies. This form of microampulla has not been previously described within the Family Plotosidae.     

In vitro growth and maintenance of two morphologically distinct populations of thymic epithelial cells

Cultures of thymic epithelial cells were generated and maintained in valine-free minimum essential medium (MEM) supplemented with 690 mg/liter of D-valine. These cultures have been maintained for 1 year through multiple passages by trypsinization of 60-70% confluent monolayers. Large and small epithelial cells were present in early cultures. They were separated into two stable subpopulations based on (1) their differential growth rates and (2) their differential adherence to the culture substratum. These morphologically distinct cell populations, TECS and TECL, were 100% keratin positive and contained cells with desmosomes and tonofilaments, all characteristics of epithelial cells. Esterase analysis of both cell populations revealed a 1 and 9% esterase-positive cell population in cultures of keratin-positive small (TECS) and large (TECL) cells, respectively. The percentages of esterase-positive cells corresponded to the 2 and 10% populations of TECS and TECL, respectively, that contained both desmosomes and phagolysosomes. These results establish conditions for the long-term propagation of pure thymic epithelial cells. Such cultures can be used to study the functional interactions between epithelial cells and lymphoid cells. Morphologic and histochemical analyses have identified subsets of these cells which may prove to have differential effects on thymocyte proliferative and developmental processes.     

Ultrastructure of human blastocyst-endometrial interactions in vitro

The interactions of seven human blastocysts with cultured endometrial cells were investigated by light microscopy and transmission electron microscopy. Trophoblastic-endometrial contact was observed at the lateral border of endometrial epithelial cells where trophoblast and endometrial epithelial cells shared apical junctional complexes and desmosomes. The first sign of penetration was invasion of a trophoblastic cytoplasmic protrusion between endometrial epithelial cells. In broad contact areas, lateral displacement of endometrial epithelial cells and formation of a peripheral pseudostratified epithelium were observed. When trophoblastic cells were interposed fully among endometrial epithelial cells, they formed a penetration cone and appeared to dislodge endometrial epithelial cells from the stromal compartment. A single penetration cone only was found in each specimen. Endometrial or trophoblastic degeneration was not observed. Formation of multinucleate (>/= three nuclei per cell) trophoblast cells was not observed, but many cells displayed areas with abrupt disappearance of well-defined plasma membranes, which is indicative of syncytium formation. In this study, adhesion and penetration occurred at the same time. The human blastocysts penetrated the endometrial surface epithelium by intrusive penetration. Epithelial penetration was achieved primarily by cellular syncytiotrophoblast-like cells and the first indications of syncytium formation were observed simultaneously with penetration of the epithelium.     

The development of rat palatal shelves in vitro. An ultrastructural analysis of the inhibition of epithelial cell death and palate fusion by the epidermal growth factor.

Unfused palatal shelves from day-15 rat embryos were cultured with their medial edges in contact. During the next 20 hr epithelial surfaces of apposing shelves adhered, and the epithelial cells in this area degenerated and were replaced by mesenchymal cells in a manner similar to that reported for palate fusion in vivo in the rat and in vitro in the mouse. Four hours after contact the superficial cells of apposing palates adhered with a 10–25-nm distance separating cell membranes while after 20 hr these cells were either eliminated or had lost their flattened appearance and become indistinguishable from the cuboidal-shaped cells adjacent to the basement membrane. The ratio of cytoplasm to nucleoplasm was reduced, and degenerated cells were eliminated by macrophages.Addition of epidermal growth factor (EGF) to the culture medium inhibited epithelial adhesion and degeneration. Basal and superficial cells retained their original appearance, while the ratio of cytoplasm to nucleoplasm was increased. Numerous desmosomes and tonofilaments were evident as well as elaborate membrane foldings. The appearance of these cellular elements is similar to that observed in keratinizing palatal epithelial cells from the oral region. These results suggest that EGF induces the epithelial cells to keratinize, and as a consequence the normal sequence of steps of palate fusion are inhibited.     

Intercellular junctions between human odontoblasts. A freeze-fracture study after demineralization

Intercellular junctions in the odontoblastic layer have been studied with a freeze-fracture technique. Children's tooth germs were fixed, sliced and demineralized. Samples of the pulpodentinal border were routinely prepared for freeze-fracture. Three kinds of intercellular junctions were detected between human odontoblast cell bodies: gap junctions, desmosomes and tight junctions. Numerous gap junctions are responsible for intercellular communication at different levels of the cell bodies. Focal tight junctions, parallel to the axis of the cell, and desmosomes are sites of cell-to-cell adhesion between lateral plasma membranes. At the distal end of the cell bodies, junctional complexes consist of zonular tight junctions and gap junctions. These zonular tight junctions, never before described between odontoblasts, contribute to the pseudo-epithelial organization of the odontoblastic layer. They constitute a predentin-pulp barrier, the permeability of which must be studied to establish their role in relation to dentin formation.     

Intercellular Attachment in the Epithelium of Hydra As Revealed by Electron Microscopy

In Hydra adjacent epithelial cells are bound firmly to each other by desmosomes of a type not described in detail hitherto. The most prominent feature of these desmosomes is the presence of a series of parallel lamellae which bridge the intercellular space and connect the two apposed cell surfaces directly. These structures, here termed intercellular attachment lamellae, display two peaks of density about 50 A apart. These dense lines appear in some instances to be continuous with the outer dense components of the plasma unit membranes of the attached cells. The presence of prominent lamellae in intercellular attachments is sufficiently distinctive to deserve special terminology; accordingly, the term septate desmosome is proposed. It is noted that septate desmosomes may have been seen in other animals in instances where published electron micrographs show cross-striations or prominent connections in regions of intercellular attachment. It is suggested that septate desmosomes in Hydra, in addition to binding cells firmly to each other, form barriers to the movement of water into intercellular spaces and thus help to protect the organism's internal environment. Observations on the use of phosphotungstic acid for improving contrast in materials embedded in epoxy resins are also recorded.     

Identification of the cytoskeletal proteins in lens-forming cells, a special epithelioid cell type

Proteins of contractile and cytoskeletal elements have been studied in bovine lens-forming cells growing in culture as well as in bovine and murine lenses grown in situ by immunofluorescence microscopy using antibodies to the following proteins: actin, myosin, tropomyosin, α-actinin, tubulin, prekeratin, vimentin, and desmin. Lens-forming cells contain actin, myosin, tropomyosin, and α-actinin which in cells grown in culture are enriched in typical cable-like structures, i.e. microfilament bundles. Antibodies to tubulin stain normal, predominantly radial arrays of microtubules. In the epithelioid lens-forming cells of both monolayer cultures grown in vitro and lens tissue grown in situ intermediate-sized filaments of the vimentin type are abundant, whereas filaments containing prekeratin-like proteins (‘cytokeratins’) and desmin filaments have not been found. The absence of cytokeratin proteins observed by immunological methods is supported by gel electrophoretic analyses of cytoskeletal proteins, which show the prominence of vimentin and the absence of detectable amounts of cytokeratins and desmin. This also correlates with electron microscopic observations that typical desmosomes and tonofilament bundles are absent in lens-forming cells, as opposed to a high density of vimentin filaments. Our observations show that the epithelioid lens-forming cells have normal arrays of (i) microfilament bundles containing proteins of contractile structures; (ii) microtubules; and (iii) vimentin filaments, but differ from most true epithelial cells by the absence of cytokeratins, tonofilaments and typical desmosomes. The question of their relationship to other epithelial tissues is discussed in relation to lens differentiation during embryogenesis. We conclude that the lens-forming cells either represent an example of cell differentiation of non-epithelial cells to epithelioid morphology, or represent a special pathway of epithelial differentiation characterized by the absence of cytokeratin filaments and desmosomes. Thus two classes of tissue with epithelia-like morphology can be distinguished: those epithelia which contain desmosomes and cytokeratin filaments and those epithelioid tissues which do not contain these structures but are rich in vimentin filaments (lens cells, germ epithelium of testis, endothelium).     

Fine structure of the rectal pads in Grylloblatta compodeiformis (walker) (Orthoptera : Grylloblattidae) with reference to fluid transport

The rectal pads of the primitive insect Grylloblatta compodeiformis (Orthoptera : Grylloblattidae) were studied using light and electron microscopy. In this species, the rectal epithelium is thickened to form 6 prominent rectal pads, each of which is composed of tall columnar epithelial cells and laterally placed slender junctional cells, but is devoid of secondary cells. The rectal pads are interconnected by simple rectal epithelium, and are lined by a thin cuticular intima. They are surrounded by an extensive connective tissue space, which contains bundles of delicate connective tissue fibers, neurosecretory axons, and tracheae and tracheoles, which do not penetrate into the pads. The epithelial cells exhibit extensive infoldings of the apical plasma membranes that are closely associated with mitochondria. The lateral membranes are also highly folded around large mitochondria that possess longitudinally oriented cristae. These membrane folds form mitochondrial-scalariform junctional complexes and enclose intercellular channels and spaces. The apical cytoplasm of the epithelial cells contains numerous coated vesicles, dense tubular elements, multivesicular bodies and lysosomes, which suggests receptor-mediated endocytosis of macromolecules. The presence of large whorls of rough endoplasmic reticulum and abundant free ribosomes in the cytoplasm and nuclei with multiple, well-developed nucleoli indicate that the epithelial cells are actively engaged in protein synthesis. The ultrastructural features were examined in relation to their role in fluid transport in a cold habitat.