Ultrastructure of cell surface coat (glycocalyx) in rat urinary bladder epithelium

Earlier statements to the contrary, the present study demonstrates the presence of a cell surface coat (glycocalyx) on the luminal plasma membrane of the superficial transitional epithelial cells lining the urinary bladder of male Buffalo rats. This coat was demonstrated with ruthenium red, an electron dense stain, which revealed a surface layer, 60-80 A thick, separated from the outer leaflet of the plasma membrane by an electron lucent layer, approximately 30 A thick. The structure of the glycocalyx was not affected by 12 weeks of treatment with dibutylnitrosamine, a known bladder carcinogen.     

The superficial cells of the transitional epithelium in the expanded and unexpanded rat urinary bladder. Transmission and scanning electron-microscopic study.

The superficial epithelial layer in the urinary bladder of adult rats was examined, in various states, using the transmission and scanning electron microscopes. A good agreement was obtained between the results of the two methods. When the urinary bladder is unexpanded, the superficial cells show marked bulges into the bladder lumen and the contacts between cells (mainly desmosomes) are displaced deep into the epithelium. The luminal surface is bizarrely bent and large parts of the membrane intrude into the cytoplasm, where they give the appearance of discoid and fusiform vesicles. Between neighboring cells, deep interdigitations are observed. In the scanning electron microscope, the surface of the epithelium appears cauliflower-like and has deep grooves, gullys and folds. When the bladder is expanded, the surface becomes smoother and the contacts between cells move to the surface. The stretched cells are angular in form (5-, 6- or 7-sided) and show great variations in surface area (150-500 mum2). The luminal cell membrane consists of an alternation of asymmetrical areas (120 A thick and 0.2-0.4 mum in length) with normal sections which are 80 A thick. In the scanning electron microscope, these thick areas appear as 4-, 5- or 6-sided plaques with a maximal diameter of 0.4 mum. The borders of the plaques are formed of portions of cell membrane which have a normal thickness and extrude as microcristae into the lumen. This produces a honeycomb appearance on the cell surface.     

Degeneration and apoptosis of endometrial cells in the bitch

The relationships between changes in plasma progesterone concentrations, degeneration of the luminal epithelium, the occurrence of apoptosis of endometrial cells and endometrial leucocyte populations in the bitch were determined. Mature bitches (n = 15) were euthanized and necropsied when in diestrus (Days 7-75, n = 12) or in anestrus (Days 10, 32 and 53). Degeneration of the luminal epithelium was observed in bitches in late diestrus (Days 38-75, n = 5) when plasma progesterone concentrations were decreasing and in anestrus (Days 10 and 32, n = 2) when plasma progesterone concentrations were < 0.5 ng/mL. Endometrial leucocyte populations increased after degeneration of the luminal epithelium (around Day 42 of diestrus). Apoptosis was mainly observed in the basal glandular epithelial cells and endothelial cells of blood capillaries in all except anestrous bitches. Very few apoptotic cells were found in the superficial glandular epithelial cells and stromal cells. Higher apoptotic indices were detected in the basal glandular epithelium on Days 12-42 of diestrus than at other stages. Therefore, apoptosis of glandular basal epithelial cells occurred mainly in early diestrus, degeneration of cells of the luminal epithelium occurred from mid-diestrus to early anestrus, and the increase in leucocyte numbers may have been a consequence and not a cause of luminal epithelial degeneration.     

Epithelial differentiation in the fetal rat colon: I. Plasma membrane phosphatase activities

During the last week of gestation of the fetal rat, the epithelium of the colon is rapidly remodeled. At 16 days a primitive stratified epithelium surrounds a small central lumen. Over the next 3 days, the main lumen extends narrow clefts down to the basal cell layer and small secondary lumina appear within the stratified epithelium between these clefts. At 19 and 20 days, secondary lumina enlarge but remain discrete; an infusion of cationic ferritin into the main lumen does not enter secondary lumina. During the 2 days prior to birth (21–22), the secondary lumina join the main lumen as superficial cells are sloughed, and the epithelium becomes simple columnar. Freeze-fracture replicas indicate that luminal and nonluminal membrane domains of epithelial cell plasma membranes are separated by continuous tight junctions throughout the conversion process. Cytochemical analysis of tissue slices from 16- to 22-day fetal colon demonstrated the appearance and segregation of two phosphatases on apical and basolateral membrane domains during epithelial conversion. Cysteine-sensitive pH 9.0 (alkaline) phosphatase activity was first detected along the luminal membranes of cells bordering both primary and secondary lumina at 18 days gestation and increased to a maximum at 20–21 days; weaker activity was present on basolateral membranes. Phosphatase activity at pH 8.0 also appeared at 18 days and increased thereafter, but was localized primarily on nonluminal membranes. At pH 8.0, reaction product appeared on both inner and outer sides of the membrane, and was only partially abolished by omission of K⁺ or addition of ouabain; thus the reaction may be only partially due to K⁺-dependent ATPase activity. Biochemical analysis of the cytochemical media confirmed the appearance of phosphatase activities at 18 days. Thus, plasma membrane phosphatase activities appear while the epithelium is still stratified, but are segregated to luminal and nonluminal membrane domains at the onset of activity. Segregation is maintained throughout the process of conversion of a simple columnar epithelium.     

Detection of a glycosphingolipid antigen in bladder cancer cells with monoclonal antibody MRG-1

Summary The monoclonal antibody MRG-1 has been evaluated for the immunohistochemical detection of the type 3 chain of blood group A in human normal bladder epithelium and bladder tumours. Light microscope examination of paraffin sections demonstrated that this antigen was present in normal epithelium and superficial bladder tumour in patients with blood group A or AB, but was absent in the invasive type of bladder tumour. In normal epithelium, the plasma membrane was positive for this antigen, and the cytoplasm was diffusely stained. In superficial transitional cell carcinoma, the plasma membrane was negative, whereas the cytoplasm was intensely stained in the perinuclear region. This pattern was different from that observed for type 1 and 2 group A antigen, which was recognized mainly at the plasma membrane. However, in superficial transitional cell carcinoma, the staining was also seen on the plasma membrane. The pattern of the localization of this antigen in this carcinoma was influenced by the treatment of organic solvents. Electron microscopical observations confirmed that this antigen was localized on the plasma membrane and also in the Golgi apparatus of the superficial tumour.These results proved that the type 3 chain of blood group A is present in human bladder epithelium and low grade tumours in correspondence with the blood type, but disappears in tumours with high malignant potential. However, its expression is independent of the expressions of the other subtypes which have been studied. Furthermore, the changes in the staining pattern caused by pretreatment with organic solvents suggested possible differences in the microenvironment of the glycolipids containing this type of sugar chain.     

The permeability of rat transitional epithelium. Kertinization and the barrier to water

Permeability barriers must exist in transitional epithelium to prevent the free flow of water from underlying blood capillaries through the epithelium into the hypertonic urine, and such a barrier has now been demonstrated in isolated bladders. This barrier is passive in function and can be destroyed by damaging the luminal surface of the transitional epithelium with sodium hydroxide and 8 M urea solutions, by digesting it with trypsin, lecithinase C, and lecithinase D, or by treating it with lipid solvents such as Triton x 100 and saponin. From this it is concluded that the barrier depends on the integrity of lipoprotein cell membranes. The barrier function is also destroyed by sodium thioglycollate solutions, and electron microscope investigations show that sodium thioglycollate damages the thick asymmetric membrane which limits the luminal face of the superficial squamous cell. Cytochemical staining shows the epithelium to contain disulfide and thiol groups and to have a concentration of these groups at the luminal margin of the superficial cells. It thus appears that the permeability barrier also depends on the presence of disulfide bridges in the epithelium, and it is presumed that these links are located in keratin. Because of the effect of thioglycollates, both on the barrier function and on the morphology of the membrane, it is suggested that keratin may be incorporated in the thick barrier membrane. It is proposed that the cells lining the urinary bladder and ureters should be regarded as a keratinizing epitheluim.     

THE MAMMALIAN URINARY BLADDERAN ACCOMMODATING ORGAN

1. Urinary bladders are found in the amphibia, chelonian reptiles and mammals. In these orders liquid urine is stored in the bladder and eliminated at intervals from the body by micturation. 2. In the amphibia and chelonian reptiles, the urinary bladder is a functional extension of the renal tubules. The composition of the urine in the bladder is modified by the active movement of water and ions across the bladder wall, and these transporting processes are under hormonal control. The bladder acts as a water reservoir which can be drawn upon in times of water shortage. 3. The mammalian bladder separates two widely differing water phases, namely the urine which is frequently hypertonic to the blood and the tissue fluids which are isotonic. Its function is uniquely one of storage, and no adjustment to the composition of the urine is made by active transport of either water or ions across the bladder wall. 4. The epithelium lining the mammalian bladder is the site of the osmotic barrier between urine and tissue fluids. This functional barrier is dependent on the structure of the epithelium and is maintained despite large alterations in the surface area of the epithelium as the bladder rapidly contracts, or slowly dilates. 5. The epithelium is of mixed mesodermal and endodermal origin, is transitional in type and is usually 3 or 4 cell-layers thick. If this urothelium is damaged, it has a high capacity for regeneration and rapidly re-establishes an intact barrier over the luminal surface. 6. The superficial cell layer of this epithelium is composed of large, polyploid, highly differentiated squamous cells which have a long life span. These cells are limited on their free surface by an unusual, angular, semi-rigid luminal membrane. This membrane is assembled in the Golgi complex. 7. The luminal membrane is composed of thickened, discoidal plaques, separated by narrow bands of thinner membrane. When the bladder contracts, the membrane folds along the thinner ‘hinge’ regions, and the rigid discoidal plates invaginate to form fusiform, cytoplasmic vacuoles. The thickened plaques contain a hexagonal lattice of sub-units, spaced at 14 nm centre-to-centre. Each sub-unit in the lattice is itself composed of 12 smaller particles. These particles may be envisaged as small rods 3 nm in diameter and 12 nm long, and are inserted into matrix from which they project on the luminal face by about 3 nm. Each rod has a central hydrophobic portion separating distal hydrophilic ends. 8. The chemical composition of this luminal membrane is unusual. Cerebroside is a major component of the polar lipid fraction and there is an unusually high proline content in the protein fraction. When the mucoproteins are adequately dispersed, and the proteins separated by electrophoresis, a few major proteins are revealed in 33000–80000 dalton range of molecular weight. 9. If the normal structure of the luminal membrane is altered, either by physical damage or by failure of the cells to produce it, the barrier function of the epithelium is lost. 10. The structure and function of this membrane depend ultimately on its chemical composition. Cerebroside is known to decrease the permeability of lipid bi-layers to water, but for maximum impermeability a lipid bi-layer must be maintained in a condensed configuration. The stresses of bladder distension and contraction might be expected to disrupt the bi-layer, and it is suggested that the function of the rigid plaque regions is to reduce mechanical stresses in the membrane to a minimum. The plaque areas occupy between 73 and 90 % of the membrane surface, and only the remaining 10–27% of the membrane is thus subject to bending and distortion when the bladder contracts or expands. The structure of the plaque areas is probably determined by the nature of the complex proteins which form the sub-units. Proline is known to confer rigidity on polypeptide chains, and may play an important rôle in ordering the structure of the plaques. 11. The bladder epithelium, though normally differentiated as a transitional epithelium, has other biologicai potentialities. It can undergo squamous metaplasia to form a stratified cornified epithelium in response to mechanical irritation and/or vitamin A deficiency. If transplanted from its normal location, it can induce other supporting mesenchyme tissues to lay down bone. When regenerating in response to damage, the newly formed transitional cells can act as phagocytes and engulf and digest damaged or dying cells. In the normal animal the epithelium is largely protected from tumour formation by cell-mediated immunological surveillance. The defensive mechanisms are triggered by tissue-type specific antigens which develop in neoplastic bladder epithelial cells.     

STRUCTURE OF THE TOAD'S URINARY BLADDER AS RELATED TO ITS PHYSIOLOGY

The structure of the urinary bladder of the toad Bufo marinus was studied by light and electron microscopy. The epithelium covering the mucosal surface of the bladder is 3 to 10 microns thick and consists of squamous epithelial cells, goblet cells, and a third class of cells containing many mitochondria and possibly representing goblet cells in early stages of their secretory cycle. This epithelium is supported on a lamina propria 30 to several hundred microns thick and containing collagen fibrils, bundles of smooth muscle fibers, and blood vessels. The serosal surface of the bladder is covered by an incomplete mesothelium. The cytoplasm of the squamous epithelial cells, which greatly outnumber the other types of cells, is organized in a way characteristic of epithelial secretory cells. Mitochondria, smooth and rough surfaced endoplasmic reticulum, a Golgi apparatus, "multivesicular bodies," and isolated particles and vesicles are present. Secretion granules are found immediately under the plasma membranes of the free surfaces of the epithelial cells and are seen to fuse with these membranes and release their contents to contribute to a fibrous surface coating found only on the free mucosal surfaces of the cells. Beneath the plasma membranes on these surfaces is an additional, finely granular component. Lateral and basal plasma membranes are heavily plicated and appear ordinary in fine structure. The cells of the epithelium are tightly held together by a terminal bar apparatus and sealed together, with an intervening space of only 0.02 mµ near the bladder lumen, in such a way as to prevent water leakage between the cells. It is demonstrated in in vitro experiments that water traversing the bladder wall passes through the cytoplasm of the epithelial cells and that a vesicle transport mechanism is not involved. In vitro experiments also show that the basal (serosal) surfaces of the epithelial cells are freely permeable to water, while the free (mucosal) surfaces are normally relatively impermeable but become permeable when the serosal surface of the bladder is treated with neurohypophyseal hormones. The permeability barrier found at the mucosal surface may be represented, structurally, either by the filamentous layer lying external to the plasma membrane, by the intracellular, granular component found just under the plasma membrane, or by both of these components of the mucosal surface complex. The polarity of the epithelial sheet is emphasized and related to the physiological role of the urinary bladder in amphibian water balance mechanisms.     

Cytochemical localisation of acid phosphatase in the phagocytising conjunctival epithelium of the guinea pig

Summary The ultrastructural localisation of acid phosphalase activity was investigated on the guinea pig conjunctival epithelium incubated in vivo with a suspension of latex spheres. Deposits of acid phosphatase reaction product were concentrated on the elements of GERL, the phagocytic vacuoles, and the cell membrane. Acid phosphatase activity in GERL was intense in basal and suprabasal cells and decreased towards the superficial cells. Phagosomes containing latex spheres and reaction product of acid phosphatase were observed mainly in the centrospheral region of the superficial and intermediate epithelial cells. Acid phosphatase activity in phagocytising cells was not increased as compared to that in non-phagocytising cells. The observations indicate that existing acid phosphatase in unstimulated conjunctival epithelial cells is released into heterophagosomes brought within the lysosomal compartment. The number of secondary phagosomes seems to be increased by intercellular transport of latex spheres to the acid phosphatase rich cells in the deep layers of the epithelium.     

Cytochemical localisation of acid phosphatase in the phagocytising conjunctival epithelium of the guinea pig

The ultrastructural localisation of acid phosphatase activity was investigated on the guinea pig conjunctival epithelium incubated in vivo with a suspension of latex spheres. Deposits of acid phosphatase reaction product were concentrated on the elements of GERL, the phagocytic vacuoles, and the cell membrane. Acid phosphatase activity in GERL was intense in basal and suprabasal cells and decreased towards the superficial cells. Phagosomes containing latex spheres and reaction product of acid phosphatase were observed mainly in the centrospheral region of the superficial and intermediate epithelial cells. Acid phosphatase activity in phagocytising cells was not increased as compared to that in non-phagocytising cells. The observations indicate that existing acid phosphatase in unstimulated conjunctival epithelial cells is released into heterophagosomes brought within the lysosomal compartment. The number of secondary phagosomes seems to be increased by intercellular transport of latex spheres to the acid phosphatase rich cells in the deep layers of the epithelium.     

Scanning electron microscopy of isolated epithelium of the murine gastrointestinal tract: morphology of the basal surface and evidence for paracrinelike cells

By using the method of Bjerknes and Cheng, isolated murine gastrointestinal epithelial sheets were prepared for scanning electron microscopy. Examination of isolated epithelium from fundic stomach revealed numerous branched gastric glands. Parietal cells were easily detected bulging from the basal surface of the glandular epithelium. The basal surface membrane of parietal cells appeared smooth, with only sparse microvilluslike projections, whereas adjacent glandular cells had numerous 1- to 2-micron fingerlike projections which interdigitated laterally with similar processes from adjacent cells. Occasionally, paracrinelike cells having long cytoplasmic processes ranging from 10 to 20 micron in length were observed on the basal epithelial surface of the stomach and the colon, but not the small intestine. In isolated intestinal epithelia, the basal surface of crypt epithelial cells showed extensive cytoplasmic interdigitations, but no distinct morphology permitting recognition of individual cell types. Various stages of intestinal crypt bifurcation were seen. Craterlike spaces in the basal surface of crypt epithelium, presumably due to migrating leukocytes, were also numerous. Examination of the luminal surface of the isolated intestinal epithelium revealed that intimate associations between epithelium and mucosal-associated microorganisms were maintained, thus suggesting that minimal alterations in surface morphology were incurred by epithelial isolation. These observations on epithelial structure suggest that isolated gastrointestinal epithelia may be well suited for physiological studies of epithelial function and interactions with the microbial flora.     

Cell differentiation lineage in the prostate

Prostatic epithelium consists mainly of luminal and basal cells, which are presumed to differentiate from common progenitor/stem cells. We hypothesize that progenitor/stem cells are highly concentrated in the embryonic urogenital sinus epithelium from which prostatic epithelial buds develop. We further hypothesize that these epithelial progenitor/stem cells are also present within the basal compartment of adult prostatic epithelium and that the spectrum of differentiation markers of embryonic and adult progenitor/stem cells will be similar. The present study demonstrates that the majority of cells in embryonic urogenital sinus epithelium and developing prostatic epithelium (rat, mouse, and human) co-expressed luminal cytokeratins 8 and 18 (CK8, CK18), the basal cell cytokeratins (CK14, CK5), p63, and the so-called transitional or intermediate cell markers, cytokeratin 19 (CK19) and glutathione-S-transferase-pi (GSTpi). The majority of luminal cells in adult rodent and human prostates only expressed luminal markers (CK8, CK18), while the basal epithelial cell compartment contained several distinct subpopulations. In the adult prostate, the predominant basal epithelial subpopulation expressed the classical basal cell markers (CK5, CK14, p63) as well as CK19 and GSTpi. However, a small fraction of adult prostatic basal epithelial cells co-expressed the full spectrum of basal and luminal epithelial cell markers (CK5, CK14, CK8, CK18, CK19, p63, GSTpi). This adult prostatic basal epithelial cell subpopulation, thus, exhibited a cell differentiation marker profile similar to that expressed in embryonic urogenital sinus epithelium. These rare adult prostatic basal epithelial cells are proposed to be the progenitor/stem cell population. Thus, we propose that at all stages (embryonic to adult) prostatic epithelial progenitor/stem cells maintain a differentiation marker profile similar to that of the original embryonic progenitor of the prostate, namely urogenital sinus epithelium. Adult progenitor/stem cells co-express both luminal cell, basal cell, and intermediate cell markers. These progenitor/stem cells differentiate into mature luminal cells by maintaining CK8 and CK18, and losing all other makers. Progenitor/stem cells also give rise to mature basal cells by maintaining CK5, CK14, p63, CK19, and GSTpi and losing K8 and K18. Thus, adult prostate basal and luminal cells are proposed to be derived from a common pleuripotent progenitor/stem cell in the basal compartment that maintains its embryonic profile of differentiation markers from embryonic to adult stages.     

Alkaline phosphatase activity of the IVth ventricular choroidal epithelium of rats during embryonic and neonatal development

The cytochemical localization of alkaline phosphatase (AlPase) activity in the developing IVth ventricular choroidal epithelium was investigated in embryonic and neonatal rats. During the initial development of the choroidal primodium the flattened and/or cuboidal epithelial cells of the ventricular roof were changed to columnar cells with well-developed microvilli and apical tight junctions. When compared to AlPase activity on the lateral plasma membranes of the surrounding ependymal cells, these columnar cells of the choroidal primodium revealed activity on the lateral and luminal plasma membranes, but no activity was found on the basal surface of these cells. On the other hand, the epithelial cells in the neonatal choroid plexus showed a continuous morphological alteration from columnar cells with short microvilli to mature cuboidal cells with numerous long microvilli. AlPase activity in immature columnar cells was observed on all plasma membranes, except for the apical junctional area of the lateral surface. With maturing of the choroidal epithelial cells, the activity appeared to be eliminated from the lateral and luminal plasma membranes of the cuboidal cells, and mature choroidal epithelial cells showed activity on the basal surface only. These findings suggest that AlPase may play an important role in the membrane activity of epithelial cells differentiating between the primitive epithelial cells of the ventricular roof and the mature choroidal epithelial cells.     

Differentiation of epithelial cells in the urinary tract

Uroplakins, cytokeratins and the apical plasma membrane were studied in the epithelia of mouse urinary tract. In the simple epithelium covering the inner medulla of the renal pelvis, no uroplakins or cytokeratin 20 were detected and cells had microvilli on their apical surface. The epithelium covering the inner band of the outer medulla became pseudostratified, with the upper layer consisting of large cells with stalks connecting them to the basal lamina. Uroplakins and cytokeratin 20 were not expressed in these cells. However, some superficial cells appeared without connections to the basal lamina; these cells expressed uroplakins Ia, Ib, II and III and cytokeratin 20, they contained sparse small uroplakin-positive cytoplasmic vesicles and their apical surface showed both microvilli and ridges. Cytokeratin 20 was seen as dots in the cytoplasm. This epithelium therefore showed partial urothelial differentiation. The epithelium covering the outer band of the outer medulla gradually changed from a two-layered to a three-layered urothelium with typical umbrella cells that contained all four uroplakins. Cytokeratin 20 was organized into a complex network. The epithelium possessed an asymmetric unit membrane at the apical cell surface and fusiform vesicles. Umbrella cells were also observed in the ureter and urinary bladder. In males and females, the urothelium ended in the bladder neck and was continued by a non-keratinized stratified epithelium in the urethra in which no urothelial cell differentiation markers were detected. We thus show here the expression, distribution and organization of specific proteins associated with the various cell types in the urinary tract epithelium.W. Mello Jr. thanks FAPESP, São Paulo, Brazil for financial support.     

Ultrastructural organization of the hamster renal pelvis.

The renal pelvis of the hamster has been studied by light microscopy (epoxy resin sections), transmission electron microscopy, and morphometric analysis of electron micrographs. Three morphologically distinct epithelia line the pelvis, and each covers a different zone of the kidney. A thin epithelium covering the outer medulla (OM) consists of two cell types: (1) granular cells are most numerous and have apically positioned granules which stain intensely with toluidine blue, are membrane-bound, and contain a fine particulate matter that stains light grey to black in electron micrographs. (2) Basal cells do not have granules, are confined to the basal lamina region, and do not reach the mucosal epithelial surface. The inner medulla (IM) is covered by a pelvic epithelium morphologically similar to collecting duct epithelium of IM. Some cells in this portion of the pelvic epithelium (IM) stain intensely dark with toluidine blue, osmium tetroxide, lead, and uranyl acetate. Transitional epithelium, which separates cortex (C) from pelvic urine, has an asymmetric luminal plasma membrane and discoid vesicles, each of which is similar to those previously observed in mammalian ureter and urinary bladder epithelia. Based on morphological comparisons with other epithelia, the IM and OM pelvic epithelia would appear permeable to solutes and/or water, while the transitional epithelium covering the C appears relatively impermeable. It would also appear that the exchange of solutes and water between pelvic urine and OM would involve capillaries, primarily, since morphometric analysis showed that both fenestrated and continuous capillaries of the OM were extremely abundant (greater than 60% of OM pelvic surface area) just under the thin pelvic epithelium.     

The isolation and characterization in vitro of normal epithelial cells,endothelial cells and fibroblasts from rat urinary bladder

Epithelial cells, microvascular endothelial cells, and fibroblasts have been isolated in culture from normal urinary bladders of Fischer rats. Normal epithelial cells were cultured most efficiently when transitional epithelial sheets were plated on to collagen-coated roller flasks. The epithelial sheets were obtained by two micro-dissection techniques. In the first method, the epithelium was peeled as a large coherent sheet from the submucosal connective tissue following subepithelial injection of a collagenase solution, and after incubation of the bladders in the same enzyme solution. Epithelial sheets with intact basal cell layers were essential for culture success. On collagenous matrices, epithelial differentiation was similar to that in vivo. The in vitro transitional epithelium was composed of three cell layers, namely superficial, intermediate, and basal cells. Basal cells were attached to newly synthesized basal lamina by means of hemidesmosomes. Superficial cells were sealed at their apical lateral membranes by a junctional complex, i.e. a terminal bar. Asymmetric luminal membrane plaques were not apparent. In the second method, the epithelium was separated from the underlying connective tissue after collagenase-trypsin digestion of everted urinary bladders. Although the digest consisted mainly of epithelial cells, these rarely survived the first passage when plated on conventional plastic growth surfaces. After the third culture week, epithelial cells usually died and slowly growing colonies of fibroblasts or large flattened epitheloid cells became apparent. Epitheloid cells were identified by their typical ultrastructure as endothelial cells, showing Weibel-Palade bodies and pinocytotic caveolae. These cells were reactive with antiserum against factor VIII. The free surface of monolayer cultures was non-thrombogenic when incubated in the presence of platelets. Fibroblasts were isolated from heavily contaminated epithelial cell cultures after differential trypsinization. These three cell types represent the normal control cells of an in vitro tumor model for the study of invasiveness. All three cell types are involved in the formation and functional maintenance of the epithelial-stromal junction. The study of cell-cell and cell-matrix interactions may provide important clues for the understanding of tumor invasiveness, a process that starts at the epithelial-stromal junction and proceeds with its destruction.     

Radial gradient culture on the inner surface of collagen tubes: Organoid growth of normal rat bladder and rat bladder cancer cell line NBT-II

Summary Radial histophysiologic gradient culture uses thin walled, permeable collagen tubes to house inocula in the form of either tissue explants, aggregates of cells, or dissociated cells. The outgrowth from these incoula spreads on the inner surface of the cylindrical tube, completely lining the lumen. Metabolites are exchanged through the wall of the collagen tube by diffusion from the pool of medium surrounding the cylinder. Urothelial cells form organoid stratified epithelium. A histophysiologic gradient occurs with the basal surface of the epithelium attached to the collagen wall. At this interface, for normal bladder, the initiation of epithelial renewal is seen in the basal zone, as shown by incorporation of tritiated thymidine. The simulation of conditions in nature is attained by the exchange of metabolites between the pool of medium and the basal zone of the epithelium. NBT-II appears as two concentric stratified epithelia. Isotopic labelling is seen throughout the epithelium attached to the collagen membrane. In the superficial stratified epithelium remnants of nuclei are seen without isotopic labelling. Preparation of living cultures and, after fixation, of histologic sections is technically easy. The work was supported by research grant CA-14137 from the National Bladder Cancer Program of the National Cancer Institute, Bethesda, MD. Editor’s Statement Histiotypic cultures of normal and cancer tissues may develop into an important diagnostic tool that may supplement the information obtained by classical histopathology. These methods also offer the possibility of probing the mechanism of genesis and maintenance of tissue architecture. Gordon H. Sato     

Immunohistochemical studies of the distribution of a basolateral-membrane protein in intestinal epithelial cells (GZ1-Ag) in rats using monoclonal antibodies

Summary The monoclonal antibody (mAb), GZ1, is specific for a 42-kilodalton (kD) protein (designated GZ1-Ag) present among the plasma membrane (PM) proteins of the absorptive cells of rat intestine. This protein only occurs in the basolateral PM and is absent from the microvillus membrane. GZ2 and GZ20 are two other mAbs that are also directed against GZ1-Ag but which specify other antigenic determinants of this protein than mAb GZ1. Used together, these three mAbs allow better characterization of GZ1-Ag and more precise investigation of its distribution and localization in various rat cells. We performed immunohistochemical labelling for GZ1-Ag at both the light-and electron-microscope levels and found that GZ1-Ag is extensively distributed in rat epithelial tissues. However, the amount of this protein present in epithelial tissue shows considerable variation. GZ1-Ag is not present in the secretory cells of terminal portions of most excretory glands or in cells of the endocrine glands and liver. The cells of kidney tubules, except for collecting tubules, also lack GZ1-Ag. Only small amounts of GZ1-Ag are present in the cells of the stratified squamous epithelium and transitional epithelium, the exception being superficial cells. High concentrations of GZ1-Ag occur in the excretory duct systems of glands and in the various kinds of epithelium present in the male and female genital tract. Our results also indicated that the GZ1-Ag in all of these cells has a very similar structure. In all cells, GZ1-Ag is localized in the PM, but it is present throughout the entire PM only in the cells of the stratified squamous epithelium and in the basal and intermediate cells of the transitional epithelium. In all epithelial cells bordering directly on the lumen, it is only present in the basolateral part of the PM, being absent from the luminal PM.     

Electron microscopic cytochemical localization of adenylate cyclase in amphibian urinary bladder epithelium: effects of antidiuretic hormone

A cytochemical technique for electron microscopic localization of adenylate cyclase was used to identify this enzyme in quiescent and hormone-stimulated toad urinary bladder epithelium. In the absence of vasopressin (antidiuretic hormone), adenylate cyclase was detected along the outer surface of the basolateral plasma membranes of granular cells, mitochondria-rich cells, and basal cells, the major cell types comprising the hormone-sensitive urinary epithelium. In the presence of antidiuretic hormone, the basolateral precipitates were markedly increased. The latter was true for both tissues incubated in the presence of an osmotic gradient and those stimulated in the absence of such a gradient. A significant mucosal reaction was never seen. Such data indicate that the hormone receptors for vasopressin are located along the basolateral membranes of all epithelial cells comprising the mucosal hormone-sensitive epithelium. All cells of the epithelium also demonstrate a vasopressin-sensitive adenylate cyclase. We discuss possible mechanisms that attempt to integrate the cytochemical data into an overall scheme for the physiological action of this hormone on amphibian urinary bladder.