THE FINE STRUCTURE OF THE TRANSITIONAL EPITHELIUM OF RAT URETER

The fine structure of the transitional epithelium of rat ureter has been studied in thin sections with the electron microscope, including some stained cytochemically to show nucleoside triphosphatase activity. The epithelium is three to four cells deep with cuboidal or columnar basal cells, intermediate cells, and superficial squamous cells. The basal cells are attached by half desmosomes, or attachment plates, on their basal membranes to a basement membrane which separates the epithelium from the lamina propria. Fine extracellular fibres, ca. 100 A in diameter, are to be found in the connective tissue layer immediately below the basement membrane of this epithelium. The plasma membranes of the basal and intermediate cells and the lateral and basal membranes of the squamous cells are deeply interdigitated, and nucleoside triphosphatase activity is associated with them. All the cells have a dense feltwork of tonofilaments which ramify throughout the cytoplasm. The existence of junctional complexes, comprising a zonula occludens, zonula adhaerens, and macula adhaerens or desmosome, between the lateral borders of the squamous cells is reported. It is suggested that this complex is the major obstacle to the free flow of water from the extracellular spaces into the hypertonic urine. The free luminal surface of the squamous cells and many cytoplasmic vesicles in these cells are bounded by an unusually thick plasma membrane. The three leaflets of this unit membrane are asymmetric, with the outer one about twice as thick as the innermost one. The vesicles and the plasma membrane maintain angular conformations which suggest the membrane to be unusually rigid. No nucleoside triphosphatase activity is associated with this membrane. Arguments are presented to support a suggestion that this thick plasma membrane is the morphological site of a passive permeability barrier to water flow across the cells, and that keratin may be included in the membrane structure. The possible origin of the thick plasma membrane in the Golgi complex is discussed. Bodies with heterogeneous contents, including characteristic hexagonally packed stacks of thick membranes, are described. It is suggested that these are "disposal units" for old or surplus thick membrane. A cell type is described, which forms only 0.1 to 0.5 per cent of the total cell population and contains bundles of tubular fibres or crystallites. Their origin and function are not known.     

小鼠膀胱上皮的中间层细胞中存在Uroplakins

本文运用超薄切片、冰冻蚀刻及免疫胶体金标记等多种电镜技术并结合免疫组化、免疫荧光染色技术,直观地显示出小鼠膀胱上皮的中间层细胞存在Uroplakins,并在梭形泡膜上形成了与表层细胞类似的AUM结构,而且梭形泡的AUM结构也结合在中间纤维上。蛋白质免疫印迹反应进一步证实中间层细胞含有与表层细胞相同的Uroplakin Ⅰ和UroplakinⅢ等AUM蛋白的主要成份,从而为AUM的发生及其与细胞分化关系的研究提供了重要的实验证据。     

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.     

LUMENAL PLASMA MEMBRANE OF THE URINARY BLADDER : I. Three-Dimensional Reconstruction from Freeze-Etch Images

To determine the three-dimensional structure of the lumenal membrane of transitional epithelium, a study was made of sectioned, negatively stained, and freeze-etched specimens from intact epithelium and membrane fractions from rabbit urinary bladder. Particulate membrane components are confined to plaque regions within which the unit membrane is asymmetric, having a thicker outer leaflet. Transversely fractured freeze-etched plaques display a thick (~80 A), particulate lumenal leaflet and a thin (~40 A) cytoplasmic one. Four different faces of the two leaflets can be distinguished: two complementary, split, inner membrane faces exposed by freeze-cleaving the bilayer and two external (lumenal and cytoplasmic) membrane surfaces revealed by deep-etching. On the split, inner face of the lumenal leaflet appear polygonal plaques of hexagonally arranged particles. These fit into holes observed on the complementary, split, innerface of the cytoplasmic leaflet. The particles, which have a center-to-center spacing of ~160 A, also seem to protrude from the external surface of the lumenal leaflet, where their subunits (~50 A in diameter) are revealed by freeze-etching and negative staining. The plaques are separated from each other by smooth-surfaced regions, which cleave like simple lipid bilayers. Since the array of plaque particles covers only ~73% of the membrane surface area, whereas 27% is taken up by particle-free interplaque regions, the presence of particles cannot in itself entirely account for the permeability barrier of the lumenal membrane. Although no particles are observed protruding from the cytoplasmic surface of the membrane, cytoplasmic filaments are attached to it by short, cross-bridge-like filaments that seem to contact the particles within the membrane. These long cytoplasmic filaments cross-link adjacent plaques. Therefore, we suggest that at least one function of the particles is to serve as anchoring sites for cytoplasmic filaments, which limit the expansion of the lumenal membrane during distention of the bladder, thereby preventing it from rupturing. The particle-free interplaque regions probably function as hinge areas between the stiff plaques, allowing the membrane to fold up when the bladder is contracted.     

THE ANATOMIC SITE OF THE TRANSEPITHELIAL PERMEABILITY BARRIERS OF TOAD BLADDER

An examination of the mucosal epithelium of the urinary bladder of the toad reveals that the two major cell types which abut on the urinary surface, the granular and mitochondria-rich cells, also contact the basement membrane. Thus, the epithelium functions as a single cell layer. Although basal cells are interpolated between the granular cells and the basement membrane over a large portion of the epithelium, they do not constitute an additional continuous cell layer. This finding is consistent with extensive physiological data which had assumed that the major permeability barriers of this epithelium were the apical and basal-lateral plasma membranes of a single layer of cells.     

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.     

INDUCTION OF CELL PROLIFERATION IN THE MOUSE BLADDER BY 4-ETHYLSULPHONYL-NAPHTHALENE-1 -SULPHONAMIDE

The reaction of the bladder epithelium of mice, following stimulation with a carcinogen, 4-ethylsulphonylnaphthalene-1-sulphonamide (ENS), was studied. A wave of cell division was induced in the resting epithelium, diploid and tetraploid cells being the main dividing elements; some of the high ploidy surface cells also underwent division. The cell cycle time for the diploid and tetraploid cells appeared to be identical. There was considerable variation in the intensity and timing of the onset of cell division in the bladder epithelium of individual animals. ENS caused severe damage to the surface cells of the bladder epithelium as indicated by increased lysosomes and the formation of large vacuoles.     

THE FINE STRUCTURE OF THE GALL BLADDER EPITHELIUM OF THE MOUSE

Sections of mouse gall bladder epithelium fixed by perfusion with buffered osmium tetroxide have been studied in the electron microscope as an example of simple columnar epithelium. The free surface presents many microvilli, each presenting a dense tip, the capitulum, and displaying a radiating corona of delicate filaments, the antennulae microvillares. Very small pit-like depressions, representing caveolae intracellulares, are encountered along the cell membrane of the microvilli. The free cell surface between microvilli shows larger cave-like depressions, likewise representing caveolae intracellulares, containing a dense material. The lateral cell borders are extensively folded into pleats, which do not interdigitate extensively with corresponding folds of the adjacent cell membrane. The terminal bars are shown to consist of thickened densities of the cell membrane itself in the region of insertion of the lateral cell wall with the free cell surface. This thickening is associated with an accumulation of dense cytoplasmic material in the immediate vicinity. The terminal bar is thus largely a cytoplasmic and cell membrane structure, rather than being primarily intercellular in nature. The basal cell membrane is relatively straight except for a conical eminence near the center of the cell, projecting slightly into the underlying tunica propria. The basal cell membrane itself is overlain by a delicate limiting membrane, which does not follow the lateral contours of the cell. Unmyelinated intercellular nerve terminals with synaptic vesicles have been encountered between the lateral walls of epithelial cells. A division of the gall bladder epithelial cell into five zones according to Ferner has been found to be convenient for this study. The following cytoplasmic components have been noted, and their distribution and appearance described: dense absorption granules, mitochondria, Golgi or agranular membranes, endoplasmic reticulum or ergastoplasm, ring figures, and irregular dense bodies, perhaps lipoid in nature. The nucleus of these cells is also described.     

大鼠体内气管损伤修复过程及气管干细胞的定位研究

目的观察大鼠体内气管损伤修复过程,进行气管干细胞的定位.方法应用氟尿嘧啶(5-FU)诱发在体气管上皮损伤,动态观察修复过程;对损伤后气管上皮细胞行Hoechst33342荧光染色,并用RT-PCR法检测ABC转运蛋白ABCG2/bcrp1基因.结果1.5-FU作用30min后大鼠气管上皮细胞绝大部分脱落,可见少量间隔分布的类似裸核的细胞呈钉状位于基底膜上,免疫组化检测增殖细胞核抗原阴性,证明为G0期细胞.其中部分细胞Hoechst33342染色阴性,为侧群(side population,SP)细胞.2.将5-FU 去除3-6h后,上皮细胞形态变为扁平,9-12h 后细胞变为立方,细胞数目逐渐增多,24h上皮细胞数更多,连接成片,可见纤毛,48h 接近恢复假复层纤毛柱状上皮.3.RT-PCR检测ABCG2/Bcrp1阳性反应产物长度为272bp.结论5-FU打击后,残余的G0期气管上皮细胞中含有干细胞.     

A COMPARATIVE STUDY OF THE ULTRASTRUCTURE OF MICROVILLI IN THE EPITHELIUM OF SMALL AND LARGE INTESTINE OF MICE

A comparative analysis of the fine structure of the microvilli on jejunal and colonic epithelial cells of the mouse intestine has been made. The microvilli in these two locations demonstrate a remarkably similar fine structure with respect to the thickness of the plasma membrane, the extent of the filament-free zone, and the characteristics of the microfilaments situated within the microvillous core. Some of the core microfilaments appear to continue across the plasma membrane limiting the tip of the microvillus. The main difference between the microvilli of small intestine and colon is in the extent and organization of the surface coat. In the small intestine, in addition to the commonly observed thin surface "fuzz," occasional areas of the jejunal villus show a more conspicuous surface coat covering the tips of the microvilli. Evidence has been put forward which indicates that the surface coat is an integral part of the epithelial cells. In contrast to the jejunal epithelium, the colonic epithelium is endowed with a thicker surface coat. Variations in the organization of the surface coat at different levels of the colonic crypts have also been noted. The functional significance of these variations in the surface coat is discussed.     

SOME FEATURES OF THE SUBMICROSCOPIC MORPHOLOGY OF SYNAPSES IN FROG AND EARTHWORM

Electron micrographs are presented of synaptic regions encountered in sections of frog sympathetic ganglia and earthworm nerve cord neuropile. Pre- and postsynaptic neuronal elements each appear to have a membrane 70 to 100 A thick, separated from each other over the synaptic area by an intermembranal space 100 to 150 A across. A granular or vesicular component, here designated the synaptic vesicles, is encountered on the presynaptic side of the synapse and consists of numerous oval or spherical bodies 200 to 500 A in diameter, with dense circumferences and lighter centers. Synaptic vesicles are encountered in close relationship to the synaptic membrane. In the earthworm neuropile elongated vesicles are found extending through perforations or gaps in the presynaptic membrane, with portions of vesicles appearing in the intermembranal space. Mitochondria are encountered in the vicinity of the synapse, and in the frog, a submicroscopic filamentary component can be seen in the presynaptic member extending up to the region where the vesicles are found, but terminating short of the synapse itself.     

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.     

ULTRASTRUCTURE OF THE LAMELLAE AND GRANA IN THE CHLOROPLASTS OF ZEA MAYS L

The fine structure of the chloroplasts of maize (Zea mays L.) has been investigated by electron microscopic examination of ultrathin sections of leaves fixed in buffered osmium tetroxide solutions. Both the parenchyma sheath and mesophyll chloroplasts contain a system of densely staining lamellae about 125 A thick immersed in a finely granular matrix material (the stroma), and are bounded by a thin limiting membrane which often appears as a double structure. In the parenchyma sheath chloroplasts, the lamellae usually extend the full width of the disc-shaped plastids, and grana are absent. The mesophyll chloroplasts, however, contain numerous grana of a fairly regular cylindrical form. These consist of highly ordered stacks of dense lamellae, the interlamellar spacing being ca. 125 A. The grana are interlinked by a system of lamellae (intergrana lamellae) which are on the average about one-half as numerous as the lamellae within the grana. In general, this appears to be due to a bifurcation of the lamellae at the periphery of the granum, but more complex interrelationships have been observed. The lamellae of the parenchyma sheath chloroplasts and those of both the grana and intergrana regions of the mesophyll chloroplasts exhibit a compound structure when oriented normally to the plane of the section. A central exceptionally dense line (ca. 35 A thick) designated the P zone is interposed between two less dense layers (the L zones, ca. 45 A thick), the outer borders of which are defined by thin dense lines (the C zones). Within the grana, the C zones, by virtue of their close apposition, give rise to thin dense intermediate lines (I zones) situated midway between adjacent P zones. A model of the lamellar structure is proposed in which mixed lipide layers (L zones) are linked to a protein layer (P zone) by non-polar interaction. Chlorophyll is distributed over the entire lamellar surface and held in the structure by van der Waals interaction of the phytol "tail" with the hydrocarbon moieties of the mixed lipide layers. The evidence in favour of the model is briefly discussed.     

RENEWAL OF GLYCEROL IN THE VISUAL CELLS AND PIGMENT EPITHELIUM OF THE FROG RETINA

The renewal of glycerol in the visual cells and pigment epithelium of the frog retina was studied by autoradiographic analysis of animals injected with [2-³H]glycerol. Assay of chloroform:methanol extracts showed that the labeled precursor was used mainly in lipid synthesis, although there was also some utilization in the formation of protein. Radioactive glycerol was initially concentrated in the myoid portion of rods and cones, indicating that this is the site of phospholipid synthesis in visual cells. The glycogen bodies (paraboloids) of accessory cones were also heavily labeled, suggesting the diversion of some glycerol into glycogenic pathways. In the pigment epithelium, only the oil droplets became significantly radioactive. The outer plexiform layer (which contains the visual cell synaptic bodies) and the cone oil droplets gradually accumulated considerable amounts of labeled material. Within 1–4 h, labeled molecules began to appear in the visual cell outer segments, evidently having been transported there from the myoid portion of the inner segment. Most of these were phospholipid molecules which became distributed throughout the outer segments, presumably replacing comparable constituents in existing membranes. In rods only, there was also an aggregation of labeled material at the base of the outer segment due to membrane biogenesis. These highly radioactive membranes, containing labeled molecules of lipid and protein, were subsequently displaced along the rod outer segments due to repeated membrane assembly at the base. The distribution of radioactivity supported the conclusion that membrane renewal by molecular replacement is more rapid for lipid than it is for protein.     

黄鳝的泌尿系统及其功能

黄鳝腹腔左侧有盲端的中空管状结构,不是退化性腺,而是十分特化的长管囊膀胱。膀胱内壁具大量发达的绒毛,绒毛表面是移行上皮。在绒毛内部或基部有丰富的血管,因此该管囊膀胱不仅可贮存尿液,而且可能对水分等有重吸收作用。在中肾管与膀胱相接处,膀胱腔背侧出现一条明显的纵行皱襞,即在其横切面上观为巨绒毛。巨绒毛形成的原因,主要是中肾管移入膀胱壁所致。中肾管在巨绒毛内移行一程后才开口于膀胱。因此,黄鳝的生殖腺不是一对,而是一个,位于腹腔右侧。黄鳝肾脏细长,呈“丫”,在腹腔背侧,紧贴脊椎。前端为头肾,无肾单位,仅是造血器官。中肾有类似于哺乳类的肾小体,但数量较少,主要分布在肾脏周缘。肾小管包括颈段、初级近曲小管、次级近曲小管、初级远曲小管和次级远曲小管。两中肾管位于两肾叶腹内侧,其上皮间或是假复层柱状上皮,间或是移行上皮。前者含有许多杯状细胞,并可见到顶浆分泌的现象。中肾的肾小管间组织是大量的红细胞样组织,头肾似具有贮存或释放刚成熟的红细胞的组织结构,因此黄鳝肾脏可能是体内主要的造血器官。     

AN ELECTRON MICROSCOPE STUDY OF THE EPITHELIUM IN THE NORMAL MATURE AND IMMATURE MOUSE CORNEA

1. An electron microscope study at high resolution of the corneal epithelium of the normal mature and immature mouse revealed new information regarding the submicroscopic appearance of these cells. 2. Two thin dense lines separated by a less dense area constituted the structure of the limiting surface membrane of epithelial cells; the thickness of this membrane was about 80 A. 3. Some differences in the appearance of the cytoplasm and mitochondria of cells from the immature mouse cornea and the appearance of the cytoplasm and mitochondria of cells from the adult mouse cornea were observed. 4. The basement membrane appeared as a dense band about 600 A wide separating the basal epithelial cells from the substantia propria. Suggestions of periodicity were seen in some phosphotungstic acid-treated specimens. 5. Round bodies believed to be bacteria were seen on the surface of the outer epithelial cells in the adult mouse cornea but not in the immature, unopened eye.     

ELECTRON MICROSCOPY OF THE UTERINE EPITHELIUM IN THE RABBIT

The ultrastructure of the uterine epithelium has been studied in estrous, ovariectomized, pregnant, and pseudopregnant rabbits. Tissue for light microscopy was fixed in Bouin''s solution and stained with hematoxylin and eosin, by the periodic acid-Schiff (PAS) method, and with methylene blue. Tissue for electron microscopy was fixed in 1 per cent osmium tetroxide in White''s saline and embedded in Araldite. The uterine epithelium in estrus is comprised of ciliated and non-ciliated cells. After ovariectomy the epithelium becomes reduced in height and PAS-positive material disappears. Multinucleated cells are formed in the epithelium in pregnancy, pseudopregnancy, and in the non-pregnant horn in unilateral pregnancy. They degenerate during the 3rd week of pseudopregnancy and during the 4th week of pregnancy in the non-pregnant horn. The formation of multinucleated cells is believed to be under hormonal control. The uterine epithelium in contact with the blastocyst changes into a "symplasma," presumably under the influence of a local (chemical?) effect produced by the blastocyst. This change is not seen in pseudopregnancy nor in the non-pregnant horn in unilateral pregnancy. A complex infolding of the basal cell membrane of the epithelium accompanies the "symplasmic" change. The remaining uterine epithelium in pregnancy shows a well developed ergastoplasm suggesting a production of secretion materials, some of which may be available for absorption by the fetus through the yolk sac or paraplacental chorion.     

层粘连蛋白在正常和异常人滋养上皮的不同定位与功能

从正常人不同发育时期, 不明原因流产, 增殖型和侵蚀型葡萄胎滋养细胞角度, 用免疫组织化学方法观察层粘连蛋白（ＬＮ） 的显微定位, 比较研究其不同定位与滋养上皮增殖, 生长, 分化, 凋亡, 迁移和浸润的关系。结果显示： 正常人不同发育时期, ＬＮ主要在早孕滋养细胞基底膜呈阳性着色, 中期无合体结处滋养细胞基底膜呈阳性着色; 不明原因流产,ＬＮ在合体滋养细胞质和顶尖部呈阳性着色; ＬＮ 在增殖型葡萄胎滋养细胞接触处呈阳性着色; ＬＮ 在侵蚀型葡萄胎滋养细胞膜呈阳性着色。提示：ＬＮ基底膜定位与滋养细胞分化和迁移密切相关,ＬＮ 胞膜定位与滋养上皮侵蚀密切相关,ＬＮ 细胞接触处定位与滋养细胞增殖可能相关, ＬＮ 胞质和顶尖部定位与滋养细胞凋亡可能相关, ＬＮ阴性着色与合体结和足月滋养细胞衰老可能无关     

THE EFFECT OF SMOOTH MUSCLE ON THE INTERCELLULAR SPACES IN TOAD URINARY BLADDER

Phase microscopy of toad urinary bladder has demonstrated that vasopressin can cause an enlargement of the epithelial intercellular spaces under conditions of no net transfer of water or sodium. The suggestion that this phenomenon is linked to the hormone's action as a smooth muscle relaxant has been tested and verified with the use of other agents effecting smooth muscle: atropine and adenine compounds (relaxants), K⁺ and acetylcholine (contractants). Furthermore, it was possible to reduce the size and number of intercellular spaces, relative to a control, while increasing the rate of osmotic water flow. A method for quantifying these results has been developed and shows that they are, indeed, significant. It is concluded, therefore, that the configuration of intercellular spaces is not a reliable index of water flow across this epithelium and that such a morphologic-physiologic relationship is tenuous in any epithelium supported by a submucosa rich in smooth muscle.