Studies on the development and maintenance of epithelial cell surface polarity with monoclonal antibodies

We examined epithelial cell surface polarity in subconfluent and confluent Madin-Darby canine kidney (MDCK) cells with monoclonal antibodies directed against plasma membrane glycoproteins of 35,000, 50,000, and 60,000 mol wt. The cell surface distribution of these glycoproteins was studied by immunofluorescence and immunoelectron microscopy. At the ultrastructural level, the electron-dense reaction product localizing all three glycoproteins was determined to be uniformly distributed over the apical and basal cell surfaces of subconfluent MDCK cells as well as on the lateral surfaces between contacted cells; however, after formation of a confluent monolayer, these glycoproteins could only be localized on the basal-lateral plasma membrane. The development of cell surface polarity was followed by assessing glycoprotein distribution with immunofluorescence microscopy at selected time intervals during growth of MDCK cells to form a confluent monolayer. These results were correlated with transepithelial electrical resistance measurements of tight junction permeability and it was determined by immunofluorescence that polarized distributions of cell surface glycoproteins were established just after electrical resistance could be detected, but before the development of maximal resistance. Our observations provide evidence that intact tight junctions are required for the establishment of the apical and basal- lateral plasma membrane domains and that development of epithelial cell surface polarity is a continuous process.     

Ultrastructure of Mature Embryos in the Parasitic Flowering PlantCuscuta japonica

The ultrastructural features of embryos were studied from mature dry and soaked seeds of the parasitic angiospermCuscuta japonica. Outer tangential walls in the protoderm cells were thickened and covered by a thin cuticle layer. These walls could play important roles in preventing water loss from theCuscuta seedling surfaces after germination and in strengthening the surfaces against various environmental stresses. In the protoderm cells of soaked embryos, lipid materials were released into the thick outer walls through the fusion of lipid bodies with the plasma membrane. In the dry embryos were stored a large number of protein bodies with globoid crystals and lipid bodies. Numerous lipid bodies also were aligned under the plasma membrane. In both dry and soaked embryos, protein bodies were digested and transformed into small vacuoles. The degraded reserves of the lipid and protein bodies could then be mobilized to nourish subsequent germination and seedling growth. Proplastids in the soaked embryo cells contained a few thylakoids and electron-dense plastoglobuli, and crystallized phytoferritin. The phytoferritin, an iron-protein complex, would also be utilized in chloroplast development for autotrophic seedling growth.     

Ultrastructural morphometric studies of myocardial cells of rats after 3 hour autolysis with and without preliminary short term physical exertion

The influence of a period of 3 h of autolysis on the ultrastructure of the heart muscle cells of 2 groups of rats was examined. One group was undergone 5 h of swimming training and the other remains without such training. The results indicate that some ultrastructural changes caused by the exercise are the same even after 3 h of autolysis. On the other hand, swimming training before autolysis affects the process of autolysis.     

Evidence for an interaction between the cell surface and intermediate filaments in cultured fibroblasts

Intermediate filaments (IF) were found in close proximity to the plasma membrane in substrate attached baby hamster kidney cells (BHK-21) and chick embryo fibroblasts (CEF) as well as cells removed from their substrate in the absence of trypsin. However, in cells removed with trypsin, it appeared that IF had retracted away from the membrane. In cells with abundant extracellular matrix (ECM), colchicine induced massive cables of IF, which appeared to interact with specialized areas of the inner plasma membrane. In cells lysed to extract most microfilaments and cytoplasmic constituents, the intact IF network which remained was closely associated with the ECM. From these ultrastructural observations it was concluded that IF interact in some way with a "cell membrane complex" defined as comprising the plasma membrane and molecules attached to its inner and outer surfaces. In order to investigate the possibility that components of the membrane complex may co-isolate with IF, native intermediate filaments (NIF) were prepared. In addition to the structural subunits and other associated polypeptides, a approximately 220 kd species which reacted specifically with antibodies directed against the ECM protein fibronectin (FN) was observed; 220 kd was still present after NIF were isolated under pH conditions where FN is more soluble, suggesting that its presence was not simply due to the coprecipitation of two insoluble proteins. Immunofluorescence and immunogold localization confirmed that FN is a component of the cell membrane complex with which IF appeared to interact.     

Receptor mediated endocytosis of N-acetylglucosamine and mannose exposing molecules by cultured chick embryo hepatocytes.

We studied the receptor mediated endocytosis of a modified glycoprotein (N-acetylglucosamine-BSA) and mannan in cultured hepatocytes isolated from 19-days-old embryos. The binding sites for molecules exposing terminal N-acetylglucosamine (GlcNac) and mannose residues were localized and quantified at the ultrastructural level by means of protein-gold complexes. The binding sites were found to be randomly distributed as single gold particles on cultured hepatocyte cell surfaces not restricted to specialized areas of the plasma membrane. The gold ligands were internalized following a receptor mediated pathway, which was studied at different interval times (15, 30 and 60 min.) after incubating the cells with the electron dense markers.     

Effect of phosphatidylinositol and inside-out erythrocyte vesicles on autolysis of mu- and m-calpain from bovine skeletal muscle

The finding that phospholipid micelles lowered the Ca2+ concentration required for autolysis of the calpains led to a hypothesis suggesting that the calpains are translocated to the plasma membrane where they interact with phospholipids to initiate their autolysis. However, the effect of plasma membranes themselves on the Ca2+ concentration required for calpain autolysis has never been reported. Also, if interaction with a membrane lowers the Ca2+ required for autolysis, the membrane-bound-calpain must autolyze itself, because it would be the only calpain having the reduced Ca2+ requirement. This implies that the autolysis is an intramolecular process, although several studies have shown that autolysis of the calpains in an in vitro assay and in the absence of phospholipid is an intermolecular process. Inside-out vesicles prepared from erythrocytes had no effect on the Ca2+ concentration required for autolysis of either mu- or m-calpain, although phosphatidylinositol (PI) decreased the Ca2+ concentration required for autolysis of the same calpains. The presence of a substrate for the calpains, beta-casein, reduced the rate of autolysis of both mu- and m-calpain both in the presence and in the absence of PI, suggesting that mu- and m-calpain autolysis is an intermolecular process in the presence of PI just as it is in its absence. Because IOV have no effect on the Ca2+ concentration required for calpain autolysis, association with the plasma membrane, at least with erythrocyte plasma membranes, does not initiate calpain autolysis by reducing the Ca2+ concentration required for autolysis as suggested by the membrane-activation hypothesis. Interaction with a membrane may serve to bind calpains to their substrates rather than promoting autolysis.     

Biochemical and ultrastructural changes in rat liver plasma membranes after temporary ischemia

In this study we have attempted to correlate reversible and irreversible cell damage induced by in vivo or in vitro ischemia with characteristics of the plasma membranes of liver parenchymal cells, as detected biochemically and ultrastructurally. The effects of in vivo or in vitro ischemia appeared to be similar. It was virtually impossible to isolate a substantial membrane fraction from ischemic livers, probably because of changes in the physical properties of the membranes by ischemia. The isolated membranes of ischemic liver cells show ultrastructural changes including the occurrence of many vesicular profiles and alterations in junctional complexes expressed by extended and smudged electron densities along the lateral surfaces. The microvilli of the bile canaliculi disappeared after only 15 min ischemia and cytoplasmic densities associated with junctional complexes also appeared extended and smudged. These changes correspond with the alterations observed in ischemic isolated membranes. After 30 min in vivo ischemia the activity of 5'-mononucleotidase used as a marker enzyme for plasma membranes, decreased by 75%, whereas the activity of thymidine 5'-phosphodiesterase was reduced only slightly. The changes in these enzyme activities were more prominent after in vitro ischemia than after in vivo. The morphological and biochemical changes observed in rat hepatocyte plasma membrane during the early stage of injury have no value in predicting the occurrence of necrosis in a later phase of the process since profound changes occur in plasma membrane properties after even short periods of ischemia (i.e. during the reversible stage).     

Distribution of insulin binding sites on Leydig cells of rat testes using insulin-coated gold particles

Summary The distribution of insulin binding sites in Leydig cells dispersed with collagenase from rat testes was studied using insulin-coated gold particles as an electron opaque ligand. Using electron microscope is convenient to distinguish Leydig cells among a variety of cells in crude preparations by their ultrastructural characteristics. Leydig cells were shown to possess insulin-binding sites on their plasma membranes. Initial binding sites of insulin were located to the microvillous surfaces. Following binding, receptor-ligand complexes seemed to move to the intermicrovillous plasma membrane, then to be internalized. Two modes of the internalization were confirmed. Most of the receptor-ligand complexes on Leydig cells appeared to be internalized via large, uncoated plasma membrane invaginations, while the remainder became internalized via small pits into vesicles. The receptor-ligand complexes were subsequently transferred to large subsurface vacuoles with electron-lucent lumens believed to correspond to endosomes. The reason why IGCs on the postendosomal pathway moving toward lysosomes was also discussed.     

Distribution of insulin binding sites on Leydig cells of rat testes using insulin-coated gold particles.

The distribution of insulin binding sites in Leydig cells dispersed with collagenase from rat testes was studied using insulin-coated gold particles as an electron opaque ligand. Using electron microscope is convenient to distinguish Leydig cells among a variety of cells in crude preparations by their ultrastructural characteristics. Leydig cells were shown to possess insulin-binding sites on their plasma membranes. Initial binding sites of insulin were located to the microvillous surfaces. Following binding, receptor-ligand complexes seemed to move to the intermicrovillous plasma membrane, then to be internalized. Two modes of the internalization were confirmed. Most of the receptor-ligand complexes on Leydig cells appeared to be internalized via large, uncoated plasma membrane invaginations, while the remainder became internalized via small pits into vesicles. The receptor-ligand complexes were subsequently transferred to large subsurface vacuoles with electron-lucent lumens believed to correspond to endosomes. The reason why IGCs on the postendosomal pathway moving toward lysosomes was also discussed.     

Histochemical and ultrastructural analysis of developing adipocytes in the fetal pig

Histochemical and ultrastructural aspects of adipocyte differentiation in subcutaneous tissue of fetal pigs were analyzed in a longitudinal study. A matrix of collagen fibers surrounding adipocytes developed after the establishment of a distinct and continuous PAS-positive basement membrane. The degree of plasma membrane invagination and specialization was positively correlated with the extent of basement membrane and collagen matrix formation. Close spatial relationships between narrow, smooth endoplasmic reticulum, plasma membrane invaginations, the surface of lipid droplets and mitochondria were observed in differentiating adipocytes. Histochemical and ultrastructural criteria for the identification of preadipocytes are: (1) perivascular location; (2) mitochondria localized in the Golgi zone; (3) cytosolic glycogen; (4) rough endoplasmic reticulum with cisternae uniformly and approximately 600 A wide; (5) free ribosomes and few polysomes, and (6) lipid droplets encased by microfilaments. These criteria permitted clear distinction from obvious fibroblasts and macrophages. Other stromal cells were morphologically abnormal. Occasionally, adipocytes and perivascular cells exhibited close intercellular contacts that were morphologically distinct from intercellular contacts between contiguous endothelial cells.     

Ultrastructural localization of concanavalin A receptors in the plasma membrane: association with underlying actin filaments

Whole-mount cell preparations of cultured rat 3Y1 cells were examined by stereo electron microscopy to identify the ultrastructural localization of concanavalin A (Con A) receptors in the plasma membrane, and to clarify the relationship between Con A receptors and cytoskeletal components. Well spread monolayer cells were extracted with saponin, briefly fixed, and then partially broken open with shearing force to facilitate the introduction of antibodies for identification of actin filaments. Stereo electron microscopy of such treated cells revealed a 3-dimensional image of filamentous structures such as fine filaments, microtubules (MT) and endoplasmic reticulum (ER) in the flattened areas of each cell. Just beneath the plasma membrane were meshworks of actin-containing fine filaments, as identified by an immunogold staining method. Microtubules and ER were observed to be either directly or indirectly associated with this meshwork. The broken open part of each cell exhibited a meshwork of filaments which were associated with the cytoplasmic surface of the plasma membrane. Some of the filaments were connected to the plasma membrane either by their ends or by their lateral surfaces. The localization of Con A receptors was examined by binding colloidal gold-labelled Con A to the surface of fixed, saponin-extracted cells. Virtually all gold particles bound externally at the same membrane sites where intracellular actin filaments attached internally. The observations strongly suggest that the distribution of Con A receptors was regulated by the underlying meshwork of actin filaments.     

Iodination of plasma membrane proteins of BHK cells in different growth states

The surfaces of BHK cells in confluent monolayers, immediately after mechanical dispersal and in logarithmically growing suspension cultures have been iodinated with ¹²⁵I using the lactoperoxidase technique. Electrophoretic resolution of the labeled proteins revealed that the representation of plasma membrane proteins varies with the growth state. Trypsinization of the cells produced a drastic revision of the surfaces leaving behind root fragments of membrane components and exposing additional proteins for iodination. The rapid turnover of membrane proteins in growing BHK cells restored the plasma membrane to a state characteristic of the replicating cell within 10 h.     

Ultrastructural Observations on CTC-Induced Callose Formation in Riella helicophylla

The Ca²⁺-chelator CTC binds to a specific site on both outer surfaces of all non-meristematic cells of the unistratose thallus of Riella, known to be rich in anionic wall components and calcium, and induces there the deposition of callose. Structural changes in this region during prolonged CTC treatment have been followed by light and transmission electron microscopy. With fluorescence microscopy punctate structures can be detected after 10 min, which upon longer incubation in CTC develop into large vesicular bodies, surrounded by a circular structure. The aniline blue-derived fluorescence intensity of these structures is highest in cells of the extension growth zone. At the ultrastructural level a mosaic of numerous smooth-surfaced vesicles, presumably containing callose, initially appears subjacent to the plasma membrane. These vesicles swell and fuse with each other, forming ultimately a circular fusion profile with the plasma membrane. This complex of callose-forming vesicles is thought to develop from elements of the partially coated reticulum (PCR), based on the presence of coated vesiculation profiles on the callose vesicles and numerous aggregates of coated vesicles in their immediate vicinity. After 30 min in CTC osmiophilic particles appear around these callose vesicles and at the cytoplasmic face of mitochondria. They are later (after 60 min) deposited in the periplasmic space between wall and plasma membrane and are also released into the surrounding medium. As judged by their reaction with FeCl₃, the osmiophilic particles appear to be phenolic in nature. We propose that upon binding of CTC a local increase of cytoplasmic calcium triggers callose synthesis in PCR-like compartments beneath the plasma membrane. However it remains to be shown as to why callose is synthesized exclusively in these intracellular compartments and not at the plasma membrane.     

Cytochemical localization of adenylate cyclase in bovine cumulus-oocyte complexes

The ultrastructural localization of adenylate cyclase was studied in bovine cumulus-oocyte complexes. Adenylate cyclase was observed on the plasma membrane of the oocyte and occasionally on the plasma membrane of cumulus cells. The cytochemical observations presented demonstrate that there is more adenylate cyclase in cumulus-oocyte complexes after in vitro stimulation with forskolin. The presence of adenylate cyclase upon the oocyte was more pronounced. In addition adenylate cyclase appeared to be localized on the cumulus cells, especially between junctional complexes of cumulus cells and on cumulus cell processes contacting the oocyte. The cumulus cells never showed the presence of adenylate cyclase in the absence of forskolin. No changes in the presence of adenylate cyclase were observed during in vitro meiotic maturation.     

Basement membrane and epithelial features of fetal-type Leydig cells in rat and human testis

The basement membranes of developing Leydig cells in fetal and newborn testis of rat were studied by ultrastructural and immunocytochemical methods. Fetal-type Leydig cells in prenatal rats were organized in irregularly outlined groups in the interstitium and were extensively surrounded by ultrastructurally identifiable basement membranes and immunocytochemically localized laminin and collagen type IV. Prenatal Leydig cell precursors had small patches of laminin and collagen type IV on their surfaces, which indicated that changes in extracellular matrix took place during their differentiation to mature fetal-type Leydig cells. Additionally, ultrastructural evidence was obtained for a basement membrane surrounding the fetal human Leydig cells similar to that in fetal rats. Soon after birth the rat fetal-type cells gathered into distinct clusters surrounded by delicate envelope cells and a discontinuous basement membrane. Basement-membrane structures, laminin, and collagen type IV were observed between the clustered cells as well. The basement membranes covering large cell surface areas of the fetal-type Leydig cells in fetal and newborn rats differed from those of the adult-type cells, which, according to our earlier study, are covered only by small patches of basement membrane. The difference between the basement membranes of the fetal- and adult-type rat Leydig cells further supports the concept of two different Leydig cell populations. The earlier findings of the epithelial nature of the Leydig cells agree with the observation of basement membranes in the Leydig cells.     

Long- and short-term freezing induce different types of injury in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> leaf cells

In nature, intact plant cells are subjected to freezing and can remain frozen for prolonged periods. We assayed the survival of Arabidopsis thaliana leaf cells following freezing and found that short- and long-term exposures produced different types of cellular injury. To identify the cause of these injuries, we examined the ultrastructure of the cell plasma membranes. Our results demonstrate that ultrastructural changes in the plasma membrane due to short-term freezing are associated with interbilayer events, including close apposition of the membranes. In both acclimated and non-acclimated leaf cells, these interbilayer events resulted in “fracture-jump lesions” in the plasma membrane. On the other hand, long-term freezing was associated with the development of extensive protein-free areas caused by the aggregation of intramembrane proteins with consequent vesiculation of the affected membrane regions; this effect was clearly different from the ultrastructural changes induced by interbilayer events. We also found that prolonged exposure of non-acclimated leaf cells to a concentrated electrolyte solution produced effects that were similar to those caused by long-term freezing, suggesting that the ultrastructural changes observed in the plasma membrane following long-term freezing are produced by exposure of the leaf cells to a concentrated electrolyte solution. This study illustrates multiple causes of freezing-induced injury in plant cells and may provide useful information regarding the functional role of the diverse changes that occur during cold acclimation.     

Ultrastructural cytochemical localization of adenylate cyclase in the early chick embryo

Summary Adenylate cyclase activity was localized in various tissues of the early chick embryo using an ultrastructural histochemical technique. Reaction product was deposited on the lateral plasma membrane of all cells, but with a preferential localization at the apical terminal complex in the epiblast. There was no activity associated with the free surfaces of these or other cells in the embryo. Intracellular deposits were found in all cells associated with the endoplasmic reticulum, nuclear envelope and Golgi bodies. In the last organelle, the deposit was sometimes observed to be distributed through the stack in a non-uniform way, with the heaviest deposits occurring at the forming face. No clear difference could be detected between the cytochemical activity associated with cells in various regions of the embryo, or with embryos at different stages of early development.     

Influence of autolysis on rat gastric endocrine cells

Summary In the present study histochemical parameters of the rat gastric endocrine cells were followed up in the course of 24-h autolysis, and their ultrastructure was studied during autolysis lasting for 60 min. The autolysis occurred at 37°C.In the light microscope, with the histochemical methods applied, only EC, ECL and G cells could be identified during the one-hour autolysis. With the autolysis proceeding for 6 and 12 h, only argyrophil method according to Grimelius (1968) enabled visualization of gastric argyrophilic cells. After 24 h of autolysis, none of the methods applied (not even the Grimelius method) proved to be adequate for successful demonstration of the gastric endocrine cells.In the course of 60-min autolysis, electron microscopic examination provided identification of the EC, ECL, AL, D₁, and G cells with the characteristical ultrastructural appearance of granules. The granules of the endocrine cells (G cells included) were found to be considerably resistant to autolysis. The effect of 60-min autolysis did not induce granule emiocytosis or dissolution of granule content. Autolysis exceeding five minutes resulted in damage of the mitochondria of different degrees and in dilatation of the profiles of endoplasmic reticulum (particularly in G and AL cells).The results obtained in the present study demonstrate the feasibility of in vitro experimental stimulation since the endocrine granules have proved to be resistant to the effects of simultaneously developing autolysis.     

Programmed cell death in cereal aleurone

Progress in understanding programmed cell death (PCD) in the cereal aleurone is described. Cereal aleurone cells are specialized endosperm cells that function to synthesize and secrete hydrolytic enzymes that break down reserves in the starchy endosperm. Unlike the cells of the starchy endosperm, aleurone cells are viable in mature grain but undergo PCD when germination is triggered or when isolated aleurone layers or protoplasts are incubated in gibberellic acid (GA). Abscisic acid (ABA) slows down the process of aleurone cell death and isolated aleurone protoplasts can be kept alive in media containing ABA for up to 6 months. Cell death in barley aleurone occurs only after cells become highly vacuolated and is manifested in an abrupt loss of plasma membrane integrity. Aleurone cell death does not follow the apoptotic pathway found in many animal cells. The hallmarks of apoptosis, including internucleosomal DNA cleavage, plasma membrane and nuclear blebbing and formation of apoptotic bodies, are not observed in dying aleurone cells. PCD in barley aleurone cells is accompanied by the accumulation of a spectrum of nuclease and protease activities and the loss of organelles as a result of cellular autolysis.     

Ultrastructural demonstration of exocytosis in intact and saponin-permeabilized cultured bovine chromaffin cells

Exocytosis is the release of intracellular vesicular contents directly to the cell exterior after fusion of the vesicular and plasma membranes. It is generally accepted as the process by which transmitters and hormones are released from neurons and neurosecretory cells. There is overwhelming biochemical evidence that exocytosis is the mechanism by which catecholamines are released from adrenal chromaffin cells. With the exception of the hamster, however, there is little ultrastructural evidence to support such a mechanism. We have used a modified in vitro tannic-acid method to visualize exocytosis by transmission electron microscopy in intact and saponin-permeabilized bovine chromaffin cells. When cells are exposed to tannic-acid-containing medium, the content of vesicles involved in exocytosis is coagulated in situ as the vesicle opens to the exterior. Numerous exocytotic profiles were observed. The exposed vesicle contents appeared more granular than those of vesicles in the cell interior. Tannic acid also made the plasma membrane more distinct. Small holes were apparent in the plasma membrane of saponin-treated cells, with little disruption of underlying cytoplasmic structure. Furthermore, when these cells were stimulated with calcium, exocytosis was evident only at regions of intact plasma membrane, not at the holes. Parallel measurements of secretion showed no secretion in the presence of tannic acid. Pretreatment with tannic acid prevented subsequent secretion by intact cells and markedly reduced that of permeabilized cells, indicating a probable change in the nature of the plasma membrane.(ABSTRACT TRUNCATED AT 250 WORDS)