A scanning electron microscopic and x-ray microanalytic study of cell surface material during amphibian neurulation.

Treatment with lanthanum (La3+) after fixation in phosphate (PO4-3)-buffered glutaraldehyde results in the deposition of a cell surface material (CSM) primarily on the developing urodele amphibian neural axis. X-ray probe microanalysis indicates that calcium (CA2+) levels are considerably higher in the neural fold region. La3+ displaces Ca2+ from negatively-charged moieties on biological membranes. Once bound, La3+ likely interacts with residual phosphate(s) resulting in deposition of CSM. Elemental X-ray microanalysis shows CSM contains mostly lanthanum and phosphorus. The high level of regional La3+ binding is correlated with inherently greater Ca2+ levels in the developing neural axis.     

A scanning electron microscopic study of the appearance and localization of cell surface material during amphibian gastrulation.

Cell surface material (CSM) has been implicated in a wide variety of morphogenetic processes. We describe here its discrete appearance at the blastoporal region throughout gastrulation in the salamander Ambystoma mexicanum. The CSM becomes visible in the scanning electron microscope after treatment with Alcian blue and lanthanum nitrate which reportedly attests to the presence of mucopolysaccharides. The possible importance of this CSM is underscored by its correlative appearance on tissue undergoing morphogenetic movement and induction.     

Phenotype and topography of human thymic B cells. An immunohistologic study.

Using single and double labeling immunohistochemical techniques and a large panel of monoclonal antibodies against B-cell differentiation antigens, including those newly defined at the Fourth International Leucocyte Typing Workshop, we have examined the immunophenotype and tissue distribution of human thymic B-cells. The existence of a distinct B-cell population as a constant constituent of the thymic microenvironment has been noted only recently. We found a significant population of B-lymphocytes in the thymic medulla expressing the B-cell restricted antigens CD19, CD20, CD22, CD37, CD72, CD76 and IgM and IgD. As with other extrafollicular B-lymphocytes, they differ significantly from both follicle mantle and germinal center cells in morphology and immunophenotype, which points to alternative modes of B-cell differentiation. Thymic B-cells themselves show considerable heterogeneity and a subpopulation with dendritic features and the expression of CD23 has been referred to as "asteroid" cells. Their close association with T-cells and medullary epithelial cells points to a functional role for B-cells in the thymus. A second population of B-lymphocytes together with frequent lymph follicles is found within the extrathymic perviascular space. Though separated from the medulla by a layer of epithelial cells, a clear distinction between the B-cells of these two compartments is not always possible. The intramedullary B-cell compartment shows a parallel numeric increase with the occurrence of germinal centers in the perivascular space, mostly due to an accumulation of B-cells in the medulla adjacent to these lymph follicles. Thus a close relationship between the intra- and extramedullary B-cell population of the thymus seems likely.     

Gap junction formation between normal and reaggregated endoderm cells ofXenopus laevis neurulae

Summary Using freeze-fracture electron microscopy and fluorescent dye injection we have analysed the contacts between cells of the deeper endoderm taken from neurulae ofXenopus laevis. Endodermal cells in situ have large 1.5 m diameter gap junctions composed of 8 nm P-face particles and corresponding E-face pits. Beside gap junctions, particle aggregates typical of desmosomal plaques are present but there are no tight junctions. The dissociation of endoderm into single cells involves profound structural alterations in the surface membrane including the complete disappearance of junctional structures among them gap junctions. The reaggregation of endoderm cells leads to the restoration of the surface membrane IMP (Intra Membrane Particle) pattern and, after ca. 30 min, to the establishment of functional pathways allowing for the intercellular transfer of fluorescent dye. Concomitantly gap junctions reappear. The observation that the dissociation and reaggregation of endodermal cells involves IMP alterations which go beyond the cell junctions themselves is discussed as an adaptation of the plasma membrane to changing environmental conditions.     

Apical to basolateral surface area ratio and polarity of MDCK cells grown on different supports.

We have established conditions under which Madin-Darby canine kidney cells develop a well-polarized monolayer on polycarbonate filters and on transparent filters. These filters have biochemical and mechanical advantages over the nitrocellulose filters which have been widely used. Transepithelial resistance was established 10 h after plating and stabilized after 24 h. The distribution of protein antigens was followed by surface immunofluorescence and quantitated by a surface immunoassay that we developed. Uvomorulin was localized to the lateral membrane, with low amounts detectable on the basal membrane. The 58-kDa antigen was distributed over the entire basolateral domain, including cell processes extending into the filter pores. This distribution was confirmed by immunogold labeling of frozen sections. The 114-kDa antigen was found to be present at similar surface densities on both the apical and the basolateral domain. The support used for growth had profound effects on the cell morphology. A morphometric analysis of the plasma membrane of both strains of the cell line showed an increase in the number and size of the microvilli, and a smoother basal membrane as compared to published data on nitrocellulose filters. The apical to basolateral surface area ratio was therefore modified.     

Cell-attached patch clamp study of the electropermeabilization of amphibian cardiac cells.

Potential gradients imposed across cell or lipid membranes break down the insulating properties of these barriers if an intensity and time-dependent threshold is exceeded. Potential gradients of this magnitude may occur throughout the body, and in particular in cardiac tissue, during clinical defibrillation, ablation, and electrocution trauma. To study the dynamics of membrane electropermeabilization a cell-attached patch clamp technique was used to directly control the potential across membrane patches of single ventricular cells enzymatically isolated from frog (Rana pipiens) hearts. Ramp waveshapes were used to reveal rapid membrane conductance changes that may have otherwise been obscured using rectangular waveshapes. We observed a step increase (delta t less than 30 microseconds) or breakdown in membrane conductance at transmembrane potential thresholds of 0.6-1.1 V in response to 0.1-1.0 kV/s voltage ramps. Conductance kinetics on a sub-millisecond time scale indicate that breakdown is preceded by a period of instability during which the noise and amplitude of the membrane conductance begin to increase. In some cells membrane breakdown was observed to be fully reversible when using an intershock interval of 1 min (20-23 degrees C). These findings support energetic models of membrane electropermeabilization which describe the formation of membrane pores (or growth of existing pores) to a conducting state (instability), followed by a rapid expansion of these pores when the energy barrier for the formation of hydrophilic pores is overcome (breakdown).     

Apical cell surface expression of rat dipeptidyl peptidase IV in transfected Madin-Darby canine kidney cells.

Dipeptidyl peptidase IV (DPPIV) is a type II membrane glycoprotein that is predominantly localized to the apical plasma membrane in various epithelial cells. In order to understand in more detail the biogenesis and sorting of DPPIV, the cDNA for rat DPPIV was inserted into a mammalian plasmid expression vector so that DPPIV expression was driven by a control region composed of the SV40 early promoter region fused to the enhancer of the Rous sarcoma virus. Madin-Darby canine kidney cells transfected with this construct were found to express the DPPIV protein. In these transfected cells, the majority of DPPIV was present on the apial cell surface. This observation suggests that the information for apical surface localization is inherent in the DPPIV molecule itself and that this sorting information is decipherable in the epithelial cells of a different species. DPPIV is transported efficiently from the endoplasmic reticulum to the Golgi apparatus as assessed by pulse-chase experiments. Furthermore, evidence is presented which suggests that the majority of DPPIV is sorted intracellularly to the apical cell surface. The same protein has, however, been reported to be sorted by an indirect pathway through transcytosis from the basolateral to the apical cell surface in hepatocytes (Bartles, J.R., Feracci, H., M., Stinger, B., and Hubbard, A.L. (1987) J. Cell Biol. 105, 1241-1251). This study suggests that the same protein can take two different pathways in different cell types for its correct apical cell surface localization.     

Apical material extracted from amphibian urinary bladder epithelium by enzymes and detergent treatment

The apical plasma membrane of epithelial cells of frog and toad urinary bladder is subject to large modifications during the induction of water permeability by the antidiuretic hormone. A better characterization of the apical membrane is necessary for a clear understanding of the mechanisms of hormone action. Towards this end, apical material was extracted by enzymatic treatment and by incubation with detergent. Proteolytic enzyme alone had little effect under our conditions. A pretreatment with several glycosidases (alpha-mannosidase or endo-beta-N-acetylglucosaminidase H) increased the hydrolytic action of papain, elastase, proteinase K or Staphylococcus aureus V8 protease and allowed the detection of a major 76 kD in SDS gel electrophoresis. The n-octyl-beta-D-glucopyranoside (0.2%) led to the extraction after 150 mn of 1 to 5 micrograms proteins per cm2 of amphibian urinary bladder apical surface. The extracted proteins migrated as several bands on SDS gels. One of them probably corresponds to the 76 kD fragment obtained after proteolysis. The absence of alteration of the water permeability after extraction and the good preservation of the ultrastructure are evidence for the localisation of the 76 kD at the apical membrane surface. This protein may be the best candidate as antigen to raise antibodies against the apical surface of amphibian urinary bladder epithelial cells.     

Plasma membrane sterol distribution resembles the surface topography of living cells

Cholesterol is an important constituent of cellular membranes. It has been suggested that cholesterol segregates into sterol-rich and -poor domains in the plasma membrane, although clear evidence for this is lacking. By fluorescence imaging of the natural sterol dehydroergosterol (DHE), the lateral sterol distribution has been visualized in living cells. The spatial labeling pattern of DHE coincided with surface structures such as ruffles, microvilli, and filopodia with correlation lengths in the range of 0.8-2.5 microm. DHE staining of branched tubules and of nanotubes connecting two cells was detected. Dynamics of DHE in folded and plane membrane regions was comparable as determined by fluorescence recovery after photobleaching. DHE colocalized with fluid membrane-preferring phospholipids in surface structures and at sites of cell attachment as well as in the cleavage furrow of dividing cells, but it was not particularly enriched in those regions. Fluorescent sterol showed homogeneous staining in membrane blebs induced by F-actin disruption. Cross-linking the ganglioside GM1--a putative raft marker--did not affect the cell surface distribution of DHE. The results suggest that spatial heterogeneities of plasma membrane staining of DHE resolvable by light microscopy reflect the cell surface topography but not phase-separated sterol domains in the bilayer plane.     

Apical and basal Forssman antigen in MDCK II cells: a morphological and quantitative study.

We have studied the surface distribution of a glycosphingolipid (the Forssman antigen) in MDCK II and CCL39 cells. The Forssman antigen is mobile on the surface of both these cell lines. Its surface distribution is homogenous on non-polarized cells. Under conditions where MDCK II cells are well polarized, the Forssman antigen is present in equal amounts on the apical membrane and on the basal membrane and its processes. Very little Forssman antigen can be detected on the lateral membrane. The nature of the mechanism excluding the Forssman antigen from the lateral domain remains to be determined. This surface distribution is established within hours after plating and was observed with cells grown on different types of filters. The surface density of the Forssman antigen on the apical and on the basal domain has been estimated. No involvement of the basal Forssman antigen in cell attachment could be demonstrated. However, the apical Forssman antigen appears to be essential to the establishment of the cells in culture.     

Using continuous porous silicon gradients to study the influence of surface topography on the behaviour of neuroblastoma cells

The effects of surface topography on cell behaviour are the subject of intense research in cell biology. These effects have so far only been studied using substrate surfaces of discretely different topography. In this paper, we present a new approach to characterise cell growth on porous silicon gradients displaying pore sizes from several thousands to a few nanometers. This widely applicable format has the potential to significantly reduce sample numbers and hence analysis time and cost. Our gradient format was applied here to the culture of neuroblastoma cells in order to determine the effects of topography on cell growth parameters. Cell viability, morphology, length and area were characterised by fluorescence and scanning electron microscopy. We observed a dramatic influence of changes in surface topography on the density and morphology of adherent neuroblastoma cells. For example, pore size regimes where cell attachment is strongly discouraged were identified providing cues for the design of low-fouling surfaces. On pore size regimes more conducive to cell attachment, lateral cell-cell interactions crosslinked the cell layer to the substratum surface, while direct substrate-cell interactions were scarce. Finally, our study revealed that cells were sensitive to nanoscale surface topography with feature sizes of <20 nm.     

Effect of cytochalasins on the surface topography of neoplastic cells in suspension

The effect of cytochalasins B or D on the surface topography of mouse neoplastic fibroblasts of L line (detached from glass by trypsin-EDTA solution) or of its LS subline (adapted to the growth in suspension in vitro), as well as on that of Ehrlich's ascites tumor cells was investigated by screening electron microscopy. Incubation of suspended cells with cytochalasin B (2 micrograms/ml) or cytochalasin D (0.2 microgram/ml) for 30-180 min led to the following changes: (I) progressive decrease of the proportion of the cells with a microvillous surface relief and simultaneous increase in the percentage of the cells with a blebbed microrelief; (2) shortening of the microvilli and decrease of their density on the cell surface; (3) appearance of surface areas with a rough folded relief; (4) formation of very large blebs on the LS or L cell surfaces; (5) unusual "polar" distribution of blebs on Ehrlich's tumor and L cells: the blebs were concentrated in one locus on the cell surface. The data show that normal organization of the actin microfilament system in the cell cortex is necessary for formation of the microvilli but not for the blebs.     

Ultrastructure and surface topography of aggregates of human limb mesenchymal cells (HLM15) in vitro.

Tissue-like aggregates of human embryo fibroblasts can be created in vitro by limited aspiration of cells released from substrate during subcultivation. Aggregates increase in size, exhibit intercellular junctions, display a surface topography characteristic of cellular movement, elaborate an extracellular matrix and possess features of cellular death and phagocytosis. These cells, when introduced to a new culture environment, do not migrate away from one another as is common when a primary culture is started from tissue fragments. Instead, cells exhibit continued contact with each other, and develop complex junctional structures during that association. Cellular aggregates generated in this manner may provide a useful system for providing further information on cellular adhesion, intercellular communication, morphogenetic cell movements and the mechanisms of cell death.     

Locomotion and adhesion of amphibian gastrula and neurula cells cultured on substrata of varied surface charge

This paper reports experiments to determine the effects of electrostatic repulsion on cell adhesion and locomotion, and to demonstrate quantitative differences in adhesiveness among cell populations of the amphibian gastrula, where it may be a factor controlling morphogenesis. Rana pipiens gastrula presumptive germ layer cells and neural crest were cultured on substrata of known surface charge and composition; cell-substratum adhesion assayed, and locomotory rate measured. Because electrokinetic mobilities of R. pipiens gastrula cells are known and that of neural crest has been measured here, various cell-substratum combinations have been ranked in order of the electrostatic force between them. Experimental methods include time-lapse cinematography and single-cell electrophoresis. The results indicate differential cell-substratum adhesion for R. pipiens inner neural ectoderm (INE), chordamesoderm (CHM) and neural crest (NC). In addition, it was found that increase in electrostatic repulsion decreases cell-substratum adhesion, and at first increases rate of locomotion, but then, as repulsion continues to increase, locomotor rate decreases. Increase in the surface potential of presumptive pharyngeal endoderm and chordamesoderm may bring about a decrease in cohesiveness thought to be necessary for the beginning of amphibian gastrulation.     

Apical surface of the epithelial cells in the gallbladder of the rainbow trout and the tench

Summary The aluminium-formaldehyde (ALFA) histofluorescence method was used to study the innervation of the gill of the marine bivalve mollusc Mytilus edulis and the results were contrasted with those obtained with the standard formaldehyde-induced-fluorescence (FIF) method. The ALFA method produced more fluorescing structures than the FIF method, thus revealing fine branches of the branchial nerve running beneath the gill epithelium which previously remained undetected. This study demonstrates the usefulness of the ALFA histofluorescence method in the study of marine invertebrates.This study was supported in part by Grants 1506RR08171 from NIMH and 5T32GM07641 from the MARC Program of NIGMS. I wish to thank E. Aiello for thoughtful discussions of the work     

Filamin and myosin are present in the secretory pole of amphibian oxyntic cells. An immunofluorescence study

The presence of a filamin-like protein in oxyntic cells was established by indirect immunofluorescence microscopy. The location of this protein and myosin was studied, using specific antibodies, on frozen sections and isolated cells. Antifilamin and antimyosin reacted strongly with the luminal cytoplasm of the cells. In resting oxyntic cells, filamin appeared organized as a reticular sheet in the apical border. In stimulated cells, the apical concentration of filamin decreased, and its distribution appeared rather diffuse. This immunoreactive band seems to correspond to the cytoplasmic region where actin microfilaments have been described previously. The changes in the apical concentration of filamin, induced by the onset of HCl secretion, correlate with the ultrastructural reorganization of the actin network that occurs during the secretory cycle. The use of antimyosin antibodies showed that this protein forms an apical peripheral ring in both resting and stimulated cells. No clear changes in the distribution of myosin, in relation to secretion, could be established by immunofluorescence. These findings, taken together with published morphological and biochemical evidence, suggest that a three-dimensional network composed of actin and filamin is present in the secretory pole of resting amphibian oxyntic cells. The hypothesis that gel-sol transitions play a role in the structural reorganization of the secretory pole of these cells is supported by the present results.