Epithelial effects on limb chondrogenesis involve extracellular matrix and cell shape

Collagen gel cultures of limb bud mesenchymal cells are normally permissive for chondrogenesis but become inhibitory for chondrogenesis when they are preconditioned by limb ectoderm. This inhibition is specific for cartilage differentiation, inasmuch as myoblast differentiation is unaffected and flattened, fibroblastic cells are more numerous on conditioned gels. The antichondrogenic effect of ectoderm-conditioned gels is not blocked by agents that elevate intracellular cyclic AMP levels and that promote chondrogenesis under other conditions. In contrast, the inhibitory effect of the ectoderm is alleviated when cultures are treated with cytochalasin D, a cytoskeleton-disrupting agent that causes the cells to remain spherical. These results suggest that ectoderm-conditioned collagen gels inhibit chondrogenesis through an effect on cell shape.     

The differential effects of N,N-dimethylformamide and transforming growth factor-beta 1 on a human ovarian cancer cell line (HOC-7).

We have compared the effects of N,N-dimethylformamide (DMF) and transforming growth factor (TGF)-beta 1 on the growth and phenotype of HOC-7 ovarian cancer cells. Previous density gradient fractionation of untreated HOC-7 cells suggested that rapidly growing small polygonal medium density cells revert spontaneously into less malignant flattened low density cells. Here we demonstrate that DMF and TGF-beta 1 induce similar flattened cell phenotypes. Both agents induce qualitatively similar alterations in the cells. DMF, however, exerted stronger effects than TGF-beta 1. The cells become flattened, develop cytoplasmic extensions, and reduce DNA-synthesis as well as anchorage-dependent and -independent growth. These effects are reversible after removal of the inducers, indicating that the cells have not become terminally differentiated. Electron microscopy demonstrates prominent filament bundles in treated cells. Immunofluorescence further shows that these cells contain large amounts of cytokeratin. Immunocytochemistry and ELISA demonstrate 1- to 5-fold higher amounts of desmoplakin and fibronectin after DMF- or TGF-beta 1-exposure. The described differentiation-like responses of HOC-7 cells can be used for recognition of pharmacologically induced maturation of ovarian cancer cells.     

A computer simulation of cell stacking for even thickness in mammalian epidermis

The method of even stacking of epidermal cells in mammalian skin was studied by computer simulation. The epidermis consists of neat vertical columns of stacked, flattened, tetrakaidecahedral cells. Cells which have been proliferated in a basal layer migrate upwards, occupy the bottom regions of vertical columns, and become members constituting columns. Computer simulations demonstrated that the column height becomes considerably varied if the cells are randomly supplied from the basal layer. In contrast, if the cells are assumed to have an ability to find the uppermost region among the column's bases consisting of one base where the cell has reached and its neighbouring bases, the cells stack into columns whose heights are remarkably uniform even if the cells are randomly supplied. The results indicated that an epidermal structure consisting of the flattened polyhedral cells could itself function as a control mechanism of the epidermal thickness.     

Alignment of desmosomes in stratifying human epidermis

Summary Cultured human epithelial cells stained with antibody to desmosomal proteins by indirect immunofluorescence showed linear arrays of desmosomes en face between stratified cells. To confirm that an extensive linear pattern existed on the cell surface, subconfluent cultures were viewed using scanning electron microscopy. Aligned arrays of blunt protrusions lying parallel to each other and extending in the direction of the long axis of the cell were observed on the surface of groups of superficial cells in intact cultures. That this pattern was indeed related to desmosomal distribution was verified by transmission microscopy of thin sections cut in a plane between the upper and lower surfaces of flattened stratified cells to view desmosomes directly. A similar arrangement of desmosomes was seen in intact tissue, using epidermal sheets separated from newborn foreskin. The same pattern found in flattened cells was sometimes apparent in more rounded basal cells where the cytoplasm was beginning to extend. Since desmosomal plaques are associated with keratin filaments, the alignment of desmosomes must occur in association with cytoskeletal changes as cells become flattened toward the distal epithelial surface. The primary initiation of desmosomal alignment remains to be investigated. However, the present findings demonstrate an increasingly regular membrane-cytoskeletal spatial interaction as stratified epithelial cells of skin mature.     

Stereoscan studies of rediae, cercariae, cysts, excysted metacercariae and migratory stages of Fasciola hepatica

The external surface of the redial body of Fasciola hepatica is provided with microvillus-like projections or short lamellae, and short cilium-like structures are common anteriorly. The anterior part of the cercarial body possesses a pattern of regularly arranged small depressions each containing a spine. Both long and short cilium-like structures occur anteriorly. The tail is spineless and provided with dorsolateral folds. The outer cyst wall is formed by granules secreted from the tegument all over the body apart from the ventral sucker. Most granules transform into fibrillae which form the thick outer spongy layer. The precursor of the inner cyst wall is at the beginning closely attached to the metacercarial surface, but later the membrane-like cyst wall extends, and when fully formed the metacercaria lies free in the flattened circular inner cyst. The ventral plug is formed by the ventral sucker. The tegument of newly excysted metacercariae is provided with simple pointed spines, but later during migration in the mouse the spines become flattened and multipointed. Very young migratory stages may be attached with host cells.     

Fibronectin gene expression during limb cartilage differentiation

A critical event in limb cartilage differentiation is a transient cellular condensation process in which prechondrogenic mesenchymal cells become closely juxtaposed and interact with one another prior to initiating cartilage matrix deposition. Fibronectin (FN) has been suggested to be involved in regulating the onset of condensation and chondrogenesis by actively promoting prechondrogenic aggregate formation during the process. We have performed a systematic quantitative study of the expression of the FN gene during the progression of chondrogenesis in vitro and in vivo. In high-density micromass cultures of limb mesenchymal cells, FN mRNA levels increase about 5-fold coincident with the crucial condensation process, and remain relatively high during the initial deposition of cartilage matrix by the cells. Thereafter, FN mRNA levels progressively decline to relatively low levels as the cultures form a virtually uniform mass of cartilage. The changes in FN mRNA levels in vitro are paralleled closely by changes in the relative rate of FN synthesis as determined by pulse-labeling and immunoprecipitation analysis. The relative rate of FN synthesis increases 4- to 5-fold at condensation and the onset of chondrogenesis, after which it progressively declines to low levels as cartilage matrix accumulates. High levels of FN gene expression also occur at the onset of chondrogenesis in vivo. In the proximal central core regions of the limb bud in which condensation and cartilage matrix deposition are being initiated, FN mRNA levels and the relative rates of FN synthesis become progressively about 4-fold higher than in the distal subridge region, which consists of undifferentiated mesenchymal cells that have not yet initiated condensation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fusion of epithelial sheets as seen in formation of the chick amnion

Summary Fusion of the amniotic folds over the chick embryo provides an example of epithelial fusion in which one group of ectodermal cells appears to contribute to traction and a second group appears to respond by moving to the midline, becoming internalized and degenerating. Neutral red staining of living embryos and transmission electron microscopy indicate that a patch of dying cells is present in the fusion region. Scanning electron microscopy shows that ectoderm cells at the rim of the amniotic folds are cylindrical in shape with long axes oriented parallel to the rim. These cells have a smooth surface, but show increasing amounts of blebbing toward the midline. Characteristically, a globular region of rounded cells showing extreme blebbing is present at the midline. Just anterior to the globular region, flattened cells are present on the surface with many taut cellular processes. Orientation of ectodermal cells around the region of fusion suggests that traction is exerted from these flattened cells. When treated with cytochalasin D, posterior progression of the zone of fusion is blocked. Also, the flattened cells anterior to the globular region round up, revealing many elongated, anteriorly-directed cytoplasmic processes presumably leading to sites of original attachment.     

Surface changes during development and involution of the cement gland of Xenopus laevis

Summary The cement gland was studied from stage 17, when the anlage is established, to stage 49, shortly before its disappearance. At early stages, the apical membrane is covered by small microvilli that are more abundant than in the surrounding epiblast cells. Vesicular protrusions along the cell boundaries are also more numerous in the gland cells.When the gland reaches maturity, the apical membranes of gland cells differentiate into two regions. In the cranial, kidney-shaped region, the membranes are very narrow and protrude above the level of cell boundaries. Long and slender villi raise from the surface adjacent to cell boundaries. Apical surfaces in the caudal portion are larger and flattened. Cell boundaries are lined with shorter and thicker surface projections. At these stages, the bordering cells are covered with secretion vesicles.During involution the number of cells is progressively reduced. The area of the caudal portion increases relative to the area of the cranial portion. Apical surfaces become more flattened. Surface projections become much shorter and invade the whole of the apical surface. Bordering cells lose their secretion vesicles and their apical surface becomes ruffled with numerous short wrinkles. The significance of the apical structures and their evolution is discussed.     

CHANGES IN CELL FINE STRUCTURE DURING LENS REGENERATION IN XENOPUS LAEVIS

Changes at the level of cell fine structure have been studied during lens regeneration in the toad, Xenopus laevis, where cornea gives rise to the new lens. The transformation of these cells may be divided into three phases. (1) In the cornea, flattened cells become cuboidal and rough endoplasmic reticulum increases in amount. (2) In the new lens vesicle, cisternae of the rough ER break down into vesicles, smooth-walled vesicles and free ribosomes increase in number, and mitochondria can become enlarged and irregular, then centrally attenuated. Rudimentary cilia form. (3) As new lens fibers form, ribosomes become very numerous and low density fibrous elements and dense clumps appear in the cytoplasm. These phases are accompanied by marked nucleolar changes. The changes during the 3rd phase are similar to changes in the lens during normal development. The first two phases show an unexpected morphological complexity.     

Lens formation by pigmented epithelial cell reaggregate from dorsal iris implanted into limb blastema in the adult newt

In newt lens regeneration, the dorsal iris has lens forming ability and the ventral iris has no such capability, whereas there is no difference in the morphological criteria. To investigate the real aspects of this characteristic lens regeneration in the newt at the cellular level, a useful model system was constructed by transplanting the dorsal and ventral reaggregate derived from singly dissociated pigmented epithelial cells of the iris into the blastema of the forelimb in the newt. The lens was formed from the dorsal reaggregate with high efficiency, but not from the ventral one. No lens formation was observed in the implantation of the reaggregate into the tissue of the intact limbs. In detailed examination of the process of lens formation from the reaggregate, it was shown that tubular formation was the first step in the rearrangement of cells within the reaggregate. This was followed by depigmentation, vesicle formation with active cell growth, and the final step was lens fiber formation by transdifferentiation of epithelial cells composing the lens vesicle. The process was almost the same as in situ lens regeneration except the reconstitution of the two-layered epithelial structure was embodied as flattened tubular formation in the first step. The present study made it possible for the first time to examine lens forming ability in the reaggregate mixed with dorsal and ventral cells, because the formation of a reaggregate was started from singly dissociated cells of the dorsal and ventral cells of the iris. Mixed reaggregate experiments indicated that the existence of the dorsal cells in a cluster within the reaggregate is important in lens formation, and ventral cells showed an inhibitory effect on the formation. The present study demonstrated that the limb system thus constructed was effective for the analysis of lens formation at the cellular level and made it possible to examine the role of dorsal and ventral cells in lens regeneration.     

A cytological study of the ovary of Rhodnius prolixus. I. The ontogeny of the follicular epithelium

The relatively undifferentiated cells comprising the prefollicular epithelium of the fourth and fifth instar of the reduvid bug Rhodninus prolixus are flattened and contain the regularly occurring organelles, lipid droplets, and aggregates of glycogen-like particles. These cells transform into the adult prefollicular tissue. During vitellogenesis there is a gradual shortening of the cells of the follicular epithelium and an increase in the size of the intercellular space between them and between follicle cells and oocyte. The follicle cells are binucleate, contain numerous microtubules, rough endoplasmic reticulum, many free and aggregate ribosomes, and Golgi complexes. They are associated with each other by gap junctions. Only the follicle cells on the lateral aspects of the oocyte exhibit the development of large extracellular spaces while those at the apical end, that produces the cap, remain tall and closely apposed to each other during vitellogenesis. The normal morphology of the follicle cells over various areas of the oocyte suggests that shape and/or volume changes of these cell may be important in regulating the access of yolk proteins to the colemma. Subsequent to vitellogenesis the follicle cells become cuboidal and once again become closely apposed to each other. They contain much rough endoplasmic reticulum and produce the secondary coat.     

Growth-promoting effect of haemocytes on insect epidermis in vitro

The epidermis of 21-day-old leg regenerates of cockroaches (Leucophaea maderae) was cultivated in vitro. Outgrowth of the epidermis only occurred in connexion with haemocytes.Haemocytes contaminating the epidermal explants show strong adherence to epidermal cells. The epidermal cells adhering to moving haemocytes are stretched out to long projections or completely pulled out of the epithelium. When more haemocytes are present, they can form an uninterrupted line at the margin of the epidermis. By the adhesion of marginal cells of the epidermis to the moving haemocytes, the epithelium is apparently pulled out into broad tongues. In these tongues the epidermal cells become highly flattened, especially at the front, and soon begin to divide. Outgrowth in the tongues continues only as long as there are haemocytes at the front. When they have disappeared, outgrowth stops, the flattened epidermal cells detach from the glass surface, round up, and the outgrown tissue may withdraw again.For further analysis of the interactions of haemocytes and epidermal cells the epidermis is placed on a monolayer of haemocytes. The epidermis rapidly grows out on such a monolayer. The epidermal cells either move over or under the haemocytes indicating that there are substances on both sides of the haemocytes which are attractive to the epidermal cells and cause their flattening and outgrowth. Similar outgrowth occurs on fixed monolayers of haemocytes. There is no outgrowth on areas where the monolayer has been scraped away. No principal differences can be found between monolayers consisting almost exclusively of either plasmatocytes or granular haemocytes.The similarities of the observed interactions of haemocytes and epidermal cells to encapsulation and wound healing are pointed out. A hypothesis is presented which assumes that the haemocytes during wound healing not only serve as a mechanical support but also as a chemical guide by which the closure of the wound by epidermal cells is enhanced.     

Induction of cortical oscillations in spreading cells by depolymerization of microtubules

Actomyosin-based cortical contractility is a common feature of eukaryotic cells but the capability to produce rhythmic contractions is found in only a few types such as cardiomyocytes. Mechanisms responsible for the acquisition of this capability remain largely unknown. Rhythmic contractility can be induced in non-muscle cells by microtubule depolymerization. Spreading epithelial cells and fibroblasts in which microtubules were depolymerized with nocodazole or colcemid underwent rhythmic oscillations of the body that lasted for several hours before the cells acquired a stable, flattened shape. By contrast, control cells spread and flattened into discoid shapes in a smooth and regular manner. Quantitative analysis of the oscillations showed that they have a period of about 50 seconds. The kinase inhibitors, HA 1077 and H7, and the more specific rho-kinase inhibitor, Y 27632, caused the oscillations to immediately cease and the cells to become flat. Transient increases in cytoplasmic calcium preceded the contractile phase of the oscillations. Wrinkle formation by cells plated on elastic substrata indicated that the contractility of colcemid-treated cells increased in comparison to controls but was drastically decreased after HA 1077 addition. These data suggest that an intact microtubular system normally prevents pulsations by moderating excessive rho-mediated actin myosin contractility. Possible mechanistic interactions between rho-mediated and calcium activated contractile pathways that could produce morphological oscillations are discussed.     

A developmental study of the epidermis of young roots ofZea mays L.

Summary In the apical meristems of main and young lateral roots of corn the uniseriate epidermis is clearly continuous with the most distal cell tier of the quiescent centre. These cells are characterized by the presence on their outer periclinal walls of material which forms the thin root cap junction layer over the apical pole and which thickens appreciably over the flanks of the meristem to form a distinctive extracellular deposit on the young epidermal cells. This material is polysaccharide in nature as indicated by strong periodic acid Schiff's positivity but its autofluorescence also suggests the presence of phenolic compounds.During their development the epidermal cells undergo marked shape change from periclinally flattened, polygonal at the root pole, through columnar on the meristem flank to tabular in the root hair zone. The mucigel thins markedly as cells become tabular but initiation of a root hair is characterized by deposition of polysaccharide on the inside of the periclinal wall where the hair will develop.     

Under-agarose folate chemotaxis of Dictyostelium discoideum amoebae in permissive and mechanically inhibited conditions.

Under-agarose chemotaxis has been used previously to assess the ability of neutrophils to respond to gradients of chemoattractant. We have adapted this assay to the chemotactic movement of Dictyostelium amoebae in response to folic acid. Troughs are used instead of wells to increase the area along which the cells can be visualized and to create a uniform front of moving cells. Imaging the transition zone where the cells first encounter the agarose, we find that the cells move perpendicular to the gradient and periodically manage to squeeze under the agarose and move up the gradient. As cells exit the troughs, their cross-sectional area increases as the cells become flattened. Three-dimensional reconstruction of confocal optical sections through GFP-labeled cells demonstrates that the increase in cross-sectional area is due to the flattening of the cells. Since the cells locally deform the agarose and become deformed by it, the concentration of the agarose, and therefore its stiffness, should affect the ability of the cells to migrate. Consistent with this hypothesis, cells in 0.5% agarose move faster and are less flat than cells under 2% agarose. Cells do not exit the troughs and move under 3% agarose at all. Therefore, this assay can be used to compare and quantify the ability of different cell types or mutant cell lines to move in a restrictive environment.     

Reassortment of cells according to position in mouse morulae

Sixteen-cell mouse morulae were disaggregated and blastomeres originally occupying outer or inner positions were separated. Outer, inner, or unsorted populations of blastomeres were labeled with either trinitrobenzene sulphonic acid (TNP) or fluorescein isothiocyanate (FITC) and individual blastomeres aggregated to unlabelled partially decompact eight- to ten-cell morulae. After up to 6 h in culture, the positions of the labelled blastomeres within the aggregates were examined. The combined results demonstrated that between 86 and 92% of outer cells remained on the surface of the aggregate and flattened into extensive polygonal shapes, whereas 76-77% of the inner cells had become engulfed by the host morula cells and retained their initial spherical shape. Using unsorted cells, 33-37% were internalised, which is compatible with the most recent estimates of the presence of six to eight inner cells at the 16-cell stage. The possibility that differential adhesiveness of the outer and inner cells is involved in the allocation of cells to the trophectoderm and inner cell mass of the blastocyst is discussed.     

The fine structure of an absorptive epithelium in a viviparous teleost

Embryos of the viviparous teleost, “Characodon” eiseni, have unusual anal processes that function only during gestation and are lost shortly after birth. This study was undertaken to determine if the fine structure of the process epithelium supports the assumption that these cells have an absorptive function. The process epithelium is a single layer of columnar cells. At peak activity intercellular spaces become very large and isolate individual cells which simultaneously lose much of their cell mass. The cells are characterized by microvilli on their free surface, much pinocytic activity and by the formation of at least four different kinds of vesicles. There is much evidence that these vesicles fuse together. A distinctive characteristic of these cells is a system of tubules and flattened cisternae that somewhat resemble the endoplasmic reticulum yet they differ from it in several respects. It is suggested these profiles aid in fragmenting the cell at periods of peak absorptive activity, thereby increasing the cell surface. Possible mechanisms of food absorption are considered. The fine structure of these cells supports the contention that these embryonic processes serve as absorptive organs during gestation.