An ultrastructural study of adhesive junctions in reaggregates of unincubated chick embryos.

Cell suspensions obtained by the dissociation of unincubated chick embryo blastoderms were allowed to reaggregate on a gyratory shaker for 24-48 hours. The reaggregates which form during this period consist of an inner phase of tightly packed cohesive cells surrounded by an external phase of loosely packed cells. This sorted out arrangement achieves its definitive form between 24 and 48 hours of rotation culture. It was determined that the external phase consists of primitive ectoderm and that the internal phase consists of primitive endoderm. Both 24- and 48-hour reaggregates were examined in the electron microscope and observations were directed to areas of close membrane apposition between cells. In 48-hour reaggregates, primitive endoderm cells were joined by many specialized junctions (desmosomes). The formation of desmosomes in reaggregates of dissociated unincubated chick embryo cells was correlated with the sorting out process.     

CELL SORTING IN THE PRESENCE OF CYTOCHALASIN B

The ability of cytochalasin B to inhibit ruffled membrane activity and cellular locomotion of vertebrate cells in monolayer culture prompted its use to study the necessity for this kind of active cellular locomotion in cell sorting in heterotypic cell aggregates. Cell sorting was inhibited in chick embryo heart-pigmented retina aggregates but a remarkable degree of sorting did occur in neural retina-pigmented retina aggregates. In these experiments, the levels of cytochalasin B employed (5 or 10 µg/ml) are sufficient to inhibit completely locomotion of these cell types in monolayer culture. It is proposed that the degree of cell movement achieved during sorting in neural retina-pigmented retina aggregates in the presence of cytochalasin B is the result of changes in cell contact resulting from adhesive interaction of cells. The effect of cytochalasin B on the initial aggregation of dissociated cells was also tested. With the cell types used in this study (chick embryo neural retina and limb bud), aggregation was not affected for a period of several hours.     

Regulated lens regeneration from isolated pigmented epithelial cells of newt iris in culture in response to FGF2/4

When a lens is removed from the newt eye, a new lens is regenerated from the pigmented epithelial cells of the dorsal iris, whereas the ventral iris never shows such an ability. It is important to clarify the nature of signaling molecules which act directly on the iris cells to accomplish lens regeneration from the iris and also to gain insight into the mechanism of dorso-ventral difference of the regeneration potential. To examine the effects of exogenous factors, we established an in vitro culture of reaggregates made from dissociated pigmented epithelial cells of dorsal or ventral halves of newt iris. Foci of depigmented cells appeared within the cell reaggregates, regardless of their origins, when the cell reaggregates were cultured with FGF2 or FGF4. In contrast, only the depigmented cells in the dorsal iris cell reaggregates underwent extensive proliferation and developed a lens with the synthesis of lens-specific crystallins, recapitulating the normal lens regeneration. On the other hand, neither FGF8, FGF10, EGF, VEGF, nor IGF promoted lens development from iris cell reaggregates. Consistent with the FGF-specific action, FGFR-specific inhibitor SU5402 suppressed the lens development from the cultured cell reaggregates. These results demonstrated that FGF2 or FGF4 is essential for the in vitro lens regeneration from the pigmented cells of the dorsal iris. In addition, these findings indicated that unequal competence in the dorsal and ventral iris to FGF2/4 contributes to the difference in lens forming ability between them.     

A decay of gap junctions in association with cell differentiation of neural retina in chick embryonic development.

Ultrastructural studies of thin-sectioned and freeze-cleaved materials were performed on developing retinal tissues of 3- to 9-day-old chick embryos to clarify the junctional structures between neural retinal cells and between neural retinal cells and cells of the pigmented epithelium. Frequency, size and position of gap junctions in developing neural retina are different at each stage of development. In 3-day-old embryos, some cells adhere to each other by gap junctions immediately below the outer limiting membrane of neural retinae. The size and number of gap junctions increase remarkably during 5-6 days of incubation. In this period of development, well developed gap junctions consisting of subcompartments of intramembrane particles are found between cell surfaces at both the outer limiting membrane region and the deeper portion of the neural retina. Gap junctions disappear thereafter, and at 7-5 days of incubation, small gap junctions are predominant between cell surfaces at the outer limiting membrane region, while the frequency of gap junctions in the deeper portion is very low. At 9 days of incubation, gap junctions are rarely found. Typical gap junctions are always found between neural retinal cells and those of the pigmented epithelium in embryos up to 7-5 days of incubation. Tight junctions are not found in the neural retina or between neural retina and pigmented epithelium throughout the stages examined.     

Localization of capping protein in chicken epithelial cells by immunofluorescence and biochemical fractionation

We have localized capping protein in epithelial cells of several chicken tissues using affinity-purified polyclonal antibodies and immunofluorescence. Capping protein has a distribution in each tissue coincident with proteins of the cell-cell junctional complex, which includes the zonula adherens, zonula occludens, and desmosome. "En face" views of the epithelial cells showed capping protein distributed in a polygonal pattern coincident with cell boundaries in intestinal epithelium, sensory epithelium of the cochlea, and the pigmented epithelium of the retina and at regions of cell-cell contact between chick embryo kidney cells in culture. "Edge-on" views obtained by confocal microscopy of intact single intestinal epithelial cells and of retinal pigmented epithelium showed that capping protein is located in the apical region of the epithelial cells coincident with the junctional complexes. These images do not resolve the individual types of junctions of the junctional complex. Immunolabeling of microvilli or stereocilia was faint or not detectable. Capping protein was also detected in the cytoplasm of intact intestinal epithelial cells and in nuclei of cells in the pigmented retina and in the kidney cell cultures, but not in nuclei of cells of the intestinal epithelium or sensory epithelium. Biochemical fractionation of isolated intestinal epithelial cells shows capping protein in the brush border fraction, which contains the junctional complexes, and in the soluble fraction. These results are consistent with the results of the immunolabeling experiments. Highly purified microvilli of the brush borders also contained capping protein; this result was unexpected based on the low intensity of immunofluorescence staining of microvilli and stereocilia. The microvilli were not contaminated with junctional complexes, as defined by the absence of several markers for cell junctions. The cause and significance of this discrepancy is not certain at this time. Since capping protein binds the barbed end of actin filaments in vitro, we hypothesize that capping protein is bound to the barbed ends of actin filaments associated with one or more of the junctions of the junctional complex.     

不同发育时期的鸡胚色素上皮对体外视网膜细胞生长的作用(简报)

眼正常发育中,色素上皮层和视刚膜之间在结构上存在着紧密的接触,功能上也相互依赖,但色素上皮的作用不甚清楚。很多脊椎动物的视网膜如果失去了与色素上皮层的紧密     

A DISTINCTIVE CELL CONTACT IN THE RAT ADRENAL CORTEX

Extensive cell contacts which resemble septate junctions occur between cells in the three major zones of the rat adrenal cortex. Characteristically, they extend between small intercellular canaliculi and the periendothelial space, frequently interrupted by gap junctions and rarely by desmosomes. Zonulae occludentes have not been identified in the adrenal cortex. Along this distinctive cell contact, the cell membranes of apposing cells are separated by 210–300 a bisected by irregularly spaced 100–150-A extracellular particles which are often circular in profile. In lanthanum preparations, these particles appear to form a continuous chain throughout the intercellular space and are visualized as an alveolate structure in sections parallel to the plane of the cell membrane. The cell membrane in the area of septate-like contact does not differ from nonjunctional areas of the cell membrane in freeze-fracture replicas. The cell contact retains its integrity after cell dispersion and after the separation of cell membranes from disrupted cells. The intercellular particles also persist after brief extraction in lipid solvents. Besides adherence, possible functions of this adrenal contact include maintenance of the width of the extracellular space, the provision of channels between intercellular canaliculi and the bloodstream, and utilization as cation depots. Similar structures are also present between adrenal cortical cells of several other species and between interstitial cells of the testis. This type of cell contact may, in fact, be a typical feature of steroid-hormone-secreting tissues in vertebrates.     

An instructive role for the interstitial matrix in tissue patterning: tissue segregation and intercellular invasion

Intercellular invasion is the intrusion of the cells of one tissue into space occupied by a second tissue. The alternative situation to invasion, one characteristic of most coherent tissues, is segregation, with identifiable boundaries existing between contiguous tissues. The interfaces between mesenchymal and myocardial tissues in the developing avian heart show a profoundly different character in different regions of the heart: the interface between epicardial mesenchyme and heart wall myocardium is planar, without intermingling of the two cell types, whereas the interface between endocardial cushion mesenchyme and myocardium is diffuse, with extensive invasion of both tissue types across the border to produce intermingling of the two tissues. Thus, invasion and tissue segregation coexist in different regions of the mesenchyme-myocardium contact zone. Investigation of the involvement of the interstitial matrix in invasion and segregation has been conducted by maintaining the two tissues in mutual contact in organ culture. Investigation of the mechanisms by which the two cell types sort out in randomized chimeric tissue reaggregates has provided insight into the conditions for tissue segregation. We have modeled invasion in organ culture by fusing aggregates of myocardial cells with aggregates of cardiac mesenchymal cells. Cells of both tissues invaded the partner aggregate during a period of 1-3 d of coculture. Both invasion and segregation in the aggregates appear to depend on the presence or absence of a fibronectin-rich interstitial matrix elaborated by the cardiac mesenchyme. During sorting, the matrix appears selectively in regions occupied by the mesenchyme. Under conditions of culture that are nonpermissive for matrix deposition, sorting fails to occur. Stimulation of matrix deposition by addition of serum, transforming growth factor beta, or isolated matrix itself is accompanied by sorting out of the two tissues. Sorting out is blocked reversibly by inclusion of the fibronectin adhesion site peptide, GRGDSP. Invasion of fused aggregates is preceded by a redistribution of the fibronectin-containing matrix of the mesenchymal aggregate such that matrix-poor regions come to occupy the interface with the myocardial partner aggregate. The invasion that ensues involves mesenchymal cells emigrating from, and myocardial cells intruding into, matrix-poor regions of the mesenchymal aggregate.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cell sorting during the regeneration of Hydra from reaggregated cells.

The role of cell sorting in the reorganization of Hydra cell reaggregates was studied. We quantitatively labeled ectodermal and endodermal cells by incubating whole animals in fluorescent beads or by injecting the beads into the gastric cavity. Beads were stably incorporated into the cells by phagocytosis. Our data show that dramatic cell sorting processes drive the formation of ectoderm and endoderm within the first 12 hr of reaggregation. After the ectoderm is established, no further rearrangement could be observed. We also tested the ability of cells to sort out with respect to their original position in Hydra by dissociating labeled apical and basal pieces of Hydra and measuring the clumping of labeled cells during reorganization. There was no increase in the clumping of cells during reorganization indicating that cell sorting is not involved in the formation of early activation centers. There was also no preferential incorporation of apically derived (presumptive head) tissue into tentacles that subsequently formed, indicating that after dissociation into single cells there is no predisposition of erstwhile presumptive head tissue to form heads.     

Difference between dorsal and ventral iris in lens producing potency in normal lens regeneration is maintained after dissociation and reaggregation of cells from the adult newt, Cynops pyrrhogaster

In Wolffian lens regeneration, lentectomized newt eye can produce a new lens from the dorsal marginal iris, but the ventral iris has never shown such capabilities. To investigate the difference of lens regenerating potency between dorsal and ventral iris epithelium at the cellular level, a transplantation system using cell reaggregates was developed. Two methods were devised for preparing the reaggregates from pigmented iris epithelial cells. One was rotating cells in an agar-coated multiplate on a gyratory shaker and the other was incubating cells in a microcentrifuge tube after slight centrifugation. Reaggregates made of dorsal iris cells that had been completely dissociated into single cells were phenotypically transformed into a lens when placed in the pupillary region of the lentectomized host eye. None of the ventral reaggregates produced a lens. Even dorsal reaggregates could not transdifferentiate into lens when they were placed away from the pupil. The produced lenses from the reaggregates were morphologically and immunohistochemically identified. To obtain evidence whether produced lenses really originated from singly dissociated cells, we labeled dissociated cells with a fluorescent dye (PKH26) before reaggregate formation and then traced it in the produced lens.     

Contacts between pigmented retina epithelial cells in culture.

The behaviour of primary cultures of dissociated embryonic chick pigmented retina epithelial (PRE) cells has been investigated. Isolated PRE cells have a mean speed of locomotion of 7-16 mum/h. Collisions between the cells normally result in the development of stable contacts between the cells involved. This leads to a gradual reduction in the number of isolated cells and an increase in the number of cells incorporated into islands. Ultrastructural observations of islands of cells after 24 h in culture show that junctional complexes are present between the cells. These complexes consist of 2 components: (a) an apically situated region of focal tight junctions and/or gap junctions, and (b) a more ventrally located zonula adhaerens with associated cytoplasmic filaments forming a band running completely around the periphery of each cell. The intermembrane gap in the region of the zonula is 6-0-12-0 nm. The junctional complexes become more differentiated with time and after 48 h in culture consist of an extensive region of tight junctions and/or gap junctions and a more specialized zonula adhaerens. It is suggested that the development of junctional complexes may be responsible for the stable contacts that the cells display in culture.     

Evaluation of different procedures for the dissociation of retinal pigmented epithelium into single viable cells

Retinal pigmented epithelium (RPE) from 7-day-old chicken embryos (stages 29 to 31) was isolated and dissociated into single cells using different procedures. The results were assessed in two ways. (1) The yield of single RPE cells per embryo was determined, and their ability to form pigmented colonies in clonal culture was tested. The most efficient and gentle procedure included isolation of the RPE in EDTA solution, trypsinization at low temperature and low enzyme concentration in the presence of EDTA, followed by incubation in culture medium for up to 4 hr. The completely dissociated cells thus obtained had a much higher plating efficiency and more uniform pattern of colony growth and differentiation than those obtained under any other conditions tested. (2) The effects of different treatments on cell junctions and morphological integrity of the cells were determined by transmission electron microscopy. EDTA solution yielded excellent separation of the epithelial sheet from the mesenchyme by dissociating it from Bruch's membrane, but had little effect on the junctions between adjacent RPE cells. Trypsinization of the epithelium under various conditions separated the basal lateral cell borders and caused loss of gap junctions, but left many cells still joined by apical tight junctions. Final disruption of the tight junctions occurred during recovery of the trypsinized cells in culture medium and was accompanied by dedifferentiation of the RPE cells.     

Herpes simplex virus gE/gI expressed in epithelial cells interferes with cell-to-cell spread

The herpes simplex virus (HSV) glycoprotein heterodimer gE/gI plays an important role in virus cell-to-cell spread in epithelial and neuronal tissues. In an analogous fashion, gE/gI promotes virus spread between certain cell types in culture, e.g., keratinocytes and epithelial cells, cells that are polarized or that form extensive cell junctions. One mechanism by which gE/gI facilitates cell-to-cell spread involves selective sorting of nascent virions to cell junctions, a process that requires the cytoplasmic domain of gE. However, the large extracellular domains of gE/gI also appear to be involved in cell-to-cell spread. Here, we show that coexpression of a truncated form of gE and gI in a human keratinocyte line, HaCaT cells, decreased the spread of HSV between cells. This truncated gE/gI was found extensively at cell junctions. Expression of wild-type gE/gI that accumulates at intracellular sites, in the trans-Golgi network, did not reduce cell-to-cell spread. There was no obvious reduction in production of infectious HSV in cells expressing gE/gI, and virus particles accumulated at cell junctions, not at intracellular sites. Expression of HSV gD, which is known to bind virus receptors, also blocked cell-to-cell spread. Therefore, like gD, gE/gI appears to be able to interact with cellular components of cell junctions, gE/gI receptors which can promote HSV cell-to-cell spread.     

Effect of pigmented epithelium from different developmental stages of chick embryo on cell growth of retinal explants

The model system to investigate the effect of retinal pigmented epithelium (PE) on the retinal development in vitro has been established in this laboratory. Chick retina separated from 5-day-old embryo (E 5) were cut into strips and explanted on the collagen substratum either in close contact with retinal PE (RPE), or without PE (R). The rates of cell proliferation of retinal strips cultured for 48 hr were measured by the uptake of radioactive thymidine and DNA contents. Both parameters in RPE were increased to values ranging from 137 to 167% when PE was taken from E5 and E6. However PE taken from E7, E8 and E9 had no effect on cell proliferation. The rate of cell proliferation of retina were increased both when separated retina and PE of E5 either from same or from an other eye closely contact again and when retina and PE of E5 were explanted together without separation. However the rates of cell proliferation were remained without much change when a millipore filter existed between retina and PE of E5 as well as the retina was inverted, the ganglion cell layer contacted with PE. The neurite outgrowth from retina explant with and without PE of E5 or E6 were also different. After culture for 24 hr the fiber length of neurite growing in RPE was only 36-39% of that in R. After 48 hr it was about 70% of that in R. This results suggested that the developmental stage of PE and the direct cell-to-cell contact of PE from E5 with photoreceptor layer of retina was important for the retinal cell proliferation. But PE had negative influence on neurite growth of retina in culture.     

Contact inhibition of locomotion and the structure of homotypic and heterotypic intercellular contacts in embryonic epithelial cultures

Epithelia from the early chick embryo have been grown in culture and then fixed for electron microscopy so that the ultrastructure of intercellular contacts could be examined. Epithelia were used which showed various forms of contact inhibition of locomotion upon confrontation with one another. Confrontations of hypoblast with hypoblast after 6 days, and endoblast with endoblast after 24 h showed type 1 contact inhibition and formed desmosomes and zonulae adhaerentes with extensive microfilament collinearity between apposed cells. Hypoblast-hypoblast confrontations after 24 h resulted in type 2 contact inhibition with considerable ruffling and position shifting. In this case desmosomes were absent and microfilament collinearity was restricted. Endoblast cells after 24 h in culture show type 2 inhibition with respect to hypoblast monolayers which they infiltrated upon confrontation. Examination of these heterotypic contacts also showed an absence of desmosomes and reduced adhaerens junctions. Intermediate filaments accumulated at all contact sites examined. It is concluded that whereas type 1 contact inhibition of locomotion in these epithelial cells is accompanied by desmosome formation and extensive zonula adhaerens junctions, type 2 inhibition is not. These junctional deficiences may be responsible in part for the cell motility characteristically observed in monolayers of type 2 inhibited cells.     

The ability of the epithelium of diencephalic origin to differentiate into cells of the ocular lens.

After the discovery that in adult salamanders following lentectomy a new, functional lens develops by transdifferentiation (cell-type conversion) of previously depigmented epithelial cells of the iris (Wolffian lens regeneration), this phenomenon has been intensively studied by various experimental approaches. During the last two decades it was shown that pleiomorphic aggregates of atypical lens cells (lentoids) differentiated in reaggregates of dissociated cells of the chick neural retina and in spread cell cultures of the pigmented epithelium of the iris and retina, of the neural retina and the pineal gland of the chick embryo. The neural retina of human fetuses and adults also displayed this capacity. We showed that lentoids developed at a low incidence in renal isografts of rat embryonic shields or isolated embryonic ectoderm and of lentectomized eyes of rat fetuses, as well as in organ cultures of rat embryonic shields in chemically defined media. The addition of transferrin significantly increased the incidence of differentiation of lentoids in explants. In both renal isografts and explants in vitro a continuous transformation of retinal epithelial cells into atypical lens cells was observed. In renal isografts lentoids were also observed to originate from the ependyma of the brain ventricle. All tissues having the capacity to convert into lens cells belong to the diencephalon in a broad sense. Evolutionary aspects of this feature are discussed.     

Alpha-actinin and actin in the outer retina: a double immunoelectron microscopic study

Actin has many diverse functions in the outer retina. To help elucidate its organization in this area, we have investigated the extent of its association with the actin cross-linking protein alpha-actinin. Ultrathin sections of chicken retina were double-immunolabelled with monospecific antibodies against actin and alpha-actinin. The highest relative amount of alpha-actinin to actin label was measured in the adherens junctions between the individual retinal pigmented epithelial (RPE) cells and between the photoreceptor and Mueller cells; in the photoreceptor myoid; and in the RPE basal microvilli. The lowest amount was in the Mueller cell microvilli, the RPE apical processes, and in the photoreceptor ellipsoid. It is likely that the areas containing the highest ratio of alpha-actinin to actin labelling are where the actin filaments are most highly cross-linked into bundles and linked to the plasma membrane by alpha-actinin. Actin filaments terminate in these areas, and, except for the myoid region, they are involved in cell-cell or cell-substrate adherens junctions.     

Cone connections of the horizontal cells of the rhesus monkey's retina

The presence in the rhesus monkey's retina of a second morphological type of horizontal cell (H2), described by Kolb et al. (1980), is confirmed. Both types of cell are here further described. Their cone connections are quantified and compared with those of mammals and other vertebrates. The dendrites and axons of the H2 type of cell contact only cones as do the dendrites of the H1 cell (originally described by Polyak (1941)) which has an axon contacting only rods. The dendrites of foveal H2 cells contact between 11 and 14 cones; those of H1 contact 7. The number of cones that each type of cell contacts increases with increasing distance from the fovea, so that, by 5-6 mm eccentricity, H2-type cells synapse with between 20 and 30 cones, and the H1 cells with 12-15. The qualitatively estimated coverage factors of each are 3 or 4; every cone synapses with more than one of both types. Neither type of horizontal cell makes chromatically specific connections that are anatomically recognizable, unlike the situation in some teleostean and turtle retinae. Individual horizontal cells, particularly those connected to foveal cones, may have different ratios of chromatic input. At equivalent eccentricities, up to about 6 mm from the fovea, the dendritic fields of H2 horizontal cells are about twice the size of H1 cells and contact about twice the number of cones. These relative differences are closely similar to those of the cat's horizontal cells and it is suggested that they are a basic feature of most placental mammals. The organization of foveal cone fibres within Henle's layer is described. The distribution of primate cone telodendria, gap junctions and synapses in the outer plexiform layer are briefly reviewed and compared with those of other vertebrate retinae.     

Development of a new coulter counter system: Measurement of the volume,internal conductivity,and dielectric breakdown voltage of a single guard cell protoplast ofVicia faba

Summary Two intracellular microelectrodes were used to study electrotonic interaction between cultured embryonic (16- to 20-day-old) chick myocardial cells reaggregated into small spheresin vitro. Under different culture conditions, reaggregates with two types of functional membrane properties were produced: (i) highly differentiated reaggregates, and (ii) reverted reaggregates. In the highly differentiated state, the cells had high stable resting potentials and produced rapidly-rising tetrodotoxin (TTX)-sensitive action potentials in response to electric field stimulation. In the reverted state, the cells exhibited slowrising spontaneous action potentials having prominent pacemaker potentials and TTX-insensitive upstrokes. These states resemble electrophysiological properties of the highly differentiated (18 daysin ovo) and less fully differentiated (3 daysin ovo) intact embryonic chick heart, respectively. Both types of reaggregates had similar ultrastructural appearance, with many elongated cells and intercalated disc-like structures; gap-like junctions were not seen. The highly differentiated cells had input resistances of about 5 M, and exhibited only little electrotonic interaction in response to intracellular current injection either when the cells were at rest or during the action potential plateau. Intracellular stimulation produced propagating action potentials which triggered contraction of the entire reaggregate. Large hyperpolarizing current pulses applied during the action potential plateau caused premature repolarization which also propagated to the other impaled cell. In the reverted reaggregates, electrotonic interaction was weak or absent in about 52% of the impaled cell pairs, moderate in 30%, and strong in 18% (encountered only at interelectrode distances of less than 100 m). The difference in degree of electrotonic interaction may be due to the state of differentiation with respect to the membrane electrical properties.     

EXPERIMENTAL MANIPULATION OF ALTERNATIVE PATHWAYS OF DIFFERENTIATION IN CULTURES OF EMBRYONIC CHICK NEURAL RETINA

Embryonic chick neural retina cells can transdifferentiate during long-term cell culture into either pigmented epithelium or lens fibres. We have found that some culture conditions influence the choice between these pathways. Pigment cell development is promoted by low initial cell densities and by the use of a medium based on Earle's salt formulation rather than Hank's, while lens fibre development is encouraged by high initial cell densities and by folding the cell sheet into multilayered regions. Some differences in in vitro cell properties of neural retina are reported for two genotypes previously found to exhibit differences in in vitro cell properties of lens epithelial cells.