AN ASSAY FOR INTERCELLULAR ADHESIVE SPECIFICITY

A modification of an assay for intercellular adhesive specificity is described. The method involves the collection of radioactively labeled cells by aggregates of the same (isotypic aggregates) or different (heterotypic aggregates) types of tissue and determination of the number of cells collected by liquid scintillation counting. The use of ³²P to label the tissues permitted a much more rapid estimation of cell collection than was obtained previously. With the use of chick embryo neural retina, liver, forebrain, pectoral muscle, and heart ventricle tissue, it was shown that isotypic was always greater than heterotypic collection. Labeled neural retina cell collection by neural retina aggregates was studied as a function of time, cell suspension density, aggregate diameter, temperature, and aggregate number. Neural retina aggregates were treated with certain enzymes in an attempt to determine whether specific changes on the surface of the aggregates would interfere with labeled neural retina cell collection. Of the various proteases and glycosidases tested, only β-galactosidase rendered the surface more nonspecific.     

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.     

Scanning electron microscopy of cell aggregation: cardiac and mixed retina-cardiac cell suspensions

Reaggregates of cells from 7-day embryonic chick hearts, 10-day neural retinas and respective cell mixtures were examined by scanning electron microscopy (SEM). Cardiac cell aggregates formed during the first 2 hours were composed of rounded cells arranged in linear or branched arrays. By further collection of single cells and accretion of cell clusters, the aggregates increased in size and formed large grape-like masses. By 12 hours, heart aggregates assumed a spherical shape with partial sorting-out of myogenic from non-myogenic cells; the muscle elements occupied the interior of the aggregates, whereas flattened, squamous-like cells, of a non-muscle character, covered the surface in a multilayered epithelium. Single rounded cells were still found on the surface of 12 to 24-hour aggregates; however, they were absent by 48 hours, suggesting that the collection of free cells by the cardiac aggregates ceased during the second day. Early aggregates (2 hours) of retina cells showed initial stages of axonal and dendritic outgrowth characteristic of neural tissue. Examination of heterotypic aggregates of neural retina and myocardial cells after 2 to 6 hours showed small groups of retina cells attached to the surface of the heart cell clusters. The retina cells did not appear to be randomly distributed within the early aggregates but formed small tissue specific clusters even by 2 hours in culture. These results indicate that SEM should be a valuable tool in the further analysis of homo- and heterotypic cellular aggregation.     

Use of preformed cell aggregates and layers to measure tissue-specific differences in intercellular adhesion

The binding of aggregates formed from various 7-day chick embryo tissues to cultured cell layers was analyzed 24 hr following trypsin dissociation of the tissues. The proprotion of aggregates binding is independent of the number of aggregates added, and changes with time over 60 min in a manner consistent with a first-order process. The adhesive parameter measured, the percentage of aggregates binding to cell layers per unit time, varies slightly with aggregate size but is not dependent upon the probability of collision of the aggregate with the layer. The rate of binding and the effect of modifiers of binding (temperature, inhibitors of oxidative metabolism and glutaraldehyde) are substantially different for neural retina interactions than for liver or heart interactions, suggesting that retina cells may form intercellular bonds via a mechanism distinct from that of liver or heart cells. The rate of binding between like tissue types is, with one exception, greater than between unlike types. Glutaraldehyde treatment of only one of the reactants abolishes this adhesive specificity. Aggregate binding provides a means of quantitatively assessing intercellular adhesion which has the advantage of reducing the effects of trypsinization on measurements of adhesion, and therefore lends itself to the investigation of cellular consequences of adhesion.     

Experimental manipulation of cell surface to affect cellular recognition mechanisms.

The mechanism of selective cell adhesion was studied using Chinese hamster V79 and chick embryonic neural retinal cells. Both of these cell types have been shown to have two experimentally separable mechanisms of adhesion; Ca²⁺-dependent and Ca²⁺-independent. Cells can be dispersed so that either or both of the mechanisms remain intact by use of different treatments. A method of labeling cells with FITC was devised to identify one of the two types of cells in a binary cell population. When cells with one of the two adhesion mechanisms were mixed with cells with the other mechanism, they segregated completely, forming independent aggregates, not only in the heterotypic combination of these cell types but also in the homotypic combination of each cell type. In contrast, when cells were mixed with others with the same adhesion mechanism, either Ca²⁺-dependent or -independent, they formed chimeric aggregates, even in the heterotypic cell combination. These results suggest that the specificity in each of those two mechanisms of cell adhesion plays an important role in cellular recognition processes.     

A FINE STRUCTURAL STUDY OF ADHESIVE CELL JUNCTIONS IN HETEROTYPIC CELL AGGREGATES

Mixed suspensions of cells obtained by dissociation of 7 day chicken embryo heart and pigmented retina were allowed to reaggregate in tissue culture. The reaggregates which resulted contained both kinds of cells. Establishment of homogeneous tissues by cell sorting out in these reaggregates was advanced by 20 hr in culture and was complete within 2 days. When sorting out was advanced, heterotypic aggregates were fixed, sectioned, and examined in the electron microscope. Particular attention was paid to the morphology of regions of contact between cells. No qualitative differences were observed in the contact junctions between like cells (heart-heart or pigmented retina-pigment retina junctions) and unlike cells (heart-pigmented retina junctions). Broad areas of undifferentiated cell contact with cell membranes separated by a 100–200 A gap were formed regardless of cell type. Specialized junctions of the fascia and macula adherens type were also present, not only between like cells but also between unlike cells.     

A requirement for trypsin-sensitive cell-surface components for cell-cell interactions of embryonic neural retina cells

A quantitative assay was used to measure the rate of collection of a population of embryonic neural retina cells to the surface of cell aggregates. The rate of collection of freshly trysinized cells was limited in the initial stages by the rate of replacement of trypsin-sensitive cell- surface components. When cells were preincubated, or "recovered," and then added to cell aggregates, collection occurred at a linear rate and was independent of protein and glycoprotein synthesis. The adhesion of recovered cells was temperature and energy dependent, and was reversibly inhibited by cytochalasin B. Colchicine had little effect on collection of recovered cells. Antiserum directed against recovered cell membranes was shown to bind to recovered cells by indirect immunofluorescence. The antiserum also was shown to inhibit collection of recovered cells to aggregates, suggesting that at least some of the antigens identified might be involved in the adhesion process. The inhibitory effect of the antiserum was dose dependent . Freshly trypsinized cells absorbed neither the immunofluorescence activity nor the adhesion-inhibiting activity. Recovered cells absorbed away both activities. In specificity studies, dorsal neural retina cells adhered to aggregates of ventral optic tectum in preference to aggregates of dorsal optic tectum. The adhesive specificity of the dorsal retina cells was less sensitive to trypsin than the adhesive specificity of ventral retina cells which adhered preferentially to dorsal tectal aggregates only after a period of recovery.     

Differential Glycosylation of the 5A11/HT7 Antigen by Neural Retina and Epithelial Tissues in the Chicken

Abstract: The 5A11/HT7 antigen, a member of the immunoglobulin supergene family, has been implicated in heterotypic cell-cell interactions during retina development. Immunopurified 5A11 antigen isolated from Nonidet P-40-solubilized retina membranes had two components as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), a 45.5-kDa doublet and a 69-kDa polypeptide. Immunoreactive bands of 46-50 kDa were recognized following SDS-PAGE of detergent-solubilized membrane proteins from liver, kidney, and erythrocytes. Treatment with N-glycosidase F (EC 3.2.2.18) converted the 45.5–50-kDa immunoreactive polypeptides from all tissues to 32 kDa, indicating that the observed differences in molecular mass were due to differences in glycosylation. N-Glycosidase Ftreatment also converted the 69-kDa form from retina to 46 kDa, indicating a different polypeptide core than the 32-kDa species. Treatment with endo-β-N-acetylglucosaminidase H (EC 3.2.1.96) resulted in modest increases in electrophoretic mobility due to hydrolysis of high mannose or hybrid oligosaccharides and lack of hydrolysis of complex oligosaccharides resistant to endo-β-N-acetylglucosaminidase H digestion. Immunoreactivity was retained after deglycosylation. Much of the difference in molecular weight could be attributed to variations in sialylation. The higher molecular mass species of the 45.5-kDa doublet from retina and the polypeptides from other tissues were susceptible to neuraminidase (EC 3.2.1.18) and O-glycosidase (endo-α-N-acetylgalactosaminidase; EC 3.2.1.97) digestion. Labeling with elderberry bark lectin (specific for α2, 6-linked sialic acid) was confined to the higher molecular mass species of the 45.5-kDa doublet and was considerably greater in antigen derived from epithelia rather than neural retina. In paraffin sections of chick retina, elderberry bark lectin staining was confined to the retinal pigmented epithelium, photoreceptor cells, and bipolar cells with no staining of the Müller cells, which bear the bulk of the 5A11 antigen. These results indicate tissue-specific posttranslational modifications, particularly differences in sialylation of antigen-bearing polypeptides.     

Sorting out in heterotypic cell aggregates is regulated by differences in the cell surface charge

Random aggregates of heterotypic cells derived from two different embryonic tissues sort out into homotypic zones, one enclosing the other. The specification of the enclosed or enclosing position is based on a tissue hierarchy. Cells differ in their net negative charge as indicated by their different isoelectric points (pI). The cells of higher pI enclose the cells of lower pI. Cell pI is lowered by treatment with heparin. Cells with experimentally altered pI also sort out, and their position is specified by the differences in their pI. It is suggested that the cell surface ionogenic groups determine the free surface energy which controls the positioning of cells in a mixed aggregate.     

A requirement for reversible binding between aggregating embryonic cells before stable adhesion.

Chick embryonic liver and neural retina cells aggregate in a two-step process. Initially, cells formed a loose association in a step that apparently did not require metabolic energy. Cells bound in this manner were dissociable by mild shear forces or by simple dilution. The results of the dilution experiments suggest a readily reversible binding of single cells to form these types of aggregates. In a second step, which required metabolic energy, the cells became firmly, or stably attached. The formation of both types of bond was temperature-dependent. Kinetic studies indicated that the formation of reversible bonds between cells was required before the cells could become stably attached, and that reversibly bound cells were converted directly into stably bound cells.     

Can retinal adhesion mechanisms determine cell-sorting patterns: a test of the differential adhesion hypothesis

Embryonic chick neural retina cells possess two classes of adhesion mechanism, one Ca2+-independent, one Ca2+-dependent, responsible for short-term cell aggregation. This study investigates the role of these mechanisms in the long-term cell sorting potentially relevant to in vivo histogenesis. Retina cells are prepared either with both (E cells) or with only one mechanism (TC cells, CD; LTE cells, CI), respectively. The two types of cell preparations are differentially labelled using fluorescein or rhodamine isothiocyanate, mixed and allowed to aggregate in the presence or absence of cycloheximide at 0.5 microgram ml-1 to retard metabolic recovery of the removed adhesive mechanism. When observed by fluorescence and phase-contrast microscopy, the aggregates formed in cycloheximide show cell sorting, the cells with both mechanisms assuming a more interior position relative to those with a single adhesion mechanism. In parallel hanging-drop experiments, preformed aggregates of cells with a single adhesion mechanism are seen to spread upon aggregates of cells with both mechanisms. No sorting occurs amongst cells from a given stage prepared using any single dissociation protocol. The observed cell sorting would thus seem to derive exclusively from differential cell adhesiveness dependent upon the different dissociation conditions and maintained in the presence of cycloheximide. The experiments support the hypothesis that the dual CI and CD adhesion mechanisms in question can play a central role in governing cell-sorting behaviour during normal histogenesis.     

Intercellular adhesive selectivity. I. An improved assay for the measurement of embryonic chick intercellular adhesion (liver and other tissues)

An improved assay for measuring intercellular adhesive selectivity of embryonic chick liver cells is described. Three major improvements over earlier procedures are noted: (a) enhanced reproducibility of liver cell-liver cell aggregate adhesion (homotypic adhesion) was achieved; (b) 25-70% of the input cells adhered to the collecting aggregates during the course of routine experiments as compared to the 0.25% in earlier assays. This increase in cellular adhesion suggests that the observed cell pick-up is a characteristic of the majority of the dissociated liver cell population; (c) the rate of intercellular adhesion was increased 1,000-fold. The main feature of the assay is that it measures the tissue adhesive selectivities of the dissociated cell population. Studies were undertaken on three embryonic chick tissues (liver, neural retina, and mesencephalon) to determine the tissue selectivity of intercellular adhesion of these dissociated cell types. Some general properties of liver cell homotypic adhesion have been studied and are reported.     

Intercellular adhesion in butyrate-treated HeLa S3 cultures : Flow cytometric analysis

The application of DNA flow cytometry (FCM) for analysis of sodium butyrate-induced intercellular adhesion in human carcinoma (HeLa S3) cell cultures is described. To prepare cell suspensions for FCM, the monolayers of cells were treated with medium containing 10% serum, 0.2% non-ionic detergent Triton X-100 and 1 μg/ml DNA fluorochrome 4,6′-diamidino-2-phenylindole (DAPI). Total numbers of single cells, and aggregates containing two, three, four or more cells, were determined from DNA histograms. In cultures treated with 5 mM butyrate for 16 h, more than 80% of the cells were aggregated. Intercellular adhesion began to appear 8 h after addition of butyrate, was maximal at 16–24 h and stable in the presence of butyrate, but disappeared 24 h after its removal. Treatment with EDTA (0.2%) dissociated only 50%, whereas trypsin (0.1%) separated all cell aggregates into single cells. Actinomycin D (actD) (0.5 μg/ml) prevented cell adhesion while blocking of cells in S phase with 250 μM 5-fluorouracil or 10 μM methotrexate did not interfere with aggregation. The number of cell aggregates estimated from DNA histograms of butyrate-treated HeLa S3 cultures was the same after staining with DAPI in the presence of Triton X-100 or after vital staining with Hoechst 33342. The DNA content was used as a marker to estimate the cellular composition of aggregates in mixed cultures of HeLa S3 cells and human fibroblasts (U cells). Intercellular adhesion in these cultures was seen only between HeLa S3 cells, indicating specificity of butyrate-induced cell aggregation. FCM provides fast automatic measurement of cell aggregate formation, estimates frequency of aggregates containing different cell numbers, shows participation of cells at different cycle phases in aggregates, and allows the detection of homotypic from heterotypic cell aggregates if the interacting cells have different DNA ploidy.     

Mobility of normal and virus-transformed cells in cellular aggregates

The mobility of embryonic chick cells and cells of four established cell lines was examined in cellular aggregates. This was done by preparing aggregates of unlabeled cells and allowing cells of the same type, but prelabeled with [3H]thymidine, to adhere to the surface of the aggregates. After 2-1/2 days in agitated liquid culture the positions of the labeled cells within the aggregates were determined by autoradiographic techniques. Since the labeled and unlabeled cells were otherwise identical, the degree of penetration of the labeled cells into the aggregates was taken as a measure of the mixing or mobility of cells in the aggregate. With this procedure, embryonic chick liver, heart, and neural retina cells were found to move an average of 2.12, 2.68, and 4.00 cell diameters inward, respectively. Mouse fibroblast BALB/c 3T3 cells moved an average of 1.13 cell diameters inward, while Simian virus 40 (SV40)-transformed BALB/c 3T3 cells moved as much as 8.80 cell diameters inward, indicating that cells of the malignant SV40-transformed line were considerably more mobile than the corresponding nonmalignant 3T3 cells. In contrast, cells of the hamster fibroblast line NIL B moved 4.17 cell diameters in 2-1/2 days, while SV40-transformed NIL B cells moved 3.00 cell diameters in the same time. It was therefore concluded that infection with oncogenic viruses does not necessarily result in increased cellular mobility.     

Adult peripheral blood mononuclear cells transdifferentiate in vitro and integrate into the retina in vivo

Adult peripheral blood-derived cells are able to differentiate into a variety of cell types, including nerve cells, liver-like cells and epithelial cells. However, their differentiation into retina-like cells is controversial. In the present study, transdifferentiation potential of human adult peripheral blood mononuclear cells into retina-like cells and integration into the retina of mice were investigated. Freshly isolated adult peripheral blood mononuclear cells were divided into two groups: cells in group I were cultured in neural stem cell medium, and cells in group II were exposed to conditioned medium from rat retinal tissue culture. After 5 days, several distinct cell morphologies were observed, including standard mononuclear, neurons with one or two axons and elongated glial-like cells. Immunohistochemical analysis of neural stem cell, neuron and retina cell markers demonstrated that cells in both groups were nestin-, MAP2 (microtubule-associated protein)- and GFAP (glial fibrillary acidic protein)-positive. Flow cytometry results suggested a significant increase in nestin-, MAP2- and CD16-positive cells in group I and nestin-, GFAP-, MAP2-, vimentin- and rhodopsin-positive cells in group II. To determine survival, migration and integration in vivo, cell suspensions (containing group I or group II cells) were injected into the vitreous or the peritoneum. Tissue specimens were obtained and immunostained 4 weeks after transplantation. We found that cells delivered by intravitreal injection integrated into the retina. Labelled cells were not detected in the retina of mice receiving differentiated cells by intraperitoneal injection, but cells (groups I and II) were detected in the liver and spleen. Our findings revealed that human adult peripheral blood mononuclear cells could be induced to transdifferentiate into neural precursor cells and retinal progenitor cells in vitro, and the differentiated peripheral blood mononuclear cells can migrate and integrate into the retina in vivo.     

The reorganization of the extracellular matrix in mixed monolayer cultures]

Heterotypic cells in combined monolayer sheets can push each other from the substratum due to a competition in attachment of pseudopodia of contacting heterotypic cells: different types of epithelium can push each other and fibroblasts from the substratum in mixed cultures. The formation of extracellular matrix in mixed cultures was studied with antisera to fibronectin and laminin by immunofluorescent microscopy. It was shown that one group of cells in the sheet pushed another group together with their extracellular matrices. It is supposed that the interaction of contacting heterotypic cells and associated extracellular matrices may play an important role in distribution of different cell types in embryogenesis and carcinogenesis.     

The stromal colony-forming cell (CFUf) count in the bone marrow of mice and the clonal nature of the fibroblast colonies they form

The clonal nature of FCFC-derived stromal colonies was tested by chromosomal analysis in mixed cultures of CBA and CBAT6T6 bone marrow cells depleted of macrophages and myeloid cells. Inoculation of the bone marrow cell suspensions in flasks coated with poly-l-lysine has revealed practically no stromal aggregates among the explanted cells. The coincidence of karyotypes within the stromal colonies in the mixed cultures proved that the FCFC-derived colonies were cell clones. It was shown by indirect immunofluorescence with antibodies to type 1 collagen that the mouse bone marrow FCFC-derived colonies consisted of stromal fibroblasts. The cloning efficiency of the bone marrow FCFS depends on the explantation density of cells; a stable colony-forming efficiency could be reached only in the presence of feeder cells (irradiated bone marrow). In the bone marrow cells suspensions obtained by trypsinization the amount of FCFC is markedly higher than in the suspensions of mechanically disaggregated bone marrow cells.     

Evidence for lymphocyte chemotaxis toward monocytes during PHA-induced aggregation in vitro.

An important, early phenomenon during the development of immune cell interactions in vitro is the formation of multicellular aggregates. We have developed a quantitative assay to determine the kinetics of multicellular aggregate formation within a heterotypic population of cells on a flat surface. This assay follows the time rate of change in the value of an aggregation index for cells in undisturbed culture. For an initial, well-separated population of cells, the index is a minimum and remains at this value if the cells do not move and interact. By contrast, for conditions that promote active cell movement followed by interaction, the index value increases with time. The index, which reflects cells' relative spatial distributions, is an "indirect enumeration" of the number of cells within aggregates as a function of time. We used this index to follow the aggregative behavior of a population of freshly isolated human peripheral lymphocytes and monocytes. Previous studies have shown that monocytes are centrally located within aggregates and that lymphocytes move to surround monocytes. In order to test if lymphocyte movements are random or directed prior to interactions with monocytes, we formulated a simple model to describe changes in the expected number of cells in an "idealized aggregate" as a function of time. A comparison of the model curves with curves generated from the changes in the aggregation index shows that the best fit derives from a model that involves directed movement of lymphocytes toward monocytes. These results suggest that monocytes produce a chemoattracting agent for lymphocytes for these experimental conditions.     

Cell interactions and the regulation of cholinergic enzymes during neural differentiation in vitro.

Seven-day-old chick embryo neural retina (NR), telencephalon (T), optic lobe (OL), and rembencephalon (Ro) were dissociated, and the resulting cell suspensions were allowed to reaggregate in vitro during 3 days either independently or in different binary combinations. Interactions could be detected by the comparison of the activity of the enzymes of the cholinergic system, choline acetyltransferase (CAT) and acetylcholinesterase (ACE), in “pure” and “combined” aggregates.The results clearly show that the activity of both enzymes in embryonic neural cells can be modified selectively by interactions between different cell populations. Thus, combined NR-OL aggregates show an increase in CAT without changes in ACE, NR-T an increase in CAT and a decrease in ACE, T-Ro a decrease in both CAT and ACE, and OL-T no changes at all. Experiments in which NR and OL cells were combined in different proportions indicate that the interactions require the presence of defined numbers of cells from each kind. Isochronous and heterochronous combinations of 7- and 10-day-old NR and OL cells show that the interactive capacities of the cells change with development.     

Specificity of intercellular adhesion mediated by various members of the immunoglobulin supergene family

The immunoglobulin supergene family members have been shown to be involved in cell-cell recognition and interaction during cell growth and differentiation. Neural cell adhesion molecule, myelin-associated glycoprotein, and carcinoembryonic antigen (CEA) are immunoglobulin supergene family members which can mediate cell adhesion. We show here that nonspecific cross-reacting antigen (NCA), a closely related CEA family member, is found on the surface of rodent cells transfected with functional NCA complementary DNA in different glycosylated forms, all of which can be deglycosylated to an Mr 35,000 core protein. Furthermore, NCA can mediate Ca2(+)-independent, homotypic aggregation of these NCA-producing transfectant cells. Since CEA has three internal repeated C2-set, immunoglobulin-like domains, whereas NCA has one, only one such domain is required for the intercellular adhesive function. We also demonstrate that NCA- and CEA-producing transfectants can form heterotypic aggregates, whereas mixtures of CEA or NCA transfectants and neural cell adhesion molecule or long form-myelin-associated glycoprotein transfectants sort themselves out into homotypic aggregates. The results suggest that subsets of the immunoglobulin superfamily, such as the CEA family, can be used in both homotypic and heterotypic cellular interactions, whereas less closely related members of the family can be used to separate different cell types by strictly homotypic interactions.