The calcium-dependent cell-cell adhesion system regulates inner cell mass formation and cell surface polarization in early mouse development

Cell surface localisation and stability of uvomorulin during early mouse development

We have examined immunocytochemically the subcellular distribution of the cell adhesion molecule uvomorulin in cleavage stage mouse embryos using conventional and confocal microscopy, under a range of detergent extraction and fixation regimes. Only traces of uvomorulin were detectable on the surface of unfertilised oocytes, whereas between 6 and 11 h after activation detergent-resistant surface expression was evident. This shift correlates with previously demonstrated changes in the pattern of synthesis and accumulation of uvomorulin from precursor state in unfertilised oocytes to mature protein after fertilisation. Embryos at subsequent stages up to the 8-cell stage exhibited a uniform distribution of uvomorulin on free surfaces and its concentration in regions of contact between blastomeres. At the 8-cell stage, during compaction, there was increased intercellular adhesion with concomitant accumulation of uvomorulin at intercellular contacts, whilst free surface uvomorulin was reduced and became relatively more susceptible to detergent extraction. When compact 8-cell embryos were decompacted in calcium-free medium, uvomorulin at contacts decreased while free surface and cytoplasmic staining increased. Blastomeres disaggregated from 4- and 8-cell embryos showed traces or 'footprints' of anti-uvomorulin staining in regions previously in apposition. These footprints disappeared over 45-60 min, during which time uvomorulin distribution became uniform. Possible mechanisms underlying the rearrangements which take place both at fertilisation and during compaction and experimental decompaction are discussed.

Differences in the effects of treatment of uncompacted and compacted mouse embryos with phorbol esters on pre- and postimplantation development

Differences are described in the effects of treatment of preimplantation mouse embryos with low levels (0.01-1 nM) of phorbol myristate acetate (PMA), during three different periods of a 48-h culture from the 2-cell stage, on pre- and postimplantation development. Treatment of embryos with PMA for 48 h (first group) or 24 h (second group) from the 2-cell stage caused premature cavitation (prior to the 16-cell stage) and it also reduced the size and alkaline phosphatase (ALPase) activity of inner cell masses (ICMs), as well as the numbers of cells in blastocysts, in a dose-dependent manner. Treatment of early morulae with PMA for 24 h (third group) did not have the above mentioned effects on embryos but inhibited the formation and subsequent enlargement of the blastocoel. The blastocysts that were allowed to develop in the three treatment groups were examined for postimplantation development. Implantation was unaffected in all groups. The survival rate after implantation was low in the first and second groups but relatively high in the third group. The results indicate that an embryo exposed to PMA for 24 h from the 2-cell stage forms a premature blastocoel, and, in such an embryo, quantitative and qualitative differentiation into the ICM is blocked but qualitative differentiation into trophectoderm is uninhibited. Consequently, the embryo can implant but does not survive for a long time. When embryos were exposed to PMA for 24 h from the early morula stage, the formation and enlargement of the blastocoel were inhibited even though the treatment had a minimal effect on other developmental events.(ABSTRACT TRUNCATED AT 250 WORDS)

Staurosporine advances interblastomeric flattening of the mouse embryo

Staurosporine, an inhibitor of protein kinase activity, causes premature intercellular flattening of blastomeres but does not induce their premature polarisation. The flattening induced is calcium dependent, is reversed transiently at mitosis and requires the continuing presence of the drug. Staurosporine also blocks the decompacting effect of phorbol ester on 8-cell embryos.

Differential expression and function of cadherin-like proteins in the sea urchin embryo

Cadherins are Ca(+2)-dependent cell surface proteins involved in the specification of the adhesive properties of cells. They are supposed to play a critical role in morphogenesis and pattern formation. In this paper we show that in the sea urchin embryo there are at least two different cadherins of relative molecular masses 140 and 125 kDa. The 140 kDa cadherin is already present in the fertilized egg and is the sea urchin equivalent of E-cadherin. The 125 kDa cadherin, which can be detected using a broad-spectrum anti-cadherin antibody, appears only at later stages of development. In later embryos these two molecules are distributed differently: E-cadherin is present predominantly in the invaginating endoderm of the gastrula while the 125 kDa protein is present on the cell surface of most epithelia. Consistently with the observed differences in expression and in distribution, antibodies directed against these two cadherins differently perturb sea urchin development. For example, when these antibodies are added to early gastrulas only the antibodies against the 125 kDa component can induce a complete disaggregation of the ectoderm, while anti E-cadherin antibodies induce an abnormal development of the endoderm while the embryo maintains its basic integrity. These results are discussed in view of the need for multiple adhesion receptors during pattern formation and embryogenesis.

Similar responses to pharmacological agents of 1,2-OAG-induced compaction-like adhesion of two-cell mouse embryo to physiological compaction

A comparison was made of responses to pharmacological agents between cell adhesion induced by an activator of Ca(2+)-phospholipid-dependent protein kinase (PKC) and physiological compaction in mouse embryos. An activator of PKC, 1-oleoyl-2-acetyl-sn-glycerol (1,2-OAG) induced the compaction-like adhesion of cells in two-cell embryos within 5-10 min and the adhesion lasted during the course of treatment for 1 h. W-7 and W-5 (calmodulin antagonists) and cytochalasin B and cytochalasin D (inhibitors of the polymerization of microfilaments) each completely interfered with the 1,2-OAG-induced adhesion of cells. Two-cell embryos having once shown evidence of cell adhesion in response to 1,2-OAG were decompacted when they were transferred to a medium that contained 1,2-OAG and any one of the agents described above. Colchicine and colcemid (inhibitors of the polymerization of microtubules) and tunicamycin (an inhibitor of N-linked protein glycosylation) each had no effect on the 1,2-OAG-induced adhesion of cells. In Ca(2+)-free medium, treatment with 1,2-OAG failed to induce any cell adhesion. These results are very similar to those reported for physiological compaction at the late eight-cell stage. Thus, the compaction-like adhesion of cells in mouse embryos at the two-cell stage appears to be a calmodulin-dependent process, requiring assembled microfilaments and extracellular Ca2+ ions but not microtubules or N-linked glycoproteins as is the case for the physiological compaction.

Molecular cloning of a novel mRNA sequence expressed in cleavage stage mouse embryos

In an approach to study genes transcribed during early mouse development, a cDNA library was constructed from poly(A) RNA isolated from the 8-cell morula. The cDNA library was differentially screened with labelled cDNA probes synthesized on poly(A) RNA isolated from the 8-cell morula or unfertilized eggs. Six clones which increased in abundance in the 8-cell morula were selected and further analyzed. Sequencing analyses showed that some of these clones corresponded to RNA transcripts from B1 and B2 repetitive sequences, as well as mRNA for cytochrome C oxidase I and NADH dehydrogenase III derived from the mitochondrial genome. One clone was not identical to any known sequences. The unidentified sequence (MO25) was found at low levels in the unfertilized egg, but increased at the 2-cell stage. The predicted amino acid sequence revealed that the MO25 gene may encode a Ca2+ binding protein.

Histochemical investigations on lectin binding in normal and irradiated mouse embryos

Lectin binding in normal and irradiated embryonic mouse tissues on day 10 of gestation was studied by peroxidase techniques. Specific binding of Dolichos biflorus lectin (DBA) was detected in the mesodermal blood vessels and in the otic vesicles. The amount of DBA as well as that of soybean agglutinin (SBA) and peanut agglutinin (PNA) increased after exposure to low doses of radiation (0.25, 0.50 and 0.75 Gy). The modifying influence of ionizing radiation was observed in the pituitary region, in the otic vesicles and in the blood vessel endothelium. The greatest effect appeared in the pituitary region at 0.75 Gy, while in the otic vesicles it appeared at 0.50 Gy. A dose-effect relationship was established for the DBA lectin affinity of the vascular endothelium. In comparison to DBA, SBA and PNA displayed more extensive staining after irradiation. The reactivity of these lectins appeared especially pronounced on the blood vessels within the central nervous system and in the luminal surface of the ependymal cells. It is of interest that maximal binding for PNA was observed at 0.25 Gy and for SBA at 0.50 Gy at the junctions between neuroepithelial cells.

Cadherin-mediated cell-cell adhesion is perturbed by v-src tyrosine phosphorylation in metastatic fibroblasts

Rat 3Y1 cells acquire metastatic potential when transformed with v-src, and this potential is enhanced by double transformation with v-src and v-fos (Taniguchi, S., T. Kawano, T. Mitsudomi, G. Kimura, and T. Baba. 1986. Jpn. J. Cancer Res. 77:1193-1197). We compared the activity of cadherin cell adhesion molecules of normal 3Y1 cells with that of v-src transformed (SR3Y1) and v-src and v-fos double transformed (fosSR3Y1) 3Y1 cells. These cells expressed similar amounts of P-cadherin, and showed similar rates of cadherin-mediated aggregation under suspended conditions. However, the aggregates or colonies of these cells were morphologically distinct. Normal 3Y1 cells formed compacted aggregates in which cells are firmly connected with each other, whereas the transformed cells were more loosely associated, and could freely migrate out of the colonies. Overexpression of exogenous E-cadherin in these transformed cells had no significant effect on their adhesive properties. We then found that herbimycin A, a tyrosine kinase inhibitor, induced tighter cell-cell associations in the aggregates of the transformed cells. In contrast, vanadate, a tyrosine phosphatase inhibitor, inhibited the cadherin-mediated aggregation of SR3Y1 and fosSR3Y1 cells but had little effect on that of normal 3Y1 cells. These results suggest that v-src-mediated tyrosine phosphorylation perturbs cadherin function directly or indirectly, and the inhibition of tyrosine phosphorylation restores cadherin action to the normal state. We next studied tyrosine phosphorylation on cadherins and the cadherin-associated proteins, catenins. While similar amounts of catenins were expressed in all of these cells, the 98-kD catenin was strongly tyrosine phosphorylated only in SR3Y1 and fosSR3Y1 cells. Cadherins were also weakly tyrosine phosphorylated only in the transformed cells. The tyrosine phosphorylation of these proteins was enhanced by vanadate, and inhibited by herbimycin A. Thus, the tyrosine phosphorylation of the cadherin-catenin system itself might affect its function, causing instable cell-cell adhesion.

Role of ultrastructural studies in the analysis of cell lineage in the mammalian pre-implantation embryo

Ultrastructural studies have contributed significantly to our understanding of cell lineage differentiation in the mammalian pre-implantation embryo. Such studies have documented, and continue to document, morphological, biochemical, and physiological characteristics of the cell lineages established during the pre-implantation period in eutherian embryos, principally that of the mouse. This review evaluates these contributions and identifies areas of study in which ultrastructural analysis is most likely to have an important role in the future.

Injection of Antisense RNA specific for E-cadherin demonstrates that E-cadherin facilitates compaction, the first differentiative step of the mammalian embryo

We have investigated the effect of antisense E-cadherin RNA in the preimplantation mouse embryo. Antisense RNA was injected into each cell of two-cell embryos that were cultured for 2 days until the normal time of compaction and scored for abnormalities. Embryos injected with the antisense RNA showed delayed compaction compared to the embryos injected with control, or sense, RNA. Delayed cleavage was not the cause because nuclear staining with Hoechst dye 33258 showed about the same number of nuclei in both uncompacted embryos injected with antisense RNA compared with compacted embryos injected with sense RNA at the same hours post human chorionic gonadotropin (hCG). Immunofluorescence with a monoclonal antibody to E-cadherin was markedly diminished in embryos injected with antisense RNA compared with control, injected embryos, suggesting that the observed delayed compaction is due to the inhibition of E-cadherin gene expression by antisense RNA. Embryos injected with antisense RNA eventually compacted and then expressed E-cadherin, but at lower apparent levels than controls. Injection of a single blastomere at the two-cell stage created half-embryo abnormalities.

The genetic program for preimplantation development

This review summarizes information on accumulation profiles of individual gene transcripts in preimplantation development. Most of the information is from the mouse, but some data from other species are reviewed as well. The principal finding is that the transcription of most genes is not temporally linked with any of the three morphogenetic transitions (compaction, cavitation, and blastocoel expansion) that characterize this period. Most genes that are expressed during preimplantation development of the mouse are already being transcribed in the 4-cell stage, and some clearly begin as early as the 2-cell stage. Once activated, a gene continues to be transcribed at least into the blastocyst stage, resulting in continuous mRNA accumulation. Thus the pattern of gene transcription established at the time of genomic activation in the 2-cell stage is perpetuated into the blastocyst, with a few additions along the way. This information is interpreted in light of previous findings concerning the sensitivity of morphogenetic transitions to inhibition of gene expression. The lack of a clear relationship between the timing of expression of most genes and the schedule of morphogenesis leads one to conclude that temporal regulation is imposed downstream of transcription and translation. This conclusion is substantiated by a consideration of factors controlling the events of compaction.

Genes for two calcium-dependent cell adhesion molecules have similar structures and are arranged in tandem in the chicken genome

Genomic sequences immediately upstream of the translational start site for the chicken liver cell adhesion molecule (L-CAM) gene contain a second closely related gene, which, because of its location, we have designated the K-CAM gene. Less than 700 base pairs separate the presumed poly(A) site in the K-CAM gene from the translation initiation site for L-CAM. The sizes of exons 4-15 of the K-CAM gene are almost identical to those in the L-CAM gene and the exon/intron junctions occur at exactly equivalent positions in both genes. Exon 16, which includes the 3' untranslated region, is much shorter in the K-CAM gene and intron sizes and sequences are not generally conserved between the two genes. Probes from the K-CAM gene hybridized to a 3-kilobase mRNA that was present at high levels in embryonic skin, at lower levels in kidney, heart, and gizzard, and at still lower levels in brain and liver, as determined by Northern blotting. The sequence of the predicted gene product was nearly identical to that of the chicken B-cadherin cDNA, although the distribution of the K-CAM gene transcript differed from that reported for the cadherin. The proximity and identical overall structure of the K-CAM and L-CAM genes strongly suggest that they arose by gene duplication and raise the possibility that genes for other calcium-dependent CAMs may be located in clusters. Moreover, the tandem arrangement of the genes may have important implications for the regulation of their expression.

E-cadherin-mediated cell-cell adhesion prevents invasiveness of human carcinoma cells

The ability of carcinomas to invade and to metastasize largely depends on the degree of epithelial differentiation within the tumors, i.e., poorly differentiated being more invasive than well-differentiated carcinomas. Here we confirmed this correlation by examining various human cell lines derived from bladder, breast, lung, and pancreas carcinomas. We found that carcinoma cell lines with an epithelioid phenotype were noninvasive and expressed the epithelium-specific cell-cell adhesion molecule E-cadherin (also known as Arc-1, uvomorulin, and cell-CAM 120/80), as visualized by immunofluorescence microscopy and by Western and Northern blotting, whereas carcinoma cell lines with a fibroblastoid phenotype were invasive and had lost E-cadherin expression. Invasiveness of these latter cells could be prevented by transfection with E-cadherin cDNA and was again induced by treatment of the transfected cells with anti-E-cadherin mAbs. These findings indicate that the selective loss of E-cadherin expression can generate dedifferentiation and invasiveness of human carcinoma cells, and they suggest further that E-cadherin acts as an invasion suppressor.

Experimental manipulation of compaction of the mouse embryo alters patterns of protein phosphorylation

Compaction, occurring at the eight-cell stage of mouse development, is the process of cell flattening and polarisation by which cellular asymmetry is first established. Changes in the pattern of protein phosphorylation have been correlated with this early event of development (TL Bloom, J McConnell: Mol Reprod Dev 26:199-210, 1990). In the study reported here, groups of embryos were treated in ways known to affect particular features of compaction and were then labeled with [32P]orthophosphate; the phosphoproteins obtained were examined following electrophoresis in one and two dimensions. Four-cell embryos were treated with protein synthesis inhibitors, which advance cell flattening. This treatment resulted in only minor differences from the phosphoprotein profile of untreated four-cell embryos. Inhibition of protein synthesis at the eight-cell stage has little effect on cell flattening or polarisation. However, some phosphoproteins that are observed normally in eight-cell but not in four-cell embryos were no longer detectable if labeling took place in the presence of protein synthesis inhibitors. Eight-cell embryos incubated in phorbol 12-myristate 13-acetate, which disrupts various features of compaction, showed a relative increase in the phosphorylation of a group of phosphoprotein spots associated with the eight-cell but not with the four-cell stage. Embryos incubated in Ca2(+)-free medium, which prevents intercellular flattening and delays polarisation, showed a relative decrease in the phosphorylation of the same group of phosphoprotein spots. The behaviour of these phosphoproteins may therefore be correlated with some of the features of compaction.

Production of identical twin and triplet mice by nuclear transplantation

Transplantation of a single nucleus from two- or four-cell embryos into one of the enucleated blastomeres of a two-cell embryo resulted in successful production of identical triplet and twin mice. The proportion of reconstituted embryos that developed in blastocysts was 71% (84/118) when four-cell embryos were used as donors of nuclei; 10 sets of quadruplet and nine sets each of triplet and twin blastocysts were obtained by this technique. After transfer to recipients, 30% (18/61) developed to term, and one set of identical triplet and four sets of identical twin mice were obtained. When two-cell embryos were used as donors of nuclei, 79 (95%) sets of twin embryos developed to blastocysts. Of 38 twin blastocysts transferred to recipients, 21 sets (55%) developed to term as identical twin mice. These results demonstrate that the enucleated two-cell embryo develops in vitro after transfer of a nucleus from a two- or four-cell embryo and the resultant blastocyst has high potential for development to term after transfer to a recipient.

The role of E-cadherin and scatter factor in tumor invasion and cell motility

The acquisition of invasive properties by transformed epithelial cells constitutes an essential step in the progression of carcinomas. We have defined 2 types of interferences leading to enhanced motility and invasiveness of epithelial cells: (i) disturbances of intercellular adhesion, and (ii) treatment with "scatter factor", a secretory protein of mesenchymal cells. Invasive properties (invasion of collagen gels or embryonal heart tissue) are acquired by epithelial cells in vitro when intercellular adhesion is inhibited by antibodies that are specific for the cell-cell adhesion molecule E-cadherin. Furthermore, we found that differentiated human carcinoma cell lines are noninvasive and express E-cadherin, whereas dedifferentiated carcinoma lines are invasive and have lost E-cadherin expression. Invasiveness of these latter cells could be prevented by transfection with E-cadherin cDNA and was again induced by treatment of the transfected cells with anti-E-cadherin antibodies. A correlation between the degree of tumor differentiation and the amount of E-cadherin expression was also visualized on frozen sections of ovarian carcinomas, lobular breast carcinomas, and squamous carcinomas of head and neck. Thus, loss of E-cadherin appears to be a critical step in the establishment of an invasive, i.e. fully malignant phenotype. Scatter factor, which is also capable of dissociating epithelial cell colonies in vitro, was isolated from conditional medium of human fibroblasts; it is a 92,000 mol.wt glycoprotein, which is proteolytically cleaved into 62,000 and 34/32,000 mol.wt subunits. The purified glycoprotein induces invasion of MDCK cells into collagen matrices, and induces or enhances the invasive properties of various human carcinoma cell lines. Sequencing of tryptic peptides of scatter factor revealed strong similarity with hepatocyte growth factor. Furthermore, both factors exhibit identical activities, i.e. scatter factor stimulates DNA synthesis of primary hepatocytes and hepatocyte growth factor dissociates and increases the motility of various epithelial cells. Thus scatter factor and hepatocyte growth factor represent identical or closely similar proteins.

Catenin association with E-cadherin changes with the state of polarity of HT-29 cells

Cadherins are transmembrane glycoproteins that mediate the calcium-dependent adhesion of cells to one another. It has been reported that at least two and probably more proteins associate with cadherins in various systems. These proteins have been called catenins. HT-29 cells can be manipulated to express either a polar or a nonpolar phenotype, depending on the growth conditions. We have taken advantage of this feature of HT-29 cells to explore the role catenins may play in cadherin-mediated adhesion. In this paper we report that several catenins co-immune-precipitate with E-cadherin in cultured human cells (HT-29 and JAR PR497) and that the nature of the complex of proteins varies with the physiological state of the HT-29 cells. In addition, we show data suggesting that the proteins that associate with calcium-dependent adhesion molecules may represent a group of proteins, some of which are present in all cells and some of which are cell-type specific.

Identification of a cadherin cell adhesion recognition sequence

The molecular mechanisms by which the cadherins interact with one another to promote cell adhesion have not been elucidated. In particular, the amino acid sequences of the cadherin cell adhesion recognition sites have not been determined. Here we demonstrate that synthetic peptides containing the sequence HAV, which is common to all of the cadherins, inhibit two processes (compaction of eight-cell-stage mouse embryos and rat neurite outgrowth on astrocytes) that are known to be mediated by cadherins. The data suggest that the tripeptide HAV is a component of a cadherin cell adhesion recognition sequence.

A cadherin-like protein in eggs and cleaving embryos of Xenopus laevis is expressed in oocytes in response to progesterone

A new cadherin-like protein (CLP) was identified in oocytes, eggs, and cleavage stage embryos of Xenopus laevis. As a probe for detecting new cadherin proteins, an antiserum was raised to a 17 amino acid peptide derived from a highly conserved region in the cytoplasmic domain of all cadherins which have been sequenced to date. This antipeptide antibody recognized Xenopus E-cadherin and a polypeptide in Xenopus brain extracts similar to N-cadherin, which were independently identified by specific mAbs. In extracts of eggs and midblastula stage embryos the antipeptide antibody recognized specifically a 120-kD glycoprotein that migrated faster on SDS gels than the 140-kD E- and N-cadherin polypeptides. This 120-kD polypeptide was not recognized by the mAbs specific to E- and N-cadherin. In fact, E- and N-cadherin were not detectable in eggs or midblastula stage embryos. The possible relationship of CLP to P-cadherin, which has been identified in mouse tissues, has not yet been determined. CLP was synthesized by large, late stage oocytes. When oocytes were induced to mature in vitro with progesterone it accumulated to the same level found in normally laid eggs. It did not accumulate further to any significant extent during the early cleavage stages. CLP was detected on the surface of stage 8 blastomeres by cell surface biotinylation, but only after the tight junctions of the blastula epithelium were opened by removal of Ca2+. We conclude that CLP is a maternally encoded protein that is the major, if not only, cadherin-related protein present in the earliest stages of Xenopus development, and we propose that it may play a role in the Ca2(+)-dependent adhesion and junction formation between cleavage stage blastomeres.

Altered uvomorulin expression in a noncompacting mutant cell line of F9 embryonal carcinoma cells

Uvomorulin (E-cadherin) is a cell adhesive molecule analogous to L-CAM in the chicken. Uvomorulin is important in the process of compaction in eight-cell mouse embryos and plays a role in F9 embryonal carcinoma cell interactions but it is not clear if it mediates aggregation or compaction, the closer interaction that also occurs in F9 cells cultured in suspension. This paper describes the finding of reduced levels of uvomorulin in a mutant cell line of F9 (5.51 att-) that is consistent with a role for uvomorulin in both aggregation and compaction. The mutant line expresses 40-50% of normal levels of uvomorulin as measured by surface radioiodination, immunoblotting, and biosynthetic labeling and immunoprecipitation with two different antisera. The mutant cell line expresses only abnormally unstable uvomorulin transcripts at very low levels. In addition, karyotypic analyses revealed an abnormal chromosome 8 on which the uvomorulin gene is located and therefore could account for aberrant uvomorulin expression. F9 5.51 att- cells aggregate loosely but do not compact (A. Grover, M. J. Rosenstraus, B. Sterman, M. E. Snook, and E. D. Anderson, 1987, Dev. Biol. 119, 1-11). The conclusion is that reduced levels of uvomorulin are sufficient for aggregation but insufficient for compaction.

Activation of protein kinase C triggers premature compaction in the four-cell stage mouse embryo

During mouse preimplantation development, the cells of the mouse embryo undergo a progressive subcellular reorganization at compaction, which eventually results in the formation of two distinct cell types. We have investigated the effect that activators of the Ca2(+)-phospholipid-dependent protein kinase (PKC) have on mouse compaction. Phorbol ester activation of PKC caused premature compaction of four-cell embryos within a few minutes of addition followed by a prolonged decompaction phase after 1 hr. This response was dose-dependent to concentrations as low as 250 pg/ml. Diacylglycerides also caused compaction; however, it was more sustained than with phorbol esters and was not followed by a phase of decompaction. Inhibition of PKC with sphingosine blocks induced compaction in a dose-dependent manner and also blocks normal compaction of eight-cell embryos. A monoclonal antibody to the cell adhesion molecule, E-cadherin, which mediates mouse embryo compaction, completely blocks compaction induced by these activators of PKC. Indirect immunofluorescence with a monoclonal antibody to E-cadherin indicates that PKC activation causes a rapid shift in the localization of this cell adhesion molecule, which coincides with the observed compaction. These results suggest that PKC plays a role in the initiation of compaction through its effect either directly or indirectly on E-cadherin.

Maintenance of compaction and adherent-type junctions in mouse morula-stage embryos

Timed morulae of different stages of development were exposed to cytochalasin B causing depolymerisation of microfilaments and to ECCD-1 antibodies interacting with Ca2(+)-dependent adhesion molecules or cultured in the absence of calcium. All three treatments decompacted mid-morula-stage embryos within one hour. Late morulae were resistant to ECCD-1 antibody treatment and relatively resistant to calcium-free cultivation, but not to cytochalasin B treatment. Scanning electron microscopy revealed that the decompacting treatments not only loosened the interblastomere contacts but also resulted in rearrangement of the cell surface microvilli. Transmission electron microscopy showed that normal, untreated embryos had specialized membrane junctions in the most apical regions of the interblastomere contacts. Immunoelectron microscopy revealed that these apical junction areas contained vinculin, a protein typical of adherent junctions. Upon decompaction the apical junctions disappeared completely. When transferred back to the normal medium, the embryos rapidly started to recompact. Simultaneously the apical junctions and cell surface microvilli reassumed the organization characteristic of the morula stage. Late morulae that were resistant to treatment had normal apical junctional areas. During subcultivation in the normal medium, the treated morulae developed into morphologically normal blastocysts. These data indicate that adherent-type junctions and cell surface microvilli participate in the initiation and maintenance of compaction of morula-stage embryos.

Mosaicism in the mouse trophectoderm

The issue of mosaicism in the mouse trophectoderm is examined by reviewing two sets of evidence: one arguing for a mosaic, the other for a non-mosaic character. Evidence for mosaicism includes documented cellular contribution from the inner cell mass to the trophectoderm, and data that reveal the gradual pace of the allocation process that separates the inner cell mass and trophectoderm lineages. Evidence suggesting a non-mosaic character for the trophectoderm is based on the polarization process undergone by exterior cells in the eight-celled embryo, the heritability of the changes brought about by this process, and the formation of gap junctions between the resulting apolar, trophectoderm progenitor cells. Since inner-cell-mass cells are developmentally labile, spatially heterogeneous and translocate to the polar trophectoderm, it is concluded that the polar trophectoderm is a mosaic tissue.

Alternative routes for the establishment of surface polarity during compaction of the mouse embryo

During the process of compaction, mouse 8-cell blastomeres flatten upon each other and polarize along an axis perpendicular to cell contacts. If the process of flattening is prevented, polarization can still occur, but does so in a lower proportion of cells than for control populations, and without the normal contact-directed orientation. We compared contact-directed and noncontact-directed processes to see if they involve common mechanisms. In nonflattened cells, surface polarization was favored in cells with nuclei located close to the cell surface, and the positions of surface poles and of nuclei tended to coincide. We present evidence that microtubules are involved in the development of microvillous poles associated with nuclei. In contrast it is known that polarization of microvilli occurs in the absence of microtubules if blastomeres are allowed to flatten. We conclude that surface polarization of mouse blastomeres can be accomplished by at least two alternative routes. One requires flattening but is independent of microtubules, and another can occur without flattening but involves a microtubule-mediated interaction between the nucleus and the cell cortex. It seems that both these pathways operate in the undisturbed embryo.

Expression of cell adhesion molecule E-cadherin in Xenopus embryos begins at gastrulation and predominates in the ectoderm

The expression of the Ca2+-dependent epithelial cell adhesion molecule E-cadherin (also known as uvomorulin and L-CAM) in the early stages of embryonic development of Xenopus laevis was examined. E-Cadherin was identified in the Xenopus A6 epithelial cell line by antibody cross-reactivity and several biochemical characteristics. Four independent mAbs were generated against purified Xenopus E-cadherin. All four mAbs recognized the same polypeptides in A6 cells, adult epithelial tissues, and embryos. These mAbs inhibited the formation of cell contacts between A6 cells and stained the basolateral plasma membranes of A6 cells, hepatocytes, and alveolar epithelial cells. The time of E-cadherin expression in early Xenopus embryos was determined by immunoblotting. Unlike its expression in early mouse embryos, E-cadherin was not present in the eggs or early blastula of Xenopus laevis. These findings indicate that a different Ca2+-dependent cell adhesion molecule, perhaps another member of the cadherin gene family, is responsible for the Ca2+-dependent adhesion between cleavage stage Xenopus blastomeres. Detectable accumulation of E-cadherin started just before gastrulation at stage 9 1/2 and increased rapidly up to the end of gastrulation at stage 15. In stage 15 embryos, specific immunofluorescence staining of E-cadherin was discernible only in ectoderm, but not in mesoderm and endoderm. The ectoderm at this stage consists of two cell layers. The outer cell layer of ectoderm was stained intensely, and staining was localized to the basolateral plasma membrane of these cells. Lower levels of staining were observed in the inner cell layer of ectoderm. The coincidence of E-cadherin expression with the process of gastrulation and its restriction to the ectoderm indicate that it may play a role in the morphogenetic movements of gastrulation and resulting segregation of embryonic germ layers.

Dissecting tumor cell invasion: epithelial cells acquire invasive properties after the loss of uvomorulin-mediated cell-cell adhesion

The generation of invasiveness in transformed cells represents an essential step of tumor progression. We show here, first, that nontransformed Madin-Darby canine kidney (MDCK) epithelial cells acquire invasive properties when intercellular adhesion is specifically inhibited by the addition of antibodies against the cell adhesion molecule uvomorulin; the separated cells then invade collagen gels and embryonal heart tissue. Second, MDCK cells transformed with Harvey and Moloney sarcoma viruses are constitutively invasive, and they were found not to express uvomorulin at their cell surface. These data suggest that the loss of adhesive function of uvomorulin (which is identical to E-cadherin and homologous to L-CAM) is a critical step in the promotion of epithelial cells to a more malignant, i.e., invasive, phenotype. Similar modulation of intercellular adhesion might also occur during invasion of carcinoma cells in vivo.

Identification of two structural types of calcium-dependent adhesion molecules in the chicken embryo

By using an immunological and peptide mapping approach two calcium-dependent cell-cell adhesion molecules (calCAMs) in the embryonic chicken are compared. A third closely related molecule is identified and compared to the two calCAMs. One of the calCAMs appears to be identical to the previously identified adhesion molecule N-cadherin, originally identified in chicken retina and localized to neural tissues. The second is the same as L-CAM, originally identified in chicken liver but localized to a variety of epithelial tissues. The third, also found in liver, is similar to L-CAM but is much closer in structure to N-cadherin. It is, however, immunologically distinct from N-cadherin. We therefore refer to this newly identified molecule as CRM-L for cadherin-related molecule in liver. CRM-L, N-cadherin, and L-CAM are all cell-surface proteins with a similar stability to tryptic digestion in the presence of calcium. CRM-L has the same molecular mass and isoelectric point as N-cadherin but is distinct from L-CAM in these properties. Two-dimensional peptide maps of complete tryptic digests reveal that CRM-L shares 69% of its peptides with N-cadherin and 20% with L-CAM. On the basis of these data, we suggest that there are at least two distinguishable types of calCAMs in the chicken embryo: one represented by the closely related molecules N-cadherin and CRM-L, and another represented by L-CAM.

Temporally specific involvement of cell surface beta-1,4 galactosyltransferase during mouse embryo morula compaction

Cell surface beta-1,4 galactosyltransferase (GalTase) is shown to mediate intercellular adhesions between embryonal carcinoma (EC) cells and specifically during late morula compaction in the preimplantation mouse embryo. Monospecific anti-GalTase IgG raised against affinity-purified bovine beta-1,4 GalTase recognizes F9 EC cell GalTase as judged by immunoprecipitation and inhibition of GalTase activity, as well as by immunoprecipitation of a single 52 kd metabolically labeled membrane protein. Anti-GalTase IgG inhibits cell adhesions between EC cells, dissociates compacted mouse morulae, and inhibits blastocyst formation. Anti-GalTase IgG specifically inhibits cell adhesions during late morula compaction, coincident with a peak of surface GalTase activity as determined by direct enzyme assay. On EC cells, GalTase activity can be proteolytically released from intact cells, and is localized by indirect immunofluorescence to areas of intercellular contact, consistent with its proposed role in cell adhesion. Beta-1,4 GalTase is the first cell adhesion molecule identified that participates during late morula compaction, subsequent to uvomorulin function.

Expression and function of cell surface extracellular matrix receptors in mouse blastocyst attachment and outgrowth

Mouse-hatched blastocysts cultured in vitro will attach and form outgrowths of trophoblast cells on appropriate substrates, providing a model for implantation. Immediately after hatching, the surfaces of blastocysts are quiescent and are not adhesive. Over the period 24-36 h post-hatching, blastocysts cultured in serum-free medium become adhesive and attach and spread on the extracellular matrix components fibronectin, laminin, and collagen type IV in a ligand specific manner. Attachment and trophoblast outgrowth on these substrates can be inhibited by addition to the culture medium of an antibody, anti-ECMr (anti-extracellular matrix receptor), that recognizes a group of 140-kD glycoproteins similar to those of the 140-kD extracellular matrix receptor complex (integrin) recognized in avian cells by CSAT and JG22 monoclonal antibodies. Addition to the culture medium of a synthetic peptide containing the Arg-Gly-Asp tripeptide cell recognition sequence of fibronectin inhibits trophoblast outgrowth on both laminin and fibronectin. However, the presence of the peptide does not affect attachment of the blastocysts to either ligand. Immunoprecipitation of 125I surface-labeled embryos using anti-ECMr reveals that antigens recognized by this antibody are exposed on the surfaces of embryos at a time when they are spreading on the substrate, but are not detectable immediately after hatching. Immunofluorescence experiments show that both the ECMr antigens and the cytoskeletal proteins vinculin and talin are enriched on the cell processes and ventral surfaces of trophectoderm cells in embryo outgrowths, in patterns similar to those seen in fibroblasts, and consistent with their role in adhesion of the trophoblast cells to the substratum.

Roles of cell junctions in gametogenesis and in early embryonic development

Recent reviews of the role of cell junctions in development have focused primarily upon functions related to the relatively subtle physiological modulation of their subunits in relation to fundamental developmental processes in a wide variety of organisms. There is, however, considerable support from numerous laboratories that the more radical modulation of the presence and number of junctional subunits in many diverse tissues may play a pivotal role in a wide spectrum of developmental phenomena ranging from gametogenesis to organogenesis. Since a great deal of recent interest in this latter subject has concentrated upon vertebrate systems including mammals, this review will examine the functional significance of the modulation of gap junctions, tight junctions and desmosomes in a developing idealized mammalian system from gamete formation to tissue and organ differentiation during embryo-genesis.

Fucosylated glycoconjugates in mouse preimplantation embryos

Preimplantation mouse embryos were metabolically labelled with 3H or 14C-fucose to investigate the synthesis of fucosylated macromolecules. Scintillation counting revealed that there was a progressive increase in both total fucose taken up by the embryo and incorporation of fucose into TCA-precipitable material as embryos developed from the 4-cell to the blastocyst stage. This was reflected in the increasing intensity of bands on autoradiographs of radioactive fucose labelled proteins separated on 10% SDS-PAGs between the 4-cell embryo (at which stage bands were first detectable) and the blastocyst. Minor qualitative changes in fucoproteins were detected at the time of compaction and additional bands appeared at the blastocyst stage. Preliminary analysis of fucolipids in 6- to 8-cell embryos indicated that an approximately equal amount of fucose was incorporated into lipid and protein. Autoradiographs of semi-thin sections of 3H-fucose-labelled embryos showed substantial amounts of radioactive material in the vicinity of the plasma membrane both adjacent to other cells and facing the zona pellucida. These data would support a predominant role for fucoconjugates in cell surface events in the preimplantation embryo from the 8-cell stage.

Expression and distribution of cell adhesion molecule uvomorulin in mouse preimplantation embryos

We have examined the synthesis and distribution of the cell adhesion molecule uvomorulin in mouse preimplantation embryos. Uvomorulin can already be detected on the cell surface of unfertilized and fertilized eggs but is not synthesized in these cells. Uvomorulin synthesis starts in late two-cell embryos and seems not to be correlated with the onset of compaction. The first signs of compaction are accompanied by a redistribution of uvomorulin on the surface of blastomeres. During compaction uvomorulin is progressively removed from the apical membrane domains of peripheral blastomeres. In compact morulae uvomorulin is no longer present on the outer surface of the embryo but is localized predominantly in membrane domains involved in cell-cell contacts of adjacent outer blastomeres. On inner blastomeres of compact morulae uvomorulin remains evenly distributed. This uvomorulin distribution once established during compaction is maintained and also found in the blastocyst: on trophectodermal cells uvomorulin localization is very similar to that in adult intestinal epithelial cells while uvomorulin remains evenly distributed on the surface of inner cell mass cells. The possible role of the redistribution of uvomorulin for the generation of trophectoderm and inner cell mass in early mouse embryos is discussed.

Expression sequences and distribution of two primary cell adhesion molecules during embryonic development of Xenopus laevis

Studies of chicken embryos have demonstrated that cell adhesion molecules are important in embryonic induction and are expressed in defined sequences during embryogenesis and histogenesis. To extend these observations and to provide comparable evidence for heterochronic changes in such sequences during evolution, the local distributions of the neural cell adhesion molecule (N-CAM) and of the liver cell adhesion molecule (L-CAM) were examined in Xenopus laevis embryos by immunohistochemical and biochemical techniques. Because of the technical difficulties presented by the existence of multiple polypeptide forms of CAMs and by autofluorescence of yolk-containing cells, special care was taken in choosing and characterizing antibodies, fluorophores, and embedding procedures. Both N-CAM and L-CAM were found at low levels in pregastrulation embryos. During gastrulation, N-CAM levels increased in the presumptive neural epithelium and decreased in the endoderm, but L-CAM continued to be expressed in all cells including endodermal cells. During neurulation, the level of N-CAM expression in the neural ectoderm increased considerably, while remaining constant in non-neural ectoderm and diminishing in the somites; in the notochord, N-CAM was expressed transiently. Prevalence modulation was also seen at all sites of secondary induction: both CAMs increased in the sensory layer of the ectoderm during condensation of the placodes. During organogenesis, the expression of L-CAM gradually diminished in the nervous system while N-CAM expression remained high. In all other organs examined, the amount of one or the other CAM decreased, so that by stage 50 these two molecules were expressed in non-overlapping territories. Embryonic and adult tissues were compared to search for concordance of CAM expression at later stages. With few exceptions, the tissue distributions of N-CAM and L-CAM were similar in the frog and in the chicken from early times of development. In contrast to previous observations in the chicken and in the mouse, N-CAM expression was found to be high in the adult liver of Xenopus, whereas L-CAM expression was low. In the adult brain, N-CAM was expressed as three components of apparent molecular mass 180, 140, and 120 kD, respectively; in earlier stages of development only the 140-kD component could be detected. In the liver, a single N-CAM band appears at 160 kD, raising the possibility that this band represents an unusual N-CAM polypeptide. L-CAM appeared at all stages as a 124-kD molecule.(ABSTRACT TRUNCATED AT 400 WORDS)

Formation of heterotypic adherens-type junctions between L-CAM-containing liver cells and A-CAM-containing lens cells

Cultured cells from either chicken lens or liver plated on solid substrates form flat epithelial sheets with adherens-type junctions between them. In lens cells these junctions contain A-CAM, while the same type of intercellular junctions in liver cells contain another cell adhesion molecule, L-CAM. Coculturing of lens and liver cells in the same dish resulted in the formation of mixed (heterotypic) adherens junctions. Double immunofluorescent labeling for both A-CAM and L-CAM indicated that the mixed junctions contained both molecules, each of which was present on one of the two partner cells. Moreover, the formation of the heterotypic junctions could be effectively inhibited by both anti-A-CAM and anti-L-CAM antibodies. It has thus been proposed that A-CAM and L-CAM share significant functional homology and may be involved in heterophilic interactions leading to the establishment of molecularly and cellularly asymmetrical adherens-type junctions.

An adhesion-defective variant of F9 embryonal carcinoma cells fails to differentiate into visceral endoderm

Adhesion-defective EC cells were isolated from a population of mutagenized F9 cells by serial transfer of cells that did not adhere to gelatin-coated dishes. The variant cells grew in suspension as multicellular clusters of loosely aggregated cells. The cells adhered to, but did not flatten on, fibroblast monolayers and extracellular matrix produced by parietal-like endoderm. Two different mutant cell lines exhibited increased sensitivity to the lectin abrin and decreased sensitivity to wheat germ agglutinin, suggesting that changes in cell surface glycosylation are associated with the mutant phenotype. These adhesion-defective mutants were used to study the relationship between cell-cell adhesion and endodermal differentiation. Unlike wild-type cells, when cultured with low concentrations of retinoic acid (RA) in suspension culture, the mutant cells did not form embryoid bodies but remained as loosely adhering strings of cells. Electron microscopic examination revealed that most of the differentiated variant cells resembled parietal endoderm, and this was confirmed by immunofluorescent staining for TROMA-3 marker. The levels of some of the markers that characterize the differentiative pathways were examined by immunoprecipitation and by enzyme-linked immunosorbent assay (ELISA). The variant line produced higher levels of laminin and type IV collagen compared to the wild-type cells. alpha-Fetoprotein (AFP) was produced at a significantly lower level by the variant compared to wild-type F9 cells during the differentiative process. The results show that variant cells differentiated toward parietal endoderm but have a very much restricted ability to differentiate to visceral endoderm. We conclude that aggregation and/or compaction provide some essential signals during the differentiation of F9 cells into epithelial layers of visceral endoderm.

The distribution of two cell surface determinants of mouse embryonal carcinoma and early embryonic cells

This study examines the distribution of two carbohydrate determinants recognized by monoclonal antibodies EMA-1 and EMA-6 on cells in culture, adult mouse tissues and day 0-7 embryos, and provides partial biochemical characterization of the molecules carrying the determinants for EMA-1 on embryonal carcinoma cells. Both antigens are present on primordial germ cells of day 8-day 10 mouse embryos (Hahnel and Eddy, 1986), and are expressed recurrently on pluripotent cells during earlier embryogenesis. Both antigens are also present on mouse embryonal carcinoma cells and the same set of adult tissue types. However, the distribution of the EMA-6 determinant on adult urogenital epithelia and during embryogenesis is more restricted than that of EMA-1. The determinants are detected only on lumenal surfaces of epithelial cells, suggesting that they are either not involved in processes of cell-cell or cell-substrate interaction, or are masked or altered during such interactions. Present biochemical evidence suggests that EMA-1 determinant on Nulli SCC1 cells may be on a large glycoprotein or a glycoprotein complex that is firmly attached to the cell membrane.

A-CAM: a 135-kD receptor of intercellular adherens junctions. I. Immunoelectron microscopic localization and biochemical studies

The recently described adherens junction-specific 135-kD protein (Volk, T., and B. Geiger, 1984, EMBO (Eur. Mol. Biol. Organ.) J., 3:2249-2260) was localized along cardiac muscle intercalated discs by immunogold labeling of ultrathin frozen sections. Analysis of this labeling indicated that the 135-kD protein, adherens junction-specific cell adhesion molecule (A-CAM), is tightly associated with the plasma membrane unlike vinculin labeling, which was present along the membrane-bound plaques of the fascia adherens. In cultured chick lens cells, A-CAM was associated with Ca2+-dependent junctions that were cleaved upon a decrease of extracellular Ca2+ concentrations to less than or equal to 0.5 mM. In the chelator-separated junction, A-CAM became exposed to exogenously added antibodies or to proteolytic enzymes. Upon addition of trypsin to EGTA-treated cells, A-CAM was cleaved into three major cell-bound antigenic peptides with apparent molecular masses of 78, 60, and 46 kD, suggesting that the extracellular domain of A-CAM has a size greater than or equal to kD. Incubation of electrophoretic gels with 125I-concanavalin A (Con A) indicated that one of the major Con A-binding proteins in chicken lens membranes is a integral of 135-kD glycoprotein that was partially purified on Con A-Sepharose column and identified as A-CAM by immunoblotting. Detergent partitioning assay using Triton X-114 biphasic system was carried out to determine whether A-CAM displays properties of an integral membrane protein. This assay indicated that the intact A-CAM molecule was recovered in the buffer phase but its cell-associated tryptic peptides, which presumably lost a great part of the A-CAM extracellular extension, readily partitioned into the detergent phase. The results obtained in this and in the following paper (Volk, T., and B. Geiger, 1986, J. Cell Biol., 103:1451-1464) strongly suggest that A-CAM is a Ca2+-dependent adherens junction-specific membrane glycoprotein that is involved in intercellular adhesion in these sites.

A-CAM: a 135-kD receptor of intercellular adherens junctions. II. Antibody-mediated modulation of junction formation

Intercellular adherens junctions between cultured lens epithelial cells are highly Ca2+-dependent and are readily dissociated upon chelation of extracellular Ca2+ ions. Addition of Ca2+ to EGTA-treated cells results in the recovery of cell-cell junctions including the reorganization of adherens junction-specific cell adhesion molecule (A-CAM), vinculin, and actin (Volk, T., and B. Geiger, 1986, J. Cell Biol., 103:000-000). Incubation of cells during the recovery phase with Fab' fragments of anti-A-CAM specifically inhibited the re-formation of cell-cell adherens junctions. This inhibition was accompanied by remarkable changes in microfilament organization manifested by an apparent deterioration of stress fibers and the appearance of fragmented actin bundles throughout the cytoplasm. Incubation of EGTA-dissociated cells with intact divalent anti-A-CAM antibodies in normal medium had no apparent inhibitory effect on junction formation and did not affect the assembly of actin microfilament bundles. Moreover, adherens junctions formed in the presence of the divalent antibodies became essentially Ca2+-independent, suggesting that cell-cell adhesion between them was primarily mediated by the antibodies. These studies suggest that A-CAM participates in intercellular adhesion in adherens-type junctions and point to its involvement in microfilament bundle assembly.

Effect of serum on cell-to-cell associations during in vitro development of preimplantation mouse embryos

We have identified an activity which alters the morphology and developmental timing of post-compaction mouse embryos. A 15-min exposure of 4- and 8-cell mouse embryos to sera containing this activity induced monolayer formation, changing the normal positions of blastomeres at the 16- to 64-cell stages. Recovered embryos form normal blastocysts, based on morphology and in vitro production of trophectoderm and inner cell mass derivatives. These results suggest that under certain circumstances blastomeres remain developmentally labile as late as the sixth or seventh cleavage cycle.

Developmentally regulated expression of the cell-cell adhesion glycoprotein cell-CAM 120/80 in peri-implantation mouse embryos and extraembryonic membranes

Peri-implantation mouse embryos and extraembryonic membranes were examined immunohistochemically for the expression of the cell-cell adhesion molecule (cell-CAM) 120/80. Cell-CAM 120/80 was seen along the lateral borders of all cells in the blastocyst but became undetectable on trophoblastic giant cells, some mononuclear trophoblastic cells and parietal yolk sac cells when blastocysts were cultured in vitro. In postimplantation embryos in vivo, all parts of the early egg-cylinder reacted with the antibody to cell-CAM 120/80 except for the cells of the parietal endoderm and the primary trophoblastic giant cells. In the late stage egg-cylinder, no cell-CAM 120/80 was seen on the cells of the primitive mesoderm or on the primordial germ cells. The germ cells in genital ridges and fetal gonads remained cell-CAM 120/80-negative throughout the fetal stages of development. In the extraembryonic membranes, the visceral yolk sac, amnion, and the cells of the placental labyrinth were cell-CAM 120/80-positive, whereas, the parietal yolk sac cells and the spongiotrophoblast cells were negative. These data show that cell-CAM 120/80 is found on cells arranged into epithelial layers in the early embryo and extraembryonic tissues, but is not expressed in the dissociated cells differentiating from these epithelia. Thus, the expression of cell-CAM 120/80 appears to be developmentally regulated.

Site-restricted expression of cytotactin during development of the chicken embryo

The sequential appearance of the extracellular matrix (ECM) protein, cytotactin, was examined during development of the chicken embryo by immunohistochemical techniques. Although cytotactin was identified as a molecule that mediates glia-neuron interactions, preliminary immunohistochemical localization of the molecule suggested that it was an ECM protein with a widespread but nonetheless more restricted distribution than either fibronectin or laminin. In the present study, it was found that cytotactin is first present in the gastrulating chicken embryo. It appears later in the basement membrane of the developing neural tube and notochord in a temporal sequence beginning in the cephalic regions and proceeding caudally. Between 2 and 3 d of development, the molecule is present at high levels in the early neural crest pathways (surrounding the neural tube and somites) but, in contrast to fibronectin and laminin, is not found in the lateral plate mesoderm or ectoderm. At later times, cytotactin is expressed extensively in the central nervous system, in lesser amounts in the peripheral nervous system, and in a number of nonneural sites, most prominently in all smooth muscles and in basement membranes of lung and kidney. Cytotactin appears in adult tissues with distributions that are similar to those seen in embryonic tissues. The findings raise the possibility that certain ECM proteins contribute to pattern formation in embryogenesis as a result of their restricted expression in a spatiotemporally regulated fashion at some sites but not at others.

The IIb-IIIa glycoprotein complex that mediates platelet aggregation is directly implicated in leukocyte adhesion

Evidence is presented that the IIb-IIIa glycoprotein complex, which functions as the receptor for fibrinogen on platelets and is central to platelet aggregation, is expressed on the surface of leukocytes where it may function as a receptor for fibronectin. F(ab')2 fragments of a monoclonal antibody, 25E11, raised against activated large granular lymphocytes, inhibited killing by natural killer cells, blocked the binding of fibronectin-coated particles by monocytes, and stimulated neutrophils to exhibit increased antibody-dependent killing. Immunoprecipitation studies of leukocytes and platelets, and the ability of 25E11 to inhibit platelet aggregation, identified the antigen as an epitope on the IIb-IIIa complex. This glycoprotein thus constitutes the first example of a receptor mediating both platelet aggregation and leukocyte adhesion.

Epithelial cell adhesion molecules

Recognition and binding between cells are of fundamental importance for a proper function of multicellular organisms, both during embryonic development and in the adult stage. Recently several cell surface proteins that are involved in these phenomena have been discovered. In the identification of these proteins, called cell adhesion molecules (CAMs), immunological methods have played a significant role. In a different approach to studies of cell-cell binding at the molecular level, the chemical composition of intercellular junctions is being studied. Intercellular junctions are specialized cell surface domains that have been identified by electron microscopy. They are particularly well developed in epithelia. Several proteins in the junctions have now been identified and characterized. This review deals with the biochemical properties of epithelial CAMs, and those proteins that are candidates for cell-to-cell binding in the junctions. In particular, the relationships between the various CAMs and junctional proteins are discussed. The tentative biological functions of these molecules are also considered.

Major loss of junctional coupling during mitosis in early mouse embryos

Junctional coupling was assessed during the transition from the fourth to the fifth cell cycle of mouse embryogenesis by injection of the dye carboxyfluorescein and by measurement of electrical continuity between cells. Junctional coupling, which arises de novo in early 8-cell mouse embryos, subsequently becomes reduced towards the end of the cell cycle as the blastomeres enter into mitosis. Arrest of the cell cycle in metaphase by nocodazole, an inhibitor of tubulin polymerization, reveals that cell coupling becomes undetectable at mitosis. Junctional coupling then is resumed during interphase of the 16-cell stage. Nocodazole itself has no effect on junctional coupling in interphase cells, regardless of the extent of intercellular flattening, whereas taxol, a microtubule-stabilizing agent, does reduce the extent of coupling in interphase cells.