Effects of trichloroethylene and its metabolite trichloroacetic acid on the expression of vimentin in the rat H9c2 cell line.

Trichloroethylene (TCE) and its metabolite trichloroacetic acid (TCAA) are environmental contaminants with specific toxicity for the embryonic heart. In an effort to identify the cellular pathways disrupted by TCE and TCAA during heart development, we investigated their effects on expression of vimentin, a marker of cardiac differentiation. Previous studies had shown that the level of vimentin transcript was inhibited in rat embryonic heart after maternal exposure to TCE via drinking water. In the same study, maternal exposure to TCAA produced the opposite effect, inducing an increased level of vimentin mRNA. In this study, we selected an in vitro system, the rat cardiac myoblast cell line H9c2, to further characterize the molecular mechanisms used by TCE and TCAA to disrupt normal heart development. In particular, we investigated the effects of both toxicants on vimentin, at both the RNA and protein levels, using dose-response and time course curves. Our experimental findings indicate that vimentin expression is affected by TCE and TCAA in H9c2 cells similarly as in vivo. The work is significant because it provides a suitable in vitro model for studies looking at toxicant effects on myocardiac cells, and it suggests that vimentin is a good marker of TCE exposure in the embryonic heart.

TGFbeta Type III and TGFbeta Type II receptors have distinct activities during epithelial-mesenchymal cell transformation in the embryonic heart.

During the early stages of heart development, progenitors for the heart valves and septa come from endothelial cells via a developmental process known as "epithelial-mesenchymal cell transformation." This process is restricted to the atrioventricular (AV) canal and outflow tract portions of the embryonic heart. TGFbeta signal transduction pathways play critical roles during epithelial-mesenchymal cell transformation in heart development. Previously, we showed that both TGFbeta Type II (TbetaRII) and Type III (TbetaRIII) receptors are required to mediate epithelial mesenchymal cell transformation in chick heart. Further, distinct TGFbeta2 and TGFbeta3 activities correspond to separate components of the embryonic cell transformation process. Studies by others of TGFbeta-mediated inhibition of cell proliferation produced a model where TbetaRIII functions by facilitating TGFbeta2 binding to TbetaRII. In the present study, we provide evidence that TbetaRIII mediates distinct cellular responses from those of TbetaRII. Blocking antibody for TbetaRIII, but not antibody against TbetaRII, specifically inhibits the endothelial cell-cell separation step. Examination of developmental markers, perturbed by blocking TbetaRIII antibody, revealed a pattern of expression distinctively different from that of TbetaRII antibody treatment. These data show that a distinct TbetaRIII-mediated process is required for endothelial cell-cell separation during epithelial mesenchymal cell transformation. As TGFbeta2 mediates endothelial cell-cell separation, the data point to a specific association of TGFbeta2 and TbetaRIII in the cell separation step of epithelial mesenchymal cell transformation. We conclude that distinct TbetaRII and TbetaRIII signal transduction pathways mediate epithelial-mesenchymal cell transformation in the heart.

Slug is an essential target of TGFbeta2 signaling in the developing chicken heart.

An epithelial-mesenchymal cell transformation (EMT) occurs during the development of endocardial cushions in the atrioventricular (AV) canal of the heart. This is a complex developmental process regulated by multiple extracellular signals and signal transduction pathways. It was recently shown that the transcription factor Slug is expressed in the AV canal and is required for initial steps of EMT. Treatment of AV canal explants with either antisense oligodeoxynucleotides toward Slug or anti-TGFbeta2 antibody inhibited initial steps of EMT. Others have identified roles for HGF and BMP during EMT in the heart. Both HGF and BMP are known to regulate Slug in other cell types. To determine whether TGFbeta2 or other signaling factors regulate Slug expression during EMT in the heart, we cultured AV canal explants in the presence of anti-TGFbeta2 antibody, anti-TGFbeta3 antibody, pertussis toxin, retinoic acid, noggin, or anti-HGF antibody. Only treatment with anti-TGFbeta2 antibody or retinoic acid inhibited Slug expression in AV canal explants. Consistent with these data, we found that retinoic acid disrupted initial steps of EMT, while antagonists of BMP and HGF signaling disrupted later steps of EMT. Transfection of AV canal explants with Slug rescued the inhibitory effect of anti-TGFbeta2 antibody but not retinoic acid on EMT. Slug is thus an essential target of TGFbeta2 signaling during EMT in the developing chicken heart.

Trichloroethylene inhibits development of embryonic heart valve precursors in vitro.

Previous epidemiological studies with humans and laboratory studies with chickens and rats linked trichloroethylene (TCE) exposure to cardiac defects. Although the cardiac defects in humans and laboratory animals produced by TCE are diverse, a majority of them involves valvular and septal structures. Progenitors of the valves and septa are formed by an epithelial-mesenchymal cell transformation of endothelial cells in the atrioventricular (AV) canal and outflow tract areas of the heart. Based on these studies, we hypothesized that TCE might cause cardiac valve and septa defects by specifically perturbing epithelial-mesenchymal cell transformation. We tested this hypothesis using an in vitro chick-AV canal culture model. This study shows that TCE affected several elements of epithelial-mesenchymal cell transformation. In particular, TCE blocked the endothelial cell-cell separation process that is associated with endothelial activation. Moreover, TCE inhibited mesenchymal cell formation throughout the concentration range tested (50-250 ppm). In contrast, TCE had no effect on the cell migration rate of the fully formed mesenchymal cells. Finally, the expression of 3 proteins (selected as molecular markers of epithelial-mesenchymal cell transformation) was analyzed in untreated and TCE-treated cultures. TCE inhibited the expression of the transcription factor Mox-1 and extracellular matrix (ECM) protein fibrillin 2. In contrast, TCE had no effect on the expression of alpha-smooth muscle actin. These data suggest that TCE may cause cardiac valvular and septal malformations by inhibiting endothelial separation and early events of mesenchymal cell formation in the heart.

Utilization of antisense oligodeoxynucleotides with embryonic tissues in culture.

Experimental embryology has long used manipulation of interacting tissues to examine questions of tissue interaction and differentiation. The potential for specific manipulation of gene expression in such tissues has made the utilization of antisense techniques desirable. However, problems with this methodology have discouraged many investigators from using this approach. Selection of target sequences for antisense oligonucleotides, delivery of oligonucleotides into cells or tissues, and the type of modification of the oligonucleotide to be used all present concerns that must be addressed. This paper describes our approach to selection of target sequence and methods of delivery and describes the synthesis of a methoxyethylamidate-modified antisense oligonucleotide that has proved useful in our studies. This approach has enabled us to explore aspects of tissue interaction in the embryonic heart that would have been difficult to explore in a genetic model.

Slug is a mediator of epithelial-mesenchymal cell transformation in the developing chicken heart.

An epithelial-mesenchymal cell transformation occurs during the development of the endocardial cushions in the atrioventricular (AV) canal of the heart. We hypothesized that the transcription factor Slug is required for this epithelial-mesenchymal cell transformation since Slug is required for similar transformations during gastrulation and neural crest differentiation in chicken embryos. We found by RT-PCR and immunostaining that the temporal and spatial localization of Slug in the embryonic chicken heart is consistent with a role for Slug in endocardial cushion formation. Moreover, we found that Slug expression by AV canal endothelial cells is induced by a signal provided by AV canal myocardium. Slug appears to be required for epithelial-mesenchymal cell transformation in the chicken heart since treatment of AV canal explants with antisense Slug oligodeoxynucleotides inhibited mesenchymal cell formation in vitro. Antisense Slug oligodeoxynucleotides prevented endothelial cell-cell separation, suggesting that Slug acts early in the transformation pathway.

TGFbeta2 and TGFbeta3 have separate and sequential activities during epithelial-mesenchymal cell transformation in the embryonic heart.

Heart valve formation is initiated by an epithelial-mesenchymal cell transformation (EMT) of endothelial cells in the atrioventricular (AV) canal. Mesenchymal cells formed from cardiac EMTs are the initial cellular components of the cardiac cushions and progenitors of valvular and septal fibroblasts. It has been shown that transforming growth factor beta (TGFbeta) mediates EMT in the AV canal, and TGFbeta1 and 2 isoforms are expressed in the mouse heart while TGFbeta 2 and 3 are expressed in the avian heart. Depletion of TGFbeta3 in avian or TGFbeta2 in mouse leads to developmental defects of heart tissue. These observations raise questions as to whether multiple TGFbeta isoforms participate in valve formation. In this study, we examined the localization and function of TGFbeta2 and TGFbeta3 in the chick heart during EMT. TGFbeta2 was present in both endothelium and myocardium before and after EMT. TGFbeta2 antibody inhibited endothelial cell-cell separation. In contrast, TGFbeta3 was present only in the myocardium before EMT and was in the endothelium at the initiation of EMT. TGFbeta3 antibodies inhibited mesenchymal cell formation and migration into the underlying matrix. Both TGFbeta2 and 3 increased fibrillin 2 expression. However, only TGFbeta2 treatment increased cell surface beta-1,4-galactosyltransferase expression. These data suggest that TGFbeta2 and TGFbeta3 are sequentially and separately involved in the process of EMT. TGFbeta2 mediates initial endothelial cell-cell separation while TGFbeta3 is required for the cell morphological change that enables the migration of cells into the underlying ECM.

Requirement of type III TGF-beta receptor for endocardial cell transformation in the heart.

Transforming growth factor-beta (TGF-beta) signaling is mediated by a complex of type I (TBRI) and type II (TBRII) receptors. The type III receptor (TBRIII) lacks a recognizable signaling domain and has no clearly defined role in TGF-beta signaling. Cardiac endothelial cells that undergo epithelial-mesenchymal transformation express TBRIII, and here TBRIII-specific antisera were found to inhibit mesenchyme formation and migration in atrioventricular cushion explants. Misexpression of TBRIII in nontransforming ventricular endothelial cells conferred transformation in response to TGF-beta2. These results support a model where TBRIII localizes transformation in the heart and plays an essential, nonredundant role in TGF-beta signaling.

Epithelial-mesenchymal transformation in the embryonic heart is mediated through distinct pertussis toxin-sensitive and TGFbeta signal transduction mechanisms.

During early development, progenitors of the heart valves and septa are formed by epithelial-mesenchymal transformation (EMT) of endothelial cells in the atrioventricular (AV) canal. Previously, we showed that pertussis toxin, a specific inhibitor of a subset of G proteins, inhibited EMT in chick AV canal cultures. This study examines in detail the effects of pertussis toxin on the process of EMT. One of the major mediators of EMT is Transforming Growth Factor beta 3 (TGFbeta3) which acts through the TGFbeta Type II receptor. To determine whether pertussis toxin affects EMT via the TGFbeta Type II receptor pathway, we compared AV cultures treated with pertussis toxin and TGFbeta Type II receptor blocking antibody. Pertussis toxin inhibited several elements of EMT. At all stages tested, pertussis toxin blocked endothelial cell-cell separation, cell hypertrophy, and the cellular polarization associated with endothelial activation. These activities were unaffected by TGFbeta Type II receptor antibodies. Pertussis toxin also reduced transformed mesenchymal cell migration by 61%. The expression patterns of several proteins (as markers of EMT) were analyzed in untreated, pertussis toxin-treated, and TGFbeta Type II receptor blocking antibody-treated cultures. These markers were alpha-smooth muscle actin, Mox-1, fibrillin 2, tenascin, cell surface beta 1,4 galactosyltransferase (GalTase), and integrin alpha6. Clear differences in marker expression were found between the two inhibitors. For example, in all cells, pertussis toxin inhibited expression of alpha-smooth muscle actin and GalTase while TGFbeta Type II receptor antibody treatment increased expression of these two proteins. These data suggest that G protein-mediated signaling is required for several elements of EMT. Furthermore, distinct G protein and TGFbeta signal transduction pathways mediate discrete components of EMT.

Morphogenetic mechanisms of epithelial tubulogenesis: MDCK cell polarity is transiently rearranged without loss of cell-cell contact during scatter factor/hepatocyte growth factor-induced tubulogenesis.

Many organ systems are composed of networks of epithelial tubes. Recently, molecules that induce development of epithelial tubules and regulate sites of branching have been identified. However, little is known about the mechanisms regulating cell rearrangements that are necessary for tubule formation. In this study we have used a scatter factor/hepatocyte growth factor-induced model system of MDCK epithelial cell tubulogenesis to analyze the mechanisms of cell rearrangement during tubule development. We examined the dynamics of cell polarity and cell-cell junctions during tubule formation and present evidence for a multistep model of tubulogenesis in which cells rearrange without loss of cell-cell contacts and tubule lumens form de novo. A three-dimensional analysis of markers for apical and basolateral membrane subdomains shows that epithelial cell polarity is transiently lost and subsequently regained during tubulogenesis. Furthermore, components of cell-cell junctional complexes undergo profound rearrangements: E-cadherin is randomly distributed around the cell surface, desmoplakins I/II accumulate intracellularly, and the tight junction protein ZO-1 remains localized at sites of cell-cell contact. This suggests that differential regulation of cell-cell junctions is important for the formation of tubules. Therefore, during tubulogenesis, cell-cell adhesive contacts are differentially regulated while the polarity and specialization of plasma membrane subdomains reorganize, enabling cells to remain in contact as they rearrange into new structures.

Production of the transforming growth factor-beta binding protein endoglin is regulated during chick heart development.

The early embryonic heart consists of two cell types. The cells form an inner epithelial tube of endocardium within an outer tube of myocardium separated by a cell-free extracellular matrix. A crucial process in heart development is the production of cushion mesenchyme in the atrioventricular (AV) canal and outflow tract (OT). Cushion mesenchyme differentiates from the endocardium in response to signaling molecules produced by the adjacent myocardium. In chicken hearts, both transforming growth factor-beta3 (TGF-beta3) and TGF-beta2 are present and have been identified as being important in the production of cushion mesenchyme. We were interested in how the signals from these two similar molecules may be differentiated during early heart development. To this end, we examined the expression of endoglin, a TGF-beta receptor molecule, in the developing chick heart. Endoglin is typically located on endothelial cell layers and binds tightly to TGF-beta1 and TGF-beta3 but not well to TGF-beta2. We show that during the formation of the primitive heart tube, endoglin is found at relatively high levels in both presumptive myocardium and endocardium. However, as myocardium differentiates and development proceeds, endoglin expression is progressively reduced. At stage 20 in the heart, endoglin expression is most readily seen in the AV canal and the OT. This pattern of expression is similar to the reported TGF-beta3 expression patterns in the heart.

Antibodies to the Type II TGFbeta receptor block cell activation and migration during atrioventricular cushion transformation in the heart.

Epithelial-mesenchymal transformation is a critical event in the development of many organ systems including the heart. Descriptive studies have implicated a number of factors in mediating this transformation, including transforming growth factor beta (TGFbeta). We now report that disruption of a TGFbeta signal transduction complex by antibodies directed against the Type II TGFbeta receptor blocks both the endocardial cell activation and subsequent migration that constitute transformation in the chick atrioventricular (AV) cushion. The Type II receptor was localized to both endothelial and endocardial cells of the chick embryo. Incubation of AV cushion explants from Stage 14, 16, and 18 embryos with antibody resulted in a blockade of AV endocardial cell transformation by greater than 50% as measured by mesenchyme formation. Similarly, the appearance of procollagen Type I, a marker of endocardial cell transformation, was blocked. In addition, within 2 hr after the incubation of activated Stage 18 explants with Type II antibody the rate of migration of transformed cells was decreased by 50%. These data suggest that TGFbeta acts directly on AV cushion endocardial cells to stimulate epithelial-mesenchymal transformation and that TGFbeta mediates at least two distinct components of AV cushion transformation, activation and migration.

Mechanisms of cell transformation in the embryonic heart.

The process of cell transformation in the heart is a complex one. By use of the invasion bioassay, we have been able to identify several critical components of the cell transformation process in the heart. TGF beta 3 can be visualized as a switch in the environment that contributes to the initial process of cell transformation. Our data show that it is a critical switch in the transformation process. Even so, it is apparently only one of the factors involved. Others may include other TGF beta family members, the ES antigens described by Markwald and co-workers and additional unknown substances. Observing the sensitivity of the process to pertussis toxin, there is likely to be a G-protein-linked receptor involved, yet we have not identified a known ligand for this type of receptor. Clearly, there are several different signal transduction processes involved. The existence of multiple pathways is consistent with the idea that the target endothelial cells receive a variety of environmental imputs, the sum of which will produce cell transformation at the correct time and place. Adjacent endothelial cells of the ventricle that do not undergo cell transformation are apparently refractory to one or more of the stimuli. Figure 4 depicts a summary diagram of this invasion process with localization of most of the molecules mentioned in this narrative. As hypothesized here, elements of the transformation process may recapitulate aspects of gastrulation. Since some conservation of mechanism is expected in cells, it is not surprising that cells undergoing phenotypic change might reutilize mechanisms used previously to produce mesenchyme from the blastodisk. Though we have preliminary data to suggest this point, confirmation of the hypothesis by perturbation of genes such as brachyury, msx-1, etc. will be required to establish this point. The advantage of this hypothesis is that it provides, from the work of others in the area of gastrulation, a ready source of molecules and mechanisms that can be tested in the transforming heart. Whereas, perturbation of such mechanisms at gastrulation may be lethal to the embryo, such molecules and mechanisms may be responsible for the high incidence of birth defects in the heart.

Expression of complete keratin filaments in mouse L cells augments cell migration and invasion.

Intermediate filament proteins have been used to diagnose the origin of specific cells. Classically, vimentin is found in mesenchymal cells, and keratins are present in epithelial cells. However, recent evidence suggests that the coexpression of these phenotype-specific proteins augments tumor cell motility, and hence, metastasis. In the present study, we used the mouse L-cell model to determine if a direct correlation exists between the expression of additional keratins in these cells, which normally express only vimentin, and their migratory ability. Mouse L cells were transfected with human keratins 8, 18, and both 8 and 18. The results indicate that the cells expressing complete keratin filaments have a higher migratory and invasive ability (through extracellular matrix-coated filters) compared with the parental and control-transfected clones. Furthermore, there is an enrichment of keratin-positive cells from a heterogeneous population of L clones selected over serial migrations. This migratory activity was directly correlated with the spreading ability of the cells on Matrigel matrix, in which the keratin-positive transfectants maintain a round morphology for a longer duration, compared with the other L-cell populations. Collectively, these data suggest that keratins may play an important role(s) in migration, through a special interaction with the extracellular environment, thereby influencing cell shape.

TGF-beta 3-mediated tissue interaction during embryonic heart development.

A critical process during early heart development is the formation of mesenchymal cells which will contribute to valves and septa of the mature heart. These cells arise by an epithelial-mesenchymal transformation of endothelial cells in the atrioventricular (AV) canal and outflow tract areas of the heart. Adjacent endothelial cells in the atrium and ventricle remain epithelial. A three-dimensional collagen gel culture system has been exploited to examine the interactions that mediate this transformation. The AV canal myocardium produces a stimulus that is transmitted through an intervening extracellular matrix to the AV canal endothelium. This interaction is regionally specific, such that ventricular myocardium does not provide an adequate stimulus and ventricular endothelium does not respond to the AV canal myocardial stimulus. Exogenous TGF-beta 1 (or TGF-beta 2) can complement ventricular myocardium to produce transformation by AV canal endothelium. A blocking antibody, effective against several TGF-beta, prevents cell transformation. To identify the specific member of the TGF-beta family that functions in situ, antisense oligonucleotides for each of the numbered TGF-beta were topically added to AV canal explant cultures. Only the oligonucleotide targeted to TGF-beta 3 was an effective inhibitor of mesenchymal cell formation. Studies have been undertaken to localize specific mRNas by in situ hybridization and RNase protection assays. These assays have concentrated on the regional and temporal appearance of TGF-beta 2 and 3. Surprisingly, RNase protection assays with a TGF-beta 3 sense probe showed the presence of a transcript complementary to TGF-beta 3.(ABSTRACT TRUNCATED AT 250 WORDS)

Sense and antisense TGF beta 3 mRNA levels correlate with cardiac valve induction.

The formation of the valves in the heart is a spatially and temporally controlled process. A tissue interaction between the endothelium and its adjacent myocardium initiates the transformation of the endothelium into the mesenchymal precursors of the heart valve. One or more of the molecules implicated as critical for valve formation are members of the transforming growth factor beta family of molecules. Presented here is a spatial and temporal analysis of TGF beta 2 and TGF beta 3 in the chick heart during valve formation. We show that TGF beta 3 mRNA is concentrated in AV canal tissue where valve formation will occur, consistent with previous observations that TGF beta 3 production is critical during valve formation. Additionally, an RNA complementary to TGF beta 3 encoding mRNA is present in the heart. The temporally controlled appearance of RNA complementary to TGF beta 3 suggests that this molecule may play a role in the regulation of TGF beta 3 production in the heart.

Purification and characterization of avian beta 1,4 galactosyltransferase: comparison with the mammalian enzyme.

Avian beta 1,4 galactosyltransferase (GalTase) was purified from chicken serum, partially characterized and compared to mammalian GalTase using antibody cross-reactivity, Northern blot hybridization and amino acid sequence analysis. The enzyme was purified to apparent homogeneity by alpha-lactalbumin(LA)-agarose affinity chromatography followed by preparative SDS-polyacrylamide gel electrophoresis, and identified as two proteins of apparent molecular masses of 39 and 46 kD. Chicken serum GalTase had a Km for UDPGal of 42 microM, for GlcNAc of 10 mM and had optimal activity in the presence of 10-20 mM MnCl2. Substrate and linkage specificity analyses indicated that the purified enzyme behaves as a traditional Gal beta 1,4 GlcNAc:GalTase, since: (i) the avian beta 1,4 GalTase bound to alpha-LA; (ii) terminal GlcNAc residues served as good acceptors for chicken serum GalTase; (iii) the enzyme was inhibited by high concentrations of GlcNAc; (iv) the galactosylated product was sensitive to beta 1,4-specific beta-galactosidase. Finally, the disaccharide reaction product comigrated with authentic beta 1,4 N-acetyllactosamine standard. No other GalTase activities were detectable using a battery of defined glycoside substrates. Polyclonal antibodies raised against the two gel-purified GalTase proteins showed reactivity with avian GalTase by ELISA and immunoprecipitation assays. The antibodies also inhibited GalTase activity toward both high mol. wt and monosaccharide acceptor substrates. Despite similar kinetics and substrate specificity, the avian and mammalian GalTases showed little overall structural similarity, since polyclonal anti-avian GalTase IgG failed to react with mammalian GalTase purified from bovine milk, and conversely anti-bovine milk GalTase IgG did not react with the avian enzyme. Furthermore, in Northern blot analysis, no hybridization was detected when chicken embryo liver poly(A)+ RNA was probed with a mouse GalTase cDNA, even under conditions of reduced stringency. Amino acid sequence analysis identified three of five tryptic peptides that are homologous to the mammalian sequence within a putative substrate binding domain and the carboxy terminal domain of the enzyme. Their overall structural disparity leads us to believe that regions of homology between the avian and mammalian GalTases may represent active sites of the enzyme.

Epithelial-mesenchymal transformation of embryonic cardiac endothelial cells is inhibited by a modified antisense oligodeoxynucleotide to transforming growth factor beta 3.

During early cardiac development, the progenitor cells of the heart valves and membranous septa undergo an epithelial-mesenchymal transformation. Previous studies have shown that this transformation depends on the activity of a transforming growth factor beta (TGF beta) molecule produced by the heart. In the present study, we have used modified antisense oligodeoxynucleotides generated to nonconserved regions of TGF beta 1, -2, -3, and -4 to examine the possible roles of these members in this transformation. A phosphoramidate-modified oligonucleotide complementary to TGF beta 3 mRNA was capable of inhibiting normal epithelial-mesenchymal transformation by 80%. Unmodified oligonucleotides to TGF beta 3, modified oligonucleotides to TGF beta 1, -2, and -4, and two modified control oligonucleotides were unable to inhibit the transformation. These data demonstrate that a specific member of the TGF beta family, TGF beta 3, is essential for the epithelial-mesenchymal cell transformation.

A comparison of fibronectin, laminin, and galactosyltransferase adhesion mechanisms during embryonic cardiac mesenchymal cell migration in vitro.

Embryonic hearts contain a homogeneous population of mesenchymal cells which migrate through an extensive extracellular matrix (ECM) to become the earliest progenitors of the cardiac valves. Since these cells normally migrate through an ECM containing several adhesion substrates, this study was undertaken to examine and compare three ECM binding mechanisms for mesenchymal cell migration in an in vitro model. Receptor mechanisms for the ECM glycoproteins fibronectin (FN) and laminin (LM) and the cell surface receptor galactosyltransferase (GalTase), which binds an uncharacterized ECM substrate, were compared. Primary cardiac explants from stage 17 chick embryos were cultured on three-dimensional collagen gels. Mesenchymal cell outgrowth was recorded every 24 hr and is reported as a percentage of control. Migration was perturbed using specific inhibitors for each of the three receptor mechanisms. These included the hexapeptide GRGDSP (300-1000 micrograms/ml), which mimics a cell binding domain of FN, the pentapeptide YIGSR (300-1000 micrograms/ml), which mimics a binding domain of LM, and alpha-lactalbumin (1-10 mg/ml), a protein modifier of GalTase activity. The functional role of these adhesion mechanisms was further tested using antibodies to avian integrin (JG22) and avian GalTase. While the FN-related peptide had no significant effect on cell migration it did produce a rounded cellular morphology. The LN-related peptide inhibited mesenchymal migration 70% and alpha-lactalbumin inhibited cell migration 50%. Antibodies against integrin and GalTase inhibited mesenchymal cell migration by 80 and 50%, respectively. The substrate for GalTase was demonstrated to be a single high molecular weight substrate which was not LM or FN. Control peptides, proteins and antibodies demonstrated the specificity of these effects. These data demonstrate that multiple adhesion mechanisms, including cell surface GalTase, are potentially functional during cardiac mesenchymal cell migration. The sensitivity of cell migration to the various inhibitors suggests that occupancy of specific ECM receptors can modulate the activity of other, unrelated, ECM adhesion mechanisms utilized by these cells.

Signal transduction of a tissue interaction during embryonic heart development.

During early cardiac development, progenitors of the valves and septa of the heart are formed by an epithelial-mesenchymal cell transformation of endothelial cells of the atrioventricular (AV) canal. We have previously shown that this event is due to an interaction between the endothelium and products of the myocardium found within the extracellular matrix. The present study examines signal transduction mechanisms governing this differentiation of AV canal endothelium. Activators of protein kinase C (PKC), phorbol myristate acetate (PMA) and mezerein, both produced an incomplete phenotypic transformation of endothelial cells in an in vitro bioassay for transformation. On the other hand, inhibitors of PKC (H-7 and staurosporine) and tyrosine kinase (genistein) blocked cellular transformation in response to the native myocardium or a myocardially-conditioned medium. Intracellular free calcium concentration ([Ca2+]i) was measured in single endothelial cells by microscopic digital analysis of fura 2 fluorescence. Addition of a myocardial conditioned medium containing the transforming stimulus produced a specific increase in [Ca2+]i in "competent" AV canal, but not ventricular, endothelial cells. Epithelial-mesenchymal cell transformation was inhibited by pertussis toxin but not cholera toxin. These data lead to the hypothesis that signal transduction of this tissue interaction is mediated by a G protein and one or more kinase activities. In response to receptor activation, competent AV canal endothelial cells demonstrate an increase in [Ca2+]i. Together, the data provide direct evidence for a regional and temporal regulation of signal transduction processes which mediate a specific extracellular matrix-mediated tissue interaction in the embryo.