Induction of an epithelial-mesenchymal transition by an in vivo adheron-like complex

The embryonic vertebrate heart consists of two epithelia: the myocardium and endothelium, separated by the myocardial basement membrane (MBM). The myocardium has been shown to induce endothelial transformation into prevalvular mesenchyme in a temporally and site restricted manner. Previously, we hypothesized that the myocardial-endothelial interaction is mediated in vivo by aggregates of 30-nm particles in the MBM which can be removed by EDTA extraction. These MBM extracts contain fibronectin and other lower Mr proteins and can initiate an epithelial-mesenchymal transition in the AV (atrioventricular canal) endothelium of embryonic chick heart in collagen gel culture. These and other data suggested that the 30-nm multicomponent particles are similar, structurally and compositionally, to multimolecular complexes, termed adherons, secreted by L6 muscle cells in culture. The purpose of this study was to (1) test whether the removal of the 30-nm particles from MBM extracts of embryonic chick hearts would remove the in vitro biological activity and (2) determine if the fractionated MBM extracts can cause AV endothelial cells to follow the same differentiation pathway observed in vivo by monitoring immunohistochemically the cell surface expression of N-CAM. Results showed that centrifugation of extract at 100,000g for 1 hr produced a supernatant fraction that was unable to initiate mesenchyme formation from AV endothelium. However, the resuspended pellet fraction did initiate differentiation of endothelium into mesenchyme. Conditioned medium from L6 skeletal muscle cultures could not substitute for the EDTA extract of embryonic heart. Endothelial cells undergoing the transition to form mesenchyme, both in vivo and in vitro, showed a concomitant decrease in N-CAM staining. This suggested that the pellet-induced formation of migrating cells in the collagen gels is not the result a novel in vitro phenomenon.     

Myocardial specificity for initiating endothelial-mesenchymal cell transition in embryonic chick heart correlates with a particulate distribution of fibronectin

The early chick heart tube consists of myocardium and endothelium separated by a myocardially derived basement membrane (MBM). As development proceeds, the endothelium undergoes a transition into mesenchyme in a regionally specific manner; only the atrioventricular (AV) and outflow tract, but not the ventricular endothelium, is transformed into mesenchyme, the progenitor of heart septa and valves. Recent experiments have shown that an EDTA extract of MBM can initiate AV endothelium to form mesenchyme in an in vitro collagen gel culture system. Two-dimensional gel electrophoresis of AV region EDTA extracts showed potentially three isoelectric forms of fibronectin (Fn), while extracts from ventricle contained only two forms. The purpose of the present study was to further investigate the significance of these regional differences by testing of specific myocardial regions (AV vs ventricle) for their ability to induce endothelium to form mesenchyme in vitro, and to immunohistochemically determine if a regionally specific distribution of Fn exists in the MBM that can be correlated with previous electrophoretic data. Embryonic heart regions cultured on three-dimensional collagen gels showed that AV endothelium could only form mesenchyme if cocultured with AV myocardium. Coculture with ventricular myocardial explants did not initiate differentiation of AV endothelium. In contrast, ventricular endothelial cells did not form mesenchyme when cocultured with AV or ventricle myocardium. Immunohistochemical localization of Fn revealed three distinct morphological patterns of distribution in the AV-MBM, i.e., an intense lamina densa staining, diffuse staining in fibrils, and as particles. The Fn localized in particles (0.1 to 0.5 micron in diameter) appeared as a gradient of decreasing concentration extending from the myocardium toward the endothelium. In contrast, no particulate Fn staining was observed in the ventricular region. EDTA extraction selectively depleted the particulate form of Fn. Previous work has shown that this extract, which contains several lower Mr proteins in addition to Fn, is biologically active in initiating mesenchyme formation from AV endothelium in vitro. These results show that a regionally specific interaction of the myocardium with the endothelium is required to initiate the formation of prevalvular mesenchyme. This interaction may be mediated by a multicomponent complex involving Fn and other proteins which appear as a regionally distinct particulate only in areas of endothelial differentiation.     

Initial expression of type I procollagen in chick cardiac mesenchyme is dependent upon myocardial stimulation

Formation of the atrioventricular (AV) mesenchyme is a critical step in early heart development. Endothelial cells are activated and transformed into a mesenchymal population that invades the cell-free myocardial basement membrane. This process can be duplicated in collagen gel culture, where it has been established that myocardium or its secretory products activate the endothelium. The purpose of the present study was to determine when these activated endothelial and/or mesenchymal cells start producing type I collagen in situ. These results were compared to those obtained from a culture model of mesenchyme formation. The production of type I collagen was monitored using a monoclonal antibody (M38) that recognizes the carboxy-terminal propeptide of human type I procollagen. The initial expression of the latter within activated AV endothelial and mesenchymal cells in ovo was 48 hr following activation. Prior to this time, only the myocardium was reactive with M38. AV explants of early hearts on collagen gels revealed staining of activated endothelial and mesenchymal cells with M38 after 48 hr in coculture with myocardial tissue. Explants that were prevented from activating (myocardium removed) never expressed the M38 antigen. Similarly, AV endothelial monolayers grown in the presence of myocardial conditioned medium activated and expressed type I collagen after 48 hr in culture, whereas those grown in standard medium did not. These results establish the initial expression of type I collagen within activated AV endothelium and mesenchyme. In addition, the data suggest that the expression of type I collagen within the AV mesenchyme may be dependent on extrinsic influences that induce the AV endothelium to transform into mesenchyme.     

An antiserum (ES1) against a particulate form of extracellular matrix blocks the transition of cardiac endothelium into mesenchyme in culture

The epithelial-mesenchymal transition of cardiac endothelium is a critical developmental event in the formation of valvular and septal anlagen. We have demonstrated previously that this event can be mimicked in culture by treating atrioventricular canal (AV) endothelium with EDTA-soluble proteins extracted from embryonic heart tissue. This activity was fractionated by ultracentrifugation of the EDTA extract, indicating that the critical proteins existed as a multicomponent complex. Based on these results we propose that: (1) the in vitro particulates in EDTA extracts correspond to an observed particulate form of extracellular matrix within the myocardial basement membrane (MBM) of mesenchyme-forming regions and (2) one or more of the proteins in the MBM particulates function to elicit the epithelial-mesenchymal transition. To test these hypotheses we utilized an antiserum, termed ES1, prepared against EDTA-extractable particulates from embryonic chick hearts. Both ES1 and an anti-fibronectin monoclonal antibody (M3H) co-localized in situ to particles within the MBM; however, no ES1 reactivity towards fibronectin could be detected by ELISA or immunoblot analysis. The ES1-positive MBM particulates were removed by extraction with EDTA, but not with PBS, indicating a divalent cation-mediated association of the constituent proteins. ES1 antibodies recognized two major (28 and 46 kDa) and three minor (93, 109, and 180 kDa) proteins on immunoblots of EDTA-extractable proteins. When tested in culture, ES1 antiserum inhibited the formation of mesenchyme from AV endothelium in a dose-dependent manner, while M3H did not. These results are consistent with an active role for one or more of the ES1 antigens in initiating the formation of AV mesenchyme. The localization of ES1 antigens to the extracellular matrix at other dynamic interfaces, e.g., ectoderm/neural tube and limb bud ectoderm/mesoderm, point to a potentially general importance of ES1 antigens in mediating similar developmental interactions.     

Bone morphogenetic protein-2 can mediate myocardial regulation of atrioventricular cushion mesenchymal cell formation in mice

Transformation of endocardial endothelial cells into invasive mesenchyme is a critical antecedent of cardiac cushion tissue formation. The message for bone morphogenetic protein (BMP)-2 is known to be expressed in myocardial cells in a manner consistent with the segmental pattern of cushion formation [Development 109(1990) 833]. In the present work, we localized BMP-2 protein in atrioventricular (AV) myocardium in mice at embryonic day (ED) 8.5 (12 somite stage) before the onset of AV mesenchymal cell formation at ED 9.5. BMP-2 protein expression was absent from ventricular myocardium throughout the stages examined. After cellularization of the AV cushion at ED 10.5, myocardial BMP-2 protein expression was diminished in AV myocardium, whereas cushion mesenchymal cells started expressing BMP protein. Expression of BMP-2 in cushion mesenchyme persisted during later stages of development, ED 13.5-16, during valuvulogenesis. Intense expression of BMP-2 persisted in the valve tissue in adult mice. Based on the expression pattern, we performed a series of experiments to test the hypothesis that BMP-2 mediates myocardial regulation of cardiac cushion tissue formation in mice. When BMP-2 protein was added to the 16-18 somite stage (ED 9.25) AV endocardial endothelium in culture, cushion mesenchymal cells were formed in the absence of AV myocardium, which invaded into collagen gels and expressed the mesenchymal marker, smooth muscle (SM) alpha-actin; whereas the endothelial marker, PECAM-1, was lost from the invaded cells. In contrast, when noggin, a specific antagonist to BMPs, was applied together with BMP-2 to the culture medium, AV endothelial cells remained as an epithelial monolayer with little expression of SM alpha-actin, and expression of PECAM-1 was retained in the endocardial cells. When noggin was added to AV endothelial cells cocultured with associated myocardium, it blocked endothelial transformation to mesenchyme. AV endothelium treated with BMP-2 expressed elevated levels of TGFbeta-2 in the absence of myocardium, as observed in the endothelium cocultured with myocardium. BMP-2-supported elevation of TGFbeta-2 expression in endocardial cells was abolished by noggin treatment. These data indicated that BMP signaling is required in and BMP-2 is sufficient for myocardial segmental regulation of AV endocardial cushion mesenchymal cell formation in mice.     

Use of 6-diazo-5-oxo-l-norleucine to study interaction between myocardial glycoconjugate secretion and endothelial activation in the early embryonic chick heart

The glutamine analog, 6-diazo-5-oxo-l-norleucine (DON), a glycoconjugate inhibitor, was used to probe the relationships between myocardial secretion of extracellular matrix and endothelial differentiation and formation of cushion mesenchyme (primordia of AV values). When DON was given to stage 12 chick embryos maintained in shell-less culture, the myocardial secretion gradient of glucose- and sulfate-labeled matrix was blocked. Concomitantly, the endothelium failed to complete activation but continued to divide and incorporate thymidine. By varying DON concentration, two distinct phases of endothelial differentiation were identified: the first (labile to 0.5 μg) involved hypertrophy, the second (labile to 0.25 μg) acquisition of migratory appendages with resultant mesenchyme formation. Glucosamine + DON (but not inosine, glucose, or glutamine) restored the matrical secretion gradient and to varying degrees both phases of endothelial activation. Endothelia totally suppressed from forming mesenchyme in situ acquired this capacity when explanted into three-dimensional collagen gel culture. The capacity was enhanced by glucosamine given in situ as an inhibitory override, dependent upon serum concentration, inhibited by heat-inactivated serum or by adding DON to the medium, but unaffected by hyaluronate. These results were compared to those obtained by co-culturing endothelium and myocardium and discussed in terms of the hypothesis that cushion mesenchyme formation results from an epithelial interaction mediated by glycoconjugates.     

Pepsinogen Induction in Chick Stomach Epithelia by Reaggregated Proventricular Mesenchymal Cells In Vitro

In vitro organ culture system which permits embryonic chick proventriculus (glandular stomach) to synthesize pepsinogen de novo was developed. Explants of the proventricular rudiment were cultured on Millipore filters in Medium 199 with Earle's salts supplemented with 50% 12-day embryo extract at 38°C in 95% air and 5% CO₂.
In these culture conditions, pepsinogen, a functional marker protein of proventriculus, was first detected after 3 days of cultivation of 6-day chick proventricular rudiment. When recombined and cultured with 6-day proventricular mesenchyme, 6-day oesophageal, proventricular or gizzard (muscular stomach) epithelium expressed pepsinogen while small intestinal epithelium did not. These results were consistent with the previous results obtained by chorioallantoic membrane (CAM) grafting, and showed that the culture conditions are permissive for pepsinogen expression.
When recombined and cultured with reaggregated mesenchymal cells isolated from 6-day proventricular mesenchymal fragments, both 6-day proventricular and gizzard epithelia formed glandular structure and expressed pepsinogen. This indicates that the proventricular mesenchymal cells retain the ability to induce morphogenesis and cytodifferentiation of the proventricular epithelium even if the normal organization of proventricular mesenchyme is once destroyed.     

Hyaluronate binding and degradation by cultured embryonic chick cardiac cushion and myocardial cells

Cultured cells obtained from developing chick heart valvular and septal primordial tissues (cardiac cushions) and myocardium were tested for their capacity to bind, internalize, and degrade hyaluronate. A presumptive lysosomal hyaluronidase capable of hyaluronate degradation has been previously isolated and partially characterized from cultures enriched in either cushion tissue cells or myocardial cells (D. H. Bernanke and R. W. Orkin, 1984, Dev. Biol. 106, 351-359). In this study, both types of cultures were found to bind hyaluronate, but only the myocardial cultures could degrade the hyaluronate substrate. The lack of hyaluronate degradative capacity in the mesenchymal cushion tissue cells appears to result from their inability to internalize the macromolecule, thus failing to make it available to the lysosomal hyaluronidase. The data suggest that hyaluronate clearance from the extracellular matrix of the developing cushion is a complex process, involving more than simple extracellular degradation adjacent to the migrating mesenchymal cushion tissue cells. Instead, a sequence of events may be indicated which includes binding of hyaluronate to the cushion tissue cell surfaces and its transport by these cells across the cushion matrix toward the myocardium. The myocardium may be involved in the ultimate removal of hyaluronate from the cardiac jelly.     

Polyionic regulation of cartilage development: promotion of chondrogenesis in vitro by polylysine is associated with altered glycosaminoglycan biosynthesis and distribution.

The development of cartilage nodules in cultures of chick limb bud mesenchyme (Hamburger-Hamilton stages 23/24) is significantly promoted when the culture medium is supplemented with (poly-L-lysine (PL) (M(r) greater than or equal to 14K) (San Antonio and Tuan, 1986. Dev. Biol. 115: 313). Here we present findings consistent with the hypothesis that PL may promote chondrogenesis by interacting electrostatically with sulfated glycosaminoglycans (GAGs): (1) poly-L-ornithine, poly-L-histidine, poly-D,L-lysine, and lysine-containing heteropolypeptides stimulate chondrogenesis in proportion to their contents of cationic residues; (2) the effects of PL are diminished when limb mesenchyme cultures are supplemented with exogenous GAGs, including heparin, dermatan sulfate, and chondroitin sulfate; (3) in high density cultures of limb bud mesenchyme, the release of sulfated macromolecules, but not of proteins in general, into the culture medium was significantly inhibited by PL (398K M(r)) treatment, and a net increase in total GAG content of the PL-treated cultures was observed; and (4) in monolayer cultures of cells derived from other chick embryonic tissues, including liver, skeletal muscle, and calvaria, PL treatment promoted the cell layer-associated retention of sulfated GAG. These effects were not observed using the nonstimulatory, low M(r) PL (4K). Based on the above findings and those from previous studies, it is proposed that PL may promote chondrogenesis by interacting electrostatically with cartilage GAGs, thus trapping the extracellular matrix around the newly emerging cartilage nodules and thereby stabilizing their growth and differentiation.     

Recognition of extracellular matrix components by neonatal and adult cardiac myocytes

The histogenesis of renal basement membranes was studied in grafts of avascular, 11-day-old mouse embryonic kidney rudiments grown on chick chorioallantoic membrane (CAM). Vessels of the chick CAM invade the mouse tissue during an incubation period of 7-10 days and eventually hybrid glomeruli composed of mouse epithelium and chick endothelium form. Formation of basement membranes during this development was followed by immunofluorescence and immunoperoxidase stainings using polyclonal and monoclonal antibodies against mouse and chick collagen type IV and against mouse laminin. These antibodies were species-specific as shown in immunochemical and immunohistologic analyses. The glomerular basement membrane contained both mouse and chick collagen type IV, demonstrating its dual cellular origin. All other basement membranes were either exclusively of chick origin (mesangium, vessels) or of mouse origin (tubuli, Bowman's capsule).     

Changes in myoblast membrane order during differentiation as measured by EPR

The events which make possible the characteristic fusion of the cell membranes of embryonic myoblasts are known to involve modification of the cell membrane (Hausman, R.E., Dobi, E.T., Woodford, E.J., Petrides, S., Ernst, M. and Nichols E.B. (1986) Dev. Biol. 113, 40-48). Myoblasts from chick embryos were allowed to differentiate in gyrotory aggregate culture and the order of their membranes was measured by EPR. Two spin-labels which insert at different depths into the lipid bilayer were used. Measurement with the 5-nitroxystearate label showed an increase in myoblast membrane order (2T' parallel) from 0-15 h of culture and again from 26-38 h of culture. Measurement with the 12-nitroxystearate label showed the 0-15 h increase in order but the second increase was greatly reduced and shifted in time. While the specific sources of these changes in membrane order cannot yet be identified, the changes observed correlated well with known events of myogenic differentiation in vitro. The initial increase in membrane order occurred while the myoblasts were recovering from the effects of trypsin dissociation and undergoing gyrotory aggregation. The second increase in membrane order occurred during the known period of prostaglandin receptor activity and increased cell-cell adhesion.     

Inductive properties of fibroblastic cell cultures derived from rat intestinal mucosa on epithelial differentiation

The present study represents a first attempt to elucidate the regulatory properties displayed by the non-epithelial portion of the intestinal mucosa, growing as fibroblasts in monolayer cultures. Thus, we compared the inductive action of 6-day suckling rat duodenal fibroblasts with that displayed by chick embryonic intestinal mesenchyme on the heterotypic cytodifferentiation of 5 1/2-day chick embryonic gizzard endoderm. The latter, isolated by 0.03% collagenase, was surrounded by intestinal intramucosal fibroblastic cell sheets. As control experiments, fibroblastic cells derived from the intestinal muscle or from 20-day fetal rat skin and lung were used. Every type of association was grafted into the coelomic cavity of 3-day chick embryos for 11 to 12 days, a system providing their vascularization and growth. The results clearly demonstrate that the mucosal fibroblastic cells of rat intestine were as potent as embryonic intestinal mesenchyme in inducing brush-border enzymes like sucrase and maltase, in conformity with an induced intestinal morphology. In contrast, the control fibroblastic cells were completely ineffective.     

Immunolocalization of basic fibroblast growth factor during chicken cardiac development

Basic fibroblast growth factor (bFGF) has been identified in cultured cardiac myocytes as well as in myocardial tissue of both embryonic and adult organisms; bFGF has also been demonstrated to regulate proliferation and differentiation of these cells in culture. Such studies suggest a possible role for bFGF in cardiac myogenesis. In vitro studies using cultured endothelial and neuronal cells also suggest that myocyte-derived bFGF may be involved in the regulation of vascularization and/or innervation of the developing heart. We have generated a spatial and temporal map for bFGF in the developing chick heart using immunohistochemical techniques and our monospecific polyclonal rabbit antihuman bFGF IgG. A progressive decrease in bFGF expression was seen in the highly trabeculated region of the ventricular myocardium, relative to the myocardium directly underlying the epicardial tissue, with increasing developmental age. bFGF expression was limited to the cytoplasm of cardiac myocytes; neither vascular endothelium nor smooth muscle contained anti-bFGF immunoreactive material. A correlation between the temporal and spatial pattern of bFGF expression seen here, with the pattern of myocyte proliferation and differentiation reported by others, suggests a role for bFGF in the autocrine regulation of myocyte proliferation and differentiation.     

Non-muscle alpha-dystroglycan is involved in epithelial development

The dystroglycan complex is a transmembrane linkage between the cytoskeleton and the basement membrane in muscle. One of the components of the complex, alpha-dystroglycan binds both laminin of muscle (laminin-2) and agrin of muscle basement membranes. Dystroglycan has been detected in nonmuscle tissues as well, but the physiological role in nonmuscle tissues has remained unknown. Here we show that dystroglycan during mouse development in nonmuscle tissues is expressed in epithelium. In situ hybridization revealed strong expression of dystroglycan mRNA in all studied epithelial sheets, but not in endothelium or mesenchyme. Conversion of mesenchyme to epithelium occurs during kidney development, and the embryonic kidney was used to study the role of alpha-dystroglycan for epithelial differentiation. During in vitro culture of the metanephric mesenchyme, the first morphological signs of epithelial differentiation can be seen on day two. Northern blots revealed a clear increase in dystroglycan mRNA on day two of in vitro development. A similar increase of expression on day two was previously shown for laminin alpha 1 chain. Immunofluorescence showed that dystroglycan is strictly located on the basal side of developing kidney epithelial cells. Monoclonal antibodies known to block binding of alpha-dystroglycan to laminin-1 perturbed development of epithelium in kidney organ culture, whereas control antibodies did not do so. We suggest that the dystroglycan complex acts as a receptor for basement membrane components during epithelial morphogenesis. It is likely that this involves binding of alpha- dystroglycan to E3 fragment of laminin-1.     

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.     

Bmp2 is essential for cardiac cushion epithelial-mesenchymal transition and myocardial patterning

Cardiac cushion development provides a valuable system to investigate epithelial to mesenchymal transition (EMT), a fundamental process in development and tumor progression. In the atrioventricular (AV) canal, endocardial cells lining the heart respond to a myocardial-derived signal, undergo EMT, and contribute to cushion mesenchyme. Here, we inactivated bone morphogenetic protein 2 (Bmp2) in the AV myocardium of mice. We show that Bmp2 has three functions in the AV canal: to enhance formation of the cardiac jelly, to induce endocardial EMT and to pattern the AV myocardium. Bmp2 is required for myocardial expression of Has2, a crucial component of the cardiac jelly matrix. During EMT, Bmp2 promotes expression of the basic helix-loop-helix factor Twist1, previously implicated in EMT in cancer metastases, and the homeobox genes Msx1 and Msx2. Deletion of the Bmp type 1A receptor, Bmpr1a, in endocardium also resulted in failed cushion formation, indicating that Bmp2 signals directly to cushion-forming endocardium to induce EMT. Lastly, we show that Bmp2 mutants failed to specify the AV myocardium with loss of Tbx2 expression uncovering a myocardial, planar signaling function for Bmp2. Our data indicate that Bmp2 has a crucial role in coordinating multiple aspects of AV canal morphogenesis.     

Formation of myocardium after the initial development of the linear heart tube.

Well after formation of the primary linear heart tube, the mesenchymal cardiac septa become largely myocardial, and myocardial sleeves are formed along the caval and pulmonary veins. This second wave of myocardium formation can be envisioned to be the result of recruitment of cardiomyocytes by differentiation from flanking mesenchyme and/or by migration from existing myocardium (myocardialization). As a first step to elucidate the underlying mechanism, we studied in chicken heart development the formation of myocardial cells within intra- and extracardiac mesenchymal structures. We show that the second wave of myocardium formation proceeds in a caudal-to-cranial gradient in vivo. At the venous pole, loosely arranged networks of cardiomyocytes are observed in the dorsal mesocardium from H/H19 onward, in the atrioventricular cushion region from H/H26 onward, and in the proximal outflow tract (conus) from H/H29 onward. The process is completed at H/H stage 43. Subsequently, we determined the potential of the different cardiac compartments to form myocardial networks in a 3D in vitro culture assay. This analysis showed that the competency to form myocardial networks in vitro is a characteristic of the myocardium that is flanked by intra- or extracardiac mesenchyme, i.e., the inflow tract, atrioventricular canal, and outflow tract. These cardiac compartments can be induced to form myocardial networks by a temporally released or secreted signal that is similar throughout the entire heart. Atrial and ventricular compartments are not competent and do not produce the inducer. Moreover, cardiac cushion mesenchyme was found to be able to (trans-)differentiate into cardiomyocytes in the in vitro culture assay. The combined observations suggest that a common mechanism and molecular regulatory pathway underlies the recruitment of mesodermal cells into the cardiogenic lineage during this second wave of myocardium formation through the entire heart.     

Localization and quantitation of 125I-epidermal growth factor binding in mouse embryonic tooth and other embryonic tissues at different developmental stages

We have shown earlier that epidermal growth factor (EGF) inhibits morphogenesis and cell differentiation in mouse embryonic teeth in organ culture. This inhibition depends on the stage of tooth development so that only teeth at early developmental stages respond to EGF (A-M. Partanen, P. Ekblom, and I. Thesleff (1985) Dev. Biol. 111, 84-94). We have now studied the quantity and pattern of EGF binding in teeth at various stages of development by incubating the dissected tooth germs with 125I-labeled EGF. Although the quantity of 125I-EGF binding per microgram DNA stays at the same level, localization of 125I-EGF binding by autoradiography reveals that the distribution of binding sites changes dramatically. In bud stage the epithelial tooth bud that is intruding into the underlying mesenchyme has binding sites for EGF, but the condensation of dental mesenchymal cells around the bud does not bind EGF. At the cap stage of development the dental mesenchyme binds EGF, but the dental epithelium shows no binding. This indicates that the dental mesenchyme is the primary target tissue for the inhibitory effect of EGF on tooth morphogenesis during early cap stage. During advanced morphogenesis the binding sites of EGF disappear also from the dental papilla mesenchyme, but the dental follicle which consists of condensed mesenchymal cells surrounding the tooth germ, binds EGF abundantly. We have also studied EGF binding during the development of other embryonic organs, kidney, salivary gland, lung, and skin, which are all formed by mesenchymal and epithelial components. The patterns of EGF binding in various tissues suggest that EGF may have a role in the organogenesis of epitheliomesenchymal organs as a stimulator of epithelial proliferation during initial epithelial bud formation and branching morphogenesis. The results of this study indicate that EGF stimulates or maintains proliferation of undifferentiated cells during embryonic development and that the expression of EGF receptors in different organs is not related to the age of the embryo, but is specific to the developmental stage of each organ.