Location and identification of the collagen found in the 14.5-d rat embryo visceral yolk sac

The collagens associated with 14.5-d rat visceral yolk sacs were localized and identified by a variety of procedures. Morphological examination showed that both the visceral epithelium and mesothelium rested upon thin basement membranes, whereas the majority of the extracellular matrix consisted of a stroma containing occasional cells and abundant banded fibrils. Immunohistochemistry at the electron microscope level showed that the basement membranes specifically cross- reacted with antibodies directed against mouse basement membrane components, whereas the stroma specifically cross-reacted with antibodies directed against rat type I collagen. Extractions of acellular visceral yolk sacs and subsequent analyses showed that type I collagen components were prevalent. Furthermore, in vitro biosynthetic studies showed only the presence of type I procollagen components (or their conversion products) and alpha-fetoprotein. These findings, taken together with our previous studies on the 14.5-d rat parietal yolk sac, provide us with protein markers for studying the origin of cells in rat parietovisceral yolk sac carcinomas.     

Characterization of a rat yolk sac carcinoma cell line

A continuous cell line was established from an experimentally induced rat yolk sac carcinoma. In the early passages both visceral and parietal yolk sac carcinoma were present (designated L1). When the cell line was reestablished in culture after serial transplantations in rats, only parietal yolk sac carcinoma could be identified (designated L2). This cell line expresses parietal yolk sac endoderm characteristics in that it synthesizes basement membrane components, in particular, laminin, but also entactin, collagen IV, and heparan sulfate proteoglycan. In addition, a noncartilage chondrotin sulfate proteoglycan is synthesized. This rat yolk sac carcinoma cell line L2 will be a valuable model for the study of basement membrane components.     

Avian vasculogenesis and the distribution of collagens I, IV, laminin, and fibronectin in the heart primordia

The heart-forming regions of the early embryo are composed of splanchnic mesoderm, endoderm, and the associated ECM. The ECM of the heart-forming regions in stage 7-9 chicken embryos was examined using immunofluorescence. Affinity purified antibodies to chicken collagens type I and IV, chicken fibronectin, and mouse laminin were used as probes. We report that (1) the basement membrane of the endoderm contains immunoreactive laminin and collagen IV; (2) the nascent basement membrane of the heart splanchnic mesoderm contains immunoreactive laminin, but not type IV collagen, and (3) the prominent ECM between the splanchnic mesoderm and the endoderm (the primitive-heart ECM) contains collagen IV, collagen I, fibronectin, but not laminin. In addition, we describe microscopic observations on the spatial relationship of cardiogenic cells to the primitive-heart ECM and the endodermal basement membrane.     

The embryonic rat parietal yolk sac. The role of the parietal endoderm in the biosynthesis of basement membrane collagen and glycoprotein in vitro.

Basement membrane biosynthesis in vitro was studied in a rapidly growing embryonic tissue, the rat parietal yolk sac. This tissue consists of a thick, nonvascular basement membrane (Reichert's membrane) separating two cellular layers (parietal endoderm and trophoblast). Morphologically, Reichert's membrane appeared similar to other basement membranes. Previous analysis of the amino acid and carbohydrate composition of acellular Reichert's membrane showed it to be typical of basement membranes isolated from other tissues and species. Analysis of [14-C]proline incorporation and hydroxy [14-C]proline synthesis during the third quarter ogestation in vitro showed that basement membrane collagen synthesis in the parietal yolk sac was maximal around the 14th day of gestation. At this time, basement membrane collagen represented nearly 10% of the newly synthesized protein. The collagen synthesized in this system was characteristic of basement membrane collagen in that about 11% of the total hydroxy [14-C]proline was present as the 3-isomer. In addition, after incubation in the presence of [14-C]lysine, 83 to 94% of the hydroxy[14-C]lysine was glycosylated, with the predominant form being glucosylgalactosylhydroxy[14-C]lysine. When the parietal endoderm and trophoblast were incubated separately with [14-C]proline, it was determined that the former was solely responsible for the synthesis of basement membrane collagen since essentially all of the 4-hydroxy[14-C]proline was associated with this cell type. Autoradiographic experiments with [3-H]glucosamine also served to localize the synthesis of noncollagen basement membrane glycoprotein components to the parietal endoderm. As with the results reported for basement membrane collagen secretion in embryonic chick lens cells, there appeared to be approximately a 60-min delay between the incorporation of [14-C]proline into protein and the secretion of collagen as measured by the appearance of 4-hydroxy[14-C]proline in the culture medium. Experiments utilizing [3H]glucosamine to monitor glycoprotein synthesis did not show a delay between the incorporation of [3H]glucosamine and the secretion of nondialyzable 3-H into the medium. The results obtained using the parietal yolk sac system to study basement membrane biosynthesis were compared to those previously obtained using the kidney glomerular and embryonic chick lens systems. It was concluded that the parietal yolk sac system is superior for a number of reasons: (a) the extracellular matrix appeared to contain only basement membrane components; there was no contamination by acid mucopolysaccharides or other types of collagen; (b) only a single cell type appeared to be responsible for the synthesis of basement membrane components; and (c) a relatively large percentage of the newly synthesized protein was basement membrane collagen.     

Insufficient folding of type IV collagen and formation of abnormal basement membrane-like structure in embryoid bodies derived from Hsp47-null embryonic stem cells

Hsp47 is a molecular chaperone that specifically recognizes procollagen in the endoplasmic reticulum. Hsp47-null mouse embryos produce immature type I collagen and form discontinuous basement membranes. We established Hsp47-/- embryonic stem cell lines and examined formation of basement membrane and production of type IV collagen in embryoid bodies, a model for postimplantation egg-cylinder stage embryos. The visceral endodermal cell layers surrounding Hsp47-/- embryoid bodies were often disorganized, a result that suggested abnormal function of the basement membrane under the visceral endoderm. Rate of type IV collagen secretion by Hsp47-/- cells was fourfold lower than that of Hsp47+/+ cells. Furthermore, type IV collagen secreted from Hsp47-/- cells was much more sensitive to protease digestion than was type IV collagen secreted from Hsp47+/+ cells, which suggested insufficient or incorrect triple helix formation in type IV collagen in the absence of Hsp47. These results indicate for the first time that Hsp47 is required for the molecular maturation of type IV collagen and suggest that misfolded type IV collagen causes abnormal morphology of embryoid bodies.     

Appearance and distribution of collagens and laminin in the early mouse embryo

Appearance and distribution of the different collagen types and the noncollagenous glycoprotein laminin was studied during early mouse development from unfertilized ova to 8-day embryos using indirect immunofluorescence techniques. Laminin was first detected intracellularly in the 16-cell compacted morula and appeared also intercellularly along cell contours. Type IV collagen was first seen in the blastocyst mainly in the inner cell mass. After implantation intense fluorescence for both of these proteins was found in all the embryonic and extraembryonic basement membranes. The interstitial collagens type I and III were first detected in the 8-day embryo closely codistributed in tissues of mesodermal origin including the head and heart mesenchymes and in basement membranes bounded by mesodermal structures. The results establish a developmental sequence for the appearance of basement membrane and extracellular matrix glycoproteins in early mouse development. The distribution of laminin suggests the presence of extracellular matrix material already in compacted morulae. The appearance of type IV collagen coincides with differentiation of the primitive endoderm and assembly of the first embryonal basement membrane. The appearance of the interstitial collagens during mesoderm differentiation indicates a stage when mesoderm acquires connective tissue characteristics.     

Fluorescein-Conjugated Bandeiraea simplicifolia Lectin as a Marker of Endodermal, Yolk Sac, and Trophoblastic Differentiation in the Mouse Embryo

Abstract. The Bandeiraea simplicifolia lectin I (BSA-I) conjugated to fluorescein isothiocyanate was used as a histochemical reagent to study the mouse embryos from fertilization to early somitogenesis. No lectin binding could be detected on the embryonic cells in the preimplantation embryo. Lectin labeled intensely the zona pellucida. In the implanting embryos lectin binding was detected along the subtrophectodermal and Reichert's membrane, in the cytoplasm of the parietal and visceral endoderm, and the trophoblastic giant cells, but not in the ectodermal cells. Studies on explanted blastocyts cultured in vitro disclosed that the cytoplasmic BSA-I binding sites in trophoblastic cells develop gradually. In the 9-day somitic embryo BSA-I reacted with epithelial cells of the yolk sac, but not with the mesenchymal cells. A continuity between the lectin-reactive endoderm and the foregut epithelium could be demonstrated. These data indicated that BSA-I lectin can be used as a histochemical probe for endodermal (yolk sac) and trophoblastic differentiation in the peri-implantational mouse embryo.     

SPARC synthesis in pre-implantation and early post-implantation mouse embryos

Summary SPARC (secreted protein acidic and rich in cysteine), also known as osteonectin and BM-40, is a secreted protein associated with a variety of embryonic and adult tissue and cell types, including placenta, parietal and visceral endoderm, certain epithelia (e.g. gut, skin, glandular epithelia), and regions of active chondrogenesis and osteogenesis. Although much is known concerning the tissue distribution of this protein, neither the time and location of its initial appearance nor its functions during embryogenesis have been clearly established. We identified the location of SPARC on two-dimensional protein gels. By using two-dimensional gel analysis of both pre- and post-implantation stage mouse embryos, we find that SPARC is initially synthesized between 3.5 and 4.5 days of embryogenesis. This is the earliest time during development at which synthesis of SPARC has been demonstrated. Inner cell masses isolated from 4.5 day blastocysts synthesize SPARC indicating that either primitive ectoderm, primitive endoderm, or both produce this protein. SPARC synthesis is also detectable in isolated trophoblast vesicles. Thus, SPARC is synthesized not only in placenta, parietal endoderm, and visceral endoderm, but in the precursors of these tissues as well. Examination of 7.5 day embryos reveals that SPARC is synthesized in isolated parietal yolk sac and in whole extraembryonic and embryonic regions. Relative to other proteins, synthesis of SPARC was most prevalent in the parietal yolk sac. The possible implications of SPARC synthesis as early as 4.5 days are discussed.     

Localization of type I interferon in murine trophoblast and decidua during decidual formation.

Mouse trophoblast and decidua were examined by means of immunohistochemistry to define the localization of type I interferon. The decidua were stained for type I interferon at the time of implantation. The strong reaction was first observed in the primary decidual zone on day 5 and subsequently in the secondary decidual zone on day 6. After day 10, the decidua basalis and decidua capsularis showed a strong reaction. At the one-cell stage, embryos were weakly labelled, but a positive reaction was recognized in compacted morulae. Blastocysts on days 3 and 4 were positive in trophoblast and inner cell mass and a strong reaction was observed in the primitive endoderm on day 4. The visceral endoderm on day 5 and the trophoblast on day 6 were positive. After day 10, the trophoblast giant cells, labyrinth, visceral yolk sac and fetal blood cells gave a positive reaction. This study is the first demonstration of type I interferon localization in situ in mouse trophoblast and decidua during decidual formation.     

Growth and proliferation in mouse parietal yolk sac during whole embryo culture

Use of the culture techniques for postimplantation rodent embryos, modified by explanting Day 9 or Day 10 embryos with the trophoblast cells removed but the remainder of the parietal yolk sac left intact, resulted in significant expansion of Reichert's membrane, accompanied by a marked increase in the numbers of the adherent parietal endoderm cells which synthesize the membrane. The surface area of the parietal endoderm/Reichert's membrane complex roughly doubled during culture, and the combined protein content of the cells and their basement membrane was also raised after incubation. Parietal endoderm cell numbers, calculated from area and cell density measurements on flattened membranes, increased by 54-190%, depending on the age of the embryo.     

In vitro production of Reichert's membrane by mouse embryo-derived parietal endoderm cell lines

We report the isolation of eight independent cell lines from preimplantation mouse embryos, which have a parietal endoderm phenotype. When grown as aggregates, these cell lines produce large amounts of a basement membrane matrix, that contains laminin, nidogen, heparan sulfate proteoglycan, collagen IV, and BM-40. The biosynthetic profiles of all eight cell lines are very similar to parietal endoderm cells in vivo which synthesize Reichert's membrane. The structure of the matrix produced by the parietal endoderm cell lines (PEC lines) resembles more closely Reichert's membrane than the Engelbreth—Holm—Swarm (EHS) tumor in susceptibility to proteolytic degradation. Since these cell lines produce large quantities of basement membrane they will be useful for structural and functional comparison of a Reichert's membrane matrix with the basement membrane produced by the EHS tumor.     

Analyses of cell surface and secreted proteins of primary cultures of mouse extraembryonic membranes

Procedures have been developed for primary culture of 13th day mouse parietal and visceral endoderm, yolk sac mesoderm, and amnion cells. We have analyzed cell surface and secreted proteins of these cultures by labeling the cells with radioactive iodine, glucosamine, or amino acids, and/or by immunofluorescence. Cell surface and secreted proteins of visceral endoderm, yolk sac mesoderm, and amnion cells resemble each other closely, whereas parietal endoderm cells are strikingly different. Unlike the other cell types, parietal endoderm cells synthesize and secrete substantial quantities of a protein tentatively identified as procollagen. These cells also secrete a number of other glycoproteins not observed in the media from the other cultures. It is proposed that the procollagen and one or more of the other unique, secreted glycoproteins are normally constituents of Reichert's membrane. Compared to the other cultures, parietal endoderm cells appear to be deficient in production of LETS protein. However, parietal endoderm—Reichert's membrane complexes analyzed by immunofluorescence directly after dissection from the uterus show an abundant association with LETS protein. It is not clear whether this LETS protein is actually synthesized by the parietal endoderm cells themselves. If so, it is possible that this protein is rapidly degraded after its secretion in parietal endoderm primary cultures. The studies reported here represent a first step in the characterization of cell surface properties of embryonic and extraembryonic cell types. The information already accumulated should be useful in investigations aimed at identification of cells derived from blastocysts and teratocarcinomas in vitro.     

In vitro production of Reichert's membrane by mouse embryo-derived parietal endoderm cell lines

We report the isolation of eight independent cell lines from preimplantation mouse embryos, which have a parietal endoderm phenotype. When grown as aggregates, these cell lines produce large amounts of a basement membrane matrix, that contains laminin, nidogen, heparan sulfate proteoglycan, collagen IV, and BM-40. The biosynthetic profiles of all eight cell lines are very similar to parietal endoderm cells in vivo which synthesize Reichert's membrane. The structure of the matrix produced by the parietal endoderm cell lines (PEC lines) resembles more closely Reichert's membrane than the Engelbreth-Holm-Swarm (EHS) tumor in susceptibility to proteolytic degradation. Since these cell lines produce large quantities of basement membrane they will be useful for structural and functional comparison of a Reichert's membrane matrix with the basement membrane produced by the EHS tumor.     

The effects of high-sucrose diets and of maternal diabetes on the ultrastructure of the visceral yolk sac endoderm in rat embryos developing in vivo and in vitro

The ultrastructure of the visceral yolk sac endoderm of in vivo developing 9- to 13-day-old embryos from 2 diabetic rat models (streptozotocin diabetes and Cohen--genetically determined--diabetes) and from nondiabetic rats fed high sucrose diets have been studied. This was compared to yolk sacs from 9.5-day-old embryos cultured for 48 h in sera from diabetic and nondiabetic rats fed a high-sucrose diet. Light-microscopic, TEM and SEM studies showed that the pathological cellular changes in the visceral yolk sac endoderm from diabetic rats were first observed on day 9 and were most severe among 11-day-old embryos. In vitro culture of control rat embryos in serum from experimental animals induced a reduction in the number of microvilli, of vacuolar intracellular inclusions and an increase in the number of degenerated endodermal cells. SEM studies showed that in addition to disappearance of microvilli, the majority of cells were collapsed and had degenerated cell membranes. Culture of embryos from diabetic animals in control serum only slightly reversed the pathological changes in the visceral yolk sac endoderm. A good correlation exists between the rate of embryonic malformations in diabetic rats and an index of endodermal-cell damage in the visceral yolk sac.     

Association of collagen with preimplantation and peri-implantation mouse embryos

By immunofluorescence analyses, we have determined that Type III procollagen, Type III collagen, and B and C chains of basement membrane collagen are associated with preimplantation mouse embryos. Type III collagen and procollagen appear to be associated with embryos at the 4-cell stage and beyond, whereas antibodies to B and C collagen chains bind to 2-cell and later embryos. All of these collagen types are detected in increasing amounts as embryos develop in a defined medium, indicating that the embryo is capable of their synthesis. By the blastocyst stage, the collagens are primarily localized intercellularly. Cells of the inner cell mass (ICM) also bind collagen antibodies. When isolated ICMs become two-layered, both the inner presumptive ectoderm layer and the outer primitive endoderm layer react with antibodies to Type III collagen and procollagen. The endoderm cells also react avidly with antibodies to B- and C-chain collagens. Preimplantation embryos and ICMs fail to react with antibodies to Types I and II collagen. During peri-implantation stages, blastocysts continue to react with antibodies to Type III and basement membrane collagens. There is no obvious relationship between the intensity of immunofluorescence and the change in the blastocyst surface from nonadhesive to adhesive. Furthermore, blastocysts prevented from undergoing implantation-related events in utero and in vitro react extensively with collagen antibodies. Blastocyst surface collagens might, nevertheless, play a role in implantation by undergoing organizational changes.     

Cell lineage analysis of the primitive and visceral endoderm of mouse embryos cultured in vitro

Cell lineages of the primitive endoderm and the visceral endoderm of mouse embryos were examined by culturing whole embryos in vitro. The primitive endoderm and visceral endoderm cells could be labelled by incubation of embryos in a medium containing horse radish peroxidase (HRP). HRP localization was chased throughout the culture period. The results show that the visceral endoderm derives from the primitive endoderm, and the visceral endoderm forms only the extra-embryonic endoderm (yolk sac endoderm) of the conceptus. The definitive endoderm which is probably derived from the head process, newly appears on the ventral surface of the embryo.     

Evidence for the existence of an early common biochemical pathway in the differentiation of F9 cells into visceral or parietal endoderm: Modulation by cyclic AMP

The addition of dibutyryl cyclic AMP (dbcAMP) to aggregate cultures of F9 cells in medium containing retinoic acid (RA) directs the pathway of differentiation into parietal endoderm instead of visceral endoderm. We examined the levels of some of the markers that characterize the two pathways and studied the time of commitment of cells to either direction of differentiation by using immunoprecipitation and enzyme-linked immunosorbent assays (ELISA). For either pathway, the levels and patterns of laminin, type IV collagen, and fibronectin are the same on the first day of differentiation, characterized by slightly decreased levels of laminin and type IV collagen synthesis and an increased level of fibronectin synthesis. These levels reverse on the second day of culture when the pathways diverge markedly. The differentiation pathway, however, can be redirected into the alternate one; parietal endoderm cells become committed after 3 days, whereas visceral endoderm cells are able to change into parietal endoderm cells at any time. Thus, α-fetoprotein (AFP)-producing F9 embryoid bodies switched to dbcAMP-containing medium lose the capacity to synthesize AFP and start to express genes characteristic of parietal endoderm. Our results indicate that at least some visceral endoderm cells may redifferentiate into parietal endoderm cells. These phenomena thus mimic features of endoderm differentiation in the mouse embryo.     

Visceral Endoderm Expression of Yin-Yang1 (YY1) Is Required for VEGFA Maintenance and Yolk Sac Development

Mouse embryos lacking the polycomb group gene member Yin-Yang1 (YY1) die during the peri-implantation stage. To assess the post-gastrulation role of YY1, a conditional knock-out (cKO) strategy was used to delete YY1 from the visceral endoderm of the yolk sac and the definitive endoderm of the embryo. cKO embryos display profound yolk sac defects at 9.5 days post coitum (dpc), including disrupted angiogenesis in mesoderm derivatives and altered epithelial characteristics in the visceral endoderm. Significant changes in both cell death and proliferation were confined to the YY1-expressing yolk sac mesoderm indicating that loss of YY1 in the visceral endoderm causes defects in the adjacent yolk sac mesoderm. Production of Vascular Endothelial Growth Factor A (VEGFA) by the visceral endoderm is essential for normal growth and development of the yolk sac vasculature. Reduced levels of VEGFA are observed in the cKO yolk sac, suggesting a cause for the angiogenesis defects. Ex vivo culture with exogenous VEGF not only rescued angiogenesis and apoptosis in the cKO yolk sac mesoderm, but also restored the epithelial defects observed in the cKO visceral endoderm. Intriguingly, blocking the activity of the mesoderm-localized VEGF receptor, FLK1, recapitulates both the mesoderm and visceral endoderm defects observed in the cKO yolk sac. Taken together, these results demonstrate that YY1 is responsible for maintaining VEGF in the developing visceral endoderm and that a VEGF-responsive paracrine signal, originating in the yolk sac mesoderm, is required to promote normal visceral endoderm development.