A new heparin binding protein regulated by retinoic acid from chick embryo

A 19 KDa heparin binding protein was previously purified from chicken embryos. Essentially localized within basement membranes in early embryonic tissues, this protein is very rich in basic and cystein residues. Its N-terminal fragment is similar to corresponding fragment of two other proteins expressed during embryogenesis and postnatal period. Its synthesis and secretion are induced by retinoic acid in chicken myoblasts and fibroblasts. This new retinoic acid induced heparin binding protein (RI-HB) does stimulate neurite outgrowth and proliferation on PC12 cells. These results suggest that retinoic acid could regulate some aspect of differentiation and development by inducing the synthesis of a new family of growth and neurotrophic factors.     

Correlations between the binding of neoglycoproteins, bovine serum albumin (BSA) and lectins in 10 to 13-day-old mouse embryos

In the present work we compared the appearance of carbohydrate binding sites for mannose, maltose, sialic acid and N-acetyl-glucosamine in the 11 to 13-day-old mouse embryo with the appearance of BSA and lectin binding sites. The carbohydrate-binding sites were localized with FITC-coupled neoglycoproteins, synthesized by chemical glycosylation of bovine serum albumin (BSA). These localizations were compared with binding of the FITC-labelled unglycosylated BSA. Furthermore the localizations of neoglycoprotein and BSA binding sites were correlated with binding of the FITC-labelled lectins WGA, RCA I and Con A. Initial appearance of neoglycoprotein binding sites occurred in the lens capsule of the 13 day old mouse embryo. Binding sites for the unglycosylated BSA appeared earlier, i.e. already in the 12-day-old embryo, in the basement membranes of the choroid plexus and the lung bud and lectin binding sites were seen in these structures in the 11-day-old embryo. The staining of the basement membrane and the lens capsule for BSA binding sites in the 12-and 13-day-old embryos correspond to WGA binding to these membranes. From these results we concluded that 1) specific carbohydrates which are probably involved in embryonic development appear much earlier in the embryo than the endogenous lectins which are able to react with these carbohydrates and 2) BSA is a protein which like WGA probably binds N-acetylglucosamine or sialic acid moieties.     

Correlations between the binding of neoglycoproteins,bovine serum albumin (BSA) and lectins in 10 to 13-day-old mouse embryos

Summary In the present work we compared the appearance of carbohydrate binding sites for mannose, maltose, sialic acid and N-acetyl-glucosamine in the 11 to 13-day-old mouse embryo with the appearance of BSA and lectin binding sites. The carbohydrate-binding sites were localized with FITC-coupled neoglycoproteins, synthesized by chemical glycosylation of bovine serum albumin (BSA). These localizations were compared with binding of the FITC-labelled unglycosylated BSA. Furthermore the localizations of neoglycoprotein and BSA binding sites were correlated with binding of the FITC-labelled lectins WGA, RCA I and Con A. Initial appearance of neoglycoprotein binding sites occurred in the lens capsule of the 13 day old mouse embryo. Binding sites for the unglycosylated BSA appeared earlier, i.e. already in the 12-day-old embryo, in the basement membranes of the choroid plexus and the lung bud and lectin binding sites were seen in these structures in the 11-day-old embryo. The staining of the basement membrane and the lens capsule for BSA binding sites in the 12-and 13-day-old embryos correspond to WGA binding to these membranes. From these results we concluded that 1) specific carbohydrates which are probably involved in embryonic development appear much earlier in the embryo than the endogenous lectins which are able to react with these carbohydrates and 2) BSA is a protein which like WGA probably binds N-acetylglucosamine or sialic acid moieties.     

Collagen I, laminin, and tenascin: ultrastructure and correlation with avian neural crest formation.

We have investigated the distribution of type I collagen, tenascin, and laminin in younger chick embryos than have previously been studied in detail. The initial appearance of type I collagen, but not tenascin and laminin, is exactly correlated with the beginning of neural crest migration, suggesting a role for collagen I in the migration. Light microscopy of whole mounts of 2-day-old chick embryos reveals that type I collagen is expressed in a rostral to caudal gradient; it localizes to the notochord sheath before accumulating around the neural tube and somites. Collagen I and tenascin also associate with central somite cells. Surprisingly, no extracellular matrix can be detected among the early sclerotomal cells, which suggests that little or no cell migration is involved in this epithelial-mesenchymal transformation. Electron microscopy using peroxidase antiperoxidase reveals that tenascin is present in nonstriated, 10 nm wide fibrils and in interstitial bodies, both of which have previously been reported to contain fibronectin. However, collagen I only occurs in the 10 nm fibrils and larger striated fibrils. This is the first ultrastructural study to assign tenascin to fibrils and interstitial bodies and to describe its appearance and disappearance from embryonic basement membranes. The discussion emphasizes the possible importance of type I collagen in neural crest cell migration and compares the ultrastructural associations of the ECM molecules present at this early embryonic stage.     

Compositional and structural requirements for laminin and basement membranes during mouse embryo implantation and gastrulation

Laminins are components of all basement membranes and have well demonstrated roles in diverse developmental processes, from the peri-implantation period onwards. Laminin 1 (alpha1beta1gamma1) is a major laminin found at early stages of embryogenesis in both embryonic and extraembryonic basement membranes. The laminin gamma1 chain has been shown by targeted mutation to be required for endodermal differentiation and formation of basement membranes; Lamc1(-/-) embryos die within a day of implantation. We report the generation of mice lacking laminin alpha1 and laminin beta1, the remaining two laminin 1 chains. Mutagenic insertions in both Lama1 and Lamb1 were obtained in a secretory gene trap screen. Lamb1(-/-) embryos are similar to Lamc1(-/-) embryos in that they lack basement membranes and do not survive beyond embryonic day (E) 5.5. However, in Lama1(-/-) embryos, the embryonic basement membrane forms, the embryonic ectoderm cavitates and the parietal endoderm differentiates, apparently because laminin 10 (alpha5beta1gamma1) partially compensates for the absent laminin 1. However, such compensation did not occur for Reichert's membrane, which was absent, and the embryos died by E7. Overexpression of laminin alpha5 from a transgene improved the phenotype of Lama1(-/-) embryos to the point that they initiated gastrulation, but this overexpression did not rescue Reichert's membrane, and trophoblast cells did not form blood sinuses. These data suggest that both the molecular composition and the integrity of basement membranes are crucial for early developmental events.     

A new family of proteins with high activity for heparin and regulated by retinoic acid]

An heparin binding protein (RIHB) was purified from chick embryos. Essentially expressed during early embryogenesis it is mainly localized within basement membranes. Its synthesis and that of the RIHB mRNA are induced by retinoic acid in chicken myoblasts cell culture. This protein belongs to the same family that HBGAM or Pleiotropin and MK protein two other heparin binding proteins exhibiting growth and/or neurotrophic activities.     

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).     

Nidogen-1. Expression and ultrastructural localization during the onset of mesoderm formation in the early mouse embryo.

Nidogen-1, a key component of basement membranes, is considered to function as a link between laminin and collagen Type IV networks and is expressed by mesenchymal cells during embryonic and fetal development. It is not clear which cells produce nidogen-1 in early developmental stages when no mesenchyme is present. We therefore localized nidogen-1 and its corresponding mRNA at the light and electron microscopic level in Day 7 mouse embryos during the onset of mesoderm formation by in situ hybridization, light microscopic immunostaining, and immunogold histochemistry. Nidogen-1 mRNA was found not only in the cells of the ectoderm-derived mesoderm but also in the cytoplasm of the endoderm and ectoderm, indicating that all three germ layers express it. Nidogen-1 was localized only in fully developed basement membranes of the ectoderm and was not seen in the developing endodermal basement membrane or in membranes disrupted during mesoderm formation. In contrast, laminin-1 and collagen Type IV were present in all basement membrane types at this developmental stage. The results indicate that, in the early embryo, nidogen-1 may be expressed by epithelial and mesenchymal cells, that both cell types contribute to embryonic basement membrane formation, and that nidogen-1 might serve to stabilize basement membranes in vivo. (J Histochem Cytochem 48:229-237, 2000)     

Monoclonal antibody analysis of ocular basement membranes during development

As a first step in a study of the role(s) of basement membranes in ocular morphogenesis, we have produced a variety of monoclonal antibodies against native lens capsule from adult chicks, and have used these reagents to stain histological sections of ocular tissues from 4 1/2- to 18-day-old chicken embryos. Four different patterns of immunofluorescence were observed in sections of corneas of 18-day-old chicken embryos stained with these antibodies. The antibodies in group 1 stained the basement membranes of both the corneal epithelium and the endothelium (as well as Descemet's membrane). Those in groups 2 and 3 stained only the epithelial or endothelial basement membranes, respectively. The group 4 antibody stained the corneal stroma as well as Bowman's membrane and Descemet's membrane. The antibodies in group 1 could be further subdivided into groups 1a and 1b on the basis of temporal differences in the onset of staining in corneas from 4 1/2- to 7-day-old embryos. Thus, this series of monoclonal antibodies appears to recognize at least five different antigenic determinants. When these antibodies were used to stain sections of eyes at different stages of development, we found that the characteristic differential staining of some basement membranes was maintained throughout development, while the staining properties of others changed. This indicates that many of the ocular basement membranes may differ from one another in composition or conformation, and that at least some of them may undergo developmental changes. We also noticed a similarity in the pattern of fluorescence associated with the basement membranes of the limbal blood vessels and the corneal endothelium that is consistent with the hypothesis that the corneal endothelium is derived from the early periocular vascular endothelium. Our observations of developing corneas also revealed that the antigen recognized by the group 4 antibody may be produced by both the corneal epithelium and the stromal fibroblasts. The suitability of monoclonal antibodies for probing basement membrane heterogeneity is discussed.     

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.     

A heparin binding protein whose expression increases during differentiation of embryonal carcinoma cells to parietal endoderm cells: cDNA cloning and sequence analysis

A cDNA clone isolated from a lambda gt11 expression library of teratocarcinoma OTT6050 specifies for a glycoprotein with a molecular weight of about 44,000. The new glycoprotein was termed heparin binding protein-44 (HBP-44), since it was absorbed to a heparin-agarose column and was eluted from it by a buffer containing 1.5 M NaCl. HBP-44 mRNA was intensely expressed in PYS-2 parietal endoderm cells and in the kidney, and the RNA level increased about 10-fold during differentiation of F9 embryonal carcinoma cells to parietal endoderm cells. From the cDNA sequence, HBP-44 was concluded to be rich in charged amino acids, and large segments of the protein appeared to form alpha-helixes. The protein was considered to be anchored to the membrane by a cluster of hydrophobic amino acids present in the N-terminal region. Indeed, the N-terminal sequence of HBP-44 was homologous to asialoglycoprotein receptor, which is anchored to the membrane by the N-terminal region. Furthermore, a portion of the N-terminal region of HBP-44 was homologous to the leucine zipper domain. Except for the N-terminal region, HBP-44 had over-all homology with structural proteins such as myosin heavy chain. We propose that HBP-44 is extruded from plasma membranes and interacts with heparin and related molecules and that it is involved in the interactions of plasma membranes with basement membranes.     

Heparin type IV collagen interactions: equilibrium binding and inhibition of type IV collagen self-assembly

Interactions between type IV collagen and heparin were examined under equilibrium conditions with rotary shadowing, solid-phase binding assays, and affinity chromatography. With the technique of rotary shadowing and electron microscopy, heparin appeared as thin, short strands and bound to the following three sites: the NC1 domain, and in the helix, at 100 and 300 nm from the NC1 domain. By solid-phase binding assays the binding of [3H]heparin in solution to type IV collagen immobilized on a solid surface was found to be specific, since it was saturable and could be displaced by an excess of unlabeled heparin. Scatchard analysis indicated three classes of binding sites for heparin-type IV collagen interactions with dissociation constants of 3, 30, and 100 nM, respectively. Furthermore, by the solid-phase binding assays, the binding of tritiated heparin could be competed almost to the same extent by unlabeled heparin and chondroitin sulfate side chains. This finding indicates that chondroitin sulfate should also bind to type IV collagen. By affinity chromatography, [3H]heparin bound to a type IV collagen affinity column and was eluted with a linear salt gradient, with a profile exhibiting three distinct peaks at 0.18, 0.22, and 0.24 M KCl, respectively. This suggested that heparin-type IV collagen binding was of an electrostatic nature. Finally, the effect of the binding of heparin to type IV collagen on the process of self-assembly of this basement membrane glycoprotein was studied by turbidimetry and rotary shadowing. In turbidity experiments, the presence of heparin, even in small concentrations, drastically reduced maximal aggregation of type IV collagen which was prewarmed to 37 degrees C. By using the morphological approach of rotary shadowing, lateral associations and network formation by prewarmed type IV collagen were inhibited in the presence of heparin. Thus, the binding of heparin resulted in hindrance of assembly of type IV collagen, a process previously described for interactions between various glycosaminoglycans and interstitial collagens. Such regulation may influence the assembly of basement membranes and possibly modify functions. Furthermore, qualitative and quantitative changes of proteoglycans which occur in certain pathological conditions, such as diabetes mellitus, may alter molecular assembly and possibly permeability functions of several basement membranes.     

Immunocytochemical localization of an H2A variant in the spermatogenic cells of the mouse

Immunocytochemical localization of protein "A," an H2A variant, has been carried out in the adult, neonatal, and embryonic spermatogenic cells of the mouse using the peroxidase-antiperoxidase technique. The results indicate an apparent enrichment of this protein in the meiotic cells of the adult testis. In addition, T-prospermatogonia present in the neonatal mouse and 16-day-old embryos were found to be immunoreactive. By contrast, Sertoli cells and other somatic elements of the neonatal and embryonic gonads were only weakly immunoreactive. These data suggest potential usefulness of protein "A" as a nuclear marker of the embryonic spermatogenic cells.     

A tonoplast intrinsic protein (TIP) is present in seeds, roots and somatic embryos of Norway spruce (Picea abies)

Many plant species contain a seed-specific tonoplast intrinsic protein (TIP) in their protein storage vacuoles (PSVs). Although the function of the protein is not known, its structure implies it to act as a transporter protein, possibly during storage nutrient accumulation/breakdown or during desiccation/imbibition of seeds. As mature somatic embryos of Picea abies (L.) Karst. (Norway spruce) contain PSVs, we examined the presence of TIP in them. Both the megagametophyte and seed embryo accumulate storage nutrients, but at different times and we therefore studied the temporal accumulation of TIP during seed development. Antiserum against the seed-specific a-TIP of Phaseolus vulgaris recognized an abundant 27 kDa tonoplast protein in mature seeds of P. abies. By immunogold labeling of sectioned mature megagametophytes we localized the protein to the PSV membrane. We also isolated the membranes of the PSVs from mature seeds and purified an integral membrane protein that reacted heavily with the antiserum. A sequence of 11 amino acid residues [AEEATHPDSIR], that was obtained from a polypeptide after in-gel trypsin digestion of the purified membrane protein, showed high local identity to a-TIP of Arabidopsis thaliana and to a-TIP of P. vulgaris. The greatest accumulation of TIP in the megagametophytes occurred at the time of storage protein accumulation. A lower molecular mass band also stained from about the time of fertilization until early embryo development. The staining of this band disappeared as the higher molecular mass (27 kDa) band accumulated in the megagametophyte during seed development. Total protein was also extracted from developing zygotic embryos and from somatic embryos. In zygotic embryos low-levels of TIP were seen at all stages investigated, but stained most at the time of storage protein accumulation. The protein was also present in mature somatic embryos but not in proliferating embryogenic tissues in culture. In addition to the seed tissue material, the antiserum also reacted with proteins present in extracts from roots and hypocotyls but not cotyledons from 13-day-old seedlings.     

Development of the differential effect of oxazepam on spontaneous and activated motility in chick embryos

Development of the acute depressant effect of oxazepam (in a dose of 10 mg/kg egg weight) on spontaneous and activated motor activity was studied in chick embryos (incubation age 11-19 days). The depressant effect of oxazepam was demonstrated for the first time in 13-day-old embryos. From the 15th day of incubation it led to prolonged depression of embryonic motility. From the 15th day the depressant effect of oxazepam depended on the connections of the central motor output with the prosencephalon. In mesencephalic, rhombencephalic and spinal preparations the effect of oxazepam was insignificant. In 13- and 15-day-old embryos oxazepam blocked the activating effect of strychnine and pentylenetetrazol, but not the picrotoxin-induced activation. The picrotoxin activation of embryonic motility was incompletely blocked for the first time in 17-day-old and completely only in 19-day-old embryos. The results are discussed with reference to heterochronia of development of the various components in the complex GABA receptor.     

Binding of mouse nidogen-2 to basement membrane components and cells and its expression in embryonic and adult tissues suggest complementary functions of the two nidogens

Nidogen-1 binds several basement membrane components by well-defined, domain-specific interactions. Organ culture and gene targeting approaches suggest that a high-affinity nidogen-binding site of the laminin gamma1 chain (gamma1III4) is important for kidney development and for nerve guidance. Other proteins may also bind gamma1III4, although human nidogen-2 binds poorly to the mouse laminin gamma1 chain. We therefore characterized recombinant mouse nidogen-2 and its binding to basement membrane proteins and cells. Mouse nidogen-1 and -2 interacted at comparable levels with collagen IV, perlecan, and fibulin-2 and, most notably, also with laminin-1 fragments P1 and gamma1III3-5, which both contain the gamma1III4 module. In embryos, nidogen-2 mRNA was produced by mesenchyme at sites of epithelial-mesenchymal interactions, but the protein was deposited on epithelial basement membranes, as previously shown for nidogen-1. Hence, binding of both nidogens to the epithelial laminin gamma1 chain is dependent on epithelial-mesenchymal interactions. Epidermal growth factor stimulated expression of both nidogens in embryonic submandibular glands. Both nidogens were found in all studied embryonic and adult basement membranes. Nidogen-2 was more adhesive than nidogen-1 for some cell lines and was mainly mediated by alpha3beta1 and alpha6beta1 integrins as shown by antibody inhibition. These findings revealed extensive coregulation of nidogen-1 and -2 expression and much more complementary functions of the two nidogens than previously recognized.     

Biomechanical properties of native basement membranes

Basement membranes are sheets of extracellular matrix that separate epithelia from connective tissues and outline muscle fibers and the endothelial lining of blood vessels. A major function of basement membranes is to establish and maintain stable tissue borders, exemplified by frequent vascular breaks and a disrupted pial and retinal surface in mice with mutations or deletions of basement membrane proteins. To directly measure the biomechanical properties of basement membranes, chick and mouse inner limiting membranes were examined by atomic force microscopy. The inner limiting membrane is located at the retinal-vitreal junction and its weakening due to basement membrane protein mutations leads to inner limiting membrane rupture and the invasion of retinal cells into the vitreous. Transmission electron microscopy and western blotting has shown that the inner limiting membrane has an ultrastructure and a protein composition typical for most other basement membranes and, thus, provides a suitable model for determining their biophysical properties. Atomic force microscopy measurements of native chick basement membranes revealed an increase in thickness from 137 nm at embryonic day 4 to 402 nm at embryonic day 9, several times thicker that previously determined by transmission electron microscopy. The change in basement membrane thickness was accompanied by a large increase in apparent Young's modulus from 0.95 MPa to 3.30 MPa. The apparent Young's modulus of the neonatal and adult mouse retinal basement membranes was in a similar range, with 3.81 MPa versus 4.07 MPa, respectively. These results revealed that native basement membranes are much thicker than previously determined. Their high mechanical strength explains why basement membranes are essential in stabilizing blood vessels, muscle fibers and the pial border of the central nervous system.     

Alpha-actinin expression during avian myogenesis in vivo. Evidence for the existence of an embryo-specific isoform of alpha-actinin

The isoforms of skeletal muscle alpha-actinin present during chick embryogenesis were analyzed by two-dimensional electrophoresis in combination with the immunoblot technique. Chicken embryonic muscles at 8-15 days contain an embryo-specific isoform of alpha-actinin. The embryonic alpha-actinin isoform has a molecular mass of 112 kDa and an isoelectric point of 5.8, whereas the values for the adult isoform of alpha-actinin were 100 kDa and 5.85, respectively. To characterize the two classes of alpha-actinin polypeptides we have compared the two proteins by 125I-labeled two-dimensional peptide mapping. The embryonic isoform is highly similar to, but exhibited extensive peptide differences to, the adult isoform of alpha-actinin. The developmental sequence of the expression of the alpha-actinins was also studied. In extracts of skeletal muscle from 8-10-day-old embryos, only the embryonic isoform was detected. In extracts from 15-day-old embryos, both the embryonic and the adult isoforms coexisted. However by 21 days, the embryonic isoform had disappeared and only the adult isoform was detected. These data suggested that the embryonic and the adult isoform of alpha-actinins are distinct proteins and that during skeletal myogenesis in ovo one class of alpha-actinin is replaced by a new class of alpha-actinin polypeptides, and that the latter is maintained into adulthood.