Cellular and subcellular distribution of laminin in adult rat anterior pituitary

Following the immunodetection of laminin in basal laminae and within some glandular cells of adult rat pituitary (Tougard et al., 1985: In Vitro 21:57), the present work had a double purpose: (a) adjustment of optimal conditions to detect laminin at both the cellular and subcellular level with an immunoperoxidase pre-embedding procedure, and (b) identification of the hormonal specificity of the laminin-containing cells, based on development of a "two-step" method combining the pre- and post-embedding approaches. In addition to extracellular localizations (basal laminae and connective tissue compartment), laminin was detected intracellularly within membrane-bounded compartments in all endocrine cell types and in the folliculo-stellate cells. It was found in rough endoplasmic reticulum cisternae, in a few Golgi saccules, and in vesicles or vacuoles. Labeled secretory granules were observed in gonadotrope, thyrotrope, and corticotrope cells but were very scarce in prolactin cells and absent in somatotrope cells. In addition, exocytotic profiles of labeled granules were frequent, suggesting a granular pathway for laminin export. Labeled vesicles, heterogeneous in size and shape, were observed mostly in prolactin cells. They might represent either a vesicular pathway for laminin export or an endocytic route for membrane-bounded laminin. These results bring complementary data to the concept that epithelial cells elaborate their basement membranes (Pierce and Nakane, 1967: Lab Invest 17:499). Moreover, the subcellular distribution of laminin within organelles involved in the biosynthesis, transport, and even in the storage of secretory products suggests that laminin might be exported by glandular pituitary cells according to different pathways.     

Gonadectomy induces laminin biosynthesis and basement membrane assembly in anterior pituitary glands of adult rats

Summary Laminin biosynthesis and basement membrane assembly in anterior pituitary glands of gonadectomized rats were studied by immuno-electron microscopy and radioimmunoassay. Three weeks after gonadectomy, rats received intravenous injections of sheep anti-laminin IgG conjugated to horseradish peroxidase, and glands were fixed and processed for microscopy 1 h later. Peroxidase reaction product uniformly labeled all perivascular and glandular epithelial basement membranes. In addition, reaction product was also found in abnormally multi-layered basement membranes seen especially beneath gonadotrophs, and unusual basement membrane-like structures projecting between gonadotrophs were also labeled. Pituitary sections from gonadectomized rats labeled with pre-embedding immunoperoxidase and post-embedding immungold techniques also localized intracellular laminin within biosynthetic organelles and light body vesicles of gonadotrophs. Neither abnormal basement membrane structures nor intracellular laminin were detected in pituitaries of nongonadectomized, control rats. Radioimmunoassays of pituitary homogenates showed nearly twice as much soluble laminin ( 15 ng/gland) in gonadectomized rats than in controls ( 8 ng/gland), which paralleled gland growth, but serum laminin concentrations did not differ ( 10 ng/ml in both groups). When anterior pituitary glands of gonadectomized rats that received injections of anti-laminin IgG-HRP were fixed 5 days after injection, lengths of unlabeled basement membrane were distributed between labeled lengths. This indicated that new basement membrane was spliced into old by a process similar to that seen in normal development. Supplementation of gonadectomized rats with testosterone, however, arrested laminin biosynthesis and basement membrane assembly and reversed glandular hypertrophy. These results indicate that, in an absence of sex hormone feedback, renewed synthesis of basement membrane components occurs in the anterior pituitary and is probably necessary to support the additional growth and differentiation of gonadotrophs and other pituitary cells.     

The connective tissue of the rat lung: electron immunohistochemical studies

The ultrastructural distribution of specific connective-tissue components in the normal rat lung was studied by electron immunohistochemistry. Three of these components were localized: type I collagen, fibronectin and laminin. Type I collagen was present not only in major airways and vascular structures, but also in alveolar septa. Laminin was found in all basement membranes, and only in basement membranes, demonstrating once more that this glycoprotein is an intrinsic component of the basement membrane. Fibronectin was found free in the interstitium and on the surfaces of collagen fibers. The basement membranes of bronchial, glandular and endothelial cells of large vessels lacked fibronectin; however, capillary endothelial and occasionally epithelial alveolar basement membranes contained some fibronectin in an irregular, spotty distribution. This localization suggests that in the lung, as in other tissues, fibronectin is not an intrinsic component of the basement membrane, but rather a stromal and plasma protein. Only basement membranes in the alveolar parenchyma contained "trapped" plasma fibronectin.     

Dome formation of keratin-containing agranular cells from rat anterior pituitary gland in vitro

Summary A certain kind of cell in the pituitary gland exhibited immunoreactive keratin and dome formations in vitro. We obtained epithelial cells, which were able to subculture, from the outgrowth of anterior pituitary organ cultures. These cells lacked hormone secretory granules and exhibited immunoreactive keratin. Furthermore, they produced dome formations or cystic structures in monolayer culture and under three-dimensional culture condition using type I collagen gel. Dome formation was stimulated by dibutyryl cyclic AMP (dbcAMP, 10⁻³ to 10⁻⁵ M). Their responsiveness to dbcAMP is similar to that of several other epithelial cells that possess transport functions in vivo and in vitro. Although the origin of our cultured cells is unknown, these cells formed dome formations that possessed transport function and were related to cystic structures in the pituitary gland in vivo. The study was supported by Grants in Aid for Scientific Research 60570018, 60870002 (for Dr. H. Ishikawa), and by The Science Research Promotion Fund from Japan Private School Promotion Foundation (for Dr. H. Ishikawa).     

Expression of fibronectin and laminin in fetal male gonads in vivo and in vitro with and without testicular morphogenesis

Sertoli cell differentiation occurs in vitro, even when testicular morphogenesis is inhibited by addition of serum to the culture medium (Magre, S. and A. Jost: Proc. Natl. Acad. Sci. USA 81, 7831-7834 (1984]. Using indirect immunohistochemical technique, we have studied the expression of fibronectin and laminin in gonads lacking testicular morphogenesis, as compared to in vivo controls and gonads cultured in synthetic medium. In undifferentiated gonads in vivo, fibronectin and laminin are distributed uniformly in the blastema. If testicular differentiation occurs in vivo, laminin is detected only in the basement membranes; when it occurs in vitro, laminin is found both in the basement membranes and among the stromal tissue. In gonads without seminiferous cords (cultured in serum-supplemented medium), fibronectin and laminin are both present, they are uniformly distributed among the gonadal cells.     

Synthesis and effects of basement membrane components in cultured rat Schwann cells

Schwann cells, the myelin-forming cells of the peripheral nervous system, are surrounded by a basement membrane. Whether cultured rat Schwann cells synthesize the basement membrane-specific components, laminin and collagen type IV, and whether these components influence the adhesion, morphology, and growth of these cells have been investigated. Both laminin and collagen type IV were detected in the cytoplasm of Schwann cells by immunofluorescence. After ascorbate treatment, laminin and collagen type IV were both found in an extracellular fibrillar matrix bound to the Schwann cell surface. Laminin was further localized on the Schwann cell surface by electron microscopy using gold immunolabeling. Anti-laminin IgG-labeled gold particles were scattered over the cell surface, and linear rows of particles and small aggregates were found along the cell edges and at points of contact with other cells. When added to the culture medium, laminin acted as a potent adhesion factor, stimulating Schwann cell adhesion as much as eightfold above control levels on type IV collagen. In the presence of laminin, the cells became stellate and by 24 hr had extended long, thin processes. Laminin also stimulated cell growth in a dose-dependent manner and anti-laminin IgG completely inhibited cell attachment and growth in the absence of exogenous laminin. Thus, cultured Schwann cells synthesize laminin and collagen type IV, two major components of basement membrane, and laminin may trigger Schwann cell differentiation in vivo during early stages of axon-Schwann cell interaction before myelination.     

Binding of intravenously injected antibodies against laminin to developing and mature endocrine glands

Summary To determine whether circulating antibodies against laminin can bind in vivo to basement membranes within endocrine glands, affinity-purified sheep or rabbit anti-laminin IgG was intravenously injected into rats. One to five hours after injection, anti-laminin IgG was bound to all basement membranes of adrenal and anterior pituitary glands of mature as well as 2-day-old newborn rats as shown by immunofluorescence microscopy. After the injection of anti-laminin conjugated directly to horseradish peroxidase (HRP), HRP reaction product was also present throughout adrenal and pituitary basement membranes in mature and immature glands 1–5 h post-injection. Ultrathin Lowicryl sections from rats that received unconjugated rabbit anti-laminin IgG 1 h prior to fixation with paraformaldehyde were labeled directly with anti-rabbit IgG-colloidal gold. In these cases, gold also bound specifically over the lamina densa and lamina rara. When adrenal or pituitary glands from mature rats were examined by immunofluorescence 1 week after the injection of sheep anti-laminin IgG, the patterns and amounts of bound sheep IgG were indistinguishable from those observed 1 h after injection. In contrast, significantly less fluorescence was present in glands from 7-day-old rat pups that had received anti-laminin IgG 5 days earlier. In addition, when anti-laminin IgG-HRP was injected into newborns and glands were fixed 5 days later, lengths of labeled endothelial and epithelial basement membranes were often interspersed with unlabeled lengths in zones of cellular proliferation in the outer adrenal cortex and throughout the pituitary gland. These results indicated that unlabeled basement membranes in these regions were probably assembled after the injection of anti-laminin IgG, which would also explain diminished labeling of basement membranes in these animals. Despite the continued presence of heterologous anti-laminin IgG within endocrine basement membranes, however, rat IgG, rat C3, inflammatory cells, or histologic abnormalities were observed in neither newborn nor adult glands under the conditions examined here. Sections from rats injected with control IgG or control IgG-HRP were entirely negative by immunofluorescence, immunoperoxidase, and immunogold techniques. We therefore conclude that (1) apparently large amounts of circulating anti-laminin IgG can bind to adrenal and pituitary basement membranes, and (2) at least some of these basement membranes are assembled during development by progressive splicing of newly synthesized matrix into that already present.     

Widespread association of annexin II with intracellular membrane systems and involvement of annexin II in granule--granule fusion in addition to granule--plasma membrane fusion in anterior pituitary cells

The subcellular localization in anterior pituitary secretory cells of annexin II, one of the Ca2+-dependent phospholipid-binding proteins, was examined by immunohistochemistry and immunoelectron microscopy. Annexin II was associated with the plasma membrane, the membranes of secretory granules and cytoplasmic organelles, such as rough endoplasmic reticulum, mitochondria and vesicles, and with the nuclear envelope. Annexin II was frequently detected at the contact sites of secretory granules with other granules and with the plasma membrane. The anterior pituitary and adrenal medulla were treated with Clostridium perfringens enterotoxin, which induces Ca2+ influx, and examined under an electron microscope. The anterior pituitary cells showed multigranular exocytosis, i.e. multiple fusions of secretory granules with each other and with the plasma membrane, but adrenal chromaffin cells, which lack annexin II on the granule membranes, never showed granule--granule fusion and only single granule exocytosis. From these results, we conclude that, in anterior pituitary secretory cells, annexin II is involved in granule--granule fusion in addition to granule--plasma membrane fusion. © 1998 Chapman & Hall     

Laminin forms an independent network in basement membranes [published erratum appears in J Cell Biol 1992 Jun;118(2):493]

Laminin self-assembles in vitro into a polymer by a reversible, entropy-driven and calcium-facilitated process dependent upon the participation of the short arm globular domains. We now find that this polymer is required for the structural integrity of the collagen-free basement membrane of cultured embryonal carcinoma cells (ECC) and for the supramolecular organization and anchorage of laminin in the collagen-rich basement membrane of the Engelbreth-Holm-Swarm tumor (EHS). First, low temperature and EDTA induced the dissolution of ECC basement membranes and released approximately 80% of total laminin from the EHS basement membrane. Second, laminin elastase fragments (E4 and E1') possessing the short arm globules of the B1, B2, and A chains selectively acted as competitive ligands that dissolved ECC basement membranes and displaced laminin from the EHS basement membrane into solution. The fraction of laminin released increased as a function of ligand concentration, approaching the level of the EDTA-reversible pool. The smaller (approximately 20%) residual pool of EHS laminin, in contrast, could only be effectively displaced by E1' and E4 if the collagenous network was first degraded with bacterial collagenase. The supramolecular architecture of freeze-etched and platinum/carbon replicated reconstituted laminin gel polymer, ECC, and collagenase-treated EHS basement membranes were compared and found to be similar, further supporting the biochemical data. We conclude that laminin forms a network independent of that of type IV collagen in basement membranes. Furthermore, in the EHS basement membrane four-fifths of laminin is anchored strictly through noncovalent bonds between laminin monomers while one-fifth is anchored through a combination of these bonds and laminin-collagen bridges.     

Intergranular bridges in the anterior pituitary cell and their possible involvement in Ca2+-induced granule-granule fusion

Quick-freeze deep-etch electron microscopy showed the presence of bridge-like structures between adjacent secretory granules in rat anterior pituitary secretory cells. These intergranular bridges were variable in length and thickness. The finest bridges were 7–8 nm in length, while the longest ones were as long as 80 nm. Annexin II, one of the Ca²⁺-dependent phospholipid-binding proteins, is known to interlink between two membranes and induce aggregation of liposomes and chromaffin granules under the presence of Ca²⁺. In anterior pituitary cells, annexin II was detected by immunoelectron microscopy at the contact sites of secretory granules with other granules. The anterior pituitary cells treated under the presence of extracellular Ca²⁺ with Clostridium perfringens enterotoxin which induces Ca²⁺ influx showed multigranular exocytosis, i.e., multiple fusions of secretory granules with each other and with the plasma membrane. The granule-granule fusion in progress could be captured by the quick-freeze deep-etch technique. The membranes of adjacent secretory granules were partially fused at their contact sites where intergranular strands were no longer seen, while there existed intergranular strands between unfused portions of the granule membranes. From these results, we consider that the intergranular bridges, some of which may be composed of annexin II, are involved in Ca²⁺-induced granule-granule fusion in anterior pituitary cells.     

Exogenous fibronectin is not required for organogenesis in vitro

Summary The biological effect of plasma fibronectin on the differentiation of embryonic mouse kidney and tooth was studied in organ cultures. Transferrin (50μg/ml) was a strong mitogen for kidney cells, whereas, the addition of soluble fibronectin (50 to 250 μg/ml) had no detectable effect on differentiation or proliferation. The same serum-free, transferrin-containing medium did not support tooth differentiation. however, fibronectin was not a necessary serum component because fibronectin-free serum supported tooth development. It was demonstrated with antibodies specific for human fibronectin that the exogenously added human fibronectin at 50 μg/ml did not become incorporated to the cultured organs. Only minimal incorporation to the kidney basement membrane area was observed when fibronectin concentration was 250μg/ml. The mesenchymal stroma and the basement membranes of the kidney and tooth rudiments cultured in fibronectin-free media stained intensely with conventional fibronectin antibodies, indicating endogenous production of fibronectin. Outgrowing epithelial cells from isolated kidney tubules produced fibronectin as well as laminin. The results suggest that the fibronectin found in the stroma and basement membranes is an endogenous product of the developing tissues and that plasma fibronectin is not required for in vitro organogenesis. The results also indicate that it is difficult to study the effect of fibronectin on morphogenetic processes because it may not penetrate the organ explants in vitro. This work was supported by grants from the Sigrid Jusélius Foundation, Finska L?kares?llskapet, Finnish Life Insurance Companies and Grant CA 28896 and Cancer Center Support Grant CA 30199 from the National Cancer Institute, Department of Health and Human Services, Washington, D.C.     

Cultivation of epithelia from the secretory coil of the ovine apocrine gland: Evidence of secretory cell function and ductal morphogenesis In vitro

Summary The secretory coil of the ovine apocrine gland is composed predominantly of two cell types, secretory cells lining the lumen and myoepithelial cells adjacent to the basement membrane. The glands synthesize a number of hormones and growth factors, but analysis of the functions of these molecules may be hampered by the mixing of apocrine and sebaceous secretions in the pilary canal. The purpose of this study was to isolate the glands and devise simple culture procedures to facilitate investigations of secretory cell function. The most successful approach involved microdissection of the secretory coils individually from skin biopsies and culture in Dulbecco’s modified Eagle’s medium. After 1–2 wk in medium, cell outgrowths were seen from explants. These consisted predominantly of populations of epithelial cells, many containing granules. Smaller granules were usually concentrated around the cell nuclei and accumulated lipophilic dyes. Large granules were unreactive. Western analysis showed that cells in culture synthesized nerve growth factor-like peptides, a feature consistent with one of the functions of the gland in vivo. When isolated secretory coils were explanted to culture dishes coated with matrigel, highly compact, multilayered masses of cells grew out. Subsequently, tubular structures formed. The observations suggest that some differentiated functions of gland cells were retained in vitro and that the procedures described provide a system for the study of apocrine secretions in isolation from those of other skin glands.     

Drosophila laminin: characterization and localization

Drosophila laminin was isolated from the medium of Drosophila Kc cell cultures. It was purified by velocity sedimentation, gel filtration, and chromatography. Drosophila laminin is a disulfide-linked molecule consisting of three chains with apparent molecular masses of 400, 215, and 185 kD. In electron micrographs, it has the cross-shaped appearance with globular domains characteristic of vertebrate laminin with closely similar dimensions. The amino acid composition and lectin-binding properties of Drosophila laminin are given. Polyclonal antibodies to Drosophila laminin were prepared and their specificity was established. In developing embryos immunofluorescence staining was detected between 6 and 8 h of development; and in sections of 8-9-h and older embryos immunostaining was seen at sites where basement membranes are present surrounding internal organs, muscles, underlying the hypodermal epithelium, and in the nervous system. Basement membrane staining was also seen in larva and adults. Cells from Drosophila embryos dissociated at the cellular blastoderm stage were grown in culture and some specific, differentiated cells synthesized laminin after several hours of culture as shown by immunofluorescence. The significance of the evolutionary conservation of the structure of this basement membrane component is discussed.     

Inhibition of Endothelial Cell Differentiation on a Glycosylated Reconstituted Basement Membrane Complex

The vascular basement membrane is involved in the regulation of endothelial cell differentiation. The accumulation of advanced glycosylation endproducts (AGEs) has been demonstrated on these basement membranes in patients with diabetes. We examined the effect of AGEs on endothelial cell behavior on reconstituted basement membrane, Matrigel. Human umbilical vein-derived endothelial cells (HUVECs) stopped proliferating and differentiated into capillary-like tube-shaped structures on Matrigel. Laminin antibody partially blocked this process. HUVECs cultured on glycosylated Matrigel, however, proliferated and formed a monolayer without tube formation. The inclusion of aminoguanidine, an inhibitor of AGE formation, during the glycosylation of Matrigel restored HUVEC differentiation. Although the laminin adsorbed onto the plastic culture wells promoted HUVEC attachment and spreading, glycosylated laminin reduced HUVEC attachment by 50% and abolished cellular spreading. These effects were restored by aminoguanidine. HUVEC attachment to glycosylated laminin was further reduced by AGE-modified albumin, poly I, acetylated low-density lipoprotein, or maleylated albumin, ligands for a scavenger receptor. Coating the culture dishes with the laminin peptides RGD, YIGSR, and SIKVAV supported the attachment of HUVECs that was unaffected by glycosylation. Results suggest that AGE accumulation on the basement membranes inhibits endothelial cell differentiation by impairing the normal interactions of endothelial cell receptors with their specific matrix ligands. This process may be involved in diabetic angiopathy.     

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.     

The role of the laminin beta subunit in laminin heterotrimer assembly and basement membrane function and development in C. elegans

Laminins are components of basement membranes that are required for morphogenesis, organizing cell adhesions and cell signaling. Studies have suggested that laminins function as alpha(x) beta(y) gamma(z) heterotrimers in vivo. In C. elegans, there is only one laminin beta gene, suggesting that it is required for all laminin functions. Our analysis is consistent with the role of the laminin beta as a subunit of laminin heterotrimers; the same cells express the laminin alpha, beta, and gamma subunits, the laminin beta subunit localizes to all basement membranes throughout development, and secretion of the beta subunit requires an alpha subunit. RNAi inhibition of the beta subunit gene or of the other subunit genes causes an embryonic lethality phenotype. Furthermore, a distinctive set of phenotypes is caused by both viable laminin alpha and beta partial loss-of-function mutations. These results show developmental roles for the laminin beta subunit, and they provide further genetic evidence for the importance of heterotrimer assembly in vivo.     

Basement membrane protein distribution in LYVE-1-immunoreactive lymphatic vessels of normal tissues and ovarian carcinomas

The endothelial cells of blood vessels assemble basement membranes that play a role in vessel formation, maintenance and function, and in the migration of inflammatory cells. However, little is known about the distribution of basement membrane constituents in lymphatic vessels. We studied the distribution of basement membrane proteins in lymphatic vessels of normal human skin, digestive tract, ovary and, as an example of tumours with abundant lymphatics, ovarian carcinomas. Basement membrane proteins were localized by immunohistochemistry with monoclonal antibodies, whereas lymphatic capillaries were detected with antibodies to the lymphatic vessel endothelial hyaluronan receptor-1, LYVE-1. In skin and ovary, fibrillar immunoreactivity for the laminin α4, β1, β2 and γ1 chains, type IV and XVIII collagens and nidogen-1 was found in the basement membrane region of the lymphatic endothelium, whereas also heterogeneous reactivity for the laminin α5 chain was detected in the digestive tract. Among ovarian carcinomas, intratumoural lymphatic vessels were found especially in endometrioid carcinomas. In addition to the laminin α4, β1, β2 and γ1 chains, type IV and XVIII collagens and nidogen-1, carcinoma lymphatics showed immunoreactivity for the laminin α5 chain and Lutheran glycoprotein, a receptor for the laminin α5 chain. In normal lymphatic capillaries, the presence of primarily α4 chain laminins may therefore compromise the formation of endothelial basement membrane, as these truncated laminins lack one of the three arms required for efficient network assembly. The localization of basement membrane proteins adjacent to lymphatic endothelia suggests a role for these proteins in lymphatic vessels. The distribution of the laminin α5 chain and Lutheran glycoprotein proposes a difference between normal and carcinoma lymphatic capillaries.     

Estrogen-mediated exocytosis in the glandular epithelium of prostates in castrated and hypophysectomized dogs

Summary Glandular cells in the prostate of the intact, adult dog contain numerous, large secretory granules that are released by exocytosis. Following hypophysectomy or castration, the glandular epithelium atrophies and the secretory granules degenerate and eventually disappear. Pharmacologic doses of estradiol-17 17-cyclopentylpropionate cause the regressed glandular cells to synthesize a new population of smaller granules that are also released by exocytosis, even though estrogen is known to inhibit fluid secretion by the canine prostate. Thus, the mechanisms involved in prostatic synthesis and exocytosis of secretory granules are independent of those regulating fluid secretion and are operative in the absence of androgen or pituitary hormones.     

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)