Identification of a 110-kDa nonintegrin cell surface laminin-binding protein which recognizes an A chain neurite-promoting peptide.

Laminin is a potent promoter of neurite outgrowth, and a synthetic peptide of 19 amino acids, PA22-2, from the A chain has been found to promote process formation. Using peptide affinity chromatography, we have identified a 110-kDa, cell surface ligand from both neural cells and brain which binds this sequence. This binding protein does not share immunological identity with the B1 chain of integrin, and reduction does not alter its mobility in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Antibody to the 110-kDa protein stained cellular processes in vivo. Sequence analysis of the first 18 amino acids from the amino terminus yielded almost exact sequence identity with nucleolin, a major 110-kDa nucleolar phosphoprotein. Antibody to nucleolin, however, does not interact with the neural-derived, laminin-peptide-binding 110-kDa protein. The 110-kDa protein appears to be a ligand for a specific site on laminin.

Adult and fetal human mesangial cells interact with specific laminin domains.

Mesangial cells are centrally located pericytes in the renal glomerulus. They are surrounded by an extracellular matrix and directly contact the glomerular basement membrane in vivo. Because these interactions are critical for renal development and function, we have studied human mesangial cell interactions with laminin, a major adhesive component of basement membranes present in the extracellular matrix of the mesangium. Human fetal and adult mesangial cell attachment was stimulated by both laminin and the laminin-derived synthetic peptides YIGSR-NH2, CQAGTFALRGDNPQG-NH2, and CIKVAVS-NH2. Furthermore, mesangial cells spread on laminin as well as on both the RGD-containing and CIKVAVS peptides. When added in solution, all three peptides inhibited mesangial cell attachment to laminin, and the latter two peptides inhibited mesangial cell spreading on laminin. Laminin affinity column chromatography demonstrated several low-molecular-mass laminin-binding proteins ranging from between 35 and 42 kDa, which predominated in fetal mesangial cells, whereas a higher molecular mass laminin-binding protein of 65 kDa was predominant in adult mesangial cells. Western blot analysis with an anti-32-kDa laminin-binding protein antibody showed increased expression of both 31- and 42-kDa proteins in fetal mesangial cells when compared with the adult. The antisera to the 32-kDa laminin-binding protein also inhibited fetal mesangial spreading on the CIKVAVS peptide. Western blot analysis with an anti-67-kDa laminin-binding protein antibody revealed a 110-kDa protein in adult mesangial cells that was not present in fetal mesangial cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Laminin receptors for neurite formation.

Laminin, a basement membrane glycoprotein promotes both cell attachment and neurite outgrowth. Separate domains on laminin elicit these responses, suggesting that distinct receptors occur on the surface of cells. NG108-15 neuroblastoma-glioma cells rapidly extend long processes in the presence of laminin. We report here that 125I-labeled laminin specifically binds to these cells and to three membrane proteins of 67, 110, and 180 kDa. These proteins were isolated by affinity chromatography on laminin-Sepharose. The 67-kDa protein reacted with antibody to the previously characterized receptor for cell attachment to laminin. Antibodies to the 110-kDa and 180-kDa bands demonstrated that the 110-kDa protein was found in a variety of epithelial cell lines and in brain, whereas the 180-kDa protein was neural specific. Antibodies prepared against the 110-kDa and 180-kDa proteins inhibited neurite outgrowth induced by the neurite-promoting domain of laminin, whereas antibodies to the 67-kDa laminin receptor had no effect on neurite outgrowth. We conclude that neuronal cells have multiple cell-surface laminin receptors and that the 110-kDa and 180-kDa proteins are involved in neurite formation.

Genes for basement membrane proteins are coordinately expressed in differentiating F9 cells but not in normal adult murine tissues.

We have obtained cDNA clones coding for the A, B1, and B2 chains of laminin by screening a cDNA library prepared from mouse EHS tumor poly(A)RNA in the lambda gt11 expression vector with polyclonal antibody against denatured laminin. These cDNA clones were used in combination with a cDNA clone coding for the alpha 1 type IV collagen chain to study the regulation of genes for these basement membrane proteins in retinoic acid-induced differentiating mouse F9 teratocarcinoma cells and in various adult murine tissues. The levels of mRNA for the laminin A, B1, and B2 chains and for the alpha 1 type IV collagen chain were increased simultaneously and reached a maximum at almost the same time during the differentiation of F9 cells, suggesting coordinate expression in these cells. The tissue levels of mRNA encoding for the basement membrane components, however, varied considerably. The highest level of the B1 chain mRNA was observed in kidney, whereas, the levels of mRNA for A and B2 chains were highest in heart. Almost the same levels of expression of the alpha 1(IV) collagen mRNA were found in kidney, lung, and heart. The results indicate that the expression of genes for the basement membrane proteins is not coordinately regulated in these tissues. It is thus possible that different subunit structures of the laminin molecule may exist in tissues.

In vitro regulation of cartilage matrix assembly by a Mr 54,000 collagen-binding protein.

In cartilage, type II collagen is present as thin, short, randomly oriented fibrils. In vitro, however, type II collagen forms fibrils of large diameter, indicating that additional factors may be involved in the regulation of collagen fibril formation. We have examined extracts of a cartilage-producing tumor for the presence of collagen-binding proteins. In addition to fibronectin and link protein, a Mr 54,000 protein was found to bind to collagen fibrils as well as to native and denatured type II collagen. Immunological studies using antibody against the protein indicate that it is a cartilage matrix protein, not present in bone or in several other tissues. In vitro studies show that the Mr 54,000 protein in combination with cartilage proteoglycan decreases the rate of type II fibril formation and causes the fibrils to be of small diameter (24 +/- 8 nm). These studies indicate that complexes between collagen and proteoglycans mediated by this protein may regulate the assembly of cartilage matrix.

Basement membrane complexes with biological activity.

We have studied the reconstitution of basement membrane molecules from extracts prepared from the basement membrane of the EHS tumor. Under physiological conditions and in the presence of added type IV collagen and heparan sulfate proteoglycan, gellike structures form whose ultrastructure appears as interconnected thin sheets resembling the lamina dense zone of basement membrane. The major components of the reconstituted structures include laminin, type IV collagen, heparan sulfate proteoglycan, entactin, and nidogen. These components polymerize in constant proportions on reconstitution, suggesting that they interact in defined proportions. Molecular sieve studies on the soluble extract demonstrate that laminin, entactin, and nidogen are associated in large but dissociable complexes which may be a necessary intermediate in the deposition of basement membrane. The reconstituted matrix was biologically active and stimulated the growth and differentiation of certain cells.

Biological activities of laminin.

Laminin is a multifunctional protein with diverse biological activities. Like fibronectin, it can influence cell adhesion, growth, morphology, differentiation, migration, and agglutination as well as the assembly of the extracellular matrix. Laminin primarily affects cells of epithelial origin, and the response varies depending on the cell. Because most differentiated cells are difficult to maintain in culture, laminin may be an important supplement in studies on cell differentiation in vitro.