Role of laminin terminal globular domains in basement membrane assembly

Laminins contribute to basement membrane assembly through interactions of their N- and C-terminal globular domains. To further analyze this process, recombinant laminin-111 heterotrimers with deletions and point mutations were generated by recombinant expression and evaluated for their ability to self-assemble, interact with nidogen-1 and type IV collagen, and form extracellular matrices on cultured Schwann cells by immunofluorescence and electron microscopy. Wild-type laminin and laminin without LG domains polymerized in contrast to laminins with deleted alpha1-, beta1-, or gamma1-LN domains or with duplicated beta1- or alpha1-LN domains. Laminins with a full complement of LN and LG domains accumulated on cell surfaces substantially above those lacking either LN or LG domains and formed a lamina densa. Accumulation of type IV collagen onto the cell surface was found to require laminin with separate contributions arising from the presence of laminin LN domains, nidogen-1, and the nidogen-binding site in laminin. Collectively, the data support the hypothesis that basement membrane assembly depends on laminin self-assembly through formation of alpha-, beta-, and gamma-LN domain complexes and LG-mediated cell surface anchorage. Furthermore, type IV collagen recruitment into the laminin extracellular matrices appears to be mediated through a nidogen bridge with a lesser contribution arising from a direct interaction with laminin.     

Molecular analysis of laminin N-terminal domains mediating self-interactions

The ability of laminins to self-polymerize is crucial for the formation of basement membranes. Development of this polymerized network has profound effects upon tissue architecture as well as on the intracellular organization and differentiation of neighboring cells. The laminin N-terminal (LN) domains have been shown to mediate this interaction and studies using proteolytic fragments derived from laminin-1 led to the theory that network assembly depends on the formation of a heterotrimeric complex between LN domains derived from alpha, beta, and gamma chains in different laminin molecules with homologous interactions being insignificant. The laminin family consists of 15 known isoforms formed from five alpha, three beta, and three gamma chains, of which some are truncated and lack the N-terminal LN domain. To address whether the model of heterotrimeric complex formation is applicable to laminin isoforms other than laminin-1, eight LN domains found in the laminin protein family were recombinantly expressed and tested in three different assays for homologous and heterologous interactions. The results showed that the lack of homologous interactions is an exception, with such interactions being seen for LN domains derived from all alpha chains and from the beta2 and beta3 subunits. The gamma chain-derived LN domains showed a far more limited binding repertoire, particularly in the case of the gamma3 chain, which is found present in a range of non-basement membrane locations. Further, whereas the interactions depended upon Ca2+ ions, with EDTA reversibly abrogating binding, EDTA-induced conformational changes were not reversible. Together these results demonstrate that the assembly model proposed on the basis of laminin-1 may be a simplification, with the assembly of naturally occurring laminin networks being far more complex and highly dependent upon which laminin isoforms are present.     

Characterization of the ligand-binding specificities of integrin alpha3beta1 and alpha6beta1 using a panel of purified laminin isoforms containing distinct alpha chains

Integrins alpha3beta1 and alpha6beta1 are two major laminin receptors expressed on the surface of mammalian cells. Interactions of cells with laminins through these integrins play important roles in cell adhesion, differentiation, motility, and matrix assembly. To determine the binding specificity and affinity of these integrins toward various types of laminins at the level of direct protein-protein interactions, we purified integrins alpha3beta1 and alpha6beta1 from human placenta, and examined their binding to a panel of laminin isoforms, each containing distinct alpha chains (i.e., laminin-1, laminin-2/4, laminin-5, laminin-8, and laminin-10/11). Integrin alpha3beta1 showed clear specificity for laminin-5 and laminin-10/11, with no significant binding to laminin-1, laminin-2/4, and laminin-8. In contrast, integrin alpha6beta1 showed a broad spectrum of specificity, with apparent binding affinity in the following order: laminin-10/11 > laminin-5 > laminin-1 > laminin-2/4 congruent with laminin-8. Integrin titration assays demonstrated that laminin-10/11 was the most preferred ligand among the five distinct laminin isoforms for both alpha3beta1 and alpha6beta1 integrins. Given that laminin-10/11 is the major basement membrane component of many adult tissues, the interaction of laminin-10/11 with these integrins should play a central role in the adhesive interactions of epithelial cells with underlying basement membranes.     

Colocalization of multiple laminin isoforms predominantly beneath hemidesmosomes in the upper lamina densa of the epidermal basement membrane.

Multiple laminin isoforms including laminins 5 (alpha3 beta3 gamma2), 6 (alpha3 beta1 gamma1), 10 (alpha5 beta1 gamma1), and possibly laminins 7 (alpha3 beta2 gamma1) and 11 (alpha5 beta2 gamma1) are present in the epidermal basement membrane. However, only the precise epidermal ultrastructural localization of laminin 5 (alpha3 beta3 gamma2) has been elucidated. We therefore determined the precise expression and ultrastructural localization of the alpha5, beta1, beta2, and gamma1 chains in the epidermis. The expression of laminin chains in skin samples was analyzed from patients with epidermolysis bullosa (EB, n=15) that harbor defects in specific hemidesmosome (HD)-associated components. The expression of the alpha5, beta1, and gamma1 chains (present in laminins 10/11) and beta2 chain (laminins 7/11) was unaffected in all intact (unseparated) skin of EB patients including Herlitz junctional EB with laminin-5 defects (n=6). In the basement membrane of human epidermis, the alpha5, beta1, beta2, and gamma1 chains were expressed but also localized to the dermal vessels. Immunogold electron microscopy of normal human epidermis localized the alpha5, beta1, beta2, and gamma1 chains to the upper lamina densa, with between 84% and 92% of labeling restricted to beneath the HDs, similar to laminin 5 (n> or =200 gold particles per sample, sample number n=4) but distinct from collagen IV labeling (with only 63% labeling beneath HDs, p<0.001). Taken together, the majority of the alpha5beta1/beta2gamma1 laminin chains are located beneath HDs. This suggests that laminin-10-associated chains have specific functions or molecular interactions beneath HDs in the epidermal basement membrane.     

Ligand-binding specificities of laminin-binding integrins: a comprehensive survey of laminin-integrin interactions using recombinant alpha3beta1, alpha6beta1, alpha7beta1 and alpha6beta4 integrins.

The interactions of cells with basement membranes are primarily mediated via the engagement of laminins by a group of integrin family proteins, including integrins alpha3beta1, alpha6beta1, alpha7beta1 and alpha6beta4. To explore the ligand-binding specificities of these laminin-binding integrins, we produced these integrins, including two alpha7beta1 splice variants (alpha7X1beta1 and alpha7X2beta1), as soluble recombinant proteins and determined their binding specificities and affinities toward a panel of purified laminin isoforms containing distinct alpha chains. Among the five laminin-binding integrins investigated, alpha3beta1 and alpha6beta4 exhibited a clear specificity for laminin-332 (alpha3beta3gamma2) and laminin-511 (alpha5beta1gamma1)/521 (alpha5beta2gamma1), while integrin alpha6beta1 showed a broad specificity, binding to all laminin isoforms with a preference for laminin-111 (alpha1beta1gamma1), laminin-332 and laminin-511/521. The two alpha7beta1 variants were distinct from alpha3beta1, alpha6beta1 and alpha6beta4 in that they did not bind to laminin-332. alpha7X1beta1 bound to all laminins, except laminin-332, with a preference for laminin-211 (alpha2beta1gamma1)/221 (alpha2beta2gamma1) and laminin-511/521, while alpha7X2beta1 bound preferentially to laminin-111 and laminin-211/221. Laminin-511/521 was the most preferred ligand for all the laminin-binding integrins, except for alpha7X2beta1, whereas laminin-411 was the poorest ligand, capable of binding to alpha6beta1 and alpha7X1beta1 with only modest binding affinities. These comprehensive analyses of the interactions between laminin-binding integrins and a panel of laminins clearly demonstrate that the isoforms of both integrins and laminins differ in their binding specificities and affinities, and provide a molecular basis for better understanding of the adhesive interactions of cells with basement membranes of defined laminin compositions.     

Localization of laminin α3B chain in vascular and epithelial basement membranes of normal human tissues and its down-regulation in skin cancers

The basement membrane (BM) proteins laminins, which consist of alpha, beta and gamma chains, play critical roles in the maintenance of tissue structures. One of laminin alpha chains, alpha3 has two isoforms, the truncated form alpha3A and the full-sized form alpha3B. In contrast to alpha3A laminins, little is known about alpha3B laminins. To show the histological distribution of the laminin alpha3B chain, we prepared alpha3B-specific monoclonal antibodies. Immunohistochemical analysis showed that the alpha3B chain was colocalized with the alpha3A, beta3 and gamma2 chains in the epithelial BMs of the skin, esophagus, breast and lung, suggesting the presence of laminin-3B32 (laminin-5B) and laminin-3A32 (laminin-5A). In the lung alveoli, laminin-3B32 was dominant over laminin-3A32, but vice versa in other epithelial BMs. In contrast, the BMs of blood vessels including capillaries were strongly positive for alpha3B, but almost or completely negative for alpha3A, beta3 and gamma2. alpha3B was colocalized with beta1 and gamma1 in these BMs. The alpha3B chain was scarcely detected in the vessels of malignant skin cancers, though the gamma2 and beta3 chains were highly expressed in the cancer cells. These results strongly suggest that the laminin alpha3B chain is widely expressed in vascular BMs of normal tissues, probably as laminin-3B11/3B21 (laminin-6B/7B).     

Distinct distribution of laminin and its integrin receptors in the pancreas.

Tissue function is regulated by the extracellular microenvironment including cell basement membranes, in which laminins are a major component. Previously, we found that laminin-1 promotes differentiation and survival of pancreatic islet cells. Here we characterize the expression pattern of laminins and their integrin receptors in adult pancreas. Although they are expressed in the basement membrane of acinar cells and duct epithelium, no laminin chains examined were detected extracellularly in the pancreatic islets. In contrast to laminin beta(1)- and gamma(1)-chains, the alpha(1)-chain, unique to laminin-1, was not detected. Laminin-10 (alpha(5)beta(1)gamma(1)) was expressed in acinar tissue, whereas laminins-2 (alpha(2)beta(1)gamma(1)) and -10 were expressed in the blood vessels. The laminin connector molecule, nidogen-1, had a distribution similar to that of laminin beta(1) and gamma(1), whereas fibulin-1 and -2, which compete with nidogen-1, were mostly confined to blood vessels. Integrin subunits alpha(6) and alpha(3) were detected in acinar cells and duct epithelial cells, but alpha(6) was absent in islet cells. Integrin alpha(6)beta(4) was detected only in duct cells, alpha(6)beta(1) in both acinar and ductal cells, and alpha(3)beta(1) in acinar, duct, and islet cells. These findings are a basis for further investigation of the role of extracellular matrix molecules and their receptors in pancreas function.     

The requirement of the glutamic acid residue at the third position from the carboxyl termini of the laminin gamma chains in integrin binding by laminins

Laminins are the major cell-adhesive proteins in the basement membrane, consisting of three subunits termed alpha, beta, and gamma. The putative binding site for integrins has been mapped to the G domain of the alpha chain, although trimerization with beta and gamma chains is necessary for the G domain to exert its integrin binding activity. The mechanism underlying the requirement of beta and gamma chains in integrin binding by laminins remains poorly understood. Here, we show that the C-terminal region of the gamma chain is involved in modulation of the integrin binding activity of laminins. We found that deletion of the C-terminal three but not two amino acids within the gamma1 chain completely abrogated the integrin binding activity of laminin-511. Furthermore, substitution of Gln for Glu-1607, the amino acid residue at the third position from the C terminus of the gamma1 chain, also abolished the integrin binding activity, underscoring the role of Glu-1607 in integrin binding by the laminin. We also found that the conserved Glu residue of the gamma2 chain is necessary for integrin binding by laminin-332, suggesting that the same mechanism operates in the modulation of the integrin binding activity of laminins containing either gamma1 or gamma2 chains. However, the peptide segment modeled after the C-terminal region of gamma1 chain was incapable of either binding to integrin or inhibiting integrin binding by laminin-511, making it unlikely that the Glu residue is directly recognized by integrin. These results, together, indicate a novel mechanism operating in ligand recognition by laminin binding integrins.     

Human amnion contains a novel laminin variant, laminin 7, which like laminin 6, covalently associates with laminin 5 to promote stable epithelial-stromal attachment

Stable attachment of external epithelia to the basement membrane and underlying stroma is mediated by transmembrane proteins such as the integrin alpha6beta4 and bullous pemphigoid antigen 2 within the hemidesmosomes along the basolateral surface of the epithelial cell and their ligands that include a specialized subfamily of laminins. The laminin 5 molecule (previously termed kalinin/nicein/epiligrin) is a member of this epithelial-specific subfamily. Laminin 5 chains are not only considerably truncated within domains III-VI, but are also extensively proteolytically processed in vitro and in vivo. As a result, the domains expected to be required for the association of laminins with other basement membrane components are lacking in the mature laminin 5 molecule. Therefore, the tight binding of laminin 5 to the basement membrane may occur by a unique mechanism. To examine laminin 5 in tissue, we chose human amnion as the source, because of its availability and the similarity of the amniotic epithelial basement membrane with that of skin. We isolated the laminin 5 contained within the basement membrane of human amnion. In addition to monomeric laminin 5, we find that much of the laminin 5 isolated is covalently adducted with laminin 6 (alpha3beta1gamma1) and a novel laminin isotype we have termed laminin 7 (alpha3beta2gamma1). We propose that the association between laminin 5 and laminins 6 and 7 is a mechanism used in amnion to allow stable association of laminin 5 with the basement membrane. The beta2 chain is seen at the human amniotic epithelial-stromal interface and at the dermal-epidermal junction of fetal and adult bovine skin by immunofluorescence, but is not present, or only weakly present, in neonatal human skin.     

Antibodies against domain E3 of laminin-1 and integrin alpha 6 subunit perturb branching epithelial morphogenesis of submandibular gland, but by different modes

Branching epithelial morphogenesis requires interactions between the surrounding mesenchyme and the epithelium, as well as interactions between basement membrane components and the epithelium. Embryonic submandibular gland was used to study the roles of two mesenchymal proteins, epimorphin and tenascin-C, as well as the epithelial protein laminin-1 and one of its integrin receptors on branching morphogenesis. Laminin-1 is a heterotrimer composed of an alpha 1 chain and two smaller chains (beta 1 and gamma 1). Immunofluorescence revealed a transient expression of laminin alpha 1 chain in the epithelial basement membrane during early stages of branching morphogenesis. Other laminin-1 chains and alpha 6, beta 1, and beta 4 integrin subunits seemed to be expressed constitutively. Expression of epimorphin, but not tenascin-C, was seen in the mesenchyme during early developmental stages, but a mAb against epimorphin did not perturb branching morphogenesis of this early epithelium. In contrast, inhibition of branching morphogenesis was seen with a mAb against the carboxy terminus of laminin alpha 1 chain, the E3 domain. An inhibition of branching was also seen with a mAb against the integrin alpha 6 subunit. The antibodies against laminin alpha 1 chain and integrin alpha 6 subunit perturbed development in distinct fashions. Whereas treatment with the anti-E3 resulted in discontinuities of the basement membrane at the tips of the branching epithelium, treatment with the mAb against alpha 6 integrin subunit seemed to leave the basement membrane intact. We suggest that the laminin E3 domain is involved in basement membrane formation, whereas alpha 6 beta 1 integrin binding to laminin-1 may elicit differentiation signals to the epithelial cells.     

Binding of netrin-4 to laminin short arms regulates basement membrane assembly

Netrins were first identified as neural guidance molecules, acting through receptors that are members of the DCC and UNC-5 family. All netrins share structural homology to the laminin N-terminal domains and the laminin epidermal growth factor-like domains of laminin short arms. Laminins use these domains to self-assemble into complex networks. Here we demonstrate that netrin-4 is a component of basement membranes and is integrated into the laminin polymer via interactions with the laminin gamma1 andgamma3 short arms. The binding is mediated through the laminin N-terminal domain of netrin-4. In contrast to netrin-4, other members of the netrin family do not bind to these laminin short arms. Moreover, a truncated form of netrin-4 completely inhibits laminin-111 self-assembly in vitro, and full-length netrin-4 can partially disrupt laminin self-interactions. When added to explant cultures, netrin-4 retards salivary gland branching morphogenesis.     

Expression and biological role of laminin-1.

Of the approximately 15 laminin trimers described in mammals, laminin-1 expression seems to be largely limited to epithelial basement membranes. It appears early during epithelial morphogenesis in most tissues of the embryo, and remains present as a major epithelial laminin in some adult tissues. Previous organ culture studies with embryonic tissues have suggested that laminin-1 is important for epithelial development. Recent data using genetically manipulated embryonic stem (ES) cells grown as embryoid bodies provide strong support for the view of a specific role of laminin-1 in epithelial morphogenesis. One common consequence of genetic ablation of FGF signaling, beta1-integrin or laminin gamma1 chain expression in ES cells is the absence of laminin-1, which correlates with failure of BM assembly and epiblast differentiation. Partial but distinct rescue of epiblast differentiation has been achieved in all three mutants by exogenously added laminin-1. Laminin-1 contains several biologically active modules, but several are found in beta1 or gamma1 chains shared by at least 11 laminins. However, the carboxytermini of the alpha chains contain five laminin globular (LG) modules, distinct for each alpha chain. There is increasing evidence for a particular role of alpha1LG4 binding to its receptors for epithelial tubulogenesis. The biological roles of this and other domains of laminin-1 are currently being explored by genetic means. The pathways controlling laminin-1 synthesis have remained largely unknown, but recent advances raise the possibility that laminin-1 and collagen IV synthesis can be regulated by pro-survival kinases of the protein kinase B/Akt family.     

Preferential locomotion of leukemic cells towards laminin isoforms 8 and 10.

To identify the laminin isoforms of the basement membranes that could be implicated in the extravasation process of neoplastic lymphocytes, a number of purified laminins and one native renal laminin complex were comparatively investigated for their ability to promote migration of neoplastic lymphocytes in vitro. The identity/composition of a human placental laminin complex was asserted by combining immunochemical assays, sequence determination of tryptic peptides, and ultrastructural analysis to be composed predominantly of laminin-10 in which the coiled-coil C-terminal regions and the G globular domain of the alpha5 chain were preserved intact despite the enzymatic treatment used for its isolation. Lymphoma and leukemic cell lines failed to migrate towards laminin-4, -9, -11, moved poorly in response to laminin-1, -2/4, -5 and the renal laminin complex, but markedly locomoted towards the subendothelial laminin-8 and -10. The motility-promoting interaction with these latter laminins was interchangeably mediated by the alpha3beta1 and alpha6beta1 integrins. Lymphocyte locomotion on laminins assayed in the presence of cytokines was either reduced or enhanced suggesting that local cytokine milieu could further influence motility response.     

Inhibition of laminin alpha 1-chain expression leads to alteration of basement membrane assembly and cell differentiation

The expression of the constituent alpha 1 chain of laminin-1, a major component of basement membranes, is markedly regulated during development and differentiation. We have designed an antisense RNA strategy to analyze the direct involvement of the alpha 1 chain in laminin assembly, basement membrane formation, and cell differentiation. We report that the absence of alpha 1-chain expression, resulting from the stable transfection of the human colonic cancer Caco2 cells with an eukaryotic expression vector comprising a cDNA fragment of the alpha 1 chain inserted in an antisense orientation, led to (a) an incorrect secretion of the two other constituent chains of laminin-1, the beta 1/gamma 1 chains, (b) the lack of basement membrane assembly when Caco2-deficient cells were cultured on top of fibroblasts, assessed by the absence of collagen IV and nidogen deposition, and (c) changes in the structural polarity of cells accompanied by the inhibition of an apical digestive enzyme, sucrase-isomaltase. The results demonstrate that the alpha 1 chain is required for secretion of laminin-1 and for the assembly of basement membrane network. Furthermore, expression of the laminin alpha 1-chain gene may be a regulatory element in determining cell differentiation.     

Structural requirement of carboxyl-terminal globular domains of laminin alpha 3 chain for promotion of rapid cell adhesion and migration by laminin-5

The basement membrane protein laminin-5, a heterotrimer of laminin alpha3, beta3, and gamma2 chains, potently promotes cellular adhesion and motility. It has been supposed that the carboxyl-terminal globular region of the alpha3 chain consisting of five distinct domains (G1 to G5) is important for its interaction with integrins. To clarify the function of each G domain, we transfected cDNAs for the full-length (wild type (WT)) and five deletion derivatives (DeltaGs) of the alpha3 chain into human fibrosarcoma cell line HT1080, which expressed and secreted the laminin beta3 and gamma2 chains but not the alpha3 chain. The transfectants with the alpha3 chain cDNAs lacking G5 (DeltaG(5)), G4-5 (DeltaG(4-5)), G3-5 (DeltaG(3-5)), and G2-5 (DeltaG(2-5)) secreted laminin-5 variants at levels comparable to that with WT cDNA. However, the transfectant with the cDNA without any G domains (DeltaG(1-5)) secreted little laminin-5, suggesting that the G domains are essential for the efficient assembly and secretion of the heterotrimer alpha3beta3gamma2. The transfectants with WT, DeltaG(5), and DeltaG(4-5) cDNAs survived in serum-free medium longer than those with DeltaG(3-5), DeltaG(2-5), and DeltaG(1-5) cDNAs. The transfectants with WT, DeltaG(5), and DeltaG(4-5) cDNAs secreted apparently the same size of laminin-5, which lacked G4 and G5 due to proteolytic cleavage between G3 and G4, and these laminin-5 forms potently promoted integrin alpha(3)beta(1)-dependent cell adhesion and migration. However, the laminin-5 forms of DeltaG(3-5) and DeltaG(2-5) hardly promoted the cell adhesion and motility. These findings demonstrate that the G3 domain, but not the G4 and G5 domains, of the alpha3 chain is essential for the potent promotion of cell adhesion and motility by laminin-5.     

Matrix assembly,regulation, and survival functions of laminin and its receptors in embryonic stem cell differentiation

Laminin-1 is essential for early embryonic basement membrane assembly and differentiation. Several steps can be distinguished, i.e., the expression of laminin and companion matrix components, their accumulation on the cell surface and assembly into basement membrane between endoderm and inner cell mass, and the ensuing differentiation of epiblast. In this study, we used differentiating embryoid bodies derived from mouse embryonic stem cells null for gamma1-laminin, beta1-integrin and alpha/beta-dystroglycan to dissect the contributions of laminin domains and interacting receptors to this process. We found that (a) laminin enables beta1-integrin-null embryoid bodies to assemble basement membrane and achieve epiblast with beta1-integrin enabling expression of the laminin alpha1 subunit; (b) basement membrane assembly and differentiation require laminin polymerization in conjunction with cell anchorage, the latter critically dependent upon a heparin-binding locus within LG module-4; (c) dystroglycan is not uniquely required for basement membrane assembly or initial differentiation; (d) dystroglycan and integrin cooperate to sustain survival of the epiblast and regulate laminin expression; and (e) laminin, acting via beta1-integrin through LG1-3 and requiring polymerization, can regulate dystroglycan expression.     

Laminin 5 processing and its integration into the ECM.

Laminins are a family of multi-functional basement membrane proteins. Their C-terminal domain binds to cell surface receptors and is thereby responsible for cell anchorage and the initiation of specific outside-in and inside-out signals. With their N-terminal parts, laminins interact with proteins of the extracellular matrix scaffold to secure the basement membrane to the underlying mesenchymal tissue. Laminins 5A (alpha3Abeta3gamma2), 5B (alpha3Bbeta3gamma2) and 6 (alpha3Abeta1gamma1) are isoforms specific of the basement membrane underneath the epidermis and they undergo a sequential series of extracellular proteolytic changes, which might successively turn on and off one or several of their biological and mechanical functions. Under physiological conditions, such as in adult human skin, epithelial laminins have lost part of the C- and N-terminal domains of the alpha3 and gamma2 chains, respectively. In contrast, in cylindromatosis, a rare inherited disease characterised by major ultrastructural alterations of the basement membrane and altered expression/distribution of integrin receptors, laminin processing has not been completed. Together, these results suggest that laminin processing may regulate signalling pathways and the architecture of the basement membrane by restricting the repertoire of interactions with cell surface receptors and extracellular matrix components.     

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.     

Laminin-11.

Laminins are a family of glycoproteins which are ubiquitous components of basement membranes and play key structural and functional roles. Eleven isoforms have been identified to date; each is an alpha beta gamma heterotrimer assembled from a repertoire of five alpha, three beta and two gamma chains. Studies of laminin-11 (alpha 5 beta 2 gamma 1) illustrate the unique expression patterns and distinct functions that can be displayed by laminin isoforms. Laminin-11 is found in the glomerular basement membrane in kidney, in the neuromuscular synaptic cleft in skeletal muscle and in other tissues such as placenta and lung. Mice lacking laminin-11 exhibit defective glomerular filtration and developmental defects in neuromuscular synapse formation, with Schwann cells invading the synaptic cleft. Consistent with these observations, both motoneurons and Schwann cells distinguish laminin-11 from other isoforms in vitro. These results suggest that laminin-11 is a structural component of the basement membrane which influences cell behavior in physiologically relevant ways. A greater understanding of laminin-11 assembly and basement membrane incorporation could provide a logical basis for therapy in merosin-deficient congenital muscular dystrophy.     

Laminin alpha5-chain is expressed early and widely during the development of the anterior segment of rat eye

The distribution of a novel laminin alpha5-chain in the basement membranes of the anterior segment of rat eye was studied. Frozen sections of embryonic day (E)16--17, post-natal day (P)2, 5, 10, 15 and 30 and adult rat eyes were immunostained for laminin chains alpha2, alpha5, beta1, beta2 and gamma1 and for laminin-5, as well as for EHS-laminin, to visualize all basement membranes. Laminin alpha5-, beta1- and gamma1-chain immunoreactivities were found in the basement membranes of the inner and outer layers of optic cup, lens epithelium, further corneal epithelium and skin of the eyelids in E16--17 rat eyes. In P2 and older rat eyes, laminin alpha5-, beta1- and gamma1-chains were all seen in the basement membranes of the corneal and conjunctival epithelium, Descemet's membrane, lens epithelium, ciliary processes, blood vessels and skin of the eyelids. There was a change in the expression pattern of laminin alpha5, beta1- and gamma1-chains in Descemet's membrane from the endothelial side of the membrane (P2--P15 eyes) to both sides of the membrane after P30. Immunoreactivity for laminin-5 was weak in the basement membrane of E16--17 epidermis, but strong in the basement membrane of corneal, conjunctival and eyelid epithelium in P2 and older rat eyes. Laminin alpha2- and beta2-chains were seen in conjunctival and uveal blood vessels in P15 and older rat eyes. The laminin beta2-chain emerged into the basement membrane of conjunctival epithelium in P30 and older rat eyes, suggesting a role for the laminin beta2-chain in the maturation of conjunctiva. The results suggest that laminin alpha5-chain, possibly in laminin-10 (alpha5beta1gamma1), is early and widely expressed in the basement membranes of developing and adult rat eye and, further, that laminin alpha5-chain is a major laminin alpha-chain, partly in coexpression with the alpha3-chain of laminin-5 in the basement membranes of the anterior segment of the eye in developing and adult rats. © 1998 Chapman & Hall