Laminins in Peripheral Nerve Development and Muscular Dystrophy

Laminins are extracellular matrix (ECM) proteins that play an important role in cellular function and tissue morphogenesis. In the peripheral nervous system (PNS), laminins are expressed in Schwann cells and participate in their development. Mutations in laminin subunits expressed in the PNS and in skeleton muscle may cause peripheral neuropathies and muscular dystrophy in both humans and mice. Recent studies using gene knockout technology, such as cell-type specific gene targeting techniques, revealed that laminins and their receptors mediate Schwann cell and axon interactions. Schwann cells with disrupted laminin expression exhibit impaired proliferation and differentiation and also undergo apoptosis. In this review, we focus on the potential molecular mechanisms by which laminins participate in the development of Schwann cells.     

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.     

Interactions between laminin and epithelial cells in intestinal health and disease

Laminins are a multigene family of extracellular matrix molecules. Quantitatively, they are one of the most abundant glycoproteins present in basement membranes. Functionally, they can modulate several key biological activities, including cell adhesion and migration, gene expression and cell survival. Variability in the spatial and temporal expression of laminins, as well as of their specific receptors of the integrin family, in various tissues and organs, suggests that different laminins perform distinct functions. This article focuses on the human intestinal epithelium as a paradigm to illustrate the potential relationship between laminin-cell interactions and the cell state. This rapidly renewing epithelium consists of spatially separated proliferative and differentiated cell populations located in the crypts and on the villi, respectively. Differential distributions of the various laminins and laminin-binding integrins have been observed along the crypt-villus axis in both the developing and the adult intestine, and important alterations in the pattern of laminin expression have been reported in various intestinal pathologies, such as tufting enteropathy, Crohn's disease and ulcerative colitis, and colorectal cancer. More-direct approaches, including experimentation with in vitro and in vivo models, have provided evidence in support of a role for laminins in intestinal cell functions. Although further work is still needed, laminins emerge more and more as key regulators of specific cell functions important in both intestinal health and intestinal disease.     

Role of laminins in physiological and pathological angiogenesis

The interaction of endothelial cells and pericytes with their microenvironment, in particular with the basement membrane, plays a crucial role during vasculogenesis and angiogenesis. In this review, we focus on laminins, a major family of extracellular matrix molecules present in basement membranes. Laminins interact with cell surface receptors to trigger intracellular signalling that shapes cell behaviour. Each laminin exerts a distinct effect on endothelial cells and pericytes which largely depends on the adhesion receptor profile expressed on the cell surface. Moreover, proteolytic cleavage of laminins may affect their role in angiogenesis. We report in vitro and in vivo data on laminin-111, -411, -511 and -332 and their associated signalling that regulates cell behaviour and angiogenesis under normal and pathological conditions. We also discuss how tissue-specific deletion of laminin genes affects the behaviour of endothelial cells and pericytes and thus angiogenesis. Finally, we examine how coculture systems with defined laminin expression contribute to our understanding of the roles of laminins in normal and pathological vasculogenesis and angiogenesis.     

Laminins of the dermo-epidermal junction.

Laminins are the most abundant structural non-collagenous glycoproteins ubiquitously present in basement membranes. They are multidomain molecules constituting a family of possibly more than 50 members. Some members such as laminins 5, 6 and 10 are specific of the basal lamina present under stratified epithelia. Although only few intact laminin isoforms have been purified from cultivated cells or tissues, genetic engineering has opened the way for a rapid development of laminin structural biology. Moreover, the phenotypes resulting from gene targeting in mouse or from laminin defects in acquired or inherited human diseases highlight the pivotal role of laminins in morphogenesis, development, and physiology. Indeed, the laminins display a remarkable repertoire of functions, most importantly as structural elements forming a network throughout the basement membrane to which other collagenous or non-collagenous glycoproteins and proteoglycans attach. Furthermore, they are signaling molecules providing adjacent cells with diverse information by interacting with cell surface components.     

Beta-1 and beta-4 integrins, and laminin 67 kDa receptors in interaction between A431 cells and laminin isoforms

Laminins, as basal membrane glycoproteins, are able to stimulate cell adhesion and migration, and to influence gene expression. The laminin molecule has a set of bioactive sites that interact with different integrin and nonintegrin receptors, and, as a result, the reaction of the same cell type to different laminin isoforms may be different. The aim of this study was to determine the contributions of both integrins with beta 1 and beta 4 chains and 67 kDa laminin receptor in the interaction of A431 cells with two laminin isoforms: laminin-1 and laminin-2/4. The obtained data show that integrin alpha 6 beta 4 is more specific for interaction with laminin-2/4 than with laminin-1 and takes part in the stage of attachment of A431 cells to laminin. 67 kDa receptor promotes cell spreading on laminin-2/4 and inhibits cell spreading on laminin-1. An assumption was made about the complex action of receptors for interaction of A431 cells with laminins ("integrin alpha 6 beta 4--67 kDa receptors" complex).     

Differences in the character of interaction of normal and transformed human keratinocytes with laminin isoforms

Laminins constitute a family of heterotrimeric glycoproteins of basement membranes. Laminins promote cell adhesion, migration, growth, and differentiation. So far, at least 12 different isoforms of laminin have been known. However, no sufficient knowledge is available on the nature of cell response on different laminins. The study was aimed to compare adhesive properties of two laminin isoforms, laminin-1 and laminin-2/4, with respect to normal (freshly isolated keratinocytes) and transformed (A-431) human skin cells. We have used the following assays: cell adhesion to the substrate covered with laminin isoformes, interaction of latex beads (D = 1 micron) coated with the same proteins with cells in suspension, and a comparative study of the cytoskeleton structure of cells spread on the immobilized laminins. It was demonstrated that laminin-2/4 is a more effective potent promotor of adhesion for both normal keratinocytes and transformed A-431 cells, compared with laminin-1. A comparison of many attached protein-covered beads allowed to estimate a relative quantity of cell surface receptors to laminin isoforms in different cell types. The relative number of receptors to laminin-2/4 on the keratinocyte surface is 7 times higher than that to laminin-1 after a 30 min incubation with cells, and is 6 times higher after 1 hour. As for A-431 cells, their attachment to laminin-2/4 beads is 5 times higher than that to laminin-1-beads after a 1 min incubation, but as early as after 5 min this distinction disappeared, owing to bead internalization. The presence of a specific receptor to laminin-2/4 but not to laminin-1 on the keratinocyte surface has been suggested. Keratin differences in cytoskeleton organization in normal and transformed skin cells spread on the substrates covered with laminin-1 and laminin-2/4 were demonstrated.     

Bridging structure with function: structural, regulatory, and developmental role of laminins

The basement membrane is a highly intricate and organized portion of the extracellular matrix that interfaces with a variety of cell types including epithelial, endothelial, muscle, nerve, and fat cells. The laminin family of glycoproteins is a major constituent of the basement membrane. The 16 known laminin isoforms are formed from combinations of alpha, beta, and gamma chains, with each chain containing specific domains capable of interacting with cellular receptors such as integrins and other extracellular ligands. In addition to its role in the assembly and architectural integrity of the basement membrane, laminins interact with cells to influence proliferation, differentiation, adhesion, and migration, processes activated in normal and pathologic states. In vitro these functions are regulated by the post-translational modifications of the individual laminin chains. In vivo laminin knockout mouse studies have been particularly instructive in defining the function of specific laminins in mammalian development and have also highlighted its role as a key component of the basement membrane. In this review, we will define how laminin structure complements function and explore its role in both normal and pathologic processes.     

Laminin isoforms: biological roles and effects on the intracellular distribution of nuclear proteins in intestinal epithelial cells

Laminins are structurally and functionally major components of the extracellular matrix. Four isoforms of laminins (laminin-1, -2, -5 and -10) are expressed in a specific pattern along the crypt-villus axis of the intestine. Previous works indicated that expression of these isoforms is developmentally regulated and that laminins could modulate the behaviour of intestinal cells, but the exact role of each isoform remained unclear. Here, we report the first systematic analysis of the cellular functions of the four isoforms using the human colon adenocarcinoma Caco2/TC7 cell line as a model. We compared the respective abilities of each isoform to modulate adhesion, proliferation and differentiation of intestinal epithelial cells. We found that the isoforms were functionally distinct, with laminin-10 being the most adhesive substratum, laminin-2, laminin-5 and laminin-10 enhancing cellular proliferation and at the opposite, laminin-1 stimulating intestinal cell differentiation. To begin to characterise the molecular events induced by the different isoforms, we examined by immunofluorescence the intracellular distribution of several nuclear proteins, recently highlighted by a nuclear proteomic approach. We observed clear nucleocytoplasmic redistribution of these proteins, which depended on the laminin isoform. These results provide evidence for a distinct functional role of laminins in intestinal cell functions characterised by specific localisation of nuclear proteins.     

Laminins in Metastatic Cancer

Laminins are a family of extracellular heterotrimeric glycoproteins that are the main structural component of basement membranes (BMs), perform a barrier function, and are important for adhesion, differentiation, migration, and resistance to apoptosis of various cells, including cancer cells. The review summarizes the current knowledge of how laminins produced by cancer and normal cells influence the key stages of carcinogenesis. Laminin 332 (LN-332) and LN-111 enhance proliferation of certain cancer cells and increase the tumour growth. LN-111 increases resistance to apoptosis, induces differentiation, and inhibits the epithelial–mesenchymal transition (EMT) of cancer cells. LN-332 is associated with higher adhesion and higher migration potential of cancer cells. LN-411 and LN-421 significantly increase motility of cancer cells. LN-332 and LN-511 facilitate cell–cell adhesion and affect the efficacy of cell–cell interactions. The laminin chains α4 and α5 are important for the development and function of blood and lymphatic vessels. The expression ratio of the α4 and α5 laminin chains defines the BM permeability to leukocytes and, presumably, cancer cells in blood and lymphatic vessels. Interactions between LN-511 and α2-containing laminins enhance selfrenewal and survival of circulating cancer stem cells. Moreover, laminins are involved in the formation of premetastatic niches and new colonies. Endogenous expression of the α4 laminin chain stimulates proliferation of individualised circulating cancer cells in vitro and in vivo and facilitates micrometastasis.     

Laminin isoforms and lung development: all isoforms are not equal

Laminins are a major component of basement membranes. Each laminin molecule is a heterotrimeric glycoprotein composed of one alpha, one beta, and one gamma chain. Fifteen laminin isoforms exist, assembled from various combinations of 5alpha, 3beta, and 3gamma chains. The embryonic lung has abundant laminin isoforms. Increasing evidence suggests that different laminin isoforms have unique functions in lung development. Studies of embryonic lung explants and organotypic co-cultures show that laminin alpha1 and laminin 111 are important for epithelial branching morphogenesis and that laminin alpha2 and laminin 211 have a role in smooth muscle cell differentiation. In vivo studies of laminin alpha5-deficient mice indicate that this laminin chain, found in laminins 511 and 521, is essential for normal lobar septation in early lung development and normal alveolization and distal epithelial cell differentiation and maturation in late lung development. However, not all of the laminin chains present in the developing lung appear to be necessary for normal lung development since laminin alpha4 null mice do not have obvious lung abnormalities and laminin gamma2 null mice have only minimal changes in lung development. The mechanisms responsible for the lung phenotypes in mice with laminin mutations are unknown, but it is clear that multiple laminin isoforms are crucial for lung development and that different laminin isoforms exhibit specific, non-overlapping functions.     

Laminin receptors: achieving specificity through cooperation

The laminins are a large family of extracellular matrix proteins that can profoundly influence development, differentiation and disease progression. The biological effects of the laminins are mediated by surface receptors that link laminin matrices to intracellular signalling pathways. Several classes of receptors, including integrins and other molecules, may cooperate to provide the specificity apparent in the diverse array of laminin-mediated phenomena. This review assesses our current understanding of laminin receptors and discusses how such receptors could recognize structural differences among the laminins and relay these differences to the cell.     

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.     

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.     

Laminins and their receptors in the CNS

Laminin, an extracellular matrix protein, is widely expressed in the central nervous system (CNS). By interacting with integrin and non‐integrin receptors, laminin exerts a large variety of important functions in the CNS in both physiological and pathological conditions. Due to the existence of many laminin isoforms and their differential expression in various cell types in the CNS, the exact functions of each individual laminin molecule in CNS development and homeostasis remain largely unclear. In this review, we first briefly introduce the structure and biochemistry of laminins and their receptors. Next, the dynamic expression of laminins and their receptors in the CNS during both development and in adulthood is summarized in a cell‐type‐specific manner, which allows appreciation of their functional redundancy/compensation. Furthermore, we discuss the biological functions of laminins and their receptors in CNS development, blood–brain barrier (BBB) maintenance, neurodegeneration, stroke, and neuroinflammation. Last, key challenges and potential future research directions are summarized and discussed. Our goals are to provide a synthetic review to stimulate future studies and promote the formation of new ideas/hypotheses and new lines of research in this field.     

Laminin alpha5 chain is required for intestinal smooth muscle development

Laminins (comprised of alpha, beta, and gamma chains) are heterotrimeric glycoproteins integral to all basement membranes. The function of the laminin alpha5 chain in the developing intestine was defined by analysing laminin alpha5(-/-) mutants and by grafting experiments. We show that laminin alpha5 plays a major role in smooth muscle organisation and differentiation, as excessive folding of intestinal loops and delay in the expression of specific markers are observed in laminin alpha5(-/-) mice. In the subepithelial basement membrane, loss of alpha5 expression was paralleled by ectopic or accelerated deposition of laminin alpha2 and alpha4 chains; this may explain why no obvious defects were observed in the villous form and enterocytic differentiation. This compensation process is attributable to mesenchyme-derived molecules as assessed by chick/mouse alpha5(-/-) grafted associations. Lack of the laminin alpha5 chain was accompanied by a decrease in epithelial alpha3beta1 integrin receptor expression adjacent to the epithelial basement membrane and of Lutheran blood group glycoprotein in the smooth muscle cells, indicating that these receptors are likely mediating interactions with laminin alpha5-containing molecules. Taken together, the data indicate that the laminin alpha5 chain is essential for normal development of the intestinal smooth muscle and point to possible mesenchyme-derived compensation to promote normal intestinal morphogenesis when laminin alpha5 is absent.     

Recombinant laminin-8 (alpha(4)beta(1)gamma(1)). Production, purification,and interactions with integrins

Laminins are a large family of heterotrimeric extracellular matrix glycoproteins that, in addition to having structural roles, take part in the regulation of processes such as cell migration, differentiation, and proliferation. The laminin alpha(4) chain is widely distributed both in adults and during development in tissues such as cardiac, skeletal and smooth muscle fibers, vascular endothelia, lungs, and in peripheral nerves. It can associate with laminin beta(1)/gamma(1) chains to form laminin-8 and with the beta(2)/gamma(1) chains to form laminin-9. Functional studies on these laminins have been hampered by poor availability of the protein in pure and soluble forms. To facilitate studies on laminin-8, recombinant laminin-8 was produced in a mammalian expression system, purified and shown to form native Y-shaped molecules in rotary shadowing electron microscopy. Integrins mediating cell adhesion to laminin-8 were identified using function-blocking mAbs. The integrin specificities were found to differ somewhat from that of laminin-1. Integrin alpha(6)beta(1) was found to be a major mediator of adhesion of HT-1080 and cultured capillary endothelial cells to laminin-8. Considering the expression patterns of laminin-8 and integrin alpha(6)beta(1) it is likely that the former is a ligand for the latter in vivo as well.     

Laminins promote postsynaptic maturation by an autocrine mechanism at the neuromuscular junction

A prominent feature of synaptic maturation at the neuromuscular junction (NMJ) is the topological transformation of the acetylcholine receptor (AChR)-rich postsynaptic membrane from an ovoid plaque into a complex array of branches. We show here that laminins play an autocrine role in promoting this transformation. Laminins containing the α4, α5, and β2 subunits are synthesized by muscle fibers and concentrated in the small portion of the basal lamina that passes through the synaptic cleft at the NMJ. Topological maturation of AChR clusters was delayed in targeted mutant mice lacking laminin α5 and arrested in mutants lacking both α4 and α5. Analysis of chimeric laminins in vivo and of mutant myotubes cultured aneurally demonstrated that the laminins act directly on muscle cells to promote postsynaptic maturation. Immunohistochemical studies in vivo and in vitro along with analysis of targeted mutants provide evidence that laminin-dependent aggregation of dystroglycan in the postsynaptic membrane is a key step in synaptic maturation. Another synaptically concentrated laminin receptor, Bcam, is dispensable. Together with previous studies implicating laminins as organizers of presynaptic differentiation, these results show that laminins coordinate post- with presynaptic maturation.     

Developmental expression and cellular origin of the laminin alpha2, alpha4, and alpha5 chains in the intestine.

Laminins are extracellular matrix glycoproteins that are involved in various cellular functions, including adhesion, proliferation, and differentiation. In this study, we examine the expression patterns and the cellular origins of the laminin alpha2, alpha4, and alpha5 chains in the developing mouse intestine and in in vitro mouse/chick or chick/mouse interspecies hybrid intestines. In situ hybridization and Northern blot analysis revealed that mRNA levels for all three laminin alpha chains are highest in the fetal intestine undergoing intense morphogenetic movements. Laminin alpha4 mRNA and polypeptide are associated with mesenchyme-derived cell populations such as endothelium and smooth muscle. In contrast, laminin alpha2 and alpha5 chains participate in the structural organization of the subepithelial basement membrane and, in the mature intestine, show a complementary pattern of expression. All three laminin alpha chains occur in the smooth muscle basement membrane, with a differential expression of laminin alpha5 chain in the circular and longitudinal smooth muscle layers. The cellular origin of laminin alpha2 and alpha5 chains found in the subepithelial cell basement membrane was studied by immunocytochemical analysis of mouse/chick or chick/mouse interspecies hybrid intestines at various stages of development using mouse-specific antibodies. Laminin alpha2 was found to be deposited into the basement membrane exclusively by mesenchymal cells, while the laminin alpha5 chain was deposited by both epithelial and mesenchymal cells in an apparently developmentally regulated pattern. We conclude that (1) multiple laminin alpha chains are expressed in the intestine, implying specific roles for individual laminin isoforms during intestinal development, and (2) reciprocal epithelial/mesenchymal interactions are essential for the formation of a structured subepithelial basement membrane.