Binding of the G domains of laminin alpha1 and alpha2 chains and perlecan to heparin, sulfatides, alpha-dystroglycan and several extracellular matrix proteins

The C-terminal G domain of the mouse laminin alpha2 chain consists of five lamin-type G domain (LG) modules (alpha2LG1 to alpha2LG5) and was obtained as several recombinant fragments, corresponding to either individual modules or the tandem arrays alpha2LG1-3 and alpha2LG4-5. These fragments were compared with similar modules from the laminin alpha1 chain and from the C-terminal region of perlecan (PGV) in several binding studies. Major heparin-binding sites were located on the two tandem fragments and the individual alpha2LG1, alpha2LG3 and alpha2LG5 modules. The binding epitope on alpha2LG5 could be localized to a cluster of lysines by site-directed mutagenesis. In the alpha1 chain, however, strong heparin binding was found on alpha1LG4 and not on alpha1LG5. Binding to sulfatides correlated to heparin binding in most but not all cases. Fragments alpha2LG1-3 and alpha2LG4-5 also bound to fibulin-1, fibulin-2 and nidogen-2 with Kd = 13-150 nM. Both tandem fragments, but not the individual modules, bound strongly to alpha-dystroglycan and this interaction was abolished by EDTA but not by high concentrations of heparin and NaCl. The binding of perlecan fragment PGV to alpha-dystroglycan was even stronger and was also not sensitive to heparin. This demonstrated similar binding repertoires for the LG modules of three basement membrane proteins involved in cell-matrix interactions and supramolecular assembly.     

Identification of a major heparin and cell binding site in the LG4 module of the laminin alpha 5 chain

The G domain of the laminin alpha chains consists of five homologous G modules (LG1-5) and has been implicated in various biological functions. In this study, we identified an active site for cell and heparin binding within the laminin alpha5 G domain using recombinant proteins and synthetic peptides. Recombinant LG4, LG5, and LG4-5 modules were generated using a mammalian expression system. The LG4 and LG4-5 modules were highly active for cell binding, whereas the LG5 module alone showed only weak binding. Heparin inhibited cell binding to the LG4-5 module, whereas no inhibition was observed with EDTA or antibodies against the integrin beta(1) subunit. These results suggest that the LG4-5 module interacts with a cell surface receptor containing heparan sulfate but not with integrins. Solid-phase assays and surface plasmon resonance measurements demonstrated strong binding of the LG4 and LG4-5 modules to heparin with K(D) values in the nanomolar range, whereas a 16-fold lower value was determined for the LG5 module. Treatment with glycosidases demonstrated that N-linked carbohydrates on the LG5 module are complex-type oligosaccharides. The LG4-5 module, devoid of N-linked carbohydrates, exhibited similar binding kinetics toward heparin. Furthermore, cell binding was unaffected by removal of N-linked glycosylation. To localize active sites on the LG4 module, various synthetic peptides were used to compete with binding of the tandem module to heparin and cells. Peptide F4 (AGQWHRVSVRWG) inhibited binding, whereas a scrambled peptide of F4 failed to compete binding. Alanine replacements demonstrated that one arginine residue within F4 was important for cell and heparin binding. Our results suggest a critical role of the LG4 module for heparan sulfate-containing receptor binding within the laminin alpha5 chain.     

The LG1-3 tandem of laminin alpha5 harbors the binding sites of Lutheran/basal cell adhesion molecule and alpha3beta1/alpha6beta1 integrins

The laminin-type globular (LG) domains of laminin alpha chains have been implicated in various cellular interactions that are mediated through receptors such as integrins, alpha-dystroglycan, syndecans, and the Lutheran blood group glycoprotein (Lu). Lu, an Ig superfamily transmembrane receptor specific for laminin alpha5, is also known as basal cell adhesion molecule (B-CAM). Although Lu/B-CAM binds to the LG domain of laminin alpha5, the binding site has not been precisely defined. To better delineate this binding site, we produced a series of recombinant laminin trimers containing modified alpha chains, such that all or part of alpha5LG was replaced with analogous segments of human laminin alpha1LG. In solid phase binding assays using a soluble Lu (Lu-Fc) composed of the Lu extracellular domain and human IgG1 Fc, we found that Lu bound to Mr5G3, a recombinant laminin containing alpha5 domains LN through LG3 fused to human laminin alpha1LG4-5. However, Lu/B-CAM did not bind other recombinant laminins containing alpha5LG3 unless alpha5LG1-2 was also present. A recombinant alpha5LG1-3 tandem lacking the laminin coiled coil (LCC) domain did not reproduce the activity of Lu/B-CAM binding. Therefore, proper structure of the alpha5LG1-3 tandem with the LCC domain was essential for the binding of Lu/B-CAM to laminin alpha5. Our results also suggest that the binding site for Lu/B-CAM on laminin alpha5 may overlap with that of integrins alpha3beta1 and alpha6beta1.     

Binding of laminin alpha1-chain LG4-5 domain to alpha-dystroglycan causes tyrosine phosphorylation of syntrophin to initiate Rac1 signaling

Previously, a signaling pathway was described [Oak, Zhou, and Jarrett (2003) J. Biol. Chem. 278, 39287-39295] that links matrix laminin binding on the outside of the sarcolemma to Grb2 binding to syntrophin on the inside surface of the sarcolemma and by way of Grb2-Sos1-Rac1-PAK1-JNK ultimately results in the phosphorylation of c-jun on Ser(65). How this signaling is initiated was investigated. Grb2-binding to syntrophin is increased by the addition of either laminin-1 or the isolated laminin alpha1 globular domain modules LG4-5, a protein referred to as E3. This identifies the LG4-5 sequences as the region of laminin responsible for signaling. Since laminin alpha1 LG4 is known to bind alpha-dystroglycan, this directly implicates alpha-dystroglycan as the laminin-signaling receptor. E3 or laminin-1 increase Grb2-binding and Rac1 activation. In the presence of E3 or laminin-1, syntrophin is phosphorylated on a tyrosine residue, and this increases and alters Grb2 binding. The alpha-dystroglycan antibody, IIH6, which blocks binding of laminins to alpha-dystroglycan, blocks both the laminin-induced Sos1/2 recruitment and syntrophin phosphorylation, showing that it is alpha-dystroglycan binding the LG4-5 region of laminin that is responsible. The C-terminal SH3 domain of Grb2 (C-SH3) binds only to nonphosphorylated syntrophin, and phosphorylation causes the Grb2 SH2 domain to bind and prevents SH3 binding. Syntrophin, tyrosine phosphate, beta-dystroglycan, and Rac1 all co-localize to the sarcolemma of rat muscle sections. A model for how this phosphorylation may initiate downstream events in laminin signaling is presented.     

Contributions of the LG modules and furin processing to laminin-2 functions

The alpha2-laminin subunit contributes to basement membrane functions in muscle, nerve, and other tissues, and mutations in its gene are causes of congenital muscular dystrophy. The alpha2 G-domain modules, mutated in several of these disorders, are thought to mediate different cellular interactions. To analyze these contributions, we expressed recombinant laminin-2 (alpha(2)beta(1)gamma(1)) with LG4-5, LG1-3, and LG1-5 modular deletions. Wild-type and LG4-5 deleted-laminins were isolated from medium intact and cleaved within LG3 by a furin-like convertase. Myoblasts adhered predominantly through LG1-3 while alpha-dystroglycan bound to both LG1-3 and LG4-5. Recombinant laminin stimulated acetylcholine receptor (AChR) clustering; however, clustering was induced only by the proteolytic processed form, even in the absence of LG4-5. Furthermore, clustering required alpha(6)beta(1) integrin and alpha-dystroglycan binding activities available on LG1-3, acting in concert with laminin polymerization. The ability of the modified laminins to mediate basement membrane assembly was also evaluated in embryoid bodies where it was found that both LG1-3 and LG4-5, but not processing, were required. In conclusion, there is a division of labor among LG-modules in which (i) LG4-5 is required for basement membrane assembly but not for AChR clustering, and (ii) laminin-induced AChR clustering requires furin cleavage of LG3 as well as alpha-dystroglycan and alpha(6)beta(1) integrin binding.     

Probing the integrin-binding site within the globular domain of laminin-511 with the function-blocking monoclonal antibody 4C7.

In an attempt to elucidate the integrin-binding site within laminin-511 (alpha5beta1gamma1), we mapped the epitope for mAb 4C7, which recognizes the globular (G) domain of the laminin alpha5 chain and inhibits binding of integrin alpha6beta1 to laminin-511, using a series of recombinant laminin-511 mutants with deletions or substitutions in the G domain. Deletion of the LG2-5 modules only partially compromised the 4C7 binding activity, while deletion of all 5 LG modules completely abrogated the activity, indicating that the epitope for 4C7 resides in the LG1 module. In support of this conclusion, 4C7 reactivity was abolished when the LG1 module of laminin-511 was swapped with the corresponding module of laminin-111, but the reactivity was retained after swapping the LG2 or LG3 module. Despite the requirement of LG1 for 4C7 binding, a recombinant LG1 module failed to bind to 4C7 when expressed alone or in tandem with LG2, but exhibited significant 4C7 binding activity when expressed as an array of LG1-3. These results indicate that 4C7 recognizes an epitope in the LG1 module, whose active conformation is stabilized in the context of the LG1-3 modules. Despite their 4C7 binding activities, neither the recombinant LG1-3 fragment nor the LG2 and LG3 swap mutants were capable of binding to integrin alpha6beta1. Thus, the integrin binding activity does not necessarily parallel the 4C7 reactivity, and possibly requires a strictly defined conformation of the LG1 module which can only be attained within an array of the intact LG1-3 modules connected to the preceding coiled-coil domain.     

Structure and function of laminin LG modules.

Laminin G domain-like (LG) modules of approximately 180-200 residues are found in a number of extracellular and receptor proteins and often are present in tandem arrays. LG modules are implicated in interactions with cellular receptors (integrins, alpha-dystroglycan), sulfated carbohydrates and other extracellular ligands. The recently determined crystal structures of LG modules of the laminin alpha2 chain reveal a compact beta sandwich fold and identify a novel calcium binding site. Binding epitopes for heparin, sulfatides and alpha-dystroglycan have been mapped by site-directed mutagenesis and show considerable overlap. The epitopes are located in surface loops around the calcium site, which in other proteins (agrin, neurexins) are modified by alternative splicing. Efficient ligand binding often requires LG modules to be present in tandem. The close proximity of the N- and C-termini in the LG module, as well as a unique link region between laminin LG3 and LG4, impose certain constraints on the arrangement of LG tandems. Further modifications may be introduced by proteolytic processing of laminin G domains, which is known to occur in the alpha2, alpha3 and alpha4 chains.     

A unique sequence of the laminin alpha 3 G domain binds to heparin and promotes cell adhesion through syndecan-2 and -4

Laminin-5, consisting of the alpha 3, beta 3, and gamma 2 chains, is localized in the skin basement membrane and supports the structural stability of the epidermo-dermal linkage and regulates various cellular functions. The alpha chains of laminins have been shown to have various biological activities. In this study, we identified a sequence of the alpha 3 chain C-terminal globular domain (LG1-LG5 modules) required for both heparin binding and cell adhesion using recombinant proteins and synthetic peptides. We found that the LG3 and LG4 modules have activity for heparin binding and that LG4 has activity for cell adhesion. Studies with synthetic peptides delineated the A3G75aR sequence (NSFMALYLSKGR, residues 1412--1423) within LG4 as a major site for both heparin and cell binding. Substitution mutations in LG4 and A3G75aR identified the Lys and Arg of the A3G75aR sequence as critical for these activities. Cell adhesion to LG4 and A3G75aR was inhibited by heparitinase I treatment of cells, suggesting that cell binding to the A3G75aR site was mediated by cell surface heparan sulfate proteoglycans. We showed by affinity chromatography that syndecan-2 from fibroblasts bound to LG4. Solid-phase assays confirmed that syndecan-2 interacted with the A3G75aR peptide sequence. Stably transfected 293T cells with expression vectors for syndecan-2 and -4, but not glypican-1, specifically adhered to LG4 and A3G75aR. These results indicate that the A3G75aR sequence within the laminin alpha 3 LG4 module is responsible for cell adhesion and suggest that syndecan-2 and -4 mediate this activity.     

Analysis of heparin, alpha-dystroglycan and sulfatide binding to the G domain of the laminin alpha1 chain by site-directed mutagenesis

The 395-residue proteolytic fragment E3, which comprises the two most C-terminal LG modules of the mouse laminin alpha1 chain, was previously shown to contain major binding sites for heparin, alpha-dystroglycan and sulfatides. The same fragment (alpha1LG4-5) and its individual alpha1LG4 and alpha1LG5 modules have now been obtained by recombinant production in mammalian cells. These fragments were apparently folded into a native form, as shown by circular dichroism, electron microscopy and immunological assays. Fragment alpha1LG4-5 bound about five- to tenfold better to heparin, alpha-dystroglycan and sulfatides than E3. These binding activities could be exclusively localized to the alpha1LG4 module. Side-chain modifications and proteolysis demonstrated that Lys and Arg residues in the C-terminal region of alpha1LG4 are essential for heparin binding. This was confirmed by 14 single to triple point mutations, which identified three non-contiguous basic regions (positions 2766-2770, 2791-2793, 2819-2820) as contributing to both heparin and sulfatide binding. Two of these regions were also recognized by monoclonal antibodies which have previously been shown to inhibit heparin binding. The same three regions and a few additional basic residues also make major contributions to the binding of the cellular receptor alpha-dystroglycan, indicating a larger binding epitope. The data are also consistent with previous findings that heparin competes for alpha-dystroglycan binding.     

Crystal structure and cell surface anchorage sites of laminin alpha1LG4-5

The laminin G-like (LG) domains of laminin-111, a glycoprotein widely expressed during embryogenesis, provide cell anchoring and receptor binding sites that are involved in basement membrane assembly and cell signaling. We now report the crystal structure of the laminin alpha1LG4-5 domains and provide a mutational analysis of heparin, alpha-dystroglycan, and galactosylsulfatide binding. The two domains of alpha1LG4-5 are arranged in a V-shaped fashion similar to that observed with laminin alpha2 LG4-5 but with a substantially different interdomain angle. Recombinant alpha1LG4-5 binding to heparin, alpha-dystroglycan, and sulfatides was dependent upon both shared and unique contributions from basic residues distributed in several clusters on the surface of LG4. For heparin, the greatest contribution was detected from two clusters, 2719RKR and 2791KRK. Binding to alpha-dystroglycan was particularly dependent on basic residues within 2719RKR, 2831RAR, and 2858KDR. Binding to galactosylsulfatide was most affected by mutations in 2831RAR and 2766KGRTK but not in 2719RKR. The combined analysis of structure and activities reveal differences in LG domain interactions that should enable dissection of biological roles of different laminin ligands.     

Identification of neurite outgrowth promoting sites on the laminin alpha 3 chain G domain

Laminins are expressed in specific tissues and are involved in various biological activities including promoting cell adhesion, growth, migration, neurite outgrowth, and differentiation. The laminin alpha3 chain is mainly located in the skin and is also expressed in the floor plate of the developing neural tube. Previously, we showed that the human laminin alpha3 chain LG4 module binds to syndecan-2/4, a membrane-associated proteoglycan, and promotes human fibroblast adhesion. Here, we have evaluated the neurite outgrowth activity of the laminin alpha3 chain LG4 and LG5 modules. Three overlapping recombinant proteins, which contained LG4 and/or LG5 modules of the human laminin alpha3 chain, were prepared using a mammalian cell expression system. Two proteins, rec-alpha3LG4-5 and rec-alpha3LG4, promoted cell attachment and neurite outgrowth of rat pheochromocytoma PC12 cells, but rec-alpha3LG5 was inactive. Twenty-two peptides covering the entire LG4 module were synthesized and tested for cell attachment and neurite outgrowth activity to identify active sites of the LG4 module. A3G75 (KNSFMALYLSKG, alpha3 chain 1411-1422) and A3G83 (GNSTISIRAPVY, alpha3 chain 1476-1487) promoted PC12 cell attachment and neurite outgrowth. Additionally, A3G75 and A3G83 inhibited PC12 cell attachment to rec-alpha3LG4. These results suggest that the A3G75 and A3G83 sites are important for PC12 cell attachment and neurite outgrowth in the laminin alpha3 chain LG4 module. We also conjugated the A3G75 and A3G83 peptides on chitosan membranes to test their potential as bio-materials. These peptide-conjugated chitosan membranes were more active for neurite outgrowth than the peptide-coated plates. These results suggest that the A3G75- and A3G83-conjugated chitosan membranes are applicable as bio-medical materials for neural tissue repair and engineering.     

Structural and functional analysis of the recombinant G domain of the laminin alpha4 chain and its proteolytic processing in tissues

The C-terminal G domains of laminin alpha chains have been implicated in various cellular and other interactions. The G domain of the alpha4 chain was now produced in transfected mammalian cells as two tandem arrays of LG modules, alpha4LG1-3 and alpha4LG4-5. The recombinant fragments were shown to fold into globular structures and could be distinguished by specific antibodies. Both fragments were able to bind to heparin, sulfatides, and the microfibrillar fibulin-1 and fibulin-2. They were, however, poor substrates for cell adhesion and had only a low affinity for the alpha-dystroglycan receptor when compared with the G domains of the laminin alpha1 and alpha2 chains. Yet antibodies to alpha4LG1-3 but not to alpha4LG4-5 clearly inhibited alpha(6)beta(1) integrin-mediated cell adhesion to laminin-8, indicating the participation of alpha4LG1-3 in a cell-adhesive structure of higher complexity. Proteolytic processing within a link region between the alpha4LG3 and alpha4LG4 modules was shown to occur during recombinant production and in endothelial and Schwann cell culture. Cleavage could be attributed to three different peptide bonds and is accompanied by the release of the alpha4LG4-5 segment. Immunohistology demonstrated abundant staining of alpha4LG1-3 in vessel walls, adipose, and perineural tissue. No significant staining was found for alpha4LG4-5, indicating their loss from tissues. Immunogold staining demonstrated an association of the alpha4 chain primarily with microfibrillar regions rather than with basement membranes, while laminin alpha2 chains appear primarily associated with various basement membranes.     

Molecular dissection of the alpha-dystroglycan- and integrin-binding sites within the globular domain of human laminin-10

The adhesive interactions of cells with laminins are mediated by integrins and non-integrin-type receptors such as alpha-dystroglycan and syndecans. Laminins bind to these receptors at the C-terminal globular domain of their alpha chains, but the regions recognized by these receptors have not been mapped precisely. In this study, we sought to locate the binding sites of laminin-10 (alpha5beta1gamma1) for alpha(3)beta(1) and alpha(6)beta(1) integrins and alpha-dystroglycan through the production of a series of recombinant laminin-10 proteins with deletions of the LG (laminin G-like) modules within the globular domain. We found that deletion of the LG4-5 modules did not compromise the binding of laminin-10 to alpha(3)beta(1) and alpha(6)beta(1) integrins but completely abrogated its binding to alpha-dystroglycan. Further deletion up to the LG3 module resulted in loss of its binding to the integrins, underlining the importance of LG3 for integrin binding by laminin-10. When expressed individually as fusion proteins with glutathione S-transferase or the N-terminal 70-kDa region of fibronectin, only LG4 was capable of binding to alpha-dystroglycan, whereas neither LG3 nor any of the other LG modules retained the ability to bind to the integrins. Site-directed mutagenesis of the LG3 and LG4 modules indicated that Asp-3198 in the LG3 module is involved in the integrin binding by laminin-10, whereas multiple basic amino acid residues in the putative loop regions are involved synergistically in the alpha-dystroglycan binding by the LG4 module.     

The crystal structure of a laminin G-like module reveals the molecular basis of alpha-dystroglycan binding to laminins, perlecan, and agrin

Laminin G-like (LG) modules in the extracellular matrix glycoproteins laminin, perlecan, and agrin mediate the binding to heparin and the cell surface receptor alpha-dystroglycan (alpha-DG). These interactions are crucial to basement membrane assembly, as well as muscle and nerve cell function. The crystal structure of the laminin alpha 2 chain LG5 module reveals a 14-stranded beta sandwich. A calcium ion is bound to one edge of the sandwich by conserved acidic residues and is surrounded by residues implicated in heparin and alpha-DG binding. A calcium-coordinated sulfate ion is suggested to mimic the binding of anionic oligosaccharides. The structure demonstrates a conserved function of the LG module in calcium-dependent lectin-like alpha-DG binding.     

Normal human keratinocytes bind to the alpha3LG4/5 domain of unprocessed laminin-5 through the receptor syndecan-1

Basal keratinocytes of the epidermis adhere to their underlying basement membrane through a specific interaction with laminin-5, which is composed by the association of alpha3, beta3, and gamma2 chains. Laminin-5 has the ability to induce either stable cell adhesion or migration depending on specific processing of different parts of the molecule. One event results in the cleavage of the carboxyl-terminal globular domains 4 and 5 (LG4/5) of the alpha3 chain. In this study, we recombinantly expressed the human alpha3LG4/5 fragment in mammalian cells, and we show that this fragment induces adhesion of normal human keratinocytes and fibrosarcoma-derived HT1080 cells in a heparan- and chondroitin sulfate-dependent manner. Immunoprecipitation experiments with Na2 35SO4-labeled keratinocyte and HT1080 cell lysates as well as immunoblotting experiments revealed that the major proteoglycan receptor for the alpha3LG4/5 fragment is syndecan-1. Syndecan-4 from keratinocytes also bound to alpha3LG4/5. Furthermore we could show for the first time that unprocessed laminin-5 specifically binds syndecan-1, while processed laminin-5 does not. These results demonstrate that the LG4/5 modules within unprocessed laminin-5 permit its cell binding activity through heparan and chondroitin sulfate chains of syndecan-1 and reinforce previous data suggesting specific properties for the precursor molecule.     

Identification of the binding site for the Lutheran blood group glycoprotein on laminin alpha 5 through expression of chimeric laminin chains in vivo

The Lutheran blood group glycoprotein (Lu), also known as basal cell adhesion molecule, is an Ig superfamily transmembrane receptor for laminin alpha5. Lu is expressed on the surface of a subset of muscle and epithelial cells in diverse tissues and is thought to be involved in both normal and disease processes, including sickle cell disease and cancer. Here we investigated the binding of Lu to laminin alpha5 in vivo and in vitro. We prepared a soluble recombinant Lu (sol-Lu) composed of the Lu extracellular domain and a His(6) tag. Sol-Lu bound specifically to laminin-10/11 (alpha5beta1/beta2gamma1) in enzyme-linked immunosorbent assays and bound to bona fide basement membranes containing laminin alpha5 in tissue sections. Sol-Lu did not bind to tissue sections of laminin alpha5 knockout embryos, despite the fact that the four other alpha chains were present. To identify the Lu-binding site on laminin alpha5, we prepared modified alpha5 cDNAs encoding chimeric laminins containing all or part of the laminin alpha1 G domain in place of the analogous alpha5 regions. These constructs were used to generate transgenic mice. Proteins derived from transgenes were detected in basement membranes and were assayed for their ability to bind Lu by examining the localization of endogenous Lu and the binding of sol-Lu applied to tissue sections. Our results demonstrate that the alpha5 LG3 module is essential for Lu binding to laminin alpha5.     

High and low affinity heparin-binding sites in the G domain of the mouse laminin alpha 4 chain

G domains of the mouse laminin alpha 1 and alpha 4 chains consisting of its five subdomains LG1-LG5 were overexpressed in Chinese hamster ovary cells and purified by heparin chromatography. alpha 1LG1-LG5 and alpha 4LG1-LG5 eluted at NaCl concentrations of 0.30 and 0.47 m, respectively. In solid phase binding assays with immobilized heparin, half-maximal concentrations of 14 (alpha 1LG1-LG5) and 1.4 nm (alpha 4LG1-LG5) were observed. N-Glycan cleavage of alpha 4LG1-LG5 did not affect affinity to heparin. The affinity of alpha 4LG1-LG5 was significantly reduced upon denaturation with 8 m urea but could be recovered by removing urea. Chymotrypsin digestion of alpha 4LG1-LG5 yielded high and low heparin affinity fragments containing either the alpha 4LG4-LG5 or alpha 4LG2-LG3 modules, respectively. Trypsin digestion of heparin-bound alpha 4LG1-LG5 yielded a high affinity fragment of about 190 residues corresponding to the alpha 4LG4 module indicating that the high affinity binding site is contained within alpha 4LG4. Competition for heparin binding of synthetic peptides covering the alpha 4LG4 region with complete alpha 4LG1-LG5 suggests that the sequence AHGRL1521 is crucial for high affinity binding. Introduction of mutation of H1518A or R1520A in glutathione S-transferase fusion protein of the alpha 4LG4 module produced in Escherichia coli markedly reduced heparin binding activity of the wild type. When compared with the known structure of alpha 2LG5, this sequence corresponds to the turn connecting strands E and F of the 14-stranded beta-sheet sandwich, which is opposite to the proposed binding sites for calcium ion, alpha-dystroglycan, and heparan sulfate.     

Molecular dissection of laminin alpha 5 in vivo reveals separable domain-specific roles in embryonic development and kidney function

Laminins are a family of basement membrane proteins with diverse roles in fundamental developmental processes such as epiblast polarization and gastrulation, as well as in organ development and function. We have focused on the laminin alpha1 and alpha5 chains, the ancestral laminin alpha chains required for development. To elucidate the unique functions of laminin alpha1 and alpha5 and their COOH-terminal LG domains, we have produced a collection of laminin knockout and transgenic mice expressing full length and chimeric laminin alpha5/alpha1 chains. Crossing the transgenes onto the Lama5-/- background generates "pseudo-knockins", so called because endogenous laminin alpha5 is replaced by transgene-encoded proteins. Expression of a chimera with the entire alpha5LG domain replaced by alpha1LG had minimal ameliorative effects on the defects observed in Lama5-/- embryos. In contrast, high level expression of a chimera with only the alpha5LG3-5 tandem replaced by alpha1LG3-5 completely rescued defects in digit septation, neural tube closure, placental labyrinth morphology, lung lobe septation, hair growth, and vascularization of kidney glomeruli. These mice were viable for several months, but they developed a lethal nephrotic syndrome. Our results show that: (1) the laminin alpha5LG1-2 tandem plays an essential role during development and harbors the great majority of the functionality of the alpha5LG domain; and (2) the alpha5LG3-5 tandem serves as a novel determinant required for the kidney's glomerular filtration barrier to plasma protein.     

Structure of the C-terminal laminin G-like domain pair of the laminin alpha2 chain harbouring binding sites for alpha-dystroglycan and heparin

The laminins are large heterotrimeric glycoproteins with fundamental roles in basement membrane architecture and function. The C-terminus of the laminin alpha chain contains a tandem of five laminin G-like (LG) domains. We report the 2.0 A crystal structure of the laminin alpha2 LG4-LG5 domain pair, which harbours binding sites for heparin and the cell surface receptor alpha-dystroglycan, and is 41% identical to the laminin alpha1 E3 fragment. LG4 and LG5 are arranged in a V-shaped fashion related by a 110 degrees rotation about an axis passing near the domain termini. An extended N-terminal segment is disulfide bonded to LG5 and stabilizes the domain pair. Two calcium ions, one each in LG4 and LG5, are located 65 A apart at the tips of the domains opposite the polypeptide termini. An extensive basic surface region between the calcium sites is proposed to bind alpha-dystroglycan and heparin. The LG4-LG5 structure was used to construct a model of the laminin LG1-LG5 tandem and interpret missense mutations underlying protein S deficiency.     

Dystroglycan binding to laminin α1LG4 module influences epithelial morphogenesis of salivary gland and lung in vitro

Dystroglycan is a receptor for the basement membrane components laminin-1, -2, perlecan, and agrin. Genetic studies have revealed a role for dystroglycan in basement membrane formation of the early embryo. Dystroglycan binding to the E3 fragment of laminin-1 is involved in kidney epithelial cell development, as revealed by antibody perturbation experiments. E3 is the most distal part of the carboxyterminus of laminin alpha1 chain, and is composed of two laminin globular (LG) domains (LG4 and LG5). Dystroglycan-E3 interactions are mediated solely by discrete domains within LG4. Here we examined the role of this interaction for the development of mouse embryonic salivary gland and lung. Dystroglycan mRNA was expressed in epithelium of developing salivary gland and lung. Immunofluorescence demonstrated dystroglycan on the basal side of epithelial cells in these tissues. Antibodies against dystroglycan that block binding of alpha-dystroglycan to laminin-1 perturbed epithelial branching morphogenesis in salivary gland and lung organ cultures. Inhibition of branching morphogenesis was also seen in cultures treated with polyclonal anti-E3 antibodies. One monoclonal antibody (mAb 200) against LG4 blocked interactions between a-dystroglycan and recombinant laminin alpha1LG4-5, and also inhibited salivary gland and lung branching morphogenesis. Three other mAbs, also specific for the alpha1 carboxyterminus and known not to block branching morphogenesis, failed to block binding of alpha-dystroglycan to recombinant laminin alpha1LG4-5. These findings clarify why mAbs against the carboxyterminus of laminin alpha1 differ in their capacity to block epithelial morphogenesis and suggest that dystroglycan binding to alpha1LG4 is important for epithelial morphogenesis of several organs.