Laminin chain assembly is regulated by specific coiled-coil interactions.

Laminins are large heterotrimeric, multidomain proteins that play a central role in organising and establishing all basement membranes. Despite a total of 45 potential heterotrimeric chain combinations formed through the coiled-coil domain of the 11 identified laminin chains (alpha1-5, beta1-3, gamma1-3), to date only 15 different laminin isoforms have been reported. This observation raises the question whether laminin assembly is regulated by differential gene expression or specific chain recognition. To address this issue, we here perform a complete analysis of laminin chain assembly and specificity. Using biochemical and biophysical techniques, all possible heterotrimeric combinations from recombinant C-terminal coiled-coil fragments of all chains were analysed. Apart from laminin 323 (alpha3, beta2, gamma3), for which no biochemical evidence of its existence in vivo is available, these experiments confirmed all other known laminin isoforms and identified two novel potential chain combinations, laminins 312 (alpha3, beta1, gamma2) and 422 (alpha4, beta2, gamma4). Our findings contribute to the understanding of basement membrane structure, function and diversity.

Structure of the extracellular domain of Tie receptor tyrosine kinases and localization of the angiopoietin-binding epitope.

Angiogenesis is essential for tissue repair and regeneration during wound healing but also plays important roles in many pathological processes including tumor growth and metastasis. The receptor protein tyrosine kinase Tie2 and its ligands, the angiopoietins, have important functions in the regulation of angiogenesis. Here, we report a detailed structural and functional characterization of the extracellular region of Tie2. Sequence analysis of the extracellular domain revealed an additional immunoglobulin-like domain resulting in a tandem repeat of immunoglobulin-like domains at the N terminus of the protein. The same domain organization was also found for the Tie1 receptor that shares a high degree of homology with Tie2. Based on structural similarities to other receptor tyrosine kinases and cell adhesion molecules, we demonstrate that the N-terminal two immunoglobulin-like domains of Tie2 harbor the angiopoietin-binding site. Using transmission electron microscopy we furthermore show that the extracellular domain of Tie receptors consists of a globular head domain and a short rod-like stalk that probably forms a spacer between the cell surface and the angiopoietin-binding site. Mutational analysis demonstrated that the head domain consists of the three immunoglobulin-like domains and the three epidermal growth factor-like modules and that the stalk is formed by the three fibronectin type III repeats. These findings might be of particular interest for drug development because Tie receptors are potential targets for treatment of angiogenesis-associated diseases.

Evidence that monoclonal antibodies directed against the integrin beta subunit plexin/semaphorin/integrin domain stimulate function by inducing receptor extension.

The overall structure of integrins is that of a ligand-binding head connected to two long legs. The legs can exhibit a pronounced bend at the "knees," and it has been proposed that the legs undergo a dramatic straightening when integrins transit from a low affinity to a high affinity state. The knee region contains domains from both alpha and beta subunits, including the N-terminal plexin/semaphorin/integrin (PSI) domain of the beta subunit. The role played by the knee domains in the regulation of integrin-ligand binding is uncertain. Here we show that: (i) monoclonal antibodies (mAbs) N29 and 8E3 have epitopes in the beta(1) subunit PSI domain and stimulate ligand binding to alpha(5)beta(1); (ii) N29 and 8E3 cause long range conformational changes that alter the ligand binding activity of the head region; (iii) the stimulatory action of these mAbs is dependent on the calf-1 domain, which forms part of the alpha subunit knee; and (iv) the epitopes of 8E3 and N29 map close to the extreme N terminus of the PSI and are likely to lie on the side of this domain that faces the alpha subunit. Taken together, our data suggest that the binding of these mAbs results in a levering apart of the PSI and calf-1 domains, and thereby causes the alpha and beta subunit knees to separate. Several major inferences can be drawn from our findings. First, the PSI domain appears to form part of an interface with the alpha subunit that normally restrains the integrin in a bent state. Second, the PSI domain is important for the transduction of conformational changes from the knee to head. Third, unbending is likely to provide a general mechanism for control of integrin-ligand recognition.