Amino acid mutagenesis within ligand-binding loops in alpha v confers loss-of-function or gain-of-function phenotype on integrin alpha v beta 3.

The crystal structure of alpha(v)beta(3) in complex with a cyclic RGD-containing ligand has recently been demonstrated. However, the functional significance of each residue within ligand binding loops has not been fully elucidated. Here, by employing alanine-scanning mutagenesis, we have examined the functional role of ligand contact residues in alpha(v). Tyr178 --> Ala substitution (Tyr178Ala) and Asp218Ala abolished a monovalent ligand, WOW-1 Fab binding as well as soluble fibrinogen binding, which is in perfect agreement with the crystallography. However, Asp150Ala showed no or only a modest inhibition of ligand binding. In contrast, Tyr substitution at Ala215 (Ala215Tyr) increased WOW-1 Fab binding, suggesting that the substitution increased the integrin affinity. The adhesion assay to immobilized fibrinogen showed essentially the same data as obtained using soluble ligands. Our present data indicate that Tyr178 and Asp218, but not Asp150 in alpha(v) is critically involved in ligand-binding and that Ala215 could regulate the affinity of alpha(v)beta(3).

A naturally occurring Tyr143His alpha IIb mutation abolishes alpha IIb beta 3 function for soluble ligands but retains its ability for mediating cell adhesion and clot retraction: comparison with other mutations causing ligand-binding defects.

The molecular basis for the interaction between a prototypic non-I-domain integrin, alpha(IIb)beta(3), and its ligands remains to be determined. In this study, we have characterized a novel missense mutation (Tyr143His) in alpha(IIb) associated with a variant of Glanzmann thrombasthenia. Osaka-12 platelets expressed a substantial amount of alpha(IIb)beta(3) (36%-41% of control) but failed to bind soluble ligands, including a high-affinity alpha(IIb)beta(3)-specific peptidomimetic antagonist. Sequence analysis revealed that Osaka-12 is a compound heterozygote for a single (521)T>C substitution leading to a Tyr143His substitution in alpha(IIb) and for the null expression of alpha(IIb) mRNA from the maternal allele. Given that Tyr143 is located in the W3 4-1 loop of the beta-propeller domain of alpha(IIb), we examined the effects of Tyr143His or Tyr143Ala substitution on the expression and function of alpha(IIb)beta(3) and compared them with KO (Arg-Thr insertion between 160 and 161 residues of alpha(IIb)) and with the Asp163Ala mutation located in the same loop by using 293 cells. Each of them abolished the binding function of alpha(IIb)beta(3) for soluble ligands without disturbing alpha(IIb)beta(3) expression. Because immobilized fibrinogen and fibrin are higher affinity/avidity ligands for alpha(IIb)beta(3), we performed cell adhesion and clot retraction assays. In sharp contrast to KO mutation and Asp163Ala alpha(IIb)beta(3), Tyr143His alpha(IIb)beta(3)-expressing cells still had some ability for cell adhesion and clot retraction. Thus, the functional defect induced by Tyr143His alpha(IIb) is likely caused by its allosteric effect rather than by a defect in the ligand-binding site itself. These detailed structure-function analyses provide better understanding of the ligand-binding sites in integrins.

Missense mutations in the beta(3) subunit have a different impact on the expression and function between alpha(IIb)beta(3) and alpha(v)beta(3).

Alpha(IIb)beta(3) and alpha(v)beta(3) belong to the beta(3) integrin subfamily. Although the beta(3) subunit is a key regulator for the biosynthesis of beta(3) integrins, it remains obscure whether missense mutations in beta(3) may induce the same defects in both alpha(IIb)beta(3) and alpha(v)beta(3). In this study, it is revealed that thrombasthenic platelets with a His280Pro mutation in beta(3), which is prevalent in Japanese patients with Glanzmann thrombasthenia, did contain significant amounts of alpha(v)beta(3) (about 50% of control) using sensitive enzyme-linked immunosorbent assay. Expression studies showed that the His280Probeta(3) mutation impaired alpha(IIb)beta(3) expression but not alpha(v)beta(3) expression in 293 cells. To extend these findings, the effects of several beta(3) missense mutations leading to an impaired alpha(IIb)beta(3) expression on alpha(v)beta(3) function as well as expression was examined: Leu117Trp, Ser162Leu, Arg216Gln, Cys374Tyr, and a newly created Arg216Gln/Leu292Ser mutation. Leu117Trp and Cys374Tyr beta(3) mutations did impair alpha(v)beta(3) expression, while Ser162Leu, Arg216Gln, and Arg216Gln/Leu292Ser mutations did not. With regard to ligand binding function, Ser162Leu mutation induced especially distinct effects between 2 beta(3) integrins: it markedly impaired ligand binding to alpha(IIb)beta(3) but not to alpha(v)beta(3) at all. These data clearly demonstrate that the biosynthesis and the ligand binding function of alpha(IIb)beta(3) and those of alpha(v)beta(3) are regulated in part by different mechanisms. Present data would be a clue to elucidate the regulatory mechanism of expression and function of beta(3) integrins.