Abstract
RNase inhibitor (RI) binds with extraordinary affinity (Ki approximately 10(-13)-10(-16) M) to diverse proteins in the pancreatic RNase superfamily. In the present study, the structural basis for the recognition of two RI ligands, human angiogenin (Ang) and bovine RNase A, has been investigated by site-specific mutagenesis of human RI and Ang. The RI residues examined were those that appear to form strong contacts with RNase A in the crystal structure of the porcine RI x RNase A complex [Kobe, B. & Deisenhofer, J. (1995) Nature (London) 374, 183-186] that would not be replicated in the Ang complex. Ala substitutions of five of these residues (Glu-287, Lys-320, Glu-401, Cys-408, and Arg-457) were found to have little or no effect on binding of RNase A. In contrast, replacements of Tyr-434, Asp-435, and Tyr-437 and deletion of the C-terminal residue Ser-460 substantially weakened affinity for RNase A: the losses of binding energy associated with the mutations were 5.9, 3.6, 2.6, and 3.5 kcal/mol, respectively. Thus these four residues, which are neighbors in the tertiary structure, appear to constitute a "hot spot" for the RNase A interaction. However, only one of them, Asp-435, was equally important for binding of Ang; the Ki increases produced by mutations of the others were 20- to 93-fold smaller for Ang than for RNase A. Consequently, Tyr-434 plays a significant but lesser role in the Ang complex, whereas Tyr-437 and Ser-460 make only minor contributions. Ala mutations of four Ang residues (His-8, Gln-12, Asn-68, and Glu-108) that correspond to RI contacts on RNase A produced no major changes in affinity for RI. These findings indicate that RI uses largely different interactions to achieve its extremely tight binding of RNase A and Ang.