Twenty-eight amino acid residues involved in most noncovalent interactions between trimeric protein subunits in the capsid of the parvovirus minute virus of mice were truncated individually to alanine, and the effects on capsid assembly, thermostability, and conformation were analyzed. Only seven side chains were essential for protein subunit recognition. These side chains virtually corresponded with those that either buried a large hydrophobic surface on trimer association or formed buried intertrimer hydrogen bonds or salt bridges. The seven residues are evolutionarily conserved, and they define regularly spaced spots on a thin equatorial belt surrounding each trimer. Truncation of the many side chains that were dispensable for assembly, including those participating in solvent-accessible polar interactions, did not substantially affect capsid thermostability either. However, the interfacial residues located at the base of the pores delineating the capsid five-fold axes participated in a heat-induced conformational rearrangement associated with externalization of the capsid protein N terminus, and they were needed for infectivity. Thus, at the subunit interfaces of this model virus capsid, only key residues involved in the strongest interactions are critical for assembly and stability, but additional residues fulfill other important biological roles. P rotein-protein recognition mediates many fundamental biological processes. A detailed knowledge of these processes requires the determination of the structural, energetic, and functional roles of individual amino acid residues and interactions in protein-protein interfaces. These studies have been generally undertaken by using small protein-ligand complexes or oligomeric proteins of moderate size (reviewed in ref. 1; see also refs. 2-4). In contrast, for multimeric protein complexes, such as viral capsids (5, 6) or large cellular assemblies, little is known about the specific molecular determinants of protein association and stability. Mutational studies of virus capsids, generally focused on a few specific amino acid residues, have provided important insights (7-22). However, exhaustive experimental studies on the relative importance of residues and molecular interactions in viral capsid assembly, disassembly, and͞or stability are still very limited. These studies contribute also to the understanding of protein structure-function relationships and evolution under conflictive selective constraints (22-27), and they could be exploited possibly in the design of thermostable vaccines and antiviral agents promoting capsid disassembly or interfering with assembly (23, 28-31).Many viruses, including viruses of medical or veterinary significance, have capsids of icosahedral symmetry. The icosahedral T ϭ 1 capsids of parvoviruses (32-37) are formed by 60 protein subunits that are contributed by three nonidentical polypeptide chains (VP1, VP2, and VP3). These polypeptides derive, however, from a single gene and show identical fold and core sequence (Fig. 1). In the minut...
