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  • Comparison of protein–protein interactions in serine protease-inhibitor and antibody-antigen complexes: Implications for the protein docking problem

  • RICHARD M. JACKSON
  • Journal:
    Protein Science / Volume 8 / Issue 3 / March 1999
    Published online by Cambridge University Press:
    01 March 1999, pp. 603-613
    Print publication:
    March 1999

  • The protein–protein interaction energy of 12 nonhomologous serine protease-inhibitor and 15 antibody-antigen complexes is calculated using a molecular mechanics formalism and dissected in terms of the main-chain vs. side-chain contribution, nonrotameric side-chain contributions, and amino acid residue type involvement in the interface interaction.

    There are major differences in the interactions of the two types of protein–protein complex. Protease-inhibitor complexes interact predominantly through a main-chain–main-chain mechanism while antibody-antigen complexes interact predominantly through a side-chain–side-chain or a side-chain–main-chain mechanism. However, there is no simple correlation between the main-chain–main-chain interaction energy and the percentage of main-chain surface area buried on binding. The interaction energy is equally effected by the presence of nonrotameric side-chain conformations, which constitute ∼20% of the interaction energy. The ability to reproduce the interface interaction energy of the crystal structure if original side-chain conformations are removed from the calculation is much greater in the protease-inhibitor complexes than the antibody-antigen complexes. The success of a rotameric model for protein–protein docking appears dependent on the extent of the main-chain–main-chain contribution to binding.

    Analysis of (1) residue type and (2) residue pair interactions at the interface show that antibody-antigen interactions are very restricted with over 70% of the antibody energy attributable to just six residue types (Tyr > Asp > Asn > Ser > Glu > Trp) in agreement with previous studies on residue propensity. However, it is found here that 50% of the antigen energy is attributable to just four residue types (Arg = Lys > Asn > Asp). On average just 12 residue pair interactions (6%) contribute over 40% of the favorable interaction energy in the antibody-antigen complexes, with charge-charge and charge/polar-tyrosine interactions being prominent. In contrast protease inhibitors use a diverse set of residue types and residue pair interactions.