About factors providing the fast protein-protein recognition in processes of complex formation.

A package of programs for the examination of areas of subunit contacts (interface) in protein-protein (PP) complexes has been created and used for a detailed study of amino acid (AA) composition and interface structure in a large number of PP complexes from Brookhaven database (PBD). It appeared that in about 75% of the complexes, the AA composition of the subunit surface is not important. This suggests that, along with the surface AA composition, interactions between AA from the inner parts of protein globules may play a significant role in PP recognition. Such interactions between relatively distant AA residues can only be of electrostatic nature and contribute to the total electric field of the protein molecule. The configuration of the electric field itself appears to determine the PP recognition. The total electric field created by protein molecules can be calculated as a result of superimposition of the fields created by the protein multipole (i.e. by the totality of partial electric charges assigned to each atom of the molecule). We performed preliminary calculations for the distant electrostatic interaction of ribonuclease subunits in a vacuum. The results reveal that the effect of the electric fields of the protein multipole is strong enough to orient protein molecules prior to their Brown collision.

[What forces can determine the formation of highly specific protein-protein complexes?]. / Kakie sily opredeliaiut obrazovanie vysokospetsificheskikh belok-belkovykh kompleksov.

A software package was designed and used in a detailed study of the contact regions (interfaces) of a large number of protein-protein complexes using the PDB data. It appeared that for about 75% of the complexes the amino acid composition of the subunit surface in the contact region is not essential. Thus one may suggest that, along with the amino acid residues at the interface, the residues in the interior of the globules substantially contribute to protein-protein recognition. Such interactions between quite remote residues are most probably of electrical nature, and are involved in recognition by contributing to the overall electric field created by the protein molecule; the configuration of this field is perhaps the definitive factor of recognition. The overall field of the protein molecule is additively built of the fields created by each constituent residue, and it can be calculated as a sum of the fields created by the protein multipole (aggregate of 'partial' electric charges assigned to every atom of the protein molecule). Preliminary calculations of the remote electrostatic interaction have been performed for ribonuclease subunits in vacuum. The results are indicative of a real possibility that the electric field created by the protein multipole can strongly influence the mutual orientation of molecules before Brownian collisions.

Molecular mechanisms of protein-protein recognition: whether the surface placed charged residues determine the recognition process?

We studied the structure and composition of contact areas in 812 different kind dimeric protein-protein complexes from Brookhaven data base (PDB ) in order to reveal their pecularities with regard to protein-protein recognition. We have found, that the large portion of complexes (approximately 70%) have oppositely charged residues in the contact areas (interfaces) on the subunits surfaces, which form electrostatic contacts - R:E, R:D, K:E, K:D, H:E, H:D. These results are consistent with the current view that high rate complex formation may be driven by the long-range electrostatic interaction between charged AA residues of subunits surfaces. However, there are many complexes among the studied ones (approximately 30%), which have no electrostatic contacts at all in their contact area. Thus a question arises: what forces account for high complex formation rates (i.e. for the distant orienting of subunits before encounter) by forming complexes where the surface contact areas lack electrostatic contacts? We believe that the long-range orienting electrostatic interaction of subunits may account for all cases of efficient complex formation if one drops the traditional view that protein subunits interact mainly through their surfaces. We suggest that the distant orienting being due to the electrostatic interaction between the whole aggregates of partial electric charges of atoms of each complex subunits. Our preliminary model calculations (unpublished) made for ribonuclease dimer (does not have electrostatic contacts) conform this suggestion.

[Protein-protein recognition: testing of some hypotheses of binding site's structure using Brookhaven data bank]. / Belok-belkovoe uznavanie: proverka nekotorykh gipotez o strukture kontaktnykh oblastei v kompleksakh belkov na materiale Brukkheivenskogo banka dannykh.

Four amino acid's complementarity hypotheses have been checked using the data on the structure of 122 protein complexes taken from protein Brookhaven Data Bank. No one of hypotheses was conformed at the analysis of the contact region structures of the protein complexes examined.