Conformational similarity among amino acid residues: 1. Analysis of protein crystal structure data

Antigenic determinants reacting with rheumatoid factor: epitopes with different primary sequences share similar conformation

Polyclonal or monoclonal human IgM rheumatoid factors (RF) react with eight antigenic sites on the CH3 IgG domain, four sites on CH2 and two on human beta 2-microglobulin. All 14 of these RF-reactive epitopes are linear 7-11 amino acid peptides with different primary sequence. We questioned whether RF reactivity with such a variety of epitopes showing no obvious sequence homology might result from conformational similarities shared by various RF-reactive regions. Strong support for this concept was obtained using rabbit antisera as well as mouse mAbs to individual CH3, CH2 or beta 2m RF-reactive peptides. Major cross-reactivity was demonstrated between most of the 14 different CH3, CH2, or beta 2m RF-reactive peptides using individual anti-epitope antibodies. Molecular modelling studies of these peptides showed striking similarities in three-dimensional shape among many RF-reactive peptides. Main-chain atoms rather than side chains seemed to contribute most directly to conformational similarity. Molecular simulation studies on control peptides showed no conformational similarities with RF-reactive peptides. Our studies indicate that autoantibodies such as RF recognize main-chain conformations of reactive epitopes and react with a number of antigenic determinants of quite different primary sequence but similar main chain conformations.

Prediction of conformational states of amino acids using a Ramachandran plot

(phi, psi) data from crystal structures of 221 proteins having high resolution and sequence similarity cut-off at the 25% level were analysed by dividing the Ramachandran plot in three regions representing three conformational states: (i) conformational state 1: conformations in the (phi, psi) range from (-140 degrees, -100 degrees) to (0 degrees, 0 degrees); (ii) conformational state 2: conformations with (phi, psi) from (-180 degrees, 80 degrees) to (0 degrees, 180 degrees); and (iii) conformational state 3: all the remaining conformations in the (phi, psi) plane which are not included in the above two conformational states. Normalized probability values of the occurrence of single amino acid residues in conformational regions 1-3 and similar values for dipeptides were calculated. Comparisons of single residue and dipeptide normalized probability values have shown that short-range interactions, although strong, destabilize conformational states of only 44 dipeptides out of the 400 x 9 possible states. However, dipeptide frequency values provide better resolving power than single-residue potentials when used to predict conformational states of residues in a protein from its primary structure. The simple approach used in the present study to predict conformational states yields an accuracy of > 70% for 14 proteins and an accuracy in the range of 50-70% for 247 proteins. Thus these studies point out yet another use of the Ramachandran plot and the role of tertiary interactions in protein folding.

Conformational characteristics of asparaginyl residues in proteins

Backbone conformations at 1064 asparaginyl residues in 123 non-homologous, high-resolution X-ray structures of proteins were analysed. Asn adopts conformations in left-handed alpha-helical region and other partially allowed regions in the Ramachandran map more readily than any other non-glycyl residue. Asn conformational clusters in the (phi, psi) regions of left-handed alpha-helix right-handed alpha-helix and extended (beta) strands were investigated in detail for their occurrence in various secondary structures, especially in beta-turn regions. Preferences were observed for Asn conformations in different positions in various beta-turn types, including the first and fourth positions of the turn. Asparaginyl residues with extended conformations are found to occur frequently in irregular regions, although they are expected to occur predominantly in extended strands or in the third position of type II beta-turns. Asn conformations at the N-cap positions of helices strongly prefer extended conformation than alpha L, which seems to be characteristic of non-glycyl residues at that position. In the liners connecting two extended strands and those connecting an alpha-helix and an extended strand, Asn with alpha L or alpha R conformation is more favoured than Asn with the beta-conformation. Analysis of Asn-Asn doublets and Asn-X-Asn triplets permitted identification of conformational families in such sequences. Results of this investigation provide useful hints in modelling Asn-rich regions in proteins such as malaria parasite coat protein.

Sequence alignment approach to pick up conformationally similar protein fragments

Crystal structure data of globular proteins were used to prepare (phi, psi) probability maps of 20 proteinous amino acids. These maps were compared grid-wise with each other and a conformational similarity index was calculated for each pair of amino acids. A weight matrix, called Conformational Similarity Weight (CSW) matrix, was prepared using the conformational similarity index. This weight matrix was used to align sequences of 21 pairs of proteins whose crystal structures are known. The aligned regions with more than seven contiguous amino acids were further analysed by plotting average weight (W) values of overlapping hepatapeptides in these regions and carrying out curve fitting by Fourier series having TEN harmonics. The protein fragments corresponding to the half-linewidth of peaks were predicted as fragments having similar conformation in the protein pair under consideration. Such an approach allows us to pick up conformationally similar protein fragments with more than 67% accuracy.

Structure-stability relationship in proteins: fundamental tasks and strategy for the development of stabilized enzyme catalysts for biotechnology

The problem of relationships between the protein structure and its stability comprises two major questions. First, how to elucidate the peculiarities of the protein structure responsible for its stability. Second, knowing the general molecular basis of protein stability, how to change the structure of a given protein in order to increase its stability. This review is an attempt to show the modern state of the first (fundamental) and the second (applied) aspects of the problem.

Obligatory amino acids in primitive proteins

Conformational similarity among amino acid residues, a property derived by analysing (phi, psi)-probability distributions of 20 proteinous amino acids from 38 different globular proteins, is used to arrive at a set of six 'obligatory' amino acids of primitive proteins. The amino acids Ser, Val, Leu, Asp, Gly and Pro have been argued to be 'obligatory' and to represent, conformationally, the remaining amino acids. The reasons for consideration of these six residues as 'obligatory' are discussed. Methods to check the validity of our proposition are suggested.

Side chain characteristic main chain conformations of amino acid residues

Main chain conformation characteristics of the respective side chains of the 20 naturally occurring amino acid residues were obtained by the analysis of (phi, psi)-data from the crystal structures of 38 different globular proteins. The following observations are of interest: (i) For amino acids other than Glu, Thr and aliphatic amino acids, at least one main chain conformation is stabilised solely by side chain atoms. Such conformations are listed. (ii) In globular proteins, the main chain conformations which are significantly destabilised by side chain atom interactions are observed. The stabilising force for those conformations seems to come from main chain atom interactions. (iii) A set of conformations for which the main chain and side chain interactions are almost equal but in opposite directions, is listed and these conformations will be taken by residues mainly due to the effect of surroundings. The results can be used to study the folding of polypeptide chains and they also provide an insight into the role of the respective side chains on main chin conformations of amino acid residues.