Role of non-glycine residues in left-handed helical conformation for the conformational stability of human lysozyme

To understand the role of non-Gly residues in the left-handed helical conformation for the conformational stability of a protein, the non-Gly to Gly and Ala mutations at six left-handed residues (R21, Y38, R50, Q58, H78, and N118) of the human lysozyme were examined. The thermodynamic parameters for denaturation were determined using a differential scanning calorimeter, and the crystal structures were analyzed by X-ray crystallography. If a left-handed non-Gly had an unfavorable steric interaction between the side-chain Cbeta and backbone, the Gly mutation would be expected to stabilize more than the Ala mutation at the same position. For the mutant human lysozymes, however, there were few differences in the denaturation Gibbs energy (DeltaG) between the Gly and Ala mutants, except for the substitution at position 58. Analysis of the changes in stability (DeltaDeltaG) based on the structures of the wild-type and mutant proteins showed that the experimental DeltaDeltaG value of Q58G was approximately 7 kJ/mol higher than the estimated value without consideration of any local steric interaction. These results indicate that only Q58G increased the stability by elimination of local constraints. The residue 58 is located at the most rigid position in the left-handed non-Gly residues and is involved in its enzymatic function. It can be concluded that the left-handed non-Gly residues do not always have unfavorable strain energies as compared with Gly at the same position.

Structural insights into the mechanism of intramolecular proteolysis

A variety of proteins, including glycosylasparaginase, have recently been found to activate functions by self-catalyzed peptide bond rearrangements from single-chain precursors. Here we present the 1.9 A crystal structures of glycosylasparaginase precursors that are able to autoproteolyze via an N --> O acyl shift. Several conserved residues are aligned around the scissile peptide bond that is in a highly strained trans peptide bond configuration. The structure illustrates how a nucleophilic side chain may attack the scissile peptide bond at the immediate upstream backbone carbonyl and provides an understanding of the structural basis for peptide bond cleavage via an N --> O or N --> S acyl shift that is used by various groups of intramolecular autoprocessing proteins.

Who checks the checkers? Four validation tools applied to eight atomic resolution structures. EU 3-D Validation Network

Eight protein crystal structures, which have been refined against X-ray diffraction data extending to atomic resolution, 1.2 A or better, were inspected using four different validation tools, PROCHECK, PROVE, SQUID and WHATCHECK. Two general questions were addressed. (1) Do the structures imply changes in "expected" stereochemical properties and are the target values used for restraints in the validation programs and the refinement protocol appropriate? (2) Can errors in models be detected and how reliable are the coordinates after refinement? Preliminary analysis by members of the network led to modifications both to the validation programs and to the refinement protocols. The results of the final analyses are reported here. Apparent discrepancies in cell dimensions were identified. Most stereochemical properties are shown to be more tightly clustered than for lower resolution analyses. In contrast the omega angle has a wider distribution. The validation software is generally available and can be accessed at servers listed at the end of the paper.

Occurrence and role of cis peptide bonds in protein structures

It has been widely assumed that the occurrence of cis peptide bonds in proteins is quite rare due to unfavorable contacts between adjacent amino acid residues in this isomeric form. To investigate this assumption, the Brookhaven Protein Data Bank was examined for the occurrences of cis peptide bonds. Out of 31,005 amide bonds, only 17, or 0.05%, are cis, while 99 of the 1534 imide bonds (X-Pro), or 6.5%, are cis. These figures are considerably less than the distribution predicted on the basis of the potential energy difference between the cis and trans isomeric forms and experimental data on small peptides. It is not known whether the lower than expected occurrence of cis peptide bonds arises from constraints imposed by the protein environment, or from assumptions made in the solution of the X-ray crystal structures. However, when the occurrence of cis bonds in the data base is examined relative to the resolution of the structures, the number of cis bonds increases with increasing resolution. The distributions seen for these peptide omega bonds in the data base are not the same shape as the distributions predicted from simple potential energy barriers. They are sharper in the main, but they are also broader at the base with significant numbers of nonplanar peptide bonds. Cis peptide bonds are found primarily in bends and turns and, in the case of cis imide bonds (X-PRO), this correlation is so high that it suggests a specific role for cis imide groups in such structures.

Studies on hydrogen bonds. Part V--Hydrogen bonding in energy minimization studies of peptides

An energy term, representing the N-H...O type of hydrogen bond, which is a function of the hydrogen bond length (R) and angle (theta) has been introduced in an energy minimization program, taking into consideration its interpolation with the non-bonded energy for borderline values of R and theta. The details of the mathematical formulation of the derivatives of the hydrogen bond function as applicable to the energy minimization have been given. The minimization technique has been applied to hydrogen bonded two and three linked peptide units (gamma-turns and beta-turns), and having Gly, Ala and Pro side chains. Some of the conformational highlights of the resulting minimum energy conformations are a) the occurrence of the expected 4----1 hydrogen bond in all of the burn-turn tripeptide sequences and b) the presence of an additional 3----1 hydrogen bond in some of the type I and II tripeptides with the hydrogen bonding scheme in such type I beta-turns occurring in a bifurcated form. These and other conformational features have been discussed in the light of experimental evidence and theoretical predictions of other workers.