Enzymes catalyzing protein folding and their cellular functions.

In live cells, protein folding often cannot occur spontaneously, but requires the participation of helper proteins - molecular chaperones and foldases. The mechanisms employed by chaperones markedly increase the effectiveness of protein folding, but have no bearing on the rate of this process, whereas foldases actually accelerate protein folding by exerting a direct influence on the rate-limiting steps of the overall reaction. Two types of foldases are known, using different principles of action. Peptidyl-prolyl cis/trans isomerase and protein-disulfide isomerase catalyze the folding of every protein that needs isomerization of prolyl peptide bonds or formation and isomerization of disulfide bonds for proper folding. By contrast, some foldases operating in the periplasm of bacterial cells are specifically designed to help in the folding of substrate proteins whose primary structure does not contain sufficient information for correct folding. In this review, we discuss recent data on the catalytic mechanisms of both types of foldases, focusing specifically on how a catalyst provides the structural information required for the folding of a target protein. Comparative analysis of the mechanisms employed by two different periplasmic foldases is used to substantiate the notion that combinations of a protein which is unable to fold independently and a specific catalyst delivering the necessary steric information are probably designed to achieve some particular biological purposes. The review also covers the problem of participation of peptidyl-prolyl cis/trans isomerase in different cellular functions, highlighting the role of this enzyme in conformational rearrangements of folded native proteins.

Antibodies specific to modified glyceraldehyde-3-phosphate dehydrogenase induce inactivation of the native enzyme and change its conformation.

The antibodies specific to an inactive glyceraldehyde-3-phosphate dehydrogenase (GAPDH) from Bacillus stearothermophilus prepared by the treatment of the tetrameric holoenzyme with glutaraldehyde were obtained. They were purified from the pool of polyclonal rabbit antibodies to GAPDH with the use of immobilized GAPDH cross-linked by glutaraldehyde as an affinity sorbent. Such antibodies were capable of interacting with the native enzyme, inducing its time-dependent inactivation; the effect was different with the apo- and holoenzyme forms. Differential scanning calorimetry of the purified [GAPDH].[antibody] complex revealed a large shift of the temperature corresponding to the maximal heat capacity of the holoenzyme towards the lower temperature. Again, the effect appeared to be different with the apoenzyme. Together, the results are consistent with the hypothesis that a specific antibody is able to exercise a certain strain on the target protein, altering its conformation toward the structure of the species which served to select the antibody. The possibility of preparing selective enzyme inhibitors based on the antibodies specific to inactive enzyme conformations is considered.

Interdomain communications in bifunctional enzymes: how are different activities coordinated?

Although bifunctional enzymes containing two different active centers located within separate domains are quite common in living systems, the significance of this bifunctionality is not always clear, and the molecular mechanisms of site-site interactions in such complex systems have come under the scrutiny of science only in recent years. This review summarizes recent data on the mechanisms of communication between active centers in bifunctional enzymes. Three types of enzymes are considered: (1) those catalyzing consecutive reactions of a metabolic pathway and exhibiting substrate channeling (glutamate synthase and imidazole glycerol phosphate synthase), (2) those catalyzing consecutive reactions without substrate channeling (lysine-ketoglutarate reductase/saccharopine dehydrogenase), and (3) those catalyzing opposed reactions (6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase). The functional role of interdomain communications is briefly discussed.