Structural and functional insights into the enzymatic activities of lipases from Burkholderia stagnalis and Burkholderia plantarii.

Lipases with high interesterification activity are important enzymes for industrial use. The lipase from Burkholderia stagnalis (BsL) exhibits higher interesterification activity than that from Burkholderia plantarii (BpL) despite their significant sequence similarity. In this study, we determined the crystal structure of BsL at 1.40 Å resolution. Utilizing structural insights, we have successfully augmented the interesterification activity of BpL by over twofold. This enhancement was achieved by substituting threonine with serine at position 289 through forming an expansive space in the substrate-binding site. Additionally, we discuss the activity mechanism based on the kinetic parameters. Our study sheds light on the structural determinants of the interesterification activity of lipase.

Chitosan-soyprotein interaction as determined by thermal unfolding experiments.

Chitosan interaction with soybean beta-conglycinin beta(3) was investigated by thermal unfolding experiments using CD spectroscopy. The negative ellipticity of the protein was enhanced with rising solution temperature. The transition temperature of thermal unfolding of the protein (T(m)) was 63.4 degrees C at pH 3.0 (0.15 M KCl). When chitosan was added to the protein solution, the T(m) value was elevated by 7.7 degrees C, whereas the T(m) elevation upon addition of chitosan hexamer (GlcN)(6) was 2.2 degrees C. These carbohydrates appear to interact with the protein stabilizing the protein structure, and the interaction ability could be evaluated from the T(m) elevation. Similar experiments were conducted at various pHs from 2.0 to 3.5, and the T(m) elevation was found to be enhanced in the higher pH region. We conclude that chitosan interacts with beta-conglycinin through electrostatic interactions between the positive charges of the chitosan polysaccharide and the negative charges of the protein surface.

Kinetic study on conformational change in a single molecular species, beta3, of beta-conglycinin in an acidic ethanol solution.

The conformational change in a single molecular species, beta3, of beta-conglycinin in an acidic ethanol solution was kinetically studied by the stopped-flow technique, utilizing the intrinsic fluorescence of proteins and the fluorescence of 1-anilinonaphthalene-8-sulfonic acid (ANS) bound to the proteins. The time-course of the intrinsic fluorescence changes clearly showed the rate of conformational change below and above 25% ethanol to be quite different from each other. ANS could bind well to the protein in an ethanol concentration range of 15-25%. However, the rate of conformational change of the protein corresponding to that for ANS binding could not be obtained at less than 25% ethanol, while the rate of conformational change agreed well with that for ANS binding at more than 25% ethanol. In addition, the process showing the greatest and slowest ANS binding was not apparent in the denaturation of beta-conglycinin under the conditions employed. These results lead to the conclusions that the beta-conglycinin structure could be maintained in the mild molten globule-like denaturation state, and that various tertiary structural changes could take place without any significant effect on the high sensitivity of intrinsic fluorescence after the secondary structural changes.