Improvement of the optimum temperature of lipase activity for Rhizopus niveus by random mutagenesis and its structural interpretation.

Random mutagenesis was used to improve the optimum temperature for Rhizopus niveus lipase (RNL) activity. The lipase gene was mutated using the error-prone PCR technique. One desirable mutant was isolated, and three amino acids were substituted in this mutant (P18H, A36T and E218V). The wild-type and this randomly mutated lipase were both purified and characterized. The specific activity of the mutant lipase was 80% that of the wild-type. The optimum temperature of the mutant lipase was higher by 15 degrees C than that of the wild-type. To confirm which substitution contributed to enhancing the optimum temperature for enzymic activity, two chimeric lipases from the wild-type and randomly mutated gene were constructed: chimeric lipase 1 (CL-1; P18H and A36T) and chimeric lipase 2 (CL-2; E218V). Each of the chimeric enzymes was purified, and the optimum temperature for lipase activity was measured. CL-1 had a similar optimum temperature to that of the wild-type, and CL-2 had a higher temperature like the randomly mutated lipase. The mutational effect is interpreted in terms of a three-dimensional structure for the wild-type lipase.

The crystal structure of lipase II from Rhizopus niveus at 2.2 A resolution.

The crystal and molecular structure of Lipase II from Rhizopus niveus was analyzed using X-ray single crystal diffraction data at a resolution of 2.2 A. The structure was refined to an R-factor of 0.19 for all available data. This lipase was purified and crystallized as Lipase I, which contains two polypeptide chains combined through non-covalent interaction. However, during crystal growth, Lipase I was converted to Lipase II, which consists of a single polypeptide chain of 269 amino acid residues, by limited proteolysis. The structure of Lipase II shows a typical alpha/beta hydrolase fold containing the so-called nucleophilic elbow. The catalytic center of this enzyme is analogous to those of other neutral lipases and serine proteases. This catalytic center is sheltered by an alpha-helix lid, which appears in neutral lipases, opening the active site at the oil-water interface.

The complete amino acid sequence of yam (Dioscorea japonica) chitinase. A newly identified acidic class I chitinase.

The complete amino acid sequence of acidic chitinase from yam (Dioscorea japonica) aerial tubers was determined. The protein is composed of a single polypeptide chain of 250 amino acid residues and has a calculated molecular mass of 27,890 Da. There is an NH2-terminal domain, a hinge region, and a main structure, typical for class I chitinases (Shinshi, H., Neuhaus, J.-M., Ryals, J., and Meins, F., Jr. (1990) Plant Mol. Biol. 14, 357-368). We have obtained the first evidence for an acidic class I chitinase. Comparison with sequences of other class I chitinases revealed approximately 40% sequence similarity, a value lower than that for other class I chitinases (70-80%). We assume that there is a local conformational change in the molecule; cysteine residues that probably form disulfide bonds are completely conserved, with the exception of Cys-178. The difference in structure between this chitinase and other basic class I chitinases suggests that acidic and basic isoforms should be grouped into subclasses; this protein is an ethylene- or a pathogen-independent chitinase produced by a gene that is inherent in the tuber.

Amino acid sequence of the N-terminal domain of yam (Dioscorea japonica) aerial tuber acidic chitinase. Evidence for the presence of a wheat germ agglutinin domain in matured acidic chitinase from unstressed tuber.

The amino acid sequence of the N-terminal domain of acidic chitinase from unstressed aerial tuber was determined and proved the presence of an N-terminal domain in acidic chitinase. The amino acid sequence was determined on a pyroglutamylaminopeptidase-treated N-terminal fragment of V8 protease and on chymotryptic peptides of this fragment. The sequence determined revealed 8 residues deletion and 2 residues insertion as compared with the N-terminal domain of tobacco basic chitinase. The N-terminal domain determined showed a homology of 40% and 52% with the N-terminal domain of tobacco basic chitinase and wheat germ agglutinin, respectively.