Transglycosylation reaction catalyzed by a class V chitinase from cycad, Cycas revoluta: a study involving site-directed mutagenesis, HPLC, and real-time ESI-MS.

Class V chitinase from cycad, Cycas revoluta, (CrChi-A) is the first plant chitinase that has been found to possess transglycosylation activity. To identify the structural determinants that bring about transglycosylation activity, we mutated two aromatic residues, Phe166 and Trp197, which are likely located in the acceptor binding site, and the mutated enzymes (F166A, W197A) were characterized. When the time-courses of the enzymatic reaction toward chitin oligosaccharides were monitored by HPLC, the specific activity was decreased to about 5-10% of that of the wild type and the amounts of transglycosylation products were significantly reduced by the individual mutations. From comparison between the reaction time-courses obtained by HPLC and real-time ESI-MS, we found that the transglycosylation reaction takes place under the conditions used for HPLC but not under the ESI-MS conditions. The higher substrate concentration (5 mM) used for the HPLC determination is likely to bring about chitinase-catalyzed transglycosylation. Kinetic analysis of the time-courses obtained by HPLC indicated that the sugar residue affinity of +1 subsite was strongly reduced in both mutated enzymes, as compared with that of the wild type. The IC(50) value for the inhibitor allosamidin determined by real-time ESI-MS was not significantly affected by the individual mutations, indicating that the state of the allosamidin binding site (from -3 to -1 subsites) was not changed in the mutated enzymes. We concluded that the aromatic side chains of Phe166 and Trp197 in CrChi-A participate in the transglycosylation acceptor binding, thus controlling the transglycosylation activity of the enzyme.

26kDa endochitinase from barley seeds: real-time monitoring of the enzymatic reaction and substrate binding experiments using electrospray ionization mass spectrometry.

A 26 kDa endochitinase from barley seeds was enzymatically characterized exclusively by electrospray ionization mass spectrometry (ESI-MS). At first, oligosaccharide hydrolysis catalyzed by the barley chitinase was monitored in real-time by ESI-MS. The reaction time-course obtained by ESI-MS monitoring was found to be consistent with the data obtained earlier by HPLC, and the quantitative profile was successfully simulated by kinetic modeling of the enzymatic hydrolysis. It is obvious that the real-time monitoring method by ESI-MS allows a faster and cheaper determination of the chitinase activity with unlabeled substrate. Further, the enzymatic activity of the E67Q mutant of the barley chitinase was analyzed and the role of Glu67 was discussed comparing the mass spectra of enzyme protein obtained in native and in denatured conditions. Then it was determined that the observed loss of the enzymatic activity in E67Q is definitely caused by a point mutation of Glu67 but not due to partial unfolding of the mutated enzyme. Finally, association constants of enzyme-oligosaccharide complexes were calculated from Scatchard plots obtained by mass spectra. The binding free energy values obtained for E67Q were found to be comparable to those previously obtained in liquid phase, but less dependent upon the chain length of the oligosaccharides. To our knowledge, this study is the first enzymatic characterization of chitinase exclusively by such an innovative ESI-MS system.

Accessory active site residues of Streptomyces sp. N174 chitosanase: variations on a common theme in the lysozyme superfamily.

The chitosanase from Streptomyces sp. N174 (CsnN174) is an inverting glycoside hydrolase belonging to family 46. Previous studies identified Asp40 as the general base residue. Mutation of Asp40 into glycine revealed an unexpectedly high residual activity. D40G mutation did not affect the stereochemical mechanism of catalysis or the mode of interaction with substrate. To explain the D40G residual activity, putative accessory catalytic residues were examined. Mutation of Glu36 was highly deleterious in a D40G background. Possibly, the D40G mutation reconfigured the catalytic center in a way that allowed Glu36 to be positioned favorably to perform catalysis. Thr45 was also found to be essential. Thr45 is thought to orientate the nucleophilic water molecule in a position to attack the glycosidic link. The finding that expression of heterologous CsnN174 in Escherichia coli protects cells against the antimicrobial effect of chitosan, allowed the selection of active chitosanase variants after saturation mutagenesis. Thr45 could be replaced only by serine, indicating the importance of the hydroxyl group. The newly identified accessory catalytic residues, Glu36 and Thr45 are located on a three-strand beta sheet highly conserved in GH19, 22, 23, 24 and 46, all members of the 'lysozyme superfamily'. Structural comparisons reveal that each family has its catalytic residues located among a small number of critical positions in this beta sheet. The position of Glu36 in CsnN174 is equivalent to general base residue in GH19 chitinases, whereas Thr45 is located similarly to the catalytic residue Asp52 of GH22 lysozyme. These examples reinforce the evolutionary link among these five GH families.

Oligosaccharide hydrolysis by chitosanase enzymes monitored by real-time electrospray ionization-mass spectrometry.

The chitosanase-catalyzed hydrolysis of chitosan oligosaccharides was investigated for the first time by real-time electrospray ionization-mass spectrometry (ESI-MS). As chitosan oligosaccharides (GlcNn, n=2-6) were hydrolyzed by exochitosanase (exo-beta-glucosaminidase) from Amycolatopsis orientalis, the reaction time-courses of substrate, intermediate and products could be monitored simultaneously by direct infusion of the reaction solvent into the mass spectrometer. Consequently, the analytical approach of real-time MS is an enormous time-saving method. Furthermore, the high sensitivity of the mass spectrometric detection allows the determination of the reaction time-courses with very low quantities of substrate and therefore also a low amount of applied enzyme. Real-time mass spectrometric detection was also applicable in investigating the reaction behaviour of Streptomyces sp. N174 endochitosanase wild type and of two of its mutants. This technique establishes the fast and efficient determination of in vitro enzymatic activities of various enzyme systems.

Mass spectrometric real-time monitoring of enzymatic glycosidic hydrolysis, enzymatic inhibition and enzyme complexes.

The mass spectrometric development of an enzymatic assay resulting in enzymatic activity, its reaction pathway and its dissociation constant are described for the first time within a single experiment. The method combines the performance of a mass spectrometry-compatible enzyme assay with the direct detection of specific enzyme complexes using hen egg white lysozyme as a model. The continuous liquid-flow technique applied, when hyphenated with electrospray ionization (ESI)-time-of-flight (ToF)-mass spectrometry (MS), permitted the simultaneous detection of several substances involved in product screening as well as the direct observation of dissociation constants. Dissociation constants for the product inhibitor N, N', N''-triacetylchitotriose were calculated using a Scatchard plot (12 x 10(-6) M) and the law of mass action (18-24 x 10(-6) M), and these are in good agreement with constants obtained in earlier mass spectrometric (6-18 x 10(-6) M) or spectroscopic (6-8 x 10(-6) M) studies. Finally, the enzymatic hydrolysis of glycosidic substrate was monitored by ESI-ToF-MS in the presence of various inhibitors, thus leading to decreased activities in terms of their enzyme affinities. The associated inhibitor-enzyme complexes could be detected for up to lower micromolar K( d ) values.