Chitinolytic functions in actinobacteria: ecology, enzymes, and evolution.

Actinobacteria, a large group of Gram-positive bacteria, secrete a wide range of extracellular enzymes involved in the degradation of organic compounds and biopolymers including the ubiquitous aminopolysaccharides chitin and chitosan. While chitinolytic enzymes are distributed in all kingdoms of life, actinobacteria are recognized as particularly good decomposers of chitinous material and several members of this taxon carry impressive sets of genes dedicated to chitin and chitosan degradation. Degradation of these polymers in actinobacteria is dependent on endo- and exo-acting hydrolases as well as lytic polysaccharide monooxygenases. Actinobacterial chitinases and chitosanases belong to nine major families of glycosyl hydrolases that share no sequence similarity. In this paper, the distribution of chitinolytic actinobacteria within different ecosystems is examined and their chitinolytic machinery is described and compared to those of other chitinolytic organisms.

Chitosanases from Family 46 of Glycoside Hydrolases: From Proteins to Phenotypes.

Chitosanases, enzymes that catalyze the endo-hydrolysis of glycolytic links in chitosan, are the subject of numerous studies as biotechnological tools to generate low molecular weight chitosan (LMWC) or chitosan oligosaccharides (CHOS) from native, high molecular weight chitosan. Glycoside hydrolases belonging to family GH46 are among the best-studied chitosanases, with four crystallography-derived structures available and more than forty enzymes studied at the biochemical level. They were also subjected to numerous site-directed mutagenesis studies, unraveling the molecular mechanisms of hydrolysis. This review is focused on the taxonomic distribution of GH46 proteins, their multi-modular character, the structure-function relationships and their biological functions in the host organisms.

A highly conserved arginine residue of the chitosanase from Streptomyces sp. N174 is involved both in catalysis and substrate binding.

BACKGROUND: Streptomyces sp. N174 chitosanase (CsnN174), a member of glycoside hydrolases family 46, is one of the most extensively studied chitosanases. Previous studies allowed identifying several key residues of this inverting enzyme, such as the two catalytic carboxylic amino acids as well as residues that are involved in substrate binding. In spite of the progress in understanding the catalytic mechanism of this chitosanase, the function of some residues highly conserved throughout GH46 family has not been fully elucidated. This study focuses on one of such residues, the arginine 42. RESULTS: Mutation of Arg42 into any other amino acid resulted in a drastic loss of enzyme activity. Detailed investigations of R42E and R42K chitosanases revealed that the mutant enzymes are not only impaired in their catalytic activity but also in their mode of interaction with the substrate. Mutated enzymes were more sensitive to substrate inhibition and were altered in their pattern of activity against chitosans of various degrees of deacetylation. Our data show that Arg42 plays a dual role in CsnN174 activity. CONCLUSIONS: Arginine 42 is essential to maintain the enzymatic function of chitosanase CsnN174. We suggest that this arginine is influencing the catalytic nucleophile residue and also the substrate binding mode of the enzyme by optimizing the electrostatic interaction between the negatively charged carboxylic residues of the substrate binding cleft and the amino groups of GlcN residues in chitosan.

Chitosanase from Streptomyces coelicolor A3(2): biochemical properties and role in protection against antibacterial effect of chitosan.

Chitosan, an N-deacetylated derivative of chitin, has attracted much attention as an antimicrobial agent against fungi, bacteria, and viruses. Chitosanases, the glycoside hydrolases responsible for chitosan depolymerisation, are intensively studied as tools for biotechnological transformation of chitosan. The chitosanase CsnA (SCO0677) from Streptomyces coelicolor A3(2) was purified and characterized. CsnA belongs to the GH46 family of glycoside hydrolases. However, it is secreted efficiently by the Tat translocation pathway despite its similarity to the well-studied chitosanase from Streptomyces sp. N174 (CsnN174), which is preferentially secreted through the Sec pathway. Melting point determination, however, revealed substantial differences between these chitosanases, both in the absence and in the presence of chitosan. We further assessed the role of CsnA as a potential protective enzyme against the antimicrobial effect of chitosan. A Streptomyces lividans TK24 strain in which the csnA gene was inactivated by gene disruption was more sensitive to chitosan than the wild-type strain or a chitosanase-overproducing strain. This is the first genetic evidence for the involvement of chitosanases in the protection of bacteria against the antimicrobial effect of chitosan.

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.

Role of acidic amino acid residues in chitooligosaccharide-binding to Streptomyces sp. N174 chitosanase.

We examined the oligosaccharide binding to Streptomyces sp. N174 chitosanase by fluorescence spectroscopy. By means of the tryptophan fluorescence quenching, the oligosaccharide binding abilities were evaluated using the three mutant enzymes (D57A, E197A, and D201A). The enzymatic activities of the mutant enzymes were 0.5%, 20.0%, and 38.5% of that of the wild type, respectively. Scatchard plot obtained for the wild type enzyme showed a biphasic profile, suggesting that the oligosaccharide binds to the chitosanase with two different binding sites (the high affinity site and the low affinity site). In contrast, Scatchard plot for E197A exhibited a monophasic profile, in which the slope of the line corresponds to that for the low affinity binding of the wild type enzyme. A monophasic profile was also obtained for D201A, but the slope of the line was similar to that of the high affinity binding. Thus, we conclude that Glu197 and Asp201 are responsible for oligosaccharide binding at the high affinity site and the low affinity site, respectively, which correspond to the (-n) subsites and the (+n) subsites (n=1, 2, and 3). The fluorescence quenching was very weak in D57A, suggesting a strong contribution of this residue to the oligosaccharide binding.