Identification and characterization of a chitinase antigen from Pseudomonas aeruginosa strain 385

A chitinase antigen has been identified in Pseudomonas aeruginosa strain 385 using sera from animals immunized with a whole-cell vaccine. The majority of the activity was shown to be in the cytoplasm, with some activity in the membrane fraction. The chitinase was not secreted into the culture medium. Purification of the enzyme was achieved by exploiting its binding to crab shell chitin. The purified enzyme had a molecular mass of 58 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and a pI of 5.2. NH2-terminal amino acid sequencing revealed two sequences of M(I/L)RID and (Q/M/V)AREDAAAAM that gave an exact match to sequences in a translated putative open reading frame from the P. aeruginosa genome. The chitinase was active against chitin azure, ethylene glycol chitin, and colloidal chitin. It did not display any lysozyme activity. Using synthetic 4-methylumbelliferyl chitin substrates, it was shown to be an endochitinase. The Km and kcat for 4-nitrophenyl-beta-D-N,N'-diacetylchitobiose were 4.28 mM and 1.7 s(-1) respectively, and for 4-nitrophenyl-beta-D-N,N',N"-triacetylchitotriose, they were 0.48 mM and 0.16 s(-1) respectively. The pH optimum was determined to be pH 6.75, and 90% activity was maintained over the pH range 6.5 to 7.1. The enzyme was stable over the pH range 5 to 10 for 3 h and to temperatures up to 50 degrees C for 30 min. The chitinase bound strongly to chitin, chitin azure, colloidal chitin, lichenan, and cellulose but poorly to chitosan, xylan, and heparin. It is suggested that the chitinase functions primarily as a chitobiosidase, removing chitobiose from the nonreducing ends of chitin and chitin oligosaccharides.     

Purification, characterization and molecular cloning of the major chitinase from Tenebrio molitor larval midgut

Insect chitinases are involved in degradation of chitin from the exoskeleton cuticle or from midgut peritrophic membrane during molts. cDNAs coding for insect cuticular and gut chitinases were cloned, but only chitinases from moulting fluid were purified and characterized. In this study the major digestive chitinase from T. molitor midgut (TmChi) was purified to homogeneity, characterized and sequenced after cDNA cloning. TmChi is secreted by midgut epithelial cells, has a molecular weight of 44 kDa and is unstable in the presence of midgut proteinases. TmChi shows strong substrate inhibition when acting on umbelliferyl-derivatives of chitobio- and chitotriosaccharides, but has normal Michaelis kinetics with the N-acetylglucosamine derivative as substrate. TmChi has very low activity against colloidal chitin, but effectively converts oligosaccharides to shorter fragments. The best substrate for TmChi is chitopentaose, with highest k(cat)/K(M) value. Sequence analysis and chemical modification experiments showed that the TmChi active site contains carboxylic groups and a tryptophane, which are known to be important for catalysis in family 18 chitinases. Modification with p-hidroximercuribenzoate of a cysteine residue, which is exposed after substrate binding, leads to complete inactivation of the enzyme. TmChi mRNA encodes a signal peptide plus a protein with 37 kDa and high similarity with other insect chitinases from family 18. Surprisingly, this gene does not encode the C-terminal Ser-Thr-rich connector and chitin-binding domain normally present in chitinases. The special features of TmChi probably result from its adaptation to digest chitin-rich food without damaging the peritrophic membrane.     

Characterization of chitinase from Shewanella inventionis HE3 with bio-insecticidal effect against granary weevil,Sitophilus granarius Linnaeus (Coleoptera: Curculionidae)

A 40 kDa chitinase from Shewanella inventionis HE3 was purified (ChiA-Si40) and characterized. Using fermentor with an optimized medium for 48 h at 37 °C, enzyme activity was enhanced by 10-times compared to those using shaking-flask-culture. Purified chitinase is a homogenous monomer with molecular mass of 40 kDa. Its N-terminal residues revealed significant identity with glycoside hydrolase family 18 (GH18) chitinases from Gammaproteobacteria. Using colloidal chitin as a substrate, its finest activity was accomplished at pH 4 and a temperature of 70 °C. Its catalytic efficiency (k_cat/K_m) was superior to that of some bacterial GH18 chitinases and commercial enzyme, Chitodextrinase®. For scale-up and with regards to the improvement of ChiA-Si40 with PEG 6000 storage stability (6 months), the atomizing process was more pronounced than that of lyophilizing. Bio-assay of ChiA-Si40 against grain weevil Sitophilus granarius, indicates that it had an efficient insecticidal effect. About 10–100 % mortality rates were obtained 1-h after insect came in contact with ChiA-Si40. Histological study clearly demonstrated that luxury larval mid-gut, peritrophic-membrane, and epithelial-cells have been affected considerably after ChiA-Si40 treatment. These properties make ChiA-Si40 a potential bio-insecticidal agent for the biological control of S. granarius that is popular among insect pests of stored grains in Algeria.     

Properties of Manduca sexta chitinase and its C-terminal deletions

Manduca sexta (tobacco hornworm) chitinase is a molting enzyme that contains several domains including a catalytic domain, a serine/threonine-rich region, and a C-terminal cysteine-rich domain. Previously we showed that this chitinase acts as a biopesticide in transgenic plants where it disrupts gut physiology. To delineate the role of these domains further and to identify and characterize some of the multiple forms produced in molting fluid and in transgenic plants, three different forms with variable lengths of C-terminal deletions were generated. Appropriately truncated forms of the M. sexta chitinase cDNA were generated, introduced into a baculovirus vector, and expressed in insect cells. Two of the truncated chitinases (Chi 1-407 and Chi 1-477) were secreted into the medium, whereas the one with the longest deletion (Chi 1-376) was retained inside the insect cells. The two larger truncated chitinases and the full-length enzyme (Chi 1-535) were purified and their properties were compared. Differences in carbohydrate compositions, pH–activity profiles, and kinetic constants were observed among the different forms of chitinases. All three of these chitinases had some affinity for chitin, and they also exhibited differences in their ability to hydrolyze colloidal chitin. The results support the hypothesis that multiple forms of this enzyme occur in vivo due to proteolytic processing at the C-terminal end and differential glycosylation.     

Effect of the C-terminal domain of Vibrio proteolyticus chitinase A on the chitinolytic activity in association with pH changes

Aims: To reveal the cause of the difference in activity of chitinase A from Vibrio proteolyticus and chitinase A from a strain of Vibrio carchariae (a junior synonym of Vibrio harveyi), we investigated the pH‐dependent activity of full‐length V. proteolyticus chitinase A and a truncated recombinant corresponding to the V. harveyi form of chitinase A. Methods and Results: After overexpression in Escherichia coli strain DH5α, the full‐length and truncated recombinant chitinases were purified by ammonium sulphate precipitation and anion exchange column chromatography. Chitinase activity was measured at various pH values using α‐crystal and colloidal chitins as the substrate. The pH‐dependent patterns of the relative specific activities for α‐crystal chitin differed between the full‐length and truncated recombinant chitinases, whereas those for colloidal chitin were similar to each other. Conclusion: The difference in the activity of V. proteolyticus chitinase A and V. harveyi chitinase A might be partly due to a change in the pH dependence of the chitinase activities against α‐crystal chitin, resulting from C‐terminal processing. Significance and Impact of Study: The present results are important findings for not only ecological studies on the genus Vibrio in association with survival strategies, but also phylogenetic studies.     

Properties of Manduca sexta chitinase and its C-terminal deletions

Manduca sexta (tobacco hornworm) chitinase is a molting enzyme that contains several domains including a catalytic domain, a serine/threonine-rich region, and a C-terminal cysteine-rich domain. Previously we showed that this chitinase acts as a biopesticide in transgenic plants where it disrupts gut physiology. To delineate the role of these domains further and to identify and characterize some of the multiple forms produced in molting fluid and in transgenic plants, three different forms with variable lengths of C-terminal deletions were generated. Appropriately truncated forms of the M. sexta chitinase cDNA were generated, introduced into a baculovirus vector, and expressed in insect cells. Two of the truncated chitinases (Chi 1-407 and Chi 1-477) were secreted into the medium, whereas the one with the longest deletion (Chi 1-376) was retained inside the insect cells. The two larger truncated chitinases and the full-length enzyme (Chi 1-535) were purified and their properties were compared. Differences in carbohydrate compositions, pH–activity profiles, and kinetic constants were observed among the different forms of chitinases. All three of these chitinases had some affinity for chitin, and they also exhibited differences in their ability to hydrolyze colloidal chitin. The results support the hypothesis that multiple forms of this enzyme occur in vivo due to proteolytic processing at the C-terminal end and differential glycosylation.     

Characterization of chitinases excreted by Bacillus cereus CH

Bacillus cereus CH was shown to excrete chitinases into the culture supernatant when cultivated in a medium containing 0.2% colloidal chitin, whereas the removal of colloidal chitin resulted in a low activity. After concentration of the culture supernatant by precipitation with ammonium sulfate, the induced chitinases were purified by sequential chromatography. Four different chitinases, A, B1, B2, and B3 with molecular masses of 35, 47, 58, and 64 kDa, respectively, were separated. All chitinases showed similarities in their kinetic parameters when observed with colloidal chitin, including an optimal pH of 5.0-7.5, and an optimal temperature between 50-60 degrees C. Chitinase A hydrolyzed glycol chitin and p-nitrophenyl-di-N-acetyl-beta-chitobioside at similar rates to that of colloidal chitin, whereas group B chitinases hydrolyzed both substrates in much lower rates. From analyses of the reaction products, it is most likely that chitinase A and all group B chitinases hydrolyze the substrates tested in an endo-fashion. However, group B chitinases were distinct from chitinase A in possessing high transglycosylation activity. From amino terminal sequencing, chitinases B1, B2, and B3 were shown to have almost identical sequences, which differed from that of chitinase A. The similarities in the reaction modes and amino terminal sequences among chitinases B1, B2, and B3 suggest that these chitinases may be derived from a presumptive precursor protein through C-terminal processing.     

Potentiation of the synergistic activities of chitinases ChiA, ChiB and ChiC from Serratia marcescens CFFSUR-B2 by chitobiase (Chb) and chitin binding protein (CBP)

With the goal of understanding the chitinolytic mechanism of the potential biological control strain Serratia marcescens CFFSUR-B2, genes encoding chitinases ChiA, ChiB and ChiC, chitobiase (Chb) and chitin binding protein (CBP) were cloned, the protein products overexpressed in Escherichia coli as 6His-Sumo fusion proteins and purified by affinity chromatography. Following affinity tag removal, the chitinolytic activity of the recombinant proteins was evaluated individually and in combination using colloidal chitin as substrate. ChiB and ChiC were highly active while ChiA was inactive. Reactions containing both ChiB and ChiC showed significantly increased N-acetylglucosamine trimer and dimer formation, but decreased monomer formation, compared to reactions with either enzyme alone. This suggests that while both ChiB and ChiC have a general affinity for the same substrate, they attack different sites and together degrade chitin more efficiently than either enzyme separately. Chb and CBP in combination with ChiB and ChiC (individually or together) increased their chitinase activity. We report for the first time the potentiating effect of Chb on the activity of the chitinases and the synergistic activity of a mixture of all five proteins (the three chitinases, Chb and CBP). These results contribute to our understanding of the mechanism of action of the chitinases produced by strain CFFSUR-B2 and provide a molecular basis for its high potential as a biocontrol agent against fungal pathogens.     

Isolation and characterization of three chitinases from Trichoderma harzianum.

Three proteins which display chitinase activity were purified from the supernatants of Trichoderma harzianum CECT 2413 grown in minimal medium supplemented with chitin as the sole carbon source. Purification was carried out after protein precipitation with ammonium sulphate, adsorption to colloidal chitin and digestion, and, finally, chromatofocusing. By this procedure, two chitinases of 42 kDa (CHIT42) and 37 kDa (CHIT37) were purified to homogeneity, as judged by SDS/PAGE and gel filtration, whereas a third, of 33 kDa (CHIT33), was highly purified. The isoelectric points for CHIT42, CHIT37 and CHIT33 were 6.2, 4.6 and 7.8, respectively. The three enzymes displayed endochitinase activities and showed different kinetic properties. CHIT33 was able to hydrolyze chitin oligomers of a polymerization degree higher than n = 4, its Km for colloidal chitin being 0.3 mg/ml. CHIT42 and CHIT37 were able to hydrolyze chitin oligomers with a minimal polymerization degree of n = 3, their Km values for colloidal chitin being 1.0 mg/ml and 0.5 mg/ml respectively. With regard to their lytic activity with purified cell walls of the phytopathogenic fungus Botrytis cinerea, a hydrolytic action was observed only when CHIT42 was present. Antibodies against CHIT42 and CHIT37 specifically recognized the proteins and did not display cross-reaction, suggesting that each protein is encoded by a different gene.     

Chitinase system of Bacillus circulans WL-12 and importance of chitinase A1 in chitin degradation.

Bacillus circulans WL-12, isolated as a yeast cell wall-lytic bacterium, secretes a variety of polysaccharide-degrading enzymes into culture medium. When chitinases of the bacterium were induced with chitin, six distinct chitinase molecules were detected in the culture supernatant. These chitinases (A1, A2, B1, B2, C, and D) showed the following distinct sizes and isoelectric points: Mr 74,000, pI 4.7 (A1); Mr 69,000, pI 4.5 (A2); Mr 38,000, pI 6.6 (B1); Mr 38,000, pI 5.9 (B2); Mr 39,000, pI 8.5 (C); and Mr 52,000, pI 5.2 (D). Among these chitinases, A1 and A2 had the highest colloidal-chitin-hydrolyzing activities. Chitinase A1 showed a strong affinity to insoluble substrate chitin. Purified chitinase A1 released predominantly chitobiose [(GlcNAc)2] and a trace amount of N-acetylglucosamine (GlcNAc) from colloidal chitin. N-terminal amino acid sequence analysis of chitinases A1 and A2 indicated that chitinase A2 was generated from chitinase A1, presumably by proteolytic removal of a C-terminal portion of chitinase A1. Since chitinase A2 did not have the ability to bind to chitin, the importance of the C-terminal region of chitinase A1 to the strong affinity of chitinase A1 to substrate chitin was suggested. Strong affinity of the chitinase seemed to be required for complete degradation of insoluble substrate chitin. From these results, it was concluded that chitinase A1 is the key enzyme in the chitinase system of this bacterium.     

Purification and characterization of Streptomyces albidoflavus antifungal components

Chitinolytic strain Streptomyces albidoflavus was isolated from soil of the central region of Poland. Its identification was based on analysis of 16S rRNA gene sequence. The colloidal chitin was revealed as the finest substrate for the production of chitinases by S. albidoflavus. The enzyme catalyzed the hydrolysis of the disaccharide 4-methylumbelliferyl-β-D-N,N′,N″-triacetylchitotriose most efficiently and was, therefore, classified as an endochitinase. The chitinase of S. albidoflavus was purified by applying the two-step procedure: fractionation with ammonium sulphate and chitin affinity chromatography. The molecular weight of the purified enzyme determined by SDS-PAGE was approximately 50 kDa. The enzyme was characterised as thermostable during 180 min of preincubation at the temperature of 35°C and 40°C. The activity of the enzyme was strongly inhibited in the presence of Hg²⁺ and Mn²⁺ ions, SDS but stabilized by Ca²⁺ and Mg²⁺ ions. Both purified and crude chitinases from S. albidoflavus inhibited the development of fungal phytopathogens. Purified chitinase inhibited the growth of Alternaria alternata, Fusarium culmorum, Fusarium oxysporum and Botrytis cinerea. Additionally, the crude chitinase inhibited the growth of Fusarium solani.     

A chitinase indispensable for formation of protoplast of Schizophyllum commune in basidiomycete-lytic enzyme preparation produced by Bacillus circulans KA-304

KA-prep, a culture filtrate of Bacillus circulans KA-304 grown on a cell-wall preparation of Schizophyllum commune, has an activity to form protoplasts from S. commune mycelia. alpha-1,3-Glucanase, which was isolated from an ammonium sulfate fraction of 0-30% saturation of KA-prep, gave the protoplast-forming activity to an ammonium sulfate fraction of 30-50% saturation of KA-prep, which contained chitinase(s) and beta-glucanase(s) but was inactive in the protoplast formation. Chitinase(s) and beta-glucanase(s) in the ammonium sulfate fraction of 30-50% saturation were separated by DEAE-cellulofine A-500 column chromatography, and the protoplast-forming activity appeared when the chitinase preparation was mixed with the alpha-1,3-glucanase. The beta-glucanase preparation was not effective for the protoplast formation whereas its addition enhanced the protoplast-forming activity of the mixture of alpha-1,3-glucanase and the chitinase preparation. The chitinase preparation contained two chitinases (chitinase I and II). Chitinase I showed the protoplast-forming activity with alpha-1,3-glucanase, but chitinase II did not. Chitinase I, a monomeric protein with a molecular weight of 41,000, was active toward colloidal chitin and ethylene glycol chitin. Chitinase I produced predominantly N,N'-diacetylchitobiose and N,N',N"-triacetylchitotriose from colloidal chitin, and the enzyme was inactive to p-NP-beta-D-N-acetylglucosaminide, suggesting that it was an endo-type enzyme. The N-terminal amino acid sequence of chitinase I (A L A T P T L N V S A S S G M) had no sequential identity to those of known chitinases.     

Chitinolytic properties of Bacillus pabuli K1

The chitinolytic properties of Bacillus pabuli K1 isolated from mouldy grain was studied. Chitinase activity was measured as the release of p -nitrophenol from p -nitrophenyl-N, N'-diacetylchitobiose. Influences of substrate concentration and different environmental variables on growth and chitinase activity were determined. The optimum environmental conditions for chitinase production were: 30°C, initial pH 8, initial oxygen 10% and a_w > 0.99. Chitinase production was induced when B. pabuli K1 was grown on colloidal chitin. The smallest chito-oligosaccharide able to induce chitinase production was N, N'-diacetylchitobiose, (GlcNAc)₂. Production was also induced by (GlcNAc)₃ and (GlcNAc)₄. When the bacterium was grown on glucose or N -acetylglucosamine, no chitinases were formed. The highest chitinase production observed was obtained with colloidal chitin as substrate. The production of chitinases by B. pabuli K1 growing on chitin was repressed by high levels (0.6%) of glucose. The production was also repressed by 0.6% starch, laminarin and β-glucan from barley and by glycerol. The addition of pectin and carboxymethyl cellulose increased chitinase production.     

Identification, characterization and functional analysis of a GH-18 chitinase from Streptomyces roseolus

A 40 kDa chitinase from Streptomyces roseolus DH was purified to homogeneity from culture medium. The N-terminal sequence was TPPPAKAVKLGYFTNWGVYG, which was highly homologous to the glycoside hydrolase (GH) 18 conserved domain of Streptomyces chitinases and included the two crucial Trp and Tyr sites. The purified enzyme showed maximal activity at 60 °C, pH 6.0 and exhibited good thermal and pH stabilities. The enzyme displayed strict substrate specificity on colloidal or glycol chitin, but not on chitosan derivatives. It was activated by Mg²⁺, Ba²⁺ and Ca²⁺, and inhibited by Cu²⁺, Co²⁺, Mn²⁺, whereas Zn²⁺ and ethylenediamine tetraacetic acid showed little inhibitory effects. Morphological changes observed by scanning electron microscopy revealed the occurrence of regular pores on the surface with the progress of enzymatic chitinolysis. Additionally, this GH-18 chitinase had a marked inhibitory effect on fungal hyphal extensions. In conclusion, this chitinase may have great potential for the enzymatic degradation of chitin.     

低温几丁质酶基因在乳酸克鲁维酵母中的重组表达及酶学性质表征

【目的】通过构建假交替单胞菌(Pseudoalteromonassp.DL-6)低温几丁质酶(chitinaseA,chi A;chitinase C,chi C)的重组乳酸克鲁维酵母菌株、纯化重组蛋白并对其进行酶学性质表征,为低温几丁质酶潜在工业化生产几丁寡糖奠定理论基础。【方法】人工合成密码子优化的几丁质酶基因,构建重组乳酸克鲁维酵母表达质粒(p KLAC1-chi A、p KLAC1-chi C)并用电脉冲法转化到乳酸克鲁维酵母中,实现低温几丁质酶的可溶表达。利用镍柱亲和层析纯化得到高纯度的重组几丁质酶。【结果】成功构建产低温几丁质酶的重组乳酸克鲁维酵母并纯化获得高纯度的重组几丁质酶。经SDS-PAGE分析在110 k Da与90 k Da附近出现符合预期大小的蛋白条带。铁氰化钾法测得Chi A和Chi C的酶活分别为51.45 U/mg与108.56 U/mg。最适反应温度分别为20°C和30°C,最适p H分别为8.0和9.0。在低于40°C,p H 8.0–12.0时,Chi A和Chi C重组酶较稳定。Chi A和Chi C对胶体几丁质以及粉状底物α-几丁质与β-几丁质具有明显的降解活性,且具有一定协同降解能力。【结论】首次实现假交替单胞菌来源的低温几丁质酶在乳酸克鲁维酵母中的重组表达、纯化、酶学性质及其降解产物分析,为其他低温几丁质酶的研究提供借鉴意义。     

Cloning, purification, and characterization of chitinase from Bacillus sp. DAU101

A chitinase encoding gene from Bacillus sp. DAU101 was cloned in Escherichia coli. The nucleotide sequencing revealed a single open reading frame containing 1781 bp and encoding 597 amino acids with 66 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and zymogram. The chitinase was composed of three domains: a catalytic domain, a fibronectin III domain, and a chitin binding domain. The chitinase was purified by GST-fusion purification system. The pH and temperature optima of the enzyme were 7.5 and 60 degrees C, respectively. The metal ions, Zn(2+), Cu(2+), and Hg(2+), were strongly inhibited chitinase activity. However, chitinase activity was increased 1.4-fold by Co(2+). Chisb could hydrolyze GlcNAc(2) to N-acetylglucosamine and was produced GlcNAc(2), when chitin derivatives were used as the substrate. This indicated that Chisb was a bifunctional enzyme, N-acetylglucosaminase and chitobiosidase. The enzyme could not hydrolyze glycol chitin, glycol chitosan, or CMC, but hydrolyzed colloidal chitin and soluble chitosan.     

Production and purification of extracellular chitinases from Penicillium aculeatum NRRL 2129 under solid-state fermentation

Fourteen Penicillium strains have been screened on wheat bran–crude chitin mixture medium for extracellular chitinase production in solid-state fermentation. Under the experimental conditions tested, Penicillium aculeatum NRRL 2129 (=ATCC 10409) was selected as the best enzyme producer. The optimum incubation period for chitinase production by the potent organism was found to be 72 h. Chromatofocusing was performed as the first step in the purification scheme, but high amount of contaminating proteins interfered with the method. Hence, ion-exchange chromatography experiments were carried out followed by gel filtration to separate and isolate chitinase isoenzymes. Four major chitinase peaks of molecular weight 82.7, 44.6, 28.2 and 26.9 kDa were observed after gel filtration chromatography while, on SDS-PAGE, three protein bands of molecular weights 82.6, 33.9 and 29.1 kDa were identified. The purified enzyme showed optimal temperature and pH at 50 and 5.5 °C, respectively.     

Cytosolic and membrane-bound chitinases of two mucoraceous fungi: a comparative study.

Chitinases isolated from membrane and cytosolic fractions of two mucoraceous fungi, Choanephora cucurbitarum and Phascolomyces articulosus, were investigated. The membrane-bound chitinase was isolated by Bio-Gel P-100 and DEAE Bio-Gel A chromatographic techniques. On SDS-PAGE the chitinase from both fungi migrated as a single band of M(r) 66 kDa. The cytosolic chitinase from the mycelial extracts of these fungi was separated by heat treatment, ammonium sulphate precipitation, and by affinity chromatography with regenerated chitin. SDS-PAGE showed two bands for each fungus with M(r) of 69.5 and 55 kDa in C. cucurbitarum and M(r) 69.5 and 53 kDa in Ph. articulosus. Chitinases, membrane bound or cytosolic, hydrolyzed regenerated chitin, colloidal chitin, glycol chitin, N,N'-diacetylchitobiose, and N,N',N"-triacetylchitotriose. Heavy metals, inhibitors, and N-acetylglucosamine inhibited chitinase activity, whereas trypsin and an acid protease enhanced its activity. Chitinase preparations showed lysozyme activity that was inhibited by histamine but not by N-acetylglucosamine. There was no N-acetylglucosamanidase activity, but beta-1,3 glucanase activity was found in cytosolic preparations only. Despite slight differences in their molecular mass, both the membrane-bound and cytosolic chitinases showed similarities in substrate utilization, response to inhibitors, and activation by trypsin and acid protease; pH and temperature optima also were similar.     

Chitinolytic activities in the gut of Aedes aegypti (Diptera:Culicidae) larvae and their role in digestion of chitin-rich structures

Mosquito larvae are believed to be capable of digesting chitin, an insoluble polysaccharide of N-acetylglucosamine, for their nutritional benefit. Studies based on physiological and biochemical assays were conducted in order to detect the presence of chitinase activities in the gut of the detritus-feeding Aedes aegypti larvae. Larvae placed for 24 h in suspensions of chitin azure were able to digest the ingested chitin. Semi-denaturing PAGE using glycol chitin and two fluorogenic substrate analogues showed the presence of two distinct chitinase activities: an endochitinase that catalyzed the hydrolysis of chitin and an endochitinase that cleaved the short substrates [4MU(GlcNAc)(3)] and [4MU(GlcNAc)(2)] that hydrolyzed the chitobioside [4MU(GlcNAc)(2)]. The endochitinase had an extremely broad pH-activity against glycol chitin and chitin azure, pH ranging from 4.0 to 10.0. When the substrate [4MU(GlcNAc)(3)] was used, two activities were observed at pH ranges 4.0-6.0 and 8.0-10.0. Chitinase activity against [4MU(GlcNAc)(3)] was detected throughout the gut with the highest specific activity in the hindgut. The pH of the gut contents was determined by observing color changes in gut after feeding the larvae with color indicator dyes. It was observed a correlation between the pH observed in the gut of feeding larvae (pH 10-6.0) and the optimum pH for gut chitinase activities. In this work, we report that gut chitinases may be involved in the digestion of chitin-containing structures and also in the partial degradation of the chitinous peritrophic matrix in the hindgut.     

Three Extracellular Chitinases in Suspension-cultured Rice Cells Elicited by N-Acetylchitooligosaccharides

In rice suspension culture, a large part (about 90% of total activity in the culture) of the chitinase activity was found in the medium. Two extracellular chitinases (which we named RCH-A and -B) were separated from the cell suspension by DEAE-cellulofìne column chromatography. When cells were treated with N-acetylchitooligosaccharides (chitin oligosaccharides) for 3 days, extracellular chitinase activity increased about 3-fold over the control culture. After the treatment, another extracellular chitinase (named RCH-C) appeared in addition to increases in the levels of RCH-A and -B. Partial amino acid sequences of these enzymes indicated that RCH-A (33.5 kDa) and -B (34kDa) were class Ib chitinases but RCH-C (27kDa) was a class III chitinase. RCH-A and -B were capable of actively degrading water-insoluble chitin with high affinities, while RCH-C had less affinity for the substrate. However, when a water-soluble chitin derivative, 6–O-hydroxyethylchitin (glycolchitin) was used, RCH-C as well as RCH-A and -B degraded actively with a high affinity. A synergistic effect was observed when these three chitinases acted simultaneously in the hydrolysis of chitin.