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.     

Molecular characterization of an intracellular beta-N-acetylglucosaminidase involved in the chitin degradation system of Streptomyces thermoviolaceus OPC-520

We purified and characterized an intracellular beta-N-acetylglucosaminidase (NagC) from a cytoplasmic fraction of Streptomyces thermoviolaceus OPC-520. The molecular mass of NagC was estimated to be 60 kDa by SDS-polyacrylamide gel electrophoresis (SDS-PAGE). The optimum pH and temperature of the enzyme were 6.0 and 50 degrees C respectively. Purified NagC hydrolyzed chitin oligosaccharides from N,N'-diacetylchitobiose (GlcNAc)(2) to chitopentaose (GlcNAc)(5), hydrolyzed N,N'-diacetylchitobiose especially rapidly, and showed a tendency to decrease with increases in the degree of polymerization. But, NagC didn't hydrolyze chitohexaose (GlcNAc)(6). The gene encoding NagC was cloned and sequenced. The open reading frame of nagC encoded a protein of 564 amino acids with a calculated molecular mass of 62,076 Da. The deduced amino acid sequence of NagC showed homology with several beta-N-acetylglucosaminidases belonging to glycosyl hydrolase family 20. The expression plasmid coding for NagC was constructed in Escherichia coli. The recombinant enzyme showed pH and temperature optima and substrate specificity similar to those of the native enzyme. The gene arrangement near the nagC gene of S. thermoviolaceus OPC-520 was compared with that of S. coelicolor A3(2). Three genes, which appear to constitute an ABC transport system for sugar, were missing in the vicinity of the nagC gene.     

Kinetic analysis of the reaction catalyzed by chitinase A1 from Bacillus circulans WL-12 toward the novel substrates, partially N-deacetylated 4-methylumbelliferyl chitobiosides

The kinetic behavior of chitinase A1 from Bacillus circulans WL-12 was investigated using the novel fluorogenic substrates, N-deacetylated 4-methylumbelliferyl chitobiosides [GlcN-GlcNAc-UMB (2), GlcNAc-GlcN-UMB (3), and (GlcN)(2)-UMB (4)], and the results were compared with those obtained using 4-methylumbelliferyl N, N'-diacetylchitobiose [(GlcNAc)(2)-UMB (1)] as the substrate. The chitinase did not release the UMB moiety from compound 4, but successfully released UMB from the other substrates. k(cat)/K(m) values determined from the releasing rate of the UMB moiety were: 145.3 for 1, 8.3 for 2, and 0.1 s(-1) M(-1) for 3. The lack of an N-acetyl group at subsite (-1) reduced the activity to a level 0.1% of that obtained with compound 1, while the absence of the N-acetyl group at subsite (-2) reduced the relative activity to 5.7%. These observations strongly support the theory that chitinase A1 catalysis occurs via a 'substrate-assisted' mechanism. Using these novel fluorogenic substrates, we were able to quantitatively evaluate the recognition specificity of subsite (-2) toward the N-acetyl group of the substrate sugar residue. The (-2) subsite of chitinase A1 was found to specifically recognize an N-acetylated sugar residue, but this specificity was not as strict as that found in subsite (-1).     

Molecular analysis of the gene encoding a novel transglycosylative enzyme from Alteromonas sp. strain O-7 and its physiological role in the chitinolytic system.

We purified from the culture supernatant of Alteromonas sp. strain O-7 and characterized a transglycosylating enzyme which synthesized beta-(1-->6)-(GlcNAc)2, 2-acetamido-6-O-(2-acetamido-2-deoxy-beta-D-glucopyranosyl)-2- deoxyglucopyranose from beta-(1-->4)-(GlcNAc)2. The gene encoding a novel transglycosylating enzyme was cloned into Escherichia coli, and its nucleotide sequence was determined. The molecular mass of the deduced amino acid sequence of the mature protein was determined to be 99,560 Da which corresponds very closely with the molecular mass of the cloned enzyme determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The molecular mass of the cloned enzyme was much larger than that of enzyme (70 kDa) purified from the supernatant of this strain. These results suggest that the native enzyme was the result of partial proteolysis occurring in the N-terminal region. The enzyme showed significant sequence homology with several bacterial beta-N-acetylhexosaminidases which belong to family 20 glycosyl hydrolases. However, this novel enzyme differs from all reported beta-N-acetylhexosaminidases in its substrate specificity. To clarify the role of the enzyme in the chitinolytic system of the strain, the effect of beta-(1-->6)-(GlcNAc)2 on the induction of chitinase was investigated. beta-(1-->6)-(GlcNAc)2 induced a level of production of chitinase similar to that induced by the medium containing chitin. On the other hand, GlcNAc, (GlcNAc)2, and (GlcNAc)3 conversely repressed the production of chitinase to below the basal level of chitinase activity produced constitutively in medium without a carbon source.     

Purification and characterization of a new hyperthermostable,allosamidin-insensitive and denaturation-resistant chitinase from the hyperthermophilic archaeon Thermococcus chitonophagus

A new chitinase (1,4-beta-D-N-acetyl-glucosaminidase, EC 3.2.1.14) was detected and purified to homogeneity in its native form from the chitinolytic enzyme system of the extremely thermophilic archaeon Thermococcus chitonophagus. This is the first nonrecombinant chitinase purified and characterized from archaea and also constitutes the first case of a membrane-associated chitinase isolated from archaea. The enzyme is a monomer with an apparent molecular weight of 70 kDa [therefore named chitinase 70 (Chi70)] and pI of 5.9; it is hydrophobic and appears to be associated with the outer side of the cell membrane. Chi70 is optimally active at 70 degrees C and pH 7.0 and exhibits remarkable thermostability, maintaining 50% activity even after 1 h at 120 degrees C, and therefore the enzyme is the most thermostable chitinase so far isolated. The enzyme was not inhibited by allosamidin, the natural inhibitor of chitinolytic activity, and was also resistant to denaturation by urea and SDS. On the other hand, guanidine hydrochloride significantly reduced enzymatic activity, indicating that, apart from the hydrophobic interactions, ion pairs located on the surface of the protein could be playing an important role in maintaining the protein's fold and enzyme activity. Chi70 showed broad substrate specificity for several chitinous substrates and derivatives. The lowest K(m) and highest K(cat) values were found for pNP(NAG)(2) as substrate and were determined to be 0.14 mM and 23 min(-1), respectively. The hydrolysis pattern was similar for oligomers and polymers, with N, N'-diacetylchitobiose [(NAG)(2)] being the final, major hydrolysis product. Chi70 was classified as an endochitinase due to its ability to release chitobiose from colloidal chitin. Additionally, the enzyme presented considerable cellulolytic activity. Analysis of the NH(2)-terminal amino acid sequence showed no detectable homology with other known sequences, suggesting that Chi70 is a new protein.     

Identification of a novel endochitinase from a marine bacterium Vibrio proteolyticus strain No. 442

Chitin binding proteins prepared from Vibrio proteolyticus were purified and the N-terminal amino-acid sequence of a protein from a 110-kDa band on SDS-PAGE was found to be 85-90% identical to the 22nd-41st residues of the N-termini of chitinase A precursor proteins from other vibrios. We cloned the corresponding gene, which encodes a putative protein of 850 amino acids containing a 26-residue signal sequence. The chitinase precursor from V. proteolyticus was 78-80% identical to those from Vibrio parahaemolyticus, Vibrio alginolyticus and Vibrio carchariae. However, the proteolytic cleavage site for C-terminal processing between R597 and K598 in the chitinase precursor of other vibrios was not observed in the amino acid sequence of V. proteolyticus, which instead had the sequence R600 and A601. Subsequently, full-length and truncated chitinases were generated in Escherichia coli. The specific activity of full-length chitinase expressed in E. coli was 17- and 20-folds higher for colloidal and alpha-chitins (insoluble substrate), respectively, than that of the C-terminal truncated enzyme. However, both recombinants showed similar hydrolysis patterns of hexa-N-acetyl-chitohexaose (soluble substrate), producing di-N-acetyl-chitobiose as major product on TLC analysis. We showed that the C-terminus of the V. proteolyticus chitinase A was important for expression of high specific activity against insoluble chitins.     

Production and secretion of a recombinant Vibrio parahaemolyticus chitinase by Escherichia coli and its purification from the culture medium

An open reading frame encoding the chitinase gene and its signal sequence was cloned from the Vibrio parahaemolyticus KN1699 genome. An expression plasmid containing the gene was introduced into Escherichia coli cells, and recombinant chitinase (Pa-rChi) was produced and secreted into the culture medium with the aid of the signal peptide. Pa-rChi was purified and its substrate specificity was determined.     

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.     

两株对虾幼体弧菌病病原的分离和鉴定

从患弧菌病的凡纳滨对虾(Litopenaeus vannamei)幼体中分离到两株病原菌zouA和zouB, 常规形态和生理生化试验表明均为弧菌属菌种, 弧菌编码鉴定系统分别鉴定为溶藻弧菌(Vibrio alginolyticus)和副溶血弧菌(V. parahaemolyticus)。副溶血弧菌R72H序列检测结果进一步证实菌株zouB为副溶血弧菌。对菌株zouA的16S rRNA基因序列分析表明该菌株与溶藻弧菌、副溶血弧菌等弧菌的相似性均高于98%, 相互间不能区分; HSP60基因序列分析表明该菌株与溶藻弧菌相似性达98%以上, 而与所有其它弧菌的相似性不到92%。结合表型和分子特征的鉴定结果, 菌株zouA和zouB分别被鉴定为溶藻弧菌和副溶血弧菌。     

两株对虾幼体弧菌病病原的分离和鉴定

从患弧菌病的凡纳滨对虾（Litopenaeus vannamei）幼体中分离到两株病原菌zouA和zouB,常规形态和生理生化试验表明均为弧菌属菌种,弧菌编码鉴定系统分别鉴定为溶藻弧菌（Vibrioatginolyticus）和副溶血弧菌（V.parahaemolyticus）。副溶血弧菌R72H序列检测结果进一步证实菌株zouB为副溶血弧菌。对菌株zouA的16S rRNA基因序列分析表明该菌株与溶藻弧菌、副溶血弧菌等弧菌的相似性均高于98％,相互间不能区分;HSP60基因序列分析表明该菌株与溶藻弧菌相似性达98％以上,而与所有其它弧菌的相似性不到92％。结合表型和分子特征的鉴定结果,菌株zouA和zouB分别被鉴定为溶藻弧菌和副溶血弧菌。     

Identification of an essential tyrosine residue in the catalytic site of a chitinase isolated from Zea mays that is selectively modified during inactivation with 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide.

Chitinase isolated from Zea mays seeds is inactivated by 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) in the absence of exogenous nucleophiles. Oligomers of N-acetylglucosamine,N,N',N",N"'-tetra-N-acetylchitotetraose (GlcNAc4), and to a lesser extent, N,N',N"-tri-N-acetylchitotriose (GlcNAc3) and N,N'-di-N-acetylchitobiose (GlcNAc2) provide partial protection against inactivation by the reagent. An examination of the concentration dependence of the protection afforded by GlcNAc4 revealed direct competition between the substrate analog and the reagent for the same binding sites on the enzyme. Isolation and Edman degradation of a "new" tryptic fragment, observed after inactivation of chitinase with EDC, revealed the sequence G-P-L-Q-I-S-W-N-*-N-Y-G-P-A-G-R, where the asterisk represents a cycle in which no amino acid was detected, presumably as a consequence of derivatization with EDC. In basic chitinases from dicotyledonous plants such as Arabidopsis thaliana, Phaseolis vulgaris (bean), Nicotiana tabacum (tobacco), and Solanum tuberosum (potato), as well as in the chitinase isolated from the monocotyledonous plant Hordeum vulgare (barley), this position is invariably occupied by a tyrosine. However, in the Oryza sativa (rice) basic chitinase, this position is occupied by a phenylalanine. The following additional evidence supports identification of this residue as tyrosine in Z. mays chitinase. (a) Inactivation of chitinase with EDC is reversible by treatment with hydroxylamine. (b) Liquid secondary ion mass spectrometric analysis of the isolated derivatized peptide revealed the presence of a molecular ion with a mass to charge ratio consistent with the peptide containing a derivatized tyrosine residue. These results provide evidence for an essential tyrosine residue at or near the catalytic site of chitinase that is selectively modified during inactivation with EDC.     

Chitin catabolism in the marine bacterium Vibrio furnissii. Identification, molecular cloning, and characterization of A N, N'-diacetylchitobiose phosphorylase

The major product of bacterial chitinases is N,N'-diacetylchitobiose or (GlcNAc)(2). We have previously demonstrated that (GlcNAc)(2) is taken up unchanged by a specific permease in Vibrio furnissii (unlike Escherichia coli). It is generally held that marine Vibrios further metabolize cytoplasmic (GlcNAc)(2) by hydrolyzing it to two GlcNAcs (i.e. a "chitobiase "). Here we report instead that V. furnissii expresses a novel phosphorylase. The gene, chbP, was cloned into E. coli; the enzyme, ChbP, was purified to apparent homogeneity, and characterized kinetically. The DNA sequence indicates that chbP encodes an 89-kDa protein. The enzymatic reaction was characterized as follows. (GlcNAc)(2)+P(i) GlcNAc-alpha-1-P+GlcNAc K'(cq)=1.0+/-0.2 Reaction 1 The K(m) values for the four substrates were in the range 0.3-1 mm. p-Nitrophenyl-(GlcNAc)(2) was cleaved at 8.5% the rate of (GlcNAc)(2), and p-nitrophenyl (PNP)-GlcNAc was 36% as active as GlcNAc in the reverse direction. All other compounds tested displayed 相似文献   

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.     

Expression and characterization of endochitinase C from Serratia marcescens BJL200 and its purification by a one-step general chitinase purification method

In this study we cloned, expressed, purified, and charaterized chitinase C1 from Serratia marcescens strain BJL200. As expected, the BJL200-ChiC1 amino acid sequence of this strain was highly similar to sequences of ChiC1 identified in two other strains of S. marcescens. BJL200-ChiC1 was overproduced in E. coli by the T7 expression system, and purified by a one-step hydrophobic interaction chromatography (HIC) with phenyl-sepharose. BJL200-ChiA and BJL200-ChiB had an approximately 30-fold higher k(cat) and 15 fold-lower K(m) than BJL200-ChiC1 for the oligomeric substrate 4-methylumbelliferyl-beta-D-N-N'-N'-triacetylchitotrioside, while BJL200-ChiC1 was 10-15 times faster than BJL200-ChiB and BJL200-ChiA in degrading the polymeric substrate CM-chitin-RBV. BJL200-ChiC1 degradation of beta-chitin resulted in a range of different chito-oligosaccharides (GlcNAc)(2) (main product), GlcNAc, (GlcNAc)(3), (GlcNAc)(4), and (GlcNAc)(5), indicating endo activity. The purification method used for BJL200-ChiC1 in this study is generally applicable to family 18 chitinases and their mutants, including inactive mutants, some of which tend to bind almost irreversibly to chitin columns. The high specificity of the interaction with the (non-chitinous) column material is mediated by aromatic residues that occur in the substrate-binding clefts and surfaces of the enzymes.     

Characterization of a novel Salmonella Typhimurium chitinase which hydrolyzes chitin, chitooligosaccharides and an N-acetyllactosamine conjugate

Salmonella contain genes annotated as chitinases; however, their chitinolytic activities have never been verified. We now demonstrate such an activity for a chitinase assigned to glycoside hydrolase family 18 encoded by the SL0018 (chiA) gene in Salmonella enterica Typhimurium SL1344. A C-terminal truncated form of chiA lacking a putative chitin-binding domain was amplified by PCR, cloned and expressed in Escherichia coli BL21 (DE3) with an N-terminal (His)(6) tag. The purified enzyme hydrolyzes 4-nitrophenyl N,N'-diacetyl-β-D-chitobioside, 4-nitrophenyl β-D-N,N',N″-triacetylchitotriose and carboxymethyl chitin Remazol Brilliant Violet but does not act on 4-nitrophenyl N-acetyl-β-D-glucosaminide, peptidoglycan or 4-nitrophenyl β-D-cellobioside. Enzyme activity was also characterized by directly monitoring product formation using (1)H-nuclear magnetic resonance which showed that chitin is a substrate with the release of N,N'-diacetylchitobiose. Hydrolysis occurs with the retention of configuration and the enzyme acts on only the β-anomers of chitooligosaccharide substrates. The enzyme also released N-acetyllactosamine disaccharide from Galβ1 → 4GlcNAcβ-O-(CH(2))(8)CONH(CH(2))(2)NHCO-tetramethylrhodamine, a model substrate for LacNAc terminating glycoproteins and glycolipids.     

Sequence of a cloned pR72H fragment and its use for detection of Vibrio parahaemolyticus in shellfish with the PCR.

The nucleotide sequence of pR72H cloned from Vibrio parahaemolyticus 93 was determined. We examined all V. parahaemolyticus gene sequences published in the GenBank-EMBL databases for homology and found that no other DNA sequence of V. parahaemolyticus was highly homologous to the sequence reported in this study. A pair of primers, VP33-VP32, derived from a pR72H fragment were selected to detect V. parahaemolyticus. The sensitivity of PCR detection for a pure culture of V. parahaemolyticus was 10 cells from crude bacterial lysates. Furthermore, a detection level of 2.6 fg, equivalent to 1 cell, was obtained by using purified chromosomal DNA as the template. The expected PCR products were obtained from all V. parahaemolyticus strains tested (n = 124), while no PCR amplicons were found in other vibrios or related genera (n = 50). High levels (10(6) to 10(10) CFU/ml) of Escherichia coli cells did not affect the PCR assay sensitivity. The presence of 10(8) V. parahaemolyticus cells or 10(9) E. coli cells in the PCR mixtures completely inhibited the PCR. When oyster samples were inoculated with V. parahaemolyticus 93 and cultured in tryptic soy broth containing 3% NaCl for 3 h at 35 degrees C, an initial sample inoculum level of 9.3 CFU/g was detected in a PCR assay with crude bacterial lysates. The PCR assay with enrichment culturing in salt polymyxin broth was compared with the conventional method for naturally contaminated shellfish and fish samples. We conclude that this PCR assay with enrichment culturing is a good alternative method for the detection of V. parahaemolyticus.     

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.     

Characterization of a cold-adapted and salt-tolerant exo-chitinase (ChiC) from <Emphasis Type="Italic">Pseudoalteromonas</Emphasis> sp. DL-6

We have previously reported a non-processive endo-type chitinase, ChiA, from a newly isolated marine psychrophilic bacterium, Pseudoalteromonas sp. DL-6. In this study, a processive exo-type chitinase, ChiC, was cloned from the same bacterium and characterized in detail. ChiC could hydrolyze crystalline chitin into (GlcNAc)₂ as the only observed product. It exhibited high catalytic activity even at low temperatures, e.g. close to 0 °C, or in the presence of 5 M NaCl, suggesting that ChiC was a cold-adapted and highly salt-tolerant chitinase. ChiC could also hydrolyze other substrates, including chitosan and Avicel, indicating its broad substrate specificity. Sequence features indicated that ChiC was a multi-domain protein having a deep substrate-binding groove that was regarded as characteristic of processive exo-chitinases. Enzymatic hydrolysis of chitin by ChiC could be remarkably boosted in the presence of ChiA, suggesting the synergy of ChiC and ChiA. This work provided a new evidence to prove that marine psychrophilic bacteria utilized a synergistic enzyme system to degrade recalcitrant chitin.     

The chitin disaccharide, N,N'-diacetylchitobiose, is catabolized by Escherichia coli and is transported/phosphorylated by the phosphoenolpyruvate:glycose phosphotransferase system

We have previously reported that wild type strains of Escherichia coli grow on the chitin disaccharide N,N'-diacetylchitobiose, (GlcNAc)(2), as the sole source of carbon (Keyhani, N. O., and Roseman, S. (1997) Proc. Natl. Acad. Sci., U. S. A. 94, 14367-14371). A nonhydrolyzable analogue of (GlcNAc)(2,) methyl beta-N, N'-[(3)H]diacetylthiochitobioside ([(3)H]Me-TCB), was used to characterize the disaccharide transport process, which was found to be mediated by the phosphoenolpyruvate:glycose phosphotransferase system (PTS). Here and in the accompanying papers (Keyhani, N. O., Boudker, O., and Roseman, S. (2000) J. Biol. Chem. 275, 33091-33101; Keyhani, N. O., Bacia, K., and Roseman, S. (2000) J. Biol. Chem. 275, 33102-33109; Keyhani, N. O., Rodgers, M., Demeler, B., Hansen, J., and Roseman, S. (2000) J. Biol. Chem. 275, 33110-33115), we report that transport of [(3)H]Me-TCB and (GlcNAc)(2) involves a specific PTS Enzyme II complex, requires Enzyme I and HPr of the PTS, and results in the accumulation of the sugar derivative as a phosphate ester. The phosphoryl group is linked to the C-6 position of the GlcNAc residue at the nonreducing end of the disaccharide. The [(3)H]Me-TCB uptake system was induced only by (GlcNAc)(n), n = 2 or 3. The apparent K(m) of transport was 50-100 micrometer, and effective inhibitors of uptake included (GlcNAc)(n), n = 2 or 3, cellobiose, and other PTS sugars, i.e. glucose and GlcNAc. Presumably the PTS sugars inhibit by competing for PTS components. Kinetic properties of the transport system are described.     

Carbohydrate microheterogeneity of rat serotransferrin. Determination of glycan primary structures and characterization of a new type of trisialylated diantennary glycan

A previously established procedure [Regoeczi, E., Chindemi, P.A., Rudolph, J. R., Spik, G. & Montreuil, J. (1987) Biochem. Cell Biol. 65, 948-954] was used to isolate from three DEAE-cellulose chromatographic fractions of diferric rat serotransferrin (rTf) subpopulations having discernible affinities for concanavalin A (ConA). These entities are designated rTf-1 (not retarded by ConA column), rTf-2 (retarded) and rTf-3 (bound). Each rTf type was found to be endowed with carbohydrate sufficient to account for a single diantennary glycan/protein molecule. Glycan structures were determined on the glycopeptides by employing GLC/MS and 400-MHz 1H-NMR spectroscopy. All glycans possessed a common, trimannosyl-N,N'-diacetylchitobiose core with or without one L-fucose alpha-1,6-linked to the Asn-linked GlcNAc. However, there were differences in the antennae. Thus, in rTf-3, both antennae were of the disialylated diantennary N-acetyllactosamine type which is frequently encountered in other plasma glycoproteins. However, the alpha-1,3-Man-linked antenna in rTf-1 as well as rTf-2 had the sequence: Neu5Ac(alpha 2-3)Gal(beta 1-3)[Neu5Ac(alpha 2-6)]GlcNAc(beta 1-2)Man. In addition, the alpha-1,6-Man-linked antenna deviated in rTf-2 from the standard structure by having the sequence: Neu5Ac(alpha 2-3)Gal(beta 1-3)GlcNAc(beta 1-2)Man. The possible relevance of the above structures to the ConA binding of rTf is discussed. A further preparation, obtained from the most anionic DEAE-cellulose fraction (peak V) or rTf contained several tetrasialylated diantennary glycans whose precise structures remain to be established in future studies.