Enhanced degradation of α-chitin materials prepared from shrimp processing byproduct and production of N-acetyl-D-glucosamine by thermoactive chitinases from soil mesophilic fungi

Soil isolates of mesophilic Penicillium monoverticillium CFR 2, Aspergillus flavus CFR 10 and Fusarium oxysporum CFR 8 were cultivated in solid state fermentation (SSF) using wheat bran solid medium supplemented with α-chitin in order to produce chitinolytic enzyme. Under SSF cultivation, maximum enzymes (U/g IDS) production was 41.0 (endo-chitinase) and 195.4 (β-N-acetylhexosaminidase) by P. monoverticillium, 26.8 (endo-chitinase) and 222.1 (β-N-acetylhexosaminidase) by A. flavus and 13.3 (endo-chitinase) and 168.3 (β-N-acetylhexosaminidase) by F. oxysporum after 166?h of incubation. The crude endo-chitinase and β-N-acetylhexosaminidase derived from A. flavus and F. oxysporum revealed optimum temperature at 62?±?1°C, but the enzymes from P. monoverticillium showed optimum temperature at 52?±?1°C for maximum activity. Several fold increase in endo-chitinase and β-N-acetylhexosaminidase activities in the crude enzymes preparation was achieved after concentrating with polyethylene glycol. The concentrated crude chitinases from P. monoverticillium, A. flavus and F. oxysporum, respectively yielded 95.6, 96.6 and 96.1?mmol/l of N-acetyl-D: -glucosamine (GlcNAc) in 48?h of reaction from colloidal chitin. While, the crude enzyme preparations of P. monoverticillium, A. flavus and F. oxysporum produced 10.11, 6.85 and 10.7?mmol/l of GlcNAc respectively, in 48?h of reaction from crystalline α-chitin. HPLC analysis of colloidal chitin hydrolysates prepared with crude chitinases derived from P. monoverticillium, A. flavus and F. oxysporum revealed that the major reaction product was monomeric GlcNAc (~80%) and a small amount of (GlcNAc)(4) (~20%), indicating the potential of these enzymes for efficient production of GlcNAc from α-chitin.     

Thermoactive β-N-acetylhexosaminidase production by a soil isolate of Penicillium monoverticillium CFR 2 under solid state fermentation: parameter optimization and application for N-acetyl chitooligosaccharides preparation from chitin

Two fungal strains were evaluated for β-N-acetylhexosaminidase production by solid state fermentation using different agro-industrial residues such as commercial wheat bran (CWB) and shrimp shell chitin waste (SSCW), of which Penicillium monoverticillium CFR 2 a local soil isolate showed significantly (P ≤ 0.001) higher β-N-acetylhexosaminidase activity on CWB medium as compared with the activity of Fusarium oxysporum CFR 8. Fermentation parameters such as incubation temperature, incubation time, initial moisture content and inoculum concentration were optimized by statistically designed experiments, using 3**(4–1) fractional factorial design of Response Surface Methodology. The high R² (0.9512) observed during validation experiment showed the usefulness of the model. Highest level of enzyme activity (311.84 U/g IDS) was predicted at 75% (w/w) initial moisture content, 26 °C incubation temperature, 168 h incubation time and initial inoculum, at the highest concentration tested (2.95 ml spore suspension/5 g substrate). Statistical optimization yielded a 4.5 fold increase in β-N-acetylhexosaminidase activity. The crude β-N-acetylhexosaminidase showed optimum temperature of 57 ± 1 °C and pH of 3.6 and retained 50% activity after 1 h of incubation at 57 ± 1 °C. SDS–PAGE zymogram revealed crude enzyme was a monomer with an apparent molecular weight ~110 kDa. The crude enzyme formed 6.81 ± 0.03 mM/l of N-acetyl chitooligosaccharides from colloidal chitin in 24 h of incubation. HPLC analysis revealed hydrolysate contained 37.57% N-acetyl chitotriose and 62.43% N-acetyl chitohexose, indicating its potential for specific N-acetyl chitooligosaccharides production.     

An acidic,thermostable exochitinase with β-<Emphasis Type="Italic">N</Emphasis>-acetylglucosaminidase activity from <Emphasis Type="Italic">Paenibacillus barengoltzii</Emphasis> converting chitin to <Emphasis Type="Italic">N</Emphasis>-acetyl glucosamine

Background

N-acetyl-β-D-glucosamine (GlcNAc) is widely used as a valuable pharmacological agent and a functional food additive. The traditional chemical process for GlcNAc production has some problems such as high production cost, low yield, and acidic pollution. Hence, to identify a novel chitinase that is suitable for bioconversion of chitin to GlcNAc is of great value.

Results

A novel chitinase gene (PbChi74) from Paenibacillus barengoltzii was cloned and heterologously expressed in Escherichia coli as an intracellular soluble protein. The gene has an open reading frame (ORF) of 2,163 bp encoding 720 amino acids. The recombinant chitinase (PbChi74) was purified to apparent homogeneity with a purification fold of 2.2 and a recovery yield of 57.9%. The molecular mass of the purified enzyme was estimated to be 74.6 kDa and 74.3 kDa by SDS-PAGE and gel filtration, respectively. PbChi74 displayed an acidic pH optimum of 4.5 and a temperature optimum of 65°C. The enzyme showed high activity toward colloidal chitin, glycol chitin, N-acetyl chitooligosaccharides, and p-nitrophenyl N-acetyl β-glucosaminide. PbChi74 hydrolyzed colloidal chitin to yield N- acetyl chitobiose [(GlcNAc)₂] at the initial stage, which was further converted to its monomer N-acetyl glucosamine (GlcNAc), suggesting that it is an exochitinase with β-N-acetylglucosaminidase activity. The purified PbChi74 coupled with RmNAG (β-N-acetylglucosaminidase from Rhizomucor miehei) was used to convert colloidal chitin to GlcNAc, and GlcNAc was the sole end product at a concentration of 27.8 mg mL^-1 with a conversion yield of 92.6%. These results suggest that PbChi74 may have great potential in chitin conversion.

Conclusions

The excellent thermostability and hydrolytic properties may give the exochitinase great potential in GlcNAc production from chitin. This is the first report on an exochitinase with N-acetyl-β-D-glucosaminidase activity from Paenibacillus species.

     

Biotechnological aspects of chitinolytic enzymes: a review

Chitin and chitinases (EC 3.2.1.14) have an immense potential. Chitinolytic enzymes have wide-ranging applications such as preparation of pharmaceutically important chitooligosaccharides and N-acetyl d-glucosamine, preparation of single-cell protein, isolation of protoplasts from fungi and yeast, control of pathogenic fungi, treatment of chitinous waste, and control of malaria transmission. In this review, we discuss the occurrence and structure of chitin, the types and sources of chitinases, their mode of action, chitinase production, as well as molecular cloning and protein engineering of chitinases and their biotechnological applications.     

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.     

Fully Deacetylated Chitooligosaccharides Act as Efficient Glycoside Hydrolase Family 18 Chitinase Inhibitors

Small molecule inhibitors against chitinases have potential applications as pesticides, fungicides, and antiasthmatics. Here, we report that a series of fully deacetylated chitooligosaccharides (GlcN)_2–7 can act as inhibitors against the insect chitinase OfChtI, the human chitinase HsCht, and the bacterial chitinases SmChiA and SmChiB with IC₅₀ values at micromolar to millimolar levels. The injection of mixed (GlcN)_2–7 into the fifth instar larvae of the insect Ostrinia furnacalis resulted in 85% of the larvae being arrested at the larval stage and death after 10 days, also suggesting that (GlcN)_2–7 might inhibit OfChtI in vivo. Crystal structures of the catalytic domain of OfChtI (OfChtI-CAD) complexed with (GlcN)_5,6 were obtained at resolutions of 2.0 Å. These structures, together with mutagenesis and thermodynamic analysis, suggested that the inhibition was strongly related to the interaction between the −1 GlcN residue of the inhibitor and the catalytic Glu¹⁴⁸ of the enzyme. Structure-based comparison showed that the fully deacetylated chitooligosaccharides mimic the substrate chitooligosaccharides by binding to the active cleft. This work first reports the inhibitory activity and proposed inhibitory mechanism of fully deacetylated chitooligosaccharides. Because the fully deacetylated chitooligosaccharides can be easily derived from chitin, one of the most abundant materials in nature, this work also provides a platform for developing eco-friendly inhibitors against chitinases.     

Chitinases: in agriculture and human healthcare

Abstract

Biological control of phytopathogenic fungi and insects continues to inspire the research and development of environmentally friendly bioactive alternatives. Potentially lytic enzymes, chitinases can act as a biocontrol agent against agriculturally important fungi and insects. The cell wall in fungi and protective covers, i.e. cuticle in insects shares a key structural polymer, chitin, a β-1,4-linked N-acetylglucosamine polymer. Therefore, it is advantageous to develop a common biocontrol agent against both of these groups. As chitin is absent in plants and mammals, targeting its metabolism will signify an eco-friendly strategy for the control of agriculturally important fungi and insects but is innocuous to mammals, plants, beneficial insects and other organisms. In addition, development of chitinase transgenic plant varieties probably holds the most promising method for augmenting agricultural crop protection and productivity, when properly integrated into traditional systems. Recently, human proteins with chitinase activity and chitinase-like proteins were identified and established as biomarkers for human diseases. This review covers the recent advances of chitinases as a biocontrol agent and its various applications including preparation of medically important chitooligosaccharides, bioconversion of chitin as well as in implementing chitinases as diagnostic and prognostic markers for numerous diseases and the prospect of their future utilization.     

Growth of Hyperthermophilic Archaeon Pyrococcus furiosus on Chitin Involves Two Family 18 Chitinases

Pyrococcus furiosus was found to grow on chitin, adding this polysacharide to the inventory of carbohydrates utilized by this hyperthermophilic archaeon. Accordingly, two open reading frames (chiA [Pf1234] and chiB [Pf1233]) were identified in the genome of P. furiosus, which encodes chitinases with sequence similarity to proteins from the glycosyl hydrolase family 18 in less-thermophilic organisms. Both enzymes contain multiple domains that consist of at least one binding domain and one catalytic domain. ChiA (ca. 39 kDa) contains a putative signal peptide, as well as a binding domain (ChiA_BD), that is related to binding domains associated with several previously studied bacterial chitinases. chiB, separated by 37 nucleotides from chiA and in the same orientation, encodes a polypeptide with two different proline-threonine-rich linker regions (6 and 3 kDa) flanking a chitin-binding domain (ChiB_BD [11 kDa]), followed by a catalytic domain (ChiB_cat [35 kDa]). No apparent signal peptide is encoded within chiB. The two chitinases share little sequence homology to each other, except in the catalytic region, where both have the catalytic glutamic acid residue that is conserved in all family 18 bacterial chitinases. The genes encoding ChiA, without its signal peptide, and ChiB were cloned and expressed in Escherichia coli. ChiA exhibited no detectable activity toward chitooligomers smaller than chitotetraose, indicating that the enzyme is an endochitinase. Kinetic studies showed that ChiB followed Michaelis-Menten kinetics toward chitotriose, although substrate inhibition was observed for larger chitooligomers. Hydrolysis patterns on chitooligosaccharides indicated that ChiB is a chitobiosidase, processively cleaving off chitobiose from the nonreducing end of chitin or other chitooligomers. Synergistic activity was noted for the two chitinases on colloidal chitin, indicating that these two enzymes work together to recruit chitin-based substrates for P. furiosus growth. This was supported by the observed growth on chitin as the sole carbohydrate source in sulfur-free media.     

Production of lytic enzymes and siderophores,and inhibition of germination of basidiospores of Moniliophthora (ex Crinipellis) perniciosa by phylloplane actinomycetes

Streptomyces albovinaceus, Streptomyces caviscabies, Streptomyces griseus, Streptomyces setonii, and Streptomyces virginiae selected as antagonists of Moniliophthora (ex Crinipellis) perniciosa, the causal agent of cacao Witches’ broom, were examined in vitro to detect production of chitinases, β-1,3-glucanases, and cellulases. All the species produced chitinases, but not β-1,3-glucanases or cellulases, when grown on a liquid mineral medium containing glucose, colloidal chitin, or cell walls of M. perniciosa as a carbon source. There were no quantitative differences among species in the production of chitinase, however, the germination inhibition of basidiospores of M. perniciosa was higher when they were cultivated using glucose as a carbon source, followed by colloidal chitin and cell walls. All the species also produced hydroxymate type siderophores in similar quantities, and the quantity of siderophores did not correlate with the inhibition of basidiospore germination. The germination inhibition was more pronounced when S. albovinaceus, S. griseus, and S. virginiae were cultivated on iron-deficient medium, suggesting involvement of siderophores in the antagonism by these species of actinomycetes.     

Purification and characterization of a chitinase from Serratia proteamaculans

A chitinase gene from Serratia proteamaculans 18A1 was cloned, sequenced, and expressed in Escherichia coli M15. Recombinant enzyme (ChiA) was purified by Ni-NTA affinity column chromatography. The ChiA gene contains an open reading frame (ORF), encoding an endochitinase with a deduced molecular weight 60 kDa and predicted isoelectric point of 6.35. Comparison of ChiA with other chitinases revealed a modular structure containing an N-terminal PKD-domain, a family 18 catalytic domain and a C-terminal putative chitin-binding domain. Turn over rate (K _cat) of the enzyme was determined using colloidal chitin (49.71 ± 1.15 S^?1) and crystalline β-chitin (17.20 ± 0.83 S^?1) as substrates. The purified enzyme was active over a broad range of pH (pH 4.5–9.0) and temperature (4–70°C) with a peak activity at pH 5.5 and 55°C. However, enzyme activity was found to be stable up to 45°C for longer incubation periods. Purified enzyme was shown to inhibit fungal spore germination and hyphal growth of pathogenic fungi Fusarium oxysporum and Aspergillus niger.     

Inhibitory effect of chitinases isolated from Semillon grapes (Vitis vinifera) on growth of grapevine pathogens

Characteristics and antifungal activity of chitinases in Semillon grapes were investigated. Chitinases were isolated from the juice of Semillon grapes by chitin affinity chromatography. Native and SDS-PAGE analyses of the fraction showing chitin affinity (active fraction) demonstrated only the presence of protein bands of chitinases. Three types of class IV chitinases (chi-1a, chi-1b and chi-2) were purified from the active fraction. These chitinases actively hydrolyzed chitin under acidic conditions (pH 4.0–4.5). The isoelectric points and the molecular weights of chi-1a, chi-1b and chi-2 were 4.73, 4.60, and 7.87, and 32.1 kDa, 31.6 kDa, and 29.0 kDa, respectively. The active fraction was found to inhibit Botrytis cinerea mycelial growth and the inhibitory effect was due to the activity of chitinases. The active fraction inhibited twenty strains of B. cinerea collected from the experimental vineyard. The effect of chitinases was enhanced in media containing more than 20% sugar. When the active fraction was tested on Glomerella cingulata, the growth inhibitory effect observed was markedly less than that seen on B. cinerea.     

Cloning,expression and biocharacterization of OfCht5, the chitinase from the insect Ostrinia furnacalis

Abstract Chitinase catalyzes β‐1,4‐glycosidic linkages in chitin and has attracted research interest due to it being a potential pesticide target and an enzymatic tool for preparation of N‐acetyl‐β‐D‐glucosamine. An individual insect contains multiple genes encoding chitinases, which vary in domain architectures, expression patterns, physiological roles and biochemical properties. Herein, OfCht5, the glycoside hydrolase family 18 chitinase from the widespread lepidopteran pest Ostrinia furnacalis, was cloned, expressed in the yeast Pichia pastoris and biochemically characterized in an attempt to facilitate both pest control and biomaterial preparation. Complementary DNA sequence analysis indicated that OfCHT5 consisted of an open reading frame of 1 665‐bp nucleotides. Phylogenic analysis suggested OfCht5 belongs to the Group I insect chitinases. Expression of OfCht5 in Pichia pastoris resulted in highest specific activity after 120 h of induction with methanol. Through two steps of purification, consisting of ammonium sulfate precipitation and metal chelating chromatography, about 7 mg of the recombinant OfCht5 was purified to homogeneity from 1 L culture supernatant. OfCht5 effectively converted colloidal chitin into chitobiose, but had relatively low activity toward α‐chitin. When chitooligosaccharides [(GlcNAc)_n, n= 3–6] were used as substrates, OfCht5 was observed to possess the highest catalytic efficiency parameter toward (GlcNAc)₄ and predominantely hydrolyzed the second glycosidic bond from the non‐reducing end. Together with β‐N‐acetyl‐D‐hexosaminidase OfHex1, OfCht5 achieved its highest efficiency in chitin degradation that yielded N‐acetyl‐β‐D‐glucosamine, a valuable pharmacological reagent and food supplement, within a molar concentration ratio of OfCht5 versus OfHex1 in the range of 9 : 1–15 : 1. This work provides an alternative to existing preparation of chitinase for pesticides and other applications.     

Biodegradation of shrimp processing bio-waste and concomitant production of chitinase enzyme and N-acetyl-D-glucosamine by marine bacteria: production and process optimization

A total of 250 chitinolytic bacteria from 68 different marine samples were screened employing enrichment method that utilized native chitin as the sole carbon source. After thorough screening, five bacteria were selected as potential cultures and identified as; Stenotrophomonas sp. (CFR221?M), Vibrio sp. (CFR173?M), Phyllobacteriaceae sp. (CFR16?M), Bacillus badius (CFR198?M) and Bacillus sp. (CFR188?M). All five strains produced extracellular chitinase and GlcNAc in SSF using shrimp bio-waste. Scanning electron microscopy confirmed the ability of these marine bacteria to adsorb onto solid shrimp bio-waste and to degrade chitin microfibers. HPLC analysis of the SSF extract also confirmed presence of 36-65?% GlcNAc as a product of the degradation. The concomitant production of chitinase and GlcNAc by all five strains under SSF using shrimp bio-waste as the solid substrate was optimized by 'one factor at a time' approach. Among the strains, Vibrio sp. CFR173?M produced significantly higher yields of chitinase (4.8 U/g initial dry substrate) and GlcNAc (4.7?μmol/g initial dry substrate) as compared to other cultures tested. A statistically designed experiment was applied to evaluate the interaction of variables in the biodegradation of shrimp bio-waste and concomitant production of chitinase and GlcNAc by Vibrio sp. CFR173?M. Statistical optimization resulted in a twofold increase of chitinase, and a 9.1 fold increase of GlcNAc production. These results indicated the potential of chitinolytic marine bacteria for the reclamation of shrimp bio-waste, as well as the potential for economic production of chitinase and GlcNAc employing SSF using shrimp bio-waste as an ideal substrate.     

Microbial production of N-acetyl cis-4-hydroxy-l-proline by coexpression of the Rhizobium l-proline cis-4-hydroxylase and the yeast N-acetyltransferase Mpr1

The proline analogue cis-4-hydroxy-l-proline (CHOP), which inhibits the biosynthesis of collagen, has been clinically evaluated as an anticancer drug, but its water solubility and low molecular weight limits its therapeutic potential since it is rapidly excreted. In addition, CHOP is too toxic to be practical as an anticancer drug, due primarily to its systematic effects on noncollagen proteins. To promote CHOP’s retention in blood and/or to decrease its toxicity, N-acetylation of CHOP might be a novel approach as a prodrug. The present study was designed to achieve the microbial production of N-acetyl CHOP from l-proline by coexpression of l-proline cis-4-hydroxylases converting l-proline into CHOP (SmP4H) from the Rhizobium Sinorhizobium meliloti and N-acetyltransferase converting CHOP into N-acetyl CHOP (Mpr1) from the yeast Saccharomyces cerevisiae. We constructed a coexpression plasmid harboring both the SmP4H and Mpr1 genes and introduced it into Escherichia coli BL21(DE3) or its l-proline oxidase gene-disrupted (ΔputA) strain. M9 medium containing l-proline produced more N-acetyl CHOP than LB medium containing l-proline. E. coli ΔputA cells accumulated l-proline (by approximately 2-fold) compared to that in wild-type cells, but there was no significant difference in CHOP production between wild-type and ΔputA cells. The addition of NaCl and l-ascorbate resulted in a 2-fold increase in N-acetyl CHOP production in the l-proline-containing M9 medium. The highest yield of N-acetyl CHOP was achieved at 42 h cultivation in the optimized medium. Five unknown compounds were detected in the total protein reaction, probably due to the degradation of N-acetyl CHOP. Our results suggest that weakening of the degradation or deacetylation pathway improves the productivity of N-acetyl CHOP.     

A novel strain of Brevibacillus laterosporus produces chitinases that contribute to its biocontrol potential

A novel strain exhibiting entomopathogenic and chitinolytic activity was isolated from mangrove marsh soil in India. The isolate was identified as Brevibacillus laterosporus by phenotypic characterization and 16S rRNA sequencing and designated Lak1210. When grown in the presence of colloidal chitin as the sole carbon source, the isolate produced extracellular chitinases. Chitinase activity was inhibited by allosamidin indicating that the enzymes belong to the family 18 chitinases. The chitinases were purified by ammonium sulfate precipitation followed by chitin affinity chromatography yielding chitinases and chitinase fragments with 90, 75, 70, 55, 45, and 25 kDa masses. Mass spectrometric analyses of tryptic fragments showed that these fragments belong to two distinct chitinases that are almost identical to two putative chitinases, a 89.6-kDa four-domain chitodextrinase and a 69.4-kDa two-domain enzyme called ChiA1, that are encoded on the recently sequenced genome of B. laterosporus LMG15441. The chitinase mixture showed two pH optima, at 6.0 and 8.0, and an optimum temperature of 70 °C. The enzymes exhibited antifungal activity against the phytopathogenic fungus Fusarium equiseti. Insect toxicity bioassays with larvae of diamondback moths (Plutella xylostella), showed that addition of chitinases reduced the time to reach 50 % mortality upon infection with non-induced B. laterosporus from 3.3 to 2.1 days. This study provides evidence for the presence of inducible, extracellular chitinolytic enzymes in B. laterosporus that contribute to the strain’s antifungal activity and insecticidal activity.     

Bioconversion of Chitin to Bioactive Chitooligosaccharides: Amelioration and Coastal Pollution Reduction by Microbial Resources

Chitin-metabolizing products are of high industrial relevance in current scenario due to their wide biological applications, relatively lower cost, greater abundance, and sustainable supply. Chitooligosaccharides have remarkably wide spectrum of applications in therapeutics such as antitumor agents, immunomodulators, drug delivery, gene therapy, wound dressings, as chitinase inhibitors to prevent malaria. Hypocholesterolemic and antimicrobial activities of chitooligosaccharides make them a molecule of choice for food industry, and their functional profile depends on the physicochemical characteristics. Recently, chitin-based nanomaterials are also gaining tremendous importance in biomedical and agricultural applications. Crystallinity and insolubility of chitin imposes a major hurdle in the way of polymer utilization. Chemical production processes are known to produce chitooligosaccharides with variable degree of polymerization and properties along with ecological concerns. Biological production routes mainly involve chitinases, chitosanases, and chitin-binding proteins. Development of bio-catalytic production routes for chitin will not only enhance the production of commercially viable chitooligosaccharides with defined molecular properties but will also provide a means to combat marine pollution with value addition.     

Overview of chitin metabolism enzymes in Manduca sexta: Identification,domain organization,phylogenetic analysis and gene expression

Chitin is one of the most abundant biomaterials in nature. The biosynthesis and degradation of chitin in insects are complex and dynamically regulated to cope with insect growth and development. Chitin metabolism in insects is known to involve numerous enzymes, including chitin synthases (synthesis of chitin), chitin deacetylases (modification of chitin by deacetylation) and chitinases (degradation of chitin by hydrolysis). In this study, we conducted a genome-wide search and analysis of genes encoding these chitin metabolism enzymes in Manduca sexta. Our analysis confirmed that only two chitin synthases are present in M. sexta as in most other arthropods. Eleven chitin deacetylases (encoded by nine genes) were identified, with at least one representative in each of the five phylogenetic groups that have been described for chitin deacetylases to date. Eleven genes encoding for family 18 chitinases (GH18) were found in the M. sexta genome. Based on the presence of conserved sequence motifs in the catalytic sequences and phylogenetic relationships, two of the M. sexta chitinases did not cluster with any of the current eight phylogenetic groups of chitinases: two new groups were created (groups IX and X) and their characteristics are described. The result of the analysis of the Lepidoptera-specific chitinase-h (group h) is consistent with its proposed bacterial origin. By analyzing chitinases from fourteen species that belong to seven different phylogenetic groups, we reveal that the chitinase genes appear to have evolved sequentially in the arthropod lineage to achieve the current high level of diversity observed in M. sexta. Based on the sequence conservation of the catalytic domains and on their developmental stage- and tissue-specific expression, we propose putative functions for each group in each category of enzymes.     

The Fusarium oxysporum gnt2, Encoding a Putative N-Acetylglucosamine Transferase,Is Involved in Cell Wall Architecture and Virulence

With the aim to decipher the molecular dialogue and cross talk between Fusarium oxysporum f.sp. lycopersci and its host during infection and to understand the molecular bases that govern fungal pathogenicity, we analysed genes presumably encoding N-acetylglucosaminyl transferases, involved in glycosylation of glycoproteins, glycolipids, proteoglycans or small molecule acceptors in other microorganisms. In silico analysis revealed the existence of seven putative N-glycosyl transferase encoding genes (named gnt) in F. oxysporum f.sp. lycopersici genome. gnt2 deletion mutants showed a dramatic reduction in virulence on both plant and animal hosts. Δgnt2 mutants had αalterations in cell wall properties related to terminal αor β-linked N-acetyl glucosamine. Mutant conidia and germlings also showed differences in structure and physicochemical surface properties. Conidial and hyphal aggregation differed between the mutant and wild type strains, in a pH independent manner. Transmission electron micrographs of germlings showed strong cell-to-cell adherence and the presence of an extracellular chemical matrix. Δgnt2 cell walls presented a significant reduction in N-linked oligosaccharides, suggesting the involvement of Gnt2 in N-glycosylation of cell wall proteins. Gnt2 was localized in Golgi-like sub-cellular compartments as determined by fluorescence microscopy of GFP::Gnt2 fusion protein after treatment with the antibiotic brefeldin A or by staining with fluorescent sphingolipid BODIPY-TR ceramide. Furthermore, density gradient ultracentrifugation allowed co-localization of GFP::Gnt2 fusion protein and Vps10p in subcellular fractions enriched in Golgi specific enzymatic activities. Our results suggest that N-acetylglucosaminyl transferases are key components for cell wall structure and influence interactions of F. oxysporum with both plant and animal hosts during pathogenicity.     

Structural and functional characterization of a putative polysaccharide deacetylase of the human parasite Encephalitozoon cuniculi

The microsporidian Encephalitozoon cuniculi is an intracellular eukaryotic parasite considered to be an emerging opportunistic human pathogen. The infectious stage of this parasite is a unicellular spore that is surrounded by a chitin containing endospore layer and an external proteinaceous exospore. A putative chitin deacetylase (ECU11_0510) localizes to the interface between the plasma membrane and the endospore. Chitin deacetylases are family 4 carbohydrate esterases in the CAZY classification, and several bacterial members of this family are involved in evading lysis by host glycosidases, through partial de‐N‐acetylation of cell wall peptidoglycan. Similarly, ECU11_0510 could be important for E. cuniculi survival in the host, by protecting the chitin layer from hydrolysis by human chitinases. Here, we describe the biochemical, structural, and glycan binding properties of the protein. Enzymatic analyses showed that the putative deacetylase is unable to deacetylate chitooligosaccharides or crystalline β‐chitin. Furthermore, carbohydrate microarray analysis revealed that the protein bound neither chitooligosaccharides nor any of a wide range of other glycans or chitin. The high resolution crystal structure revealed dramatic rearrangements in the positions of catalytic and substrate binding residues, which explain the loss of deacetylase activity, adding to the unusual structural plasticity observed in other members of this esterase family. Thus, it appears that the ECU11_0510 protein is not a carbohydrate deacetylase and may fulfill an as yet undiscovered role in the E. cuniculi parasite.