Properties of chitin synthase in homogenates from Chironomus cells

Homogenates of Chironomus cells synthesize chitin as effectively as intact cells. Chitin is produced in a dose-dependent manner, when GlcN, GlcNAc, or UDP-GlcNAc is used as precursor. Due to the lability of UDP-GlcNAc incorporation of this substrate is underestimated. No allosteric effect is observed when GlcN or GlcNAc is used as a substrate. Chitin synthesis is stimulated by Mg²⁺ and inhibited by uridine monophosphate (UMP), uridine diphosphate (UDP), and uridine triphosphate (UTP). The apparent temperature optimum is 30°C, the apparent pH optimum is 5.5–6. Addition of the chitinase inhibitor allosamidin does not enhance chitin synthesis significantly. The time course of chitin formation reveals a lag period of about 12 h, which can be overcome by trypsin treatment. Addition of protease inhibitors prevents chitin synthesis.     

Distribution of Chitinases in the Entomopathogen <Emphasis Type="Italic">Metarhizium anisopliae</Emphasis> and Effect of <Emphasis Type="Italic">N</Emphasis>-Acetylglucosamine in Protein Secretion

For a long time, fungi have been characterized by their ability to secrete enzymes, mostly hydrolytic in function, and thus are defined as extracellular degraders. Chitin and chitinolytic enzymes are gaining importance for their biotechnological applications. Particularly, chitinases are used in agriculture to control plant pathogens. Metarhizium anisopliae produces an extracellular chitinase when grown on a medium containing chitin, indicating that synthesis is subject to induction by the substrate. Various sugar combinations were investigated for induction and repression of chitinase. N-acetylglucosamine (GlcNAc) shows a special dual regulation on chitinase production. M. anisopliae has at least two distinct, cell-bound, chitinolytic enzymes when cultured with GlcNAc as one of the carbon sources, and we suggest that this carbohydrate has an important role in protein secretion.     

Calcofluor disrupts the midgut defense system in insects

The insect midgut is generally lined with a unique protective chitin/protein structure, the peritrophic membrane (PM). We demonstrated that in Trichoplusia ni larvae, the majority of PM proteins were assembled with chitin as a consequence of their chitin binding properties. These proteins could be dissociated from the PM in vitro by Calcofluor, a well-known chemical with chitin binding properties. The chitin binding characteristics of PM proteins were confirmed by their high affinity binding in vitro to regenerated chitin. In vivo assays demonstrated that Calcofluor could inhibit PM formation in five lepidopteran insects tested. The inhibition of T. ni PM formation by Calcofluor, was accompanied by increased larval susceptibility to baculovirus infection. Continuous inhibition of PM formation by Calcofluor resulted in retarded larval development and mortality. The destructive effect of Calcofluor on PM formation was demonstrated to be transient and reversible depending on the presence of Calcofluor within the midgut. In addition, degradation of the insect intestinal mucin was observed concurrently with the inhibition of PM formation by Calcofluor. Our studies revealed a potential novel approach to develop strategies for insect control by utilizing chitin binding molecules to specifically target PM formation in a broad range of insect pest species.     

Induction and purification of a thermophilic chitinase produced byAeromonas sp. DYU-too7 using glucosamine

In the presence of chitin,Aeromonas sp. DYU-Too7 can produce extra-cellular, chitin-degrading enzymes. Chitin analogues and other carbon sources can be used to cultivate this bacterial strain. The chitinases produced by the strain were higher in the GIcN (glucosamine) medium than those in other media. The maximal chitinase activity occurred in the medium containing 0.1% GIcN. Cultivation ofAeromonas sp. DYU-Too7 in the GIcN medium sped up the chitinase production; however the same result did not appear when it was cultivated in the (Chitin+GIcN) medium. This result may indicate that GIcN can be utilized byAeromonas sp. DYU-Too7 as a carbon source and an inducer to produce chitinases. A chitinase with a molecular mass of 36 kDa was further purified and characterized to have an optimal reacting pH of 5.0 and an optimal reacting temperature of 50°C. This chitinase showed high stability in the proximity of 30°C and also high stability in the proximity of pH 7.0. The hydrolysates of colloidal chitin, with the aid of the 36-kDa chitinase, were analyzed by an HPLC and found to be chitobiose.     

Mutation of a conserved tryptophan in the chitin-binding cleft of Serratia marcescens chitinase A enhances transglycosylation

Family 18 chitinases have the signature peptide DGXDXDXE forming the fourth beta-strand in the (beta/alpha)8-barrel of their catalytic domain. The carboxyl-end glutamic acid, E315 in Serratia marcescens chitinase A, serves as the acid/base during chitin hydrolysis, and the side-chain of the preceding aspartic acid, D313, helps to position correctly the N-acetyl moiety of the glycosyl sugar undergoing hydrolysis. Chitin substrates are bound within a long cleft across the top of the barrel, whose floor consists of aromatic residues that hydrophobically stack with every other GlcNAc. Alanine substitution of the conserved Trp167 at the -3 subsite in Serratia marcescens chitinase A enhanced transglycosylation. Higher oligosaccharides were formed from both chitin tetra- and pentasaccharide, and the only hydrolytic product from chitin trisaccharide was the disaccharide. Greater retention of the glycosyl fragment at the active site of the -3 mutant of Serratia marcescens chitinase A might favor transglycosylation due to a stabilized conformation of its D313.     

Characterization of chitin and chitin synthase from the cellulosic cell wall fungusSaprolegnia monoi¨ca

The presence of chitin in hyphal cell walls and regenerating protoplast walls ofSaprolegnia monoi¨ca was demonstrated by biochemical and biophysical analyses. α-Chitin was characterized by X-ray diffraction, electron diffraction, and infrared spectroscopy. In hyphal cell walls, chitin appeared as small globular particles while cellulose, the other crystalline cell wall component, had a microfibrillar structure. Chitin synthesis was demonstrated in regenerating protoplasts by the incorporation of radioactiveN-acetylglucosamine into a KOH-insoluble product. Chitin synthase activity of cell-free extracts was particulate. This activity was stimulated by trypsin and inhibited by the competitive inhibitor polyoxin D (K_i 20 μM). The reaction product was insoluble in 1M KOH or 1M acetic acid and was hydrolyzed by chitinase into diacetylchitobiose. Fungal growth and cell wall chitin content were reduced when mycelia were grown in the presence of polyoxin D. However, hyphal morphology was not altered by the presence of the antibiotic indicating that chitin does not seem to play an important role in the morphogenesis ofSaprolegnia.     

聚丙烯酰胺凝胶电泳配合荧光增白剂显色检测木霉几丁质酶同工酶谱

为提高木霉几丁质酶检测方法的准确性和灵敏度,建立一种快速检测几丁质酶同工酶的方法。采用活性凝胶电泳、变性凝胶电泳、原位显色凝胶电泳结合荧光增白剂（Calcofluor white M2R）显色从绿色木霉LTR-2发酵产物中检测几丁质酶同工酶。活性凝胶电泳在粗酶液浓缩5倍时显示两条活性谱带,变性凝胶电泳在浓缩10倍时显示一条活性谱带,原位显色凝胶电泳在浓缩20倍时显示两条不清晰的活性谱带,SDS-PAGE显示这两条活性谱带的分子量分别为65kDa和42kDa。结果表明活性聚丙烯酰胺凝胶电泳和Calcofluor white M2R显色相结合的方法在几丁质酶上样量为0.47U时具有较好的分辨能力,是检测木霉几丁质酶同工酶的有效的方法。     

Biosynthesis of chitin by particulate fractions from Cunnighamella elegans.

The enzyme chitin synthetase (UDP-acetylaminodeoxyglucosyl transferase, EC 2.4.1.16) in Cunninghamella elegans has been investigated. The enzyme was present in the microsomal, cell wall, mitochondrial and the soluble cytoplasmic fraction of the mycelium, with the former having the highest specific activity. The properties of the enzyme in this fraction were investigated; the Km for UDP GlcNAc was 1.23 mM and 2.08 mM GlcNAc in the presence of 1 mM UDP GlcNAc. The temperature optimum was between 26 degrees and 29 degrees C and maximal activity was at pH 6.25. Mg++ ions had no effect on chitin synthesis, but soluble chitodextrins inhibited the enzyme. The production of chitin synthetase was correlated with the growth of the fungus, maximum activity being found during the late exponential phase of growth. Chitin was confirmed as the sole product of enzyme action, by digestion with chitinase.     

Multiple components and induction mechanism of the chitinolytic system of the hyperthermophilic archaeon <Emphasis Type="Italic">Thermococcus chitonophagus</Emphasis>

Thermococcus chitonophagus produces several, cellular and extracellular chitinolytic enzymes following induction with various types of chitin and chitin oligomers, as well as cellulose. Factors affecting the anaerobic culture of this archaeon, such as optimal temperature, agitation speed and type of chitin, were investigated. A series of chitinases, co-isolated with the major, cell membrane-associated endochitinase (Chi70), and a periplasmic chitobiase (Chi90) were subsequently isolated. In addition, a distinct chitinolytic activity was detected in the culture supernatant and partially purified. This enzyme exhibited an apparent molecular mass of 50 kDa (Chi50) and was optimally active at 80°C and pH 6.0. Chi50 was classified as an exochitinase based on its ability to release chitobiose as the exclusive hydrolysis product of colloidal chitin. A multi-component enzymatic apparatus, consisting of an extracellular exochitinase (Chi50), a periplasmic chitobiase (Chi90) and at least one cell-membrane-anchored endochitinase (Chi70), seems to be sufficient for effective synergistic in vivo degradation of chitin. Induction with chitin stimulates the coordinated expression of a combination of chitinolytic enzymes exhibiting different specificities for polymeric chitin and its degradation products. Among all investigated potential inducers and nutrient substrates, colloidal chitin was the strongest inducer of chitinase synthesis, whereas the highest growth rate was obtained following the addition of yeast extract and/or peptone to the minimal, mineralic culture medium in the absence of chitin. In rich medium, chitin monomer acted as a repressor of total chitinolytic activity, indicating the presence of a negative feedback regulatory mechanism. Despite the undisputable fact that the multi-component chitinolytic system of this archaeon is strongly induced by chitin, it is clear that, even in the absence of any chitinous substrates, there is low-level, basal, constitutive production of chitinolytic enzymes, which can be attributed to the presence of traces of chito-oligosaccharides and other structurally related molecules (in the undefined, rich, non-inducing medium) that act as potential inducers of chitinolytic activity. The low, basal and constitutive levels of chitinase gene expression may be sufficient to initiate chitin degradation and to release soluble oligomers, which, in turn, induce chitinase synthesis.     

The extracellular constitutive production of chitin deacetylase in Metarhizium anisopliae: possible edge to entomopathogenic fungi in the biological control of insect pests

The possible contribution of extracellular constitutively produced chitin deacetylase by Metarhizium anisopliae in the process of insect pathogenesis has been evaluated. Chitin deacetylase converts chitin, a beta-1,4-linked N-acetylglucosamine polymer, into its deacetylated form chitosan, a glucosamine polymer. When grown in a yeast extract-peptone medium, M. anisopliae constitutively produced the enzymes protease, lipase, and two chitin-metabolizing enzymes, viz. chitin deacetylase (CDA) and chitosanase. Chitinase activity was induced in chitin-containing medium. Staining of 7.5% native polyacrylamide gels at pH 8.9 revealed CDA activity in three bands. SDS-PAGE showed that the apparent molecular masses of the three isoforms were 70, 37, and 26 kDa, respectively. Solubilized melanin (10microg) inhibited chitinase activity, whereas CDA was unaffected. Following germination of M. anisopliae conidia on isolated Helicoverpa armigera, cuticle revealed the presence of chitosan by staining with 3-methyl-2-benzothiazoline hydrazone. Blue patches of chitosan were observed on cuticle, indicating conversion of chitin to chitosan. Hydrolysis of chitin with constitutively produced enzymes of M. anisopliae suggested that CDA along with chitosanase contributed significantly to chitin hydrolysis. Thus, chitin deacetylase was important in initiating pathogenesis of M. anisopliae softening the insect cuticle to aid mycelial penetration. Evaluation of CDA and chitinase activities in other isolates of Metarhizium showed that those strains had low chitinase activity but high CDA activity. Chemical assays of M. anisopliae cell wall composition revealed the presence of chitosan. CDA may have a dual role in modifying the insect cuticular chitin for easy penetration as well as for altering its own cell walls for defense from insect chitinase.     

Streptomyces lunalinharesii spores contain chitin on the outer sheath

Chitin from Streptomyces lunalinharesii spores, detected on its outermost surface layer, was isolated and characterized by chemical and spectroscopic methods, transmission electron microscopy and flow cytometry analysis. Gold–chitinase- and gold–lectin ( Lycopersicum esculentum agglutinin, LEA)-conjugated labels were used in microscopy experiments, whereas a fluorescence–lectin (LEA) conjugate was used in flow cytometry analysis. Chitin isolation consisted of several steps of hot alkali and nitrous acid treatment, and the final material was obtained in the colloidal form. The infrared and the ¹³C CP/MAS NMR spectra of Streptomyces sp. colloidal chitin and colloidal chitin obtained from commercial crab shell chitin were very similar. Incubation of the spores with gold-labeled lectin, or gold-labeled recombinant chitinase, showed the presence of gold particles around the spore surface, indicating the specific binding of the lectin or the recombinant chitinase with the chitin present on the outermost surface. Flow cytometry analysis, using the fluorescence–lectin conjugate, confirmed these results. According to scanning electron microscopy, S. lunalinharesii presented spore surface ornamentation belonging to the spiny group. This is the first detailed characterization of chitin on the spore's outermost layer from a Streptomyces species.     

Effect of calcofluor white on chitin synthases from Saccharomyces cerevisiae.

The growths of Saccharomyces cerevisiae wild-type strain and another strain containing a disrupted structural gene for chitin synthase (chs1::URA3), defective in chitin synthase 1 (Chs1) but showing a new chitin synthase activity (Chs2), were affected by Calcofluor. To be effective, the interaction of Calcofluor with growing cells had to occur at around pH 6. Treatment of growing cells from these strains with the fluorochrome led to an increase in the total levels of Chs1 and Chs2 activities measured on permeabilized cells. During treatment, basal levels (activities expressed in the absence of exogenous proteolytic activation) of Chs1 and Chs2 increased nine- and fourfold, respectively, through a mechanism dependent on protein synthesis, since the effect was abolished by cycloheximide. During alpha-factor treatment, both Chs1 and Chs2 levels increased; however, as opposed to what occurred during the mitotic cell cycle, there was no further increase in Chs1 or Chs2 activities by Calcofluor treatment.     

Structure of human chitotriosidase. Implications for specific inhibitor design and function of mammalian chitinase-like lectins

Chitin hydrolases have been identified in a variety of organisms ranging from bacteria to eukaryotes. They have been proposed to be possible targets for the design of novel chemotherapeutics against human pathogens such as fungi and protozoan parasites as mammals were not thought to possess chitin-processing enzymes. Recently, a human chitotriosidase was described as a marker for Gaucher disease with plasma levels of the enzyme elevated up to 2 orders of magnitude. The chitotriosidase was shown to be active against colloidal chitin and is inhibited by the family 18 chitinase inhibitor allosamidin. Here, the crystal structure of the human chitotriosidase and complexes with a chitooligosaccharide and allosamidin are described. The structures reveal an elongated active site cleft, compatible with the binding of long chitin polymers, and explain the inactivation of the enzyme through an inherited genetic deficiency. Comparison with YM1 and HCgp-39 shows how the chitinase has evolved into these mammalian lectins by the mutation of key residues in the active site, tuning the substrate binding specificity. The soaking experiments with allosamidin and chitooligosaccharides give insight into ligand binding properties and allow the evaluation of differential binding and design of species-selective chitinase inhibitors.     

Integumental chitin synthase activity in cell-free extracts of larvae of the Australian sheep blowfly, Lucilia cuprina, and two other species of diptera

Chitin synthase activity has been demonstrated in crude homogenates of larval integuments from L. cuprina and in similar preparations from Musca domestica and Calliphora erythrocephala. This is the first report of an insect integumental chitin synthase. This activity brings about the incorporation of radioactivity from UDP-N-acetyl-[14C]glucosamine into an ethanol- and alkali-insoluble form. A major part of this labelled product has been characterized as chitin by its insolubility in alkali, resistance to degradation by proteases and its susceptibility to digestion by chitinase and HCl. Most of the radioactivity solubilized during digestion by chitinase co-migrates with N-acetylglucosamine, glucosamine and chitobiose during paper chromatography. Some radioactivity also becomes incorporated into non-chitin products in this system. There is substantial evidence that incorporation is not brought about by whole epidermal cells or by microbial contamination in the homogenates. The extent of incorporation obtained with the homogenates is limited by the presence of degradative enzymes which rapidly break down the substrate (UDP-N-acetylglucosamine). The incorporation was partially inhibited (50-70%) by both polyoxin-D (apparent Ki 0.04 microM) and diflubenzuron (apparent Ki 5-8 microM). This is the first report of a cell-free chitin-synthesizing system derived from insect tissue which is sensitive to inhibition by diflubenzuron.     

Identification and molecular characterization of a chitinase from the hard tick Haemaphysalis longicornis

A cDNA encoding tick chitinase was cloned from a cDNA library of mRNA from Haemaphysalis longicornis eggs and designated as CHT1 cDNA. The CHT1 cDNA contains an open reading frame of 2790 bp that codes for 930 amino acid residues with a coding capacity of 104 kDa. The deduced amino acid sequence shows a 31% amino acid homology to Aedes aegypti chitinase and a multidomain structure containing one chitin binding peritrophin A domain and two glycosyl hydrolase family 18 chitin binding domains. The endogenous chitinase of H. longicornis was identified by a two-dimensional immunoblot analysis with mouse anti-rCHT1 serum and shown to have a molecular mass of 108 kDa with a pI of 5.0. A recombinant baculovirus AcMNPV.CHT1-expressed rCHT1 is glycosylated and able to degrade chitin. Chitin degradation was ablated by allosamidin in a dose-dependent manner. The optimal temperature and pH for activity of the purified chitinase were 45 degrees C and pH 5-7. The CHT1 cDNA has an ELR motif for chemokine-mediated angiogenesis and appears to be a chitinase of the chemokine family. Localization analysis using mouse anti-rCHT1 serum revealed that native chitinase is highly expressed in the epidermis and midgut of the tick. AcMNPV.CHT1 topically applied to H. longicornis ticks exhibited replication. This is the first report of insect baculovirus infection of ticks. The importance of AcMNPV.CHT1 as a novel bio-acaricide for tick control is discussed.     

Evidence for chitin synthesis in an insect cell line

Cells from the continuous MRRL-CH line derived from embryos of the tobacco hornworm synthesized chitin. Digestion of the washed pellet from [¹⁴C]-N-acetylglucosamine-labeled cells by chitinase yielded a water-soluble labeled compound. The lyophilized residue from the supernatant of the chitin digestion was analyzed by gas-liquid chromatography as its trimethylsilyl derivative. The major component cochromatographed with derivitized chitobiose. The presence of chitobiose was confirmed by gas chro-matography-mass spectrometry. The synthesis of chitin by this cell line is inhibited by diflubenzuron.     

Ultrastructural differences between wall apices of growing and non-growing hyphae ofSchizophyllum commune

Summary Newly synthesized chitin at the hyphal apex ofSchizophyllum commune was shown to be highly susceptible to chitinase degradation and solubilization by dilute mineral acid. With time this chitin became gradually more resistant to these treatments. With a combination of the shadow-cast technique and electron microscopic autoradiography it could be shown that this process occurred as the newly synthesized chitin moved into subapical parts of growing hyphae but also in non-growing apices which had ceased growth after incorporation of theN-acetyl[6-³H]glucosamine. These results are in agreement with a model which explains apical morphogenesis by assuming that the newly synthesized wall material at the apex is plastic due to the presence of individual polymer chains but becomes rigidified because of subsequent physical and chemical changes involving these polymers.Dedicated to Dr. A.Quispel, Professor of Botany at the University of Leiden, on occasion of his retirement.     

First evidence of chitin as a component of the skeletal fibers of marine sponges. Part I. Verongidae (demospongia: Porifera)

The Porifera (sponges) are often regarded as the oldest, extant metazoan phylum, also bearing the ancestral stage for most features occurring in higher animals. The absence of chitin in sponges, except for the wall of peculiar resistance bodies produced by a highly derived fresh-water group, is puzzling, since it points out chitin to be an autapomorphy for a particular sponge family rather than the ancestral condition within the metazoan lineage. By investigating the internal proteinaceous (spongin) skeleton of two demosponges (Aplysina sp. and Verongula gigantea) using a wide array of techniques (Fourier transform infrared (FTIR), Raman, X-ray, Calcofluor White Staining, Immunolabeling, and chitinase test), we show that chitin is a component of the outermost layer (cuticle) of the skeletal fibers of these demosponges. FTIR and Raman spectra, as well as X-ray difractograms consistently revealed that sponge chitin is much closer to the alpha-chitin known from other animals than to beta-chitin. These findings support the view that the occurrence of a chitin-producing system is the ancestral condition in Metazoa, and that the alpha-chitin is the primitive form in animals.     

甲壳质,壳聚糖在农业上的应用

本文综述了甲壳质、壳聚糖作为降解性地膜、植物生长调节剂、肥料和土壤改良剂、农药、食物保鲜剂及饲料、饵料添加剂等在农业方面的应用。     

Stability of chitin synthetase in cell-free preparations of a wild-type strain and a ''slime'' variant of Neurospora crassa

Chitin synthetase activity in cell-free preparations from a wild-type strain and a 'slime' variant of Neurospora crassa was monitored over many days in samples stored at 0 degrees C. Total activity in whole-cell-free extracts and low-speed supernatants from both organisms was very unstable, losing more than 90% of the initial activity on storage at 0 degrees C for 96 h. Chitin synthetase detection was not masked by chitinase activity present in the preparations. Gel-filtration chromatography of these preparations increased the stability of the activity from the 'slime' variant, whereas removal of particulate structures by high-speed centrifugation stabilized the chitin synthetase activity in the supernatant, particularly in the wild type. These results suggest that factor(s) involved in the regulation of chitin synthetase may be differentially located or altered in 'slime' cells.