Effect of 20-hydroxyecdysone and diflubenzuron on chitin production by a cockroach cell line

Summary Twelve insect cell lines were tested for their ability to synthesize chitin. Three of the 7 lepidopteran lines tested (UMN-PIE, IAL-PID2, MRRL-CH) produced a hyamine-resistant material, that was digested by chitinase. The material did not withstand a more rigorous base digestion, and 20-hydroxyecdysone and diflubenzuron had no consistent effect on the production of the, material. One of the 5 cockroach cell lines (UMBGE-4), which is an ecdysone-producing vesicle line, produced a material resistant to a strong base which was degraded to chitobiose andN-acetylglucosamine by chitinase. Production of this material by the cells is increased by 20-hydroxyecdysone and inhibited by diflubenzuron. The UMBGE-4 vesicles are covered with microvilli which bear membrane plaques and produce extra cellular material that resembles insect cuticle. Published with the approval of the Director of the North Dakota Agricultural Experiment Station as journal article No. 1622. Mention of a company name or propiertary product does not imply endorsement, by the U.S. Department of Agriculture.     

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.     

Some Effects of Diflubenzuron on Growth and Sporogenesis in Streptomyces spp

Diflubenzuron, an insect growth regulator that blocks chitin deposition in insect cuticles, was tested for its effects on morphogenesis of Streptomyces spp. Use of diflubenzuron resulted in reduced dominance of spore hairs, reduced the width of the outer wall, and prevented formation of the inner spore wall in S. bambergiensis. In S. coelicolor, diflubenzuron altered the structure of the fibrillar pattern of spore envelopes. Exposure to diflubenzuron resulted in small increases in exported protein and in a ca. 20% increase in chitinase in both Streptomyces spp.     

Chitinase activity from Candida albicans and its inhibition by allosamidin

Candida albicans chitinase isolated using the Dyno-Mill disruption technique was characterized using an improved radiometric assay procedure. The enzyme had apparent temperature and pH optima of 45 degrees C and 6.5, respectively. The preparation yielded an apparent Km of 3.9 mg chitin ml-1 [17.6 mM-N-acetylglucosamine (GlcNAc) equivalents] and V of 2.3 nmol GlcNAc formed min-1 (mg protein)-1. The potential of the streptomycete antibiotic allosamidin as an antifungal agent is discussed in view of its dose-dependent inhibition of C. albicans chitinase activity (IC50 = 0.3 microM). Allosamidin was a potent competitive inhibitor of enzyme activity (Ki = 0.23 microM).     

Chitin in the peritrophic membrane of Acarus siro (Acari: Acaridae) as a target for novel acaricides

The peritrophic membrane in Acarus siro L. (Acari: Acaridae) is produced by distinct cells located in the ventriculus. In this study, the chitin inside the peritrophic membrane was detected using wheat germ-lectin conjugated with colloidal gold (10 nm). The chitin fibrils of the peritrophic membrane were a target for chitin effectors, including 1) chitinase, which hydrolyzes chitin fibers inside the peritrophic membrane; 2) calcofluor, which binds to chitin and destroys the peritrophic membrane mesh structure; and 3) diflubenzuron, which inhibits chitin synthesis. In addition, soybean trypsin protease inhibitor (STI) and cocktails of chitinase/calcofluor, diflubenzuron/calcofluor and chitinase/STI were tested. These compounds were supplemented in diets and an increase of population initiated from 50 individuals was observed after 21 d of cultivation. Final A. siro densities on experimental and control diets were compared. The chitin in the peritrophic membrane was determined to be a suitable target for novel acaricidal compounds for suppressing the population growth of A. siro. The most effective compounds were calcofluor and diflubenzuron, whereas the suppressive effects of chitinase and STI were low. The failure of chitinase could be due to its degradation by endogenous proteases. The combination of chitinase and STI suppressed A. siro population growth more effectively than when they were tested in oral admission separately. The combinations of calcofluor/chitinase or calcofluor/difluorbenzuron showed no additive effects on final A. siro density. The presence of chitin in peritrophic membrane provides a target for novel acaricidal compounds, which disrupt peritrophic membrane structure. The suitability of chitin effectors and their practical application in the management of stored product mites is discussed.     

Analysis of chitin structure by nuclear magnetic resonance spectroscopy and chitinolytic enzyme digestion

Solid-state 13C-NMR analysis of chitin prepared from cuticle of the tobacco hornworm, Manduca sexta (L.), and of crab yielded spectra that demonstrate a high degree of chemical homogeneity (greater than 95%) for the preparations. The chemical shifts of the well-resolved carbon signals from both samples matched closely those of the monomeric unit 2-acetamido-2-deoxy-D-glucopyranoside (GlcNAc). Chromatographic analysis of products from the digestion of chitin by the binary chitinase system (endo splitting chitinase and exo splitting beta-N-acetylglucosaminidase) isolated from M. sexta molting fluid showed that the major product from both chitin preparations is GlcNAc. Also detected was a minor product (product U) that had a chromatographic retention time on the carbohydrate analysis column intermediate between those of chitin penta- and hexasaccharides. Gel filtration chromatography of U indicated that U had an apparent molecular weight intermediate between that of GlcNAc and of N,N'-diacetylchitobiose. Cation-exchange chromatography of U after acid hydrolysis revealed the presence of glucosamine only. Derivatization with trinitrobenzenesulfonate showed the presence of a free amino group in U. Solution proton and carbon NMR spectroscopy were used to identify U as a N-monoacetylchitobiose [O-beta-D-2-amino-2-deoxyglucopyranosyl- (1----4)-2-acetamido-2-deoxy-beta-D-glucopyranose] with the residue at the nonreducing end deacetylated. These studies showed that chitin prepared from alkali- and heat-treated insect or crab cuticle contains trace levels of deacetylated residues that are released as a dead-end product, N-monoacetylchitobiose, after digestion by the binary enzyme system.     

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.     

Biochemical characterization of chitin synthase activity and inhibition in the African malaria mosquito,Anopheles gambiae

Abstract Chitin synthase (CHS) is an important enzyme catalyzing the formation of chitin polymers in all chitin containing organisms and a potential target site for insect pest control. However, our understanding of biochemical properties of insect CHSs has been very limited. We here report enzymatic and inhibitory properties of CHS prepared from the African malaria mosquito, Anopheles gambiae. Our study, which represents the first time to use a nonradioactive method to assay CHS activity in an insect species, determined the optimal conditions for measuring the enzyme activity, including pH, temperature, and concentrations of the substrate uridine diphosphate N‐acetyl‐d ‐glucosamine (UDP‐GlcNAc) and Mg⁺⁺. The optimal pH was about 6.5–7.0, and the highest activity was detected at temperatures between 37°C and 44°C. Dithithreitol is required to prevent melanization of the enzyme extract. CHS activity was enhanced at low concentration of GlcNAc, but inhibited at high concentrations. Proteolytic activation of the activity is significant both in the 500 ×g supernatant and the 40 000 ×g pellet. Our study revealed only slight in vitro inhibition of A. gambiae CHS activity by diflubenzuron and nikkomycin Z at the highest concentration (2.5 μmol/L) examined. There was no in vitro inhibition by polyoxin D at any concentration examined. Furthermore, we did not observe any in vivo inhibition of CHS activity by any of these chemicals at any concentration examined. Our results suggest that the inhibition of chitin synthesis by these chemicals is not due to direct inhibition of CHS in A. gambiae.     

Some Effects of Diflubenzuron on Growth and Sporogenesis in Streptomyces spp.

Diflubenzuron, an insect growth regulator that blocks chitin deposition in insect cuticles, was tested for its effects on morphogenesis of Streptomyces spp. Use of diflubenzuron resulted in reduced dominance of spore hairs, reduced the width of the outer wall, and prevented formation of the inner spore wall in S. bambergiensis. In S. coelicolor, diflubenzuron altered the structure of the fibrillar pattern of spore envelopes. Exposure to diflubenzuron resulted in small increases in exported protein and in a ca. 20% increase in chitinase in both Streptomyces spp.     

Microsomal chitinase activity from Candida albicans

Chitinase (E.C. 3.2.1.14) was characterized in microsomal fractions from yeast cells of Candida albicans. Following six washes with buffer (50 mM Bis-Tris.Cl, pH 6.5), enzyme activity of microsomes fell markedly to 0.3% of total and 6% of the specific activity detected in the low-speed supernatant (9000 X g) of a cell lysate. An apparently zymogenic, microsomal chitinase activity became more readily detectable with washing and after six washes enzyme activity was activated 1.7-fold following pre-incubation with trypsin. The following properties of microsomal chitinase were closely comparable with those for cytosolic chitinase (indicated in parentheses): Km = 2.1 mg chitin per ml (2.9 mg chitin per ml); temperature optimum = 45 degrees C (45 degrees C); inhibition by allosamidin competitive, Ki = 0.29 microM (competitive, Ki = 0.23 microM). A range of detergents solubilized and activated microsomal chitinase in a highly specific manner. Following density gradient centrifugation of microsomes, chitinase was distributed approximately evenly throughout the gradient suggesting that microsomal chitinase is not associated exclusively with any one membrane component. The possible morphogenetic role of microsomal chitinase is discussed in relation to the potential of this enzyme as a target for highly specific antifungal agents.     

Some Properties of Unpurified Chitinase from the Crayfish Plague Fungus, Aphanomyces astaci

The culture filtrate of the crayfish plague fungus, Aphanomyces astaci (Saprolegniaceae), incubated in a peptone glucose medium was tested for chitinase activity under different conditions. The activities were assayed turbidimetrically using low-polymerized chitin as a substrate. Adsorption of chitinase was found to occur on chitin and probably on cellulose and sulphomethyl cellulose but not at all or only a little on some other cellulose derivatives. The pH optimum of the enzyme activity was found to lie at about pll 5.0–5.5. The stability was greatest near pH 6.5 and the highest degree of adsorption occurred at still higher pH values. Enzyme adsorption on the substrate seemed to protect the enzyme against inactivation by heating, shaking, and extreme pH-conditions. The chitinase activity was positively affected by the rest of the culture filtrate. Mercury, cobalt, and copper chlorides, and to a lesser degree some other metal salts, lowered the enzyme activity when present in the test medium. Cellobiose, but neither glucose nor N-acetyl glucosamine had a pronounced inhibiting effect on the activity. Neither cellobiose nor N-acetyl glucosamine seemed to affect chitinase adsorption on chitin. Some chelating and reducing compounds inactivated the culture filtrate. This activity-reducing effect of chelators was strongly prevented by EDTA in some cases.     

Kinetic analysis of a chitinase from red sea bream, Pagrus major

Kinetic analysis was done on the 46-kDa chitinase (EC 3.2.1.14) purified from the stomach of red sea bream, Pagrus major, using glycolchitin and N-acetylchitooligosaccharides (GlcNAc(n), n=2-6) as substrates. High activity was observed at two pHs, such as 2.5 and 9.0, toward glycolchitin as seen in other insect chitinases, and also at both pH 2.5 and 5.0 even toward a short substrate, N-acetylchitopentasaccharide. Allosamidin competitively inhibited chitinase with Ki value of 0.0214 microM at pH 2.5 and 0.0024 microM at pH 9.0 in the reaction of glycolchitin. Substrate inhibition was observed in the reaction of N-acetylchitopentasaccharide. The anomeric forms of the products from N-acetylchitooligosaccharides were analyzed to be beta anomer by the high pressure liquid chromatography (HPLC) method. The data for both beta-anomer formation and allosamidin inhibition suggest that red sea bream chitinase belongs to family 18 of glycosyl hydrolases. This suggestion is also supported by the results for the N-terminal amino acid sequence.     

Incorporation of [14C]glucosamine into synaptosomes in vitro

Abstract— Synaptosomes isolated from rat cerebral cortex by zonal centrifugation in-corporated radioactive glucosamine into macromolecules in vitro as glucosamine, galactosamine, N-acetylneuraminic acid, and glucuronic acid. The largest percentage of incorporated radioactivity was recovered in the particulate fraction in which radioactive carbohydrates were bound in covalent linkage requiring acid hydrolysis or enzymatic digestion for release. Less than 20 per cent of the particulate radioactivity represented incorporation into gangliosides. Some 20 per cent of the radioactivity was incorporated into proteins as glucosamine, identified in hydrolysates by paper chromatography and by the amino acid analyser. After incubation, radioactivity was demonstrable in the proteins as sialic acid by paper chromatography and specific enzymic digestion; and as glucuronic acid by chromatography, electrophoresis, and digestion with hyaluronidase. Incorporation of carbohydrate was stimulated by sodium and potassium at concentrations demonstrated to enhance incorporation of amino acids, and involved the macro-molecules of all subsynaptosomal fractions. Significant incorporation of radioactivity was found in the synaptic plasma membrane. The synthesis of glycoproteins was suggested by simultaneous incorporation of [¹⁴C]glucosamine and [³H]leucine into glycopeptides subsequently hydrolysed and subjected to polyacrylamide gel electrophoresis and two-dimensional paper chromatography and electrophoresis. Such studies demonstrated that amino acids and carbohydrates may be incorporated into glycoproteins of the synaptic membrane and suggest the possibility of local synthesis as well as modification of material brought to the nerve ending by axoplasmic flow.     

Biochemistry of insect differentiation: A system for studying the mechanism of chitinase activity in vitro

Results obtained with an in vitro system for the study of chitinase are described. The system involves soluble enzyme protein(s) and an insoluble substrate preparation. With insect molting fluid chitinase, it shows properties that parallel those observed during in vivo breakdown of cuticle during the molt. For example, molting fluid chitinase activity not previously exposed to chitin is stronly and specifically adsorbed to the substrate, in contrast to other enzymatic activities including hexosaminidase (chitobiase) present in molting fluid. This leads to partial purification of molting fluid chitinase activity reflected in increased specific activity of chitinase associated with the insoluble chitin substrate; we have previously reported increase of specific chitinase activity of (deproteinized) cuticle resulting from its incubation with molting fluid (M. L. Bade and A. Stinson, 1978, Biochem. Biophys. Res. Commun.84, 381–388). Soluble end product is generated rapidly and linearly with time by the in vitro system; the end product is assumed to be N-acetylglucosamine since the specific radioactivity of this compound is unchanged during the 10 min required for assay. Molting fluid chitinase activity may involve a number of polypeptides ranging in molecular weight from 145,000 to less than 20,000 daltons. The system described gives results consistent with a processive mechanism for molting fluid chitinase, i.e., data are given demonstrating that molting fluid chitinase continues to act on the same chitin particle(s) with which it initially associates rather than diffusing freely from substrate particle to substrate particle, and the product of its action appears to be a monosaccharide rather than a mixture of oligosaccharides. Processive behavior for chitinase would be predicted from the known structure, and the in vivo measured rate of breakdown, of cuticle chitin during the molt; the preliminary nature of this conclusion, based on what is so far known about the structure of the substrate used in the in vitro system, is briefly discussed.     

Polyamine synthesis in mammalian tissues. Isolation and characterization of spermine synthase from bovine brain

Spermine synthase, a propylamine transferase, which catalyses the biosynthesis of spermine from S-methyladenosylhomocystemine and spermidine has been purified to an apparent homogeneity (about 6000-fold) from bovine brain using spermine-Sepharose affinity chromatography. The enzyme preparation was free from S-adenosylmethionine decarboxylase and spermidine synthase activities. The molecular Stokes radius of the enzyme was calculated to be 4.16 nm. The enzyme has an apparent molecular weight of approximately 88 000, composing of two subunits of equal size. The enzyme showed a broad pH optimum between 7.0 and 8.0 and an acidic isoelectric point at pH 5.10. The apparent Km values for S-methyladenosylhomocysteamine was 0.6 microM and about 60 microM for spermidine. The enzyme showed strict specificity to spermidine as the propylamine acceptor. Both the reaction products, spermine and 5'-methylthioadenosine inhibited the enzyme activity, methylthioadenosine being a powerful competitive inhibitor with respect to S-methyladenosylhomocysteamine (Ki value of about 0.3 microM). Putrescine also inhibited competitively with respect to spermidine (Ki value of about 1.7 mM). Spermine synthase had no requirements for metal or other cofactors.     

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.     

Cell Walls and Lysis of Mortierella parvispora Hyphae

Walls of Mortierella parvispora, Pullularia pullulans, Absidia repens, Fusarium oxysporum, and of several Penicillium species varied in their susceptibilities to digestion by glucanase and chitinase. Polysaccharides were present in the residues remaining after enzymatic digestion. Acid hydrolysates of the walls contained glucose, glucosamine, and a small amount of galactose. The walls of M. parvispora, which also contained fucose, were the least digested by these two enzymes. Much of the M. parvispora wall material was resistant to decomposition by a heterogeneous soil community, and viable hyphae were not lysed by a glucanase-chitinase mixture. Walls of this fungus were fractionated, and the chemical composition of the fractions was determined. The chitin which was abundant in one of the fractions was apparently largely shielded from chitinase hydrolysis by a glucan. The ecological significance of these findings is discussed.     

Effects of carbon and nitrogen sources on the induction and repression of chitinase enzyme from<Emphasis Type="Italic">Metarhizium anisopliae</Emphasis> isolates

Metarhizium anisopliae, an entomopathogenic hyphomycete, is being used effectively in Integrated Pest Management (IPM) system. Foliar application of these fungi is quite satisfactory as it invades its host by adhering to insect cuticles and formation of penetration structures called appresoria, which produces various extracellular enzymes, including chitinase that causes the insect cuticle breaching. The induction and repression mechanism of chitinase activity is not entirely understood and activity of this enzyme is different in response to different carbon and nitrogen sources. This report illustrates the effect of two carbon sources viz. colloidal chitin and dextrose and a nitrogen source, yeast extract on the chitinase production of fourteenM. Anisopliae isolates. The chitinase activity varied among the isolates and the different media used. A high enzymatic activity was observed in the medium containing an extra nitrogen source (yeast extract) followed by the medium containing colloidal chitin as a sole source of carbon and nitrogen. The exochitinase activity and the chitinase activity gel were also studied for the isolates showing high chitinase enzyme production. An array of chitinase isozymes were observed on chitinase activity gel with a common 14.3 kDa enzyme for all the isolates.     

Effect of Bombyx mori chitinase against Japanese pine sawyer (Monochamus alternatus) adults as a biopesticide

Bombyx mori chitinase (Bm-CHI), with a molecular mass of 75 kDa, was investigated on the possibility that it can serve as a biocontrol agent against the adult Japanese pine sawyer (JPS), Monochamus alternatus (Coleoptera: Cerambycidae). Oral ingestion of purified chitinase at concentrations of 3 microM (11.25 microg/50 microl) and 0.3 micoM (1.125 microg/50 microl) caused high mortality in JPS, a significant decrease in bark consumption, and, only in high concentration, a slight reduction of body weight. Fluorescence assays indicated that peritrophic membrane (PM) chitin is degraded by the action of orally ingested Bm-CHI at 3 microM concentration only. Scanning electron micrographs clearly indicated that the beetles that ingested Bm-CHI of the same high concentration had their PM perforated and disrupted, but ultrastructural studies showed that the ingested chitinase did not affect the midgut epithelium. These findings open up the possibility of using insect chitinase as a biopesticidal enzyme. It should have agronomic potential for insect control.