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.     

Activation of old cuticle chitin as a substrate for chitinase in the molt of Manduca

During the molt, chitin in the old cuticle of $\text{Manduca}$ is digested by chitinase taken up from molting fluid, but the chitin in intact (= premolt) cuticle is not accessible to chitinase. As a prerequisite of digestion, old cuticle chitin is rendered competent to serve as chitinase substrate in a reaction attributable to trypsin-like proteolytic activity of molting fluid.     

Localization of molting chitinase in insect cuticle

Chitinase activity in molting larvae of Manduca sexta is localized in old cuticle; it is not quantitatively extracted during homogenization, has good activity at the pH of molting fluid, and preferentially utilizes endogenous cuticle chitin as substrate. It is concluded that cuticle chitinase is the physiologically active molting enzyme in Manduca.     

Insect group II chitinase OfChtII promotes chitin degradation during larva–pupa molting

The insect group II chitinase (ChtII, also known as Cht10) is a unique chitinase with multiple catalytic and chitin-binding domains. It has been proven genetically to be an essential chitinase for molting. However, ChtII's role in chitin degradation during insect development remains poorly understood. Obtaining this knowledge is the key to fully understanding the chitin degradation system in insects. Here, we investigated the role of OfChtII during the molting of Ostrinia furnacalis, a model lepidopteran pest insect. OfChtII was expressed earlier than OfChtI (OfCht5) and OfChi-h, at both the gene and protein levels during larva–pupa molting as evidenced by quantitative polymerase chain reaction and western blot analyses. A truncated OfChtII, OfChtII-B4C1, was recombinantly expressed in Pichia pastoris cells and purified to homogeneity. The recombinant OfChtII-B4C1 loosened compacted chitin particles and produced holes in the cuticle surface as evidenced by scanning electron microscopy. It synergized with OfChtI and OfChi-h when hydrolyzing insoluble α-chitin. These findings suggested an important role for ChtII during insect molting and also provided a strategy for the coordinated degradation of cuticular chitin during insect molting by ChtII, ChtI and Chi-h.     

Molting fluid enzymes of the tobacco hornworm,Manduca sexta: Timing of proteolytic and chitinolytic activity in relation to pre-ecdysial development

Developmental profiles for a number of molting fluid (MF) enzyme activities were established and related to the progress of pupal cuticle degradation during the four days that precede the eclosion of adult tobacco hornworms. Cuticle degrading activity, molting fluid protease 1 (MFP-1), and molting fluid protease 2 (MFP-2) all increased in activity at the time that loss of material from the old cuticle occurred. In contrast, chitinase and β-acetylglucosaminidase activities did not parallel weight loss from the old cuticle. These results are consistent with the hypothesis that proteolytic activity is a prerequisite for the action of chitinase on cuticle chitin. © 1993 Wiley-Liss, Inc.     

Molting fluid chitinase: a homotropic allosteric enzyme.

The molting fluid of the tobacco hornworm has chitinase activity which shows allosteric behavior with chitin. A parabolic curve is obtained on a double reciprocal plot of $\text{1}\text{v}$ vs. $\text{1}\text{[S]}$, and a sigmoid curve results when v (N-acetylglucosamine produced) is plotted against [S] (chitin concentration in terms of N-acetylglucosamine concentration). The Hill coefficient with insect chitin is 1.95 ± 0.08. Allostery of the chitinase enables the insect to exert additional control over the integrity of structure of its cuticle.     

Organisation of wing cuticle in Locusta migratoria linnaeus,Tropidacris cristata linnaeus and Romalea microptera beauvais (Orthoptera : Acrididae)

The composite fibrous architectures of the wing cuticles of Locusta migratoria, Tropidacris (= Eutropidacris) cristata and Romalea microptera (Orthoptera : Acrididae) have been established. The wing cuticle in all the 3 species consists of: (i) an exocuticle, which is either pigmented or birefringent, and which under an electron microscope shows constantly helicoidal architecture of chitin microfibrils; (ii) endocuticle, which shows alternately birefringent and isotropic layers when sectioned transversely across the wing veins; these layers show helicoidal and unidirectional architecture, respectively of chitin microfibrils under the electron microscope. In transverse section, the chitin microfibrils appear as clear rods (2.8 nm in diameter) in a darkly stained matrix. However, in the hinge called the “claval furrow”, these microfibrils are considerably larger, being 25 nm in diameter. This presumably gives sufficient hardness to the claval hinge, which is the most vulnerable area for wear and tear during flight. The pore canals follow the parabolic pattern of microfibrils in the helicoidal layer, but remain straight in the unidirectional layers. The thickness of wing cuticle increases up to about 10–12 days, the time at which the acridids most probably attain the optimum flight ability. It is suggested that changes in the wing cuticle are related to increased wing beat frequency and speed of flight with age, and may help in resisting the simultaneous increase in the bending and twisting forces on the wing.     

Cell culture techniques for studying insect cuticle

Evidence that biosynthetic pathways critical to the formation of insect cuticle are retained in continuous insect cell lines opens new possibilities for research on the cuticle system. Recent findings indicate that chitin, molting hormone, and catecholamines are all produced by a vesicle cell line derived from embryos of the cockroach Blattella germanica. The chitin that is formed by this cell line is particulate and does not show the characteristic featherlike crystalline structure found in mature cuticle. The molting hormone is produced as ecdysone and is released into the culture medium. The addition of 20-hydroxyecdysone to the cultures increases the production of chitin fourfold. These responses are similar to those found in insect organ cultures.     

Genome‐wide identification of chitin‐binding proteins and characterization of BmCBP1 in the silkworm,Bombyx mori

The insect cuticle plays important roles in numerous physiological functions to protect the body from invasion of pathogens, physical injury and dehydration. In this report, we conducted a comprehensive genome-wide search for genes encoding proteins with peritrophin A-type (ChtBD2) chitin-binding domain (CBD) in the silkworm, Bombyx mori. One of these genes, which encodes the cuticle protein BmCBP1, was additionally cloned, and its expression and location during the process of development and molting in B. mori were investigated. In total, 46 protein-coding genes were identified in the silkworm genome, including those encoding 15 cuticle proteins analogous to peritrophins with one CBD (CPAP1s), nine cuticle proteins analogous to peritrophins with three CBD (CPAP3s), 15 peritrophic membrane proteins (PMPs), four chitinases, and three chitin deacetylases, which contained at least one ChtBD2 domain. Microarray analysis indicated that CPAP-encoding genes were widely expressed in various tissues, whereas PMP genes were highly expressed in the midgut. Quantitative polymerase chain reaction and western blotting showed that the cuticle protein BmCBP1 was highly expressed in the epidermis and head, particularly during molting and metamorphosis. An immunofluorescence study revealed that chitin co-localized with BmCBP1 at the epidermal surface during molting. Additionally, BmCBP1 was notably up-regulated by 20-hydroxyecdysone treatment. These results provide a genome-level view of the chitin-binding protein in silkworm and suggest that BmCBP1 participates in the formation of the new cuticle during molting.     

Chitinase activity during Drosophila development

Before both larval moults in Drosophila melanogaster, the chitin in the cuticle is digested to a significant degree by the moulting fluid. A spurt of chitinase activity appears just before each ecdysis, drops sharply after the first ecdysis, and begins to rise again just about the time that chitin degradation becomes evident. The level of enzyme activity/mg of soluble protein reached just before the second ecdysis is about twice that reached before the first, and this declines gradually after the ecdysis until puparium formation. Chitinase activity is measured with a viscometric assay on a chitosan substrate.The enzyme activity is stable, with no loosely bound cofactor. Data also exist supporting the presence of more than one enzyme fraction in Drosophila with chitinase activity.     

Knickkopf and retroactive proteins are required for formation of laminar serosal procuticle during embryonic development of Tribolium castaneum

Chitin, a homopolymer of β-1-4-linked N-acetylglucosamine synthesized by chitin synthase A (Chs-A), is organized in the procuticle of the postembryonic cuticle or exoskeleton, which is composed of laminae stacked parallel to the cell surface to give stability and integrity to the underlying insect epidermal and other tissues. Our previous work has revealed an important role for two proteins from Tribolium castaneum named Knickkopf (TcKnk) and Retroactive (TcRtv) in postembryonic cuticular chitin maintenance. TcKnk and TcRtv were shown to be required for protection and organization of newly synthesized procuticular chitin. To study the functions of TcKnk and TcRtv in serosal and larval cuticles produced during embryogenesis in T. castaneum, dsRNAs specific for these two genes were injected into two week-old adult females. The effects of dsRNA treatment on ovarial integrity, oviposition, egg hatching and adult survival were determined. Insects treated with dsRNA for chitin synthase-A (TcChs-A) and tryptophan oxygenase (TcVer) were used as positive and negative controls for these experiments, respectively. Like TcChs-A RNAi, injection of dsRNA for TcKnk or TcRtv into adult females exhibited no adult lethality and oviposition was normal. However, a vast majority of the embryos did not hatch. The remaining (∼10%) of the embryos hatched into first instar larvae that died without molting to the second instar. Chitin content analysis following TcKnk and TcRtv parental RNAi revealed approximately 50% reduction in chitin content of eggs in comparison with control TcVer RNAi, whereas TcChs-A dsRNA-treatment led to >90% loss of chitin. Furthermore, transmission electron microscopic (TEM) analysis of serosal cuticle from TcChs-A, TcKnk and TcRtv dsRNA-treated insects revealed a complete absence of laminar organization of serosal (and larval) procuticle in comparison with TcVer dsRNA-treated controls, which exhibited normal laminar organization of procuticular chitin. The results of this study demonstrate that in addition to their essential roles in maintenance and organization of chitin in epidermal cuticle in larval and later stages of insect development, TcKnk and TcRtv also are required for egg hatch, chitin maintenance and laminar organization of both serosal and larval cuticle during embryonic development of T. castaneum.     

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.     

Cuticular protein LmTwdl1 is involved in molt development of the migratory locust

The cuticle, an essential structure for insects, is produced from cuticular proteins and chitin via a series of biochemical reactions. Tweedle genes are important members of the cuticular protein family and have four conserved motifs binding to chitin. Tweedle family genes have been found to play a profound effect on cuticle development. Here, we report that the cuticular protein gene LmTwdl1 of Locusta migratoria belongs to the Tweedle family. In situ hybridization showed that LmTwdl1 is localized to epidermal cells of the cuticle. The expression patterns of LmTwdl1 showed low expression in the cuticle during the early and middle stages of the fifth‐instar nymphs; in contrast, its expression rapidly increased in the late stages of fifth‐instar nymphs. We performed RNA interference to examine the function of LmTwdl1 in locusts. Silencing of LmTwdl1 resulted in high mortality during the molting process before the next stage. Also, the epicuticle of nymphs failed to molt, tended to be thinner and the arrangement of chitin in the procuticle appeared to be disordered compare to the control group. These results demonstrate that LmTwdl1 plays a critical role in molting, which contributes to a better understanding of the distinct functions of the Tweedle family in locusts.     

Degradation of cuticle during larval-pupal and pupal-adult development of the housefly, Musca domestica

Abstract. The patterns of changes in cuticle weight, its chitin content and chitinase activity have been studied during postembryonic development of the housefly, Musca domestica L. During pupariation the larval cuticle loses weight. During the early part of this weight-loss the decline in chitin content parallels the overall change in cuticle weight. A simultaneous elevation in chitinase activity suggests that at this time the larval cuticle is being enzymatically degraded. Later weight loss may be due to sclerotization. No significant changes in cuticle weight or its chitin content occur in pharate cuticle until one day before eclosion. However, a peak of chitinase activity found at mid-late pupal stage suggests the timing of pupal cuticle breakdown.     

Cloning and expression analysis of the chitinase gene Ifu-chit2 from Isaria fumosorosea

Entomopathogenic fungi can produce a series of chitinases, some of which function synergistically with proteases and other hydrolytic enzymes to degrade the insect cuticle. In the present study, the chitinase gene Ifu-chit2 from Isaria fumosorosea was investigated. The Ifu-chit2 gene is 1,435-bp long, interrupted by three short introns, and encodes a predicted protein of 423 amino acids with a 22 residue signal peptide. The predicted Ifu-Chit2 protein is highly homologous to Beauveria bassiana chitinase Bbchit2 and belongs to the glycohydrolase family 18. Ifu-Chit2 was expressed in Escherichia coli to verify chitinase activity, and the recombinant enzyme exhibited activity with a colloidal chitin substrate. Furthermore, the expression profiles of Ifu-chit2 were analyzed at different induction times under in vivo conditions. Quantitative real-time PCR analysis revealed that Ifu-chit2 expression peaked at two days post-induction. The expression of chitinase Ifu-chit2 in vivo suggests that the chitinase may play a role in the early stage of pathogenesis.