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.     

Proteinase inhibitors from the molting fluid of the pharate adult tobacco hornworm, Manduca sexta

The molting fluid of pharate adult Manduca sexta was found to contain at least two types of proteinase inhibitor activities. One inhibited the native cuticle degrading trypsin-like proteinase, MFP1, while the other was found to be highly specific for subtilisin-like enzymes. The developmental profiles of both these inhibitor activities were investigated. MFP-1 inhibitor activity was found to be present in the molting fluid of all stages of pre-ecdysial development, except stage 7, which possessed the highest levels of MFP-1 activity. The inhibitor was estimated to have a relative molecular mass of 14.5 k and was found to be heat stable. A role in regulation of cuticle degradation is suggested. Subtilisin inhibitor activity was found in molting fluid from all eight stages of pre-ecdysial development, although there was some variation observed between the stages when inhibitor activities were visualized using PAGE zymograms. A subtilisin inhibitor was purified using Sep-Pak cartridges and Reverse Phase HPLC. The inhibitor was found to be of low relative molecular mass (11 k), heat stable, and highly specific for fungal enzymes such as PR1 from the entomopathogen Metarhizium anisopliae. Therefore, a role in insect defense is suggested. Arch Copyright 2000 Wiley-Liss, Inc.     

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.     

Cloning of a novel protease required for the molting of Locusta migratoria manilensis

Molting is required for progression between larval stages in the life cycle of an insect. The essence of insect molting is the laying down of new cuticle followed by shedding of the old cuticle. Degradation and recycling of old cuticle are brought about by enzymes present in the molting fluid, which fills the space between the old and new cuticle. Here, we describe the cloning of a novel protease gene from Locusta migratoria manilensis, designated as Lm-TSP. The cDNA and its deduced protein sequences were deposited in GenBank (accession numbers EF081255 and ABN13876, respectively). Sequence analysis indicated that Lm-TSP belongs to the trypsin-like serine protease family. We show, by RNA interference (RNAi), that silencing of Lm-TSP leads to dramatic reductions in protease and cuticle-degrading activity of a molting fluid, which leads to molting defects from fourth-instar larvae (L4) to fifth-instar larvae (L5), and between L5 and adult stages. These observations suggest that Lm-TSP plays a critical role in L. migratoria manilensis ecdysis.     

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.     

Chitin and chitinase: A kinetic model

A model is described for the action of insect molting chitinase on chitin microfibrils in cuticle. The model reconciles the disparate structures proposed for chitin in the literature. It also accounts for the kinetic characteristics of molting fluid chitinase insofar as known from in vitro studies, viz. positive co-operativity of possibly three catalytic sites, complexity, and processivity. These have hitherto been difficult to account for in vivo, given the arrangement of chitin in anhydrous microfibrils in arthropod cuticle.     

Identification of molting fluid carboxypeptidase A (MF-CPA) in Bombyx mori

Using microarray analyses, we identified carboxypeptidase A (MF-CPA), which was induced during pupal ecdysis in the wing discs of Bombyx mori. Here, we report the functional characterization of MF-CPA. MF-CPA has amino acid sequence similarities with the proteins in the carboxypeptidase A/B subfamily, from human to nematode. The MF-CPA gene is expressed during the molting periods in the epithelial tissues. MF-CPA is detected in the molting fluid, which fills the space between the old and new cuticle during molting. By Western blot analysis, we show that MF-CPA is secreted as a zymogen and processed in the molting fluid. Recombinant MF-CPA expressed in the insect cells has carboxypeptidase A activity. We propose that MF-CPA degrades the proteins from the old cuticle during the molting periods and contributes to recycling of the amino acids.     

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.     

Functional Analysis of Insect Molting Fluid Proteins on the Protection and Regulation of Ecdysis

Molting fluid accumulates between the old and new cuticles during periodical ecdysis in Ecdysozoa. Natural defects in insect ecdysis are frequently associated with melanization (an immunity response) occurring primarily in molting fluids, suggesting that molting fluid may impact immunity as well as affect ecdysis. To address this hypothesis, proteomic analysis of molting fluids from Bombyx mori during three different types of ecdysis was performed. Many proteins were newly identified, including immunity-related proteins, in each molting fluid. Molting fluids inhibited the growth of bacteria in vitro. The entomopathogenic fungi Beauveria bassiana, which can escape immune responses in feeding larvae, is quickly recognized by larvae during ecdysis, followed by melanization in molting fluid and old cuticle. Fungal conidia germination was delayed, and no hyphae were detected in the hemocoels of pharate instar insects. Molting fluids protect the delicate pharate instar insects with extremely thin cuticles against microorganisms. To explore the function of molting fluids in ecdysis regulation, based on protein similarity, 32 genes were selected for analysis in ecdysis regulation through RNAi in Tribolium castaneum, a model commonly used to study integument development because RNAi is difficult to achieve in B. mori. We identified 24 molting proteins that affected ecdysis after knockdown, with different physiological functions, including old cuticle protein recycling, molting fluid pressure balance, detoxification, and signal detection and transfer of molting fluids. We report that insects secrete molting fluid for protection and regulation of ecdysis, which indicates a way to develop new pesticides through interrupting insect ecdysis in the future.     

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.     

Functional analysis of two chitinase genes during the pupation and eclosion stages of the beet armyworm Spodoptera exigua by RNA interference

Insect chitinases are a multigene family that is encoded by a rather large and diverse group of genes. The main function of chitinases is to digest the chitin contained in tissues such as the cuticles and gut lining during molting. In this study, we examined the role of a chitinase (SeChi) and a bacterial type chitinase (SeChi-h) during the pupation and eclosion stages of Spodoptera exigua. First, efficient silencing of the SeChi and SeChi-h genes through specific double-stranded RNA (dsRNA) injection led to a significant reduction in the mRNA levels of SeChi and SeChi-h. Additionally, different phenotypic defects were observed at the pupal and adult stages after injection of the SeChi and SeChi-h dsRNAs. After injecting SeChi dsRNA in the pupal stage, the cuticle of the head split open and the pupal cuticle was visible under the old larval cuticle. However, after injecting the SeChi-h dsRNA, animals died without exhibiting any special phenotypes. At the adult death stage, animals injected with dsSeChi could not shed their pupal shell completely, and their old cuticles remained attached to their head or chest. However, the main lethal phenotype was that insects did not emerge after dsSeChi-h injection. Additionally, the average survival rates of S. exigua were 52.02% and 40.38% at the pupal and adult stages, respectively, after injection with SeChi dsRNA. For the insects injected with SeChi-h dsRNA, the survival rates were 72.38% and 48.52%, respectively. These results suggest that SeChi and SeChi-h may have different biologic functions during the pupal-adult molting.     

黄粉虫幼虫体壁硬化过程中酚氧化酶活性的变化

为研究酚氧化酶(PO)在昆虫蜕皮过程中的功能和作用, 采用微量测定法研究了黄粉虫Tenebrio molitor体壁硬化过程中血淋巴和表皮中的PO活性变化。结果表明：初蜕皮幼虫血淋巴中PO活性较高, 但随着体壁的不断黑化与硬化, 其活性呈现下降趋势, 在3～4 h内达到最低点, 而后PO活性逐渐上升, 7 h左右活性上升至最高, 并接近于正常幼虫的水平;在刚蜕完皮后的1 h内, 体壁中 PO活性基本无变化, 但随后即开始下降, 3 h左右降到最低点, 然后开始回升, 6~7 h左右恢复到正常水平, 并趋于稳定;以L-DOPA为底物, 通过双倒数曲线作图法求得黄粉虫血淋巴PO的Km＝1.176 mmol/L, 体壁PO的Km＝0.881 mmol/L, 表明体壁PO与底物L-DOPA的亲和力要高于血淋巴PO。研究表明两种来源的酚氧化酶均参与了黄粉虫幼虫的体壁硬化过程, 但在作用方式及与底物的亲和力方面存在差异。     

家蚕蜕皮液蛋白质双向电泳及质谱分析

蜕皮液是存在于新旧表皮之间的一层液体,在昆虫蜕皮和变态发育的过程中发挥了重要的作用。为进一步探究家蚕蜕皮液的功能,利用双向电泳技术对家蚕预蛹期及羽化前期的蜕皮液的蛋白质进行了分析,结果表明,预蛹期及羽化前期的蜕皮液中分别可以检测出超过200个蛋白点,它们主要分布在等电点4-9、分子量10-180 kDa之间。利用MALDI TOF/TOF对羽化前期蜕皮液的42个蛋白点进行了鉴定分析,结果表明34个蛋白点成功得到了鉴定,它们主要包括载脂蛋白类、蛋白酶与蛋白酶抑制剂、免疫相关蛋白、几丁质结合蛋白等,部分蛋白在预蛹期的蜕皮液和羽化前的蜕皮液之间存在明显的差异表达。为了进一步验证蛋白质组分析的结果,对其中1个差异表达明显的蛋白质Apolipoprotein D进行了进一步的分析,Q-PCR的结果表明,该蛋白主要在化蛹第1–4天存在高表达,其在羽化前蜕皮液中的高度累积暗示了它可能参与了家蚕羽化变态的过程。以上研究结果进一步丰富了人们对蜕皮液蛋白质的认识,为深入研究蜕皮液蛋白质的功能提供了一些参考。     

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.     

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.     

Chitinase activity in the epidermis of the fiddler crab, Uca pugilator, as an in vivo screen for molt-interfering xenobiotics

We describe an in vivo screening assay that uses epidermal chitinase activity as the endpoint following a 7-day exposure of Uca pugilator to test chemicals. Chitinase, a chitinolytic enzyme, is the end product of endocrine cascades of a multi-hormonal system for control of crustacean molting. Wherever a molt-interfering agent adversely impacts the Y-organ-ecdysteroid receptor axis, the effect should be manifested by the activity of chitinase in the epidermis. Therefore, epidermal chitinase activity is an ideal endpoint for molt-interfering effects of xenobiotics. The validity of epidermal chitinase activity being used for such a purpose is supported by our finding that two injections of 20-hydroxyecdysone at 25 microg/g live weight induced a twofold increase in chitinase activity in the epidermis of U. pugilator. A total of nine chemicals were screened for molting hormone and anti-molting activities. o,p'-DDT was found to significantly inhibit epidermal chitinase activity while kepone and methoxychlor exhibited a tendency of inhibition of enzymatic activity. None of the remaining six chemicals, namely, p,p'-dichlorodiphenyltrichloroethane (p,p'-DDT), atrazine, tributyltin (TBT), methoprene, dieldrin and permethrin, had an effect on epidermal chitinase activity.