Epidermal collagenase activity and its induction by 20-hydroxyecdysone in the fiddler crab Uca pugilator

The epidermal collagenase activity and its induction by 20-hydroxyecdysone in Uca pugilator were investigated.Zymographic electrophoresis showed four bands of collagenae activity,16,19,22 and 29 kDa in molecular weight,with the former two accounting for 60% and 36%,respectively,of the total coUagenase activity. The collagenase activity varies during the molting cycle. Among the molt stages tested,Premoh Stage Do exhibited the highest epidermal coUagenase activity for both the 16 and 19 kDa isoenzymes and,as the molt stage proceeded,the enzymatic activity of these two isoenzymes decreased,with the lowest activity for both found in Premoh Stage D3-4. Injection of 20-hydroxyecdysone significantly induced the activity of the 16 kDa collagenase in the epidermis of Uca pugilator,suggesting that the activity of this isoenzyme is under molting hormone control.Although 20-hydroxyecdysone injection did not result in a statistically significant increase in the activity of the 19 kDa isocnzyme,a tendency of the induction was nonetheless demonstrated. This is the first report on epidermal collagenase activity and its induction by the molting hormone in a crustacean.     

Changes in integument histology and protein expression related to the molting cycle of the black tiger shrimp, Penaeus monodon

We investigated changes in the histology and protein expression in the epidermis and sub-epidermis of the black tiger shrimp (Penaeus monondon) during the molting cycle. The epidermis consists of a cell layer located beneath the cuticle, while the sub-epidermis is mainly composed of sub-epidermal cells and tegumental glands. During the molting cycle, the epidermal cells increase in cell height and number, and the sub-epidermis increases in its storage of carbohydrate, protein, mucus, and other unidentified substances at the time of the active period of cuticular regeneration. At the early premolt (stage D0), the epidermal cells are tidily organized, but short. Storage of carbohydrate and protein in the sub-epidermis is not observed. During the rest of the premolt (D1-4 stages) and the early postmolt A stage, epidermal cell height and sub-epidermal deposition are increased, and reached a maximum during the D4 to A stages. The period of late postmolt stages B-C3 is the time for a decrease in epidermal cell height and sub-epidermal depositions. Lastly at intermolt stage C4, the epidermal cells become short, and untidily organized. Sub-epidermal deposition is not observed. Protein expression in the epidermis and sub-epidermis was observed by SDS-PAGE. This revealed that the profile of a protein band with a molecular mass of 57 kDa corresponded with the profile observed by histochemistry. All results point to the conclusion that both the epidermis and sub-epidermis play major roles in cuticular regeneration. It may also reflect the level of metabolic activity of the integument during the molting cycle. In addition, for the first time, this work provides direct evidence of the epidermal and sub-epidermal changes that occur during the molting cycle of the black tiger shrimp.     

Expression and functions of dopa decarboxylase in the silkworm, Bombyx mori was regulated by molting hormone

Insect molting is an important developmental process of metamorphosis, which is initiated by molting hormone. Molting includes the activation of dermal cells, epidermal cells separation, molting fluid secretion, the formation of new epidermis and old epidermis shed and other series of continuous processes. Polyphenol oxidases, dopa decarboxylase and acetyltransferase are necessary enzymes for this process. Traditionally, the dopa decarboxylase (BmDdc) was considered as an enzyme for epidermal layer’s tanning and melanization. This work suggested that dopa decarboxylase is one set of the key enzymes in molting, which closely related with the regulation of ecdysone at the time of biological molting processes. The data showed that the expression peak of dopa decarboxylase in silkworm is higher during molting stage, and decreases after molting. The significant increase in the ecdysone levels of haemolymph was also observed in the artificially fed silkworm larvae with ecdysone hormone. Consistently, the dopa decarboxylase expression was significantly elevated compared to the control. BmDdc RNAi induced dopa decarboxylase expression obviously declined in the silkworm larvae, and caused the pupae appeared no pupation or incomplete pupation. BmDdc was mainly expressed and stored in the peripheral plasma area near the nucleus in BmN cells. In larval, BmDdc was mainly located in the brain and epidermis, which is consisted with its function in sclerotization and melanization. Overall, the results described that the dopa decarboxylase expression is regulated by the molting hormone, and is a necessary enzyme for the silkworm molting.     

Phenol oxidase is a necessary enzyme for the silkworm molting which is regulated by molting hormone

Insect molting is an important developmental process of metamorphosis, which is initiated by molting hormone. The molting process includes the activation of dermal cells, epidermal cells separation, molting fluid secretion, the formation of new epidermis and old epidermis excoriation etc. Polyphenol oxidases (PPOs), dopa decarboxylase and acetyltransferase are necessary enzymes for this process. Traditionally, the phenol oxidase was considered as an enzyme for epidermal layer’s tanning and melanization. This work suggested that polyphenol oxidases are one set of the key enzymes in molting, which closely related with the role of ecdysone in regulation of molting processes. The data showed that the expression peak of phenol oxidase in silkworm is higher during molting stage, and decreases after molting. The significant increase in the ecdysone levels of haemolymph was observed in the artificially fed silkworm larvae with ecdysone hormone. Consistently, the phenol oxidase expression was significantly elevated compared to the control. PPO1 RNAi induced phenol oxidase expression obviously declined in the silkworm larvae, and caused the pupae incomplete pupation. Overall, the results described that the phenol oxidase expression is regulated by the molting hormone, and is a necessary enzyme for the silkworm molting.     

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.     

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.     

Temporal,spatial and induced expression of chitinase in the spruce budworm,Choristoneura fumiferana

Temporal, spatial and induced expression of Choristoneura fumiferana chitinase (CfChitinase) was studied using immunohistochemistry and Western blots. CfChitinase was detected in the integument, the midgut peritrophic membrane, the cuticular lining of the trachea, the spiracle, and salivary glands. The enzyme was expressed as larvae were preparing to molt from one instar to the next. The spatial and temporal expression patterns are consistent with its function in degrading chitin during the molting process. The 20-hydroxyecdysone agonist, tebufenozide (RH5992), induced the expression of the CfChitinase gene in the early stage of the sixth-instar larvae and the enzyme was detected in the epidermis and molting fluid 24 h post treatment.     

A mechanism of action for the inhibition of black pigment dispersion in the fiddler crab, Uca pugilator, by naphthalene

The polycyclic aromatic hydrocarbon, naphthalene, inhibits the circadian dispersion of epidermal black pigment in the fiddler crab, Uca pugilator, by inhibiting the release of black pigment dispersing hormone. Naphthalene caused no permanent neural damage in Uca pugilator. Naphthalene did not cause a chemically-induced phase shift in the circadian rhythm of black pigment dispersion but reduced the daytime peak of that dispersion. Black pigment concentration, which occurs at night, was not affected by exposure to naphthalene. Black pigment dispersing hormone in naphthalene-exposed crabs can be released by an injection of norepinephrine. Given the points above, and previously published data, it is concluded that naphthalene inhibits circadian black pigment dispersion in Uca pugilator by inhibiting the release of the neurotransmitter, norepinephrine.     

Chitin synthase A: a novel epidermal development regulation gene in the larvae of Bombyx mori

Chitin synthase is the key regulatory enzyme for chitin synthesis and excretion in insects, as well as a specific target of insecticides. The chitin synthase A gene (BmChsA) cloned from Bombyx mori, the model species of lepidopteran, is an epidermis-specific expressed gene during the molting stage. Knockdown BmChsA gene in 3rd instar larvae increased the number of non-molting and abnormal molting larvae. Exposure to nikkomycin Z, a chitin synthase inhibitor downregulated the expression of BmChsA and decreased the amount of epidermis chitin during the molting process. The thickness of the new epidermis and its dense structure varied greatly. The exogenous hormones significantly upregulated the expression of BmChsA with low levels of endogenous MH and high levels of endogenous JH immediately after molting. With low levels of endogenous hormones during the mulberry intake process, BmChsA was rarely upregulated by exogenous hormones. With high levels of endogenous MH and low levels of endogenous JH during the molting stage, we did not detect the upregulation of BmChsA by exogenous hormones. The expression of BmChsA was regulated by endocrine hormones, which directly affected the chitin synthesis-dependent epidermal regeneration and molting process.     

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.     

The BmChi-h gene, a bacterial-type chitinase gene of Bombyx mori, encodes a functional exochitinase that plays a role in the chitin degradation during the molting process

The silkworm, Bombyx mori, has been recently demonstrated to contain a bacterial-type chitinase gene (BmChi-h) in addition to a well-characterized endochitinase gene (BmChitinase). The deduced amino acid sequence of BmChi-h showed extensive structural similarities with chitinases from bacteria such as Serratia marcescens chiA and baculoviruses (v-CHIA). Bacterial-type chitinase genes have not been found from any eukaryotes and viruses except for lepidopteran insects and lepidopteran baculoviruses. Thus, it was suggested that BmChi-h may be derived from a bacterial or baculovirus chitinase gene via horizontal gene transfer. In this report, we investigated the biological function of BmChi-h. Our enzymological study indicated that a chitinase encoded by BmChi-h has exo-type substrate preference, which is the same as S. marcescens chiA and v-CHIA, and different from BmChitinase, which has endo-type substrate preference. An immunohistochemical study revealed that BmChi-h localizes in the chitin-containing tissues during the molting stages, indicating that it plays a role in chitin degradation during molting. These results suggest that BmChi-h (exochitinase) and BmChitinase (endochitinase) may catalyze a native chitin by a concerted mechanism. Cloning and comparison of BmChi-h orthologues revealed that bacterial-type chitinase genes are highly conserved among lepidopteran insects, suggesting that the utilization of a bacterial-type chitinase during the molting process may be a general feature of lepidopteran insects.     

Summer molting of bowhead whales <Emphasis Type="Italic">Balaena mysticetus</Emphasis> Linnaeus, 1758, of the Okhotsk Sea population

In bowhead whales summering in Ulbanskiy Bay of the Okhotsk Sea, molting of epidermis has been found and histologically confirmed. The outer layer of the molting whale epidermis is longitudinally stratified and rejected in the form of relatively large plates up to several millimeters thick, each representing a lamellar formation consisting of longitudinal rows of parakeratocytes with degenerated nuclei, numerous pigment granules, and lipid inclusions. Molting intensity is correlated with the level of proliferation and regeneration of all epidermal layers, which helps to maintain the optimal skin thickness.     

Epidermal Molting in the Bowhead Whale <Emphasis Type="Italic">Balaena mysticetus</Emphasis>

Epidermal molting in the bowhead whales that regularly enter Ulbanskiy Bay of the Sea of Okhotsk in summer has been reported and proven by histological methods. Longitudinal delamination and detachment of thin or thick sheets of a considerable area have been established for the surface layer (stratum externum) of the whale epidermis during molting. A correlation of molting intensity to the level of proliferation and regeneration of all epidermal layers has been noted and assumed to stabilize the thickness of the skin. The phenomenon of molting is discussed from the viewpoint of adaptation of the whales to the conditions of the shallow bays of the Sea of Okhotsk that warm up thoroughly in the summer.     

A dominant-negative form of p63 is required for epidermal proliferation in zebrafish

Epidermal stem cells play a critical role in producing the multilayered vertebrate skin. Products of the p63 gene not only mark the epidermal stem cells, but also are absolutely required for the formation of mammalian epidermis. We find that early zebrafish embryos express a dominant-negative form of p63 (DeltaNp63), which accumulates in the nucleus just as epidermal growth begins. Using antisense morpholino oligonucleotides, we show that DeltaNp63 is needed for epidermal growth and limb development and is specifically required for the proliferation of epidermal cells by inhibiting p53 activity. While the structure of fish epidermis is very different from that of higher vertebrates, our study shows that DeltaNp63 has essential and ancient role in the development of skin.     

Impacts of xenobiotics on crustacean molting: the invisible endocrine disruption

Aquatic pollution has led to the accumulation of various xenobioticsin crustaceans. A number of these environmental chemicals havebeen found to interfere with molting of crustaceans. Resultsof initial mechanistic studies with Uca pugilator suggest thatthe disruption of molting results from the disturbance to theY-organ-ecdysteroid receptor (EcR) axis by xenobiotics. Suchdisturbance to the Y-organ-EcR axis can be caused by interferencewith epidermal ecdysteroid signaling and/or alterations in ecdysteroidogenesisand/or ecdysteroid disposition. Because the adverse impactson crustacean molting cannot be readily seen in the wild, thedisruption of molting represents an invisible form of endocrinedisruption.     

Suppression of the powdery mildew pathogen by chitinase microinjected into barley coleoptile epidermal cells

An exogenous chitinase from Streptomyces griseus was introduced into coleoptile epidermal cells of barley (Hordeum vulgare) by microinjection, and the effect of injected chitinase on the growth or development of the powdery mildew pathogen (Erysiphe graminis f. sp. hordei) was examined. Prior to microinjection, an enzymatic degradation of fungal haustorium, the organ taking nutrients from host plant cells, was examined by treating fixed coleoptile epidermis harboring haustoria with this enzyme. The result showed that haustoria were effectively digested by chitinase, suggesting the effectiveness of chitinase treatment for suppressing the fungal development. Microinjection of chitinase was conducted using living coleoptile tissues inoculated with the pathogen. Epidermal cells in which the haustorial primordia had been formed, or in which the haustoria had matured, were selected as targets for injection. The result clearly indicated that injection at the stage of primordium formation was effective in completely digesting haustoria and suppressing the subsequent formation of secondary hyphae of the pathogen. In microinjection after haustorial maturation, hyphal elongation was considerably suppressed though there was no detectable morphological change in the haustoria. Thus, the present study provides the experimental basis for genetically manipulating barley to produce transgenic plants resistant to the powdery mildew disease.     

Molting and cuticle deposition in the subterranean trichoniscid Titanethes albus (Crustacea, Isopoda)

Terrestrial isopods are a suitable group for the study of cuticle synthesis and calcium dynamics because they molt frequently and have evolved means to store calcium during molt. Little data is currently available on molting in Synocheta and subterranean isopods. We studied the molting dynamics in the subterranean trichoniscid Titanethes albus under laboratory conditions and performed a microscopic investigation of sternal CaCO(3) deposits and the tergal epithelium during molt in this species. In accordance with its lower metabolic rate, molting in the laboratory is roughly 2-3 times less frequent in Titanethes albus than would be expected for an epigean isopod under similar conditions. Animals assumed characteristic postures following the molt of each body half and did not consume the posterior exuviae after posterior molt. The structure of sternal calcium deposits and the ultrastructural characteristics of the epidermis during cuticle formation in Titanethes albus are similar to those described in representatives of Ligiidae. During the deposition of the exocuticle, the apical plasma membrane of epidermal cells forms finger-like extensions and numerous invaginations. In the ecdysial space of individuals in late premolt we observed cellular extensions surrounded by bundles of tubules.     

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.     

Properties of catalytic,linker and chitin-binding domains of insect chitinase

Manduca sexta (tobacco hornworm) chitinase is a glycoprotein that consists of an N-terminal catalytic domain, a Ser/Thr-rich linker region, and a C-terminal chitin-binding domain. To delineate the properties of these domains, we have generated truncated forms of chitinase, which were expressed in insect cells using baculovirus vectors. Three additional recombinant proteins composed of the catalytic domain fused with one or two insect or plant chitin-binding domains (CBDs) were also generated and characterized. The catalytic and chitin-binding activities are independent of each other because each activity is functional separately. When attached to the catalytic domain, the CBD enhanced activity toward the insoluble polymer but not the soluble chitin oligosaccharide primarily through an effect on the Km for the former substrate. The linker region, which connects the two domains, facilitates secretion from the cell and helps to stabilize the enzyme in the presence of gut proteolytic enzymes. The linker region is extensively modified by O-glycosylation and the catalytic domain is moderately N-glycosylated. Immunological studies indicated that the linker region, along with elements of the CBD, is a major immunogenic epitope. The results support the hypothesis that the domain structure of insect chitinase evolved for efficient degradation of the insoluble polysaccharide to soluble oligosaccharides during the molting process.