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.     

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.     

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.     

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.     

Identification of differentially expressed proteins during larval molting of Helicoverpa armigera

Insect molting involves many molecular processes, such as protein degradation and protein synthesis in the epidermis. Various proteins have been implicated in these processes. The differentially expressed proteins during larval molting of Helicoverpa armigera were investigated using two-dimensional electrophoresis (2-D-PAGE) and matrix-assisted laser desorption/ionization-time-of-flight-mass spectrometry (MALTI-TOF-MS). Four larval tissues sampled during molting and feeding were examined. Seventy-seven differentially expressed proteins were identified in these tissues, including 20 proteins from the fifth-molting epidermis (fifth instar molting to sixth instar), 36 proteins from the fifth-molting hemolymph, and 21 from the fifth-molting fat bodies. No obviously different spots were identified from the fifth-molting midgut under these experimental conditions. After application of MALTI-TOF-MS and similarity analysis comparing results to a Drosophila protein database, 30 proteins were identified: 10 proteins from the fifth-molting epidermis, 11 proteins from the hemolymph, and 9 proteins from fat bodies. These proteins were separated into 5 groups according to their probable functions, such as enzymes, regulators, protein hydrolases, receptors, and proteins with unknown functions. These differentially expressed proteins were proposed to be involved in the Helicoverpa molting cascade.     

家蚕蜕皮液羧肽酶A的表征及免疫荧光定位分析

蜕皮是许多变态发育昆虫的一种重要生理现象,昆虫通过蜕皮液中的酶对新旧表皮进行分离。已有相关蛋白组学的研究证明,家蚕蜕皮液中具有一种含量丰富的羧肽酶A(Bombyx mori-carboxypeptidase A, Bm-CPA),目前对其作用功能尚不清楚。为了更好地了解Bm-CPA在家蚕蜕皮发育过程的作用,本研究通过生物信息学分析、实时荧光定量PCR、抗体制备、免疫荧光染色和毕赤酵母表达等方法对Bm-CPA进行了研究。结果显示,Bm-CPA具有保守的M14锌羧肽酶结构域和糖基化位点,并且受蜕皮激素(20-hydroxyecdysone, 20E)调控,在眠期和上簇期的表皮中大量表达;免疫荧光染色显示Bm-CPA在眠期的表皮中富集,Bm-CPA抑制剂会导致幼虫因无法蜕皮而死亡;通过毕赤酵母表达系统在体外成功获得大量的重组Bm-CPA蛋白。这些结果为深入了解家蚕蜕皮发育过程提供了一定的参考。     

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.     

The origin,transport and cleavage of the molt-associated cuticular protein CECP22 from Calpodes ethlius (Lepidoptera,Hesperiidae)

CECP22 (Calpodes ethlius Cuticular Protein 22 kDa) is a molt associated protein found in the cuticle of C. ethlius larvae and pupae. The mRNA for the CECP22 cuticular protein is expressed in the epidermis and fat body during the intermolt. The protein itself accumulates in intermolt hemolymph, but at molting, when the cuticle is being digested, it is also found in the cuticle of surface integument, tracheae, foregut and hindgut and in the molting fluid. CECP22 exists in two forms. The large form (19.17 kDa, pI 6.2) becomes smaller (16.1 kDa, pI 7.4) by cleavage at the proteolytic cleavage site (position 170) with amidation of the C-terminal. The small, more basic peptide, appears only at molting, first in the cuticle and then in the molting fluid. It is presumed to be the active form of an amidase involved in the earliest stages of cuticle degradation. The inactive form accumulates in the hemolymph during the long intermolt and probably represents an abundant source of precursor enzyme that can be provided to all cuticle containing organs for a precise initiation of cuticle degradation.     

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.     

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.     

Effects of exposure to diethyl phthalate, 4-(tert)-octylphenol,and 2,4,5-trichlorobiphenyl on activity of chitobiase in the epidermis and hepatopancreas of the fiddler crab,Uca pugilator

Seven-day exposure of fiddler crabs, Uca pugilator, to diethyl phthalate at 50.0 mg l⁻¹ significantly inhibited the activity of chitobiase (also known as N-acetyl-β-glucosaminidase) in the epidermis and hepatopancreas. Epidermal chitobiase activity of crabs exposed to 10.0 mg l⁻¹ 4-(tert)-octylphenol for 7 days significantly decreased. PCB29 at 0.5 and 2.0 mg l⁻¹ significantly inhibited chitobiase activity in the epidermis and hepatopancreas of crabs exposed for 3 days. The inhibitory effects rendered by diethyl phthalate and PCB29 can at least partly account for the delayed molting they cause because chitobiase is needed to break down the old exoskeleton of crustaceans prior to ecdysis. Since chitinolytic enzymes are apparently the products of ecdysteroid regulated genes in arthropods, the decline in chitobiase activity after exposure to diethyl phthalate, 4-(tert)-octylphenol, and PCB29 along with the delayed molting they cause strongly suggests that these xenobiotics disturb the Y-organ–ecdysteroid receptor axis. Such disturbance may involve an interaction between ecdysteroid receptors and steroid mimics where the steroid mimics act as antagonists of endogenous steroid molting hormones, and/or arise from the interference with synthesis and excretion of ecdysteroids by these compounds.     

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.     

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。     

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.     

Requirements for molting of the crochet epidermis of the tobacco hornworm larva in vivo and in vitro

Summary In the tobacco hornworm,Manduca sexta, the epidermis which underlies the larval crochets is the first tissue to become independent of the prothoracic glands (PG) in a larval molt. In each successive larval molt, crochet forming cells increase in size, form hooks at their distal ends and, finally, secrete cuticle. This paper examines the endocrine requirements for competence to molt and describes parallel cultures in vivo and in vitro to define the hormonal control of crochet molting. When implanted into a fourth instar host larva prior to initiation of the last larval molt, competent crochet epidermis molted, forming crochets synchronously with its host. In the fourth instar, competence to form crochets is attained slowly during the first two days following ecdysis from the third instar. During the feeding phase of the fifth (last) instar, the crochet epidermis remains competent to molt (to form an extra sixth instar set of crochets) until the larva attains a weight of about 4.5 gm. Then, concurrent with the decline in the titer of juvenile hormone (JH) in the hemolymph, competence to form crochets declines. A similar loss of competence did not occur when fourth instar crochet epidermis was exposed to a declining JH titer by culture in either fourth instar isolated abdomens for 72 h or in fifth instar host larvae between 4 and 7 gm. Responses of crochet epidermis cultured in vitro also were examined. Competent fourth instar crochet epidermis formed crochets following 3–6 h exposure to ecdysone in vitro. Six ×10^–7M -ecdysone was required for 50% response, whereas a 10–50-fold higher concentration of -ecdysone was necessary. Although formation of morphologically complete crochets in vitro proceeded with similar time course to that in situ, no molt-induced growth occurred in vitro. When crochet epidermis was exposed to ecdysone in vitro immediately after explantation, exogenous JH was not required for molting. But when tissue was first cultured for 72 h without hormones, subsequent molting in vitro could not be elicited, although molting still could occur when the tissue subsequently was implanted into a fourth instar host. Exposure to corpora allata or to JH during the 72 h of culture in vivo partially prevented the loss in capacity to respond to ecdysone in vitro, suggesting that JH may be one factor involved directly or indirectly in maintenance of tissue responsiveness.Preliminary presentation of some of this work given at the December, 1973 Meeting of the American Society of Zoologists (Fain and Riddiford, 1973)     

Obstructor-A is required for epithelial extracellular matrix dynamics, exoskeleton function, and tubulogenesis

The epidermis and internal tubular organs, such as gut and lungs, are exposed to a hostile environment. They form an extracellular matrix to provide epithelial integrity and to prevent contact with pathogens and toxins. In arthropods, the cuticle protects, shapes, and enables the functioning of organs. During development, cuticle matrix is shielded from premature degradation; however, underlying molecular mechanisms are poorly understood. Previously, we identified the conserved obstructor multigene-family, which encodes chitin-binding proteins. Here we show that Obstructor-A is required for extracellular matrix dynamics in cuticle forming organs. Loss of obstructor-A causes severe defects during cuticle molting, wound protection, tube expansion and larval growth control. We found that Obstructor-A interacts and forms a core complex with the polysaccharide chitin, the cuticle modifier Knickkopf and the chitin deacetylase Serpentine. Knickkopf protects chitin from chitinase-dependent degradation and deacetylase enzymes ensure extracellular matrix maturation. We provide evidence that Obstructor-A is required to control the presence of Knickkopf and Serpentine in the extracellular matrix. We propose a model suggesting that Obstructor-A coordinates the core complex for extracellular matrix protection from premature degradation. This mechanism enables exoskeletal molting, tube expansion, and epithelial integrity. The evolutionary conservation suggests a common role of Obstructor-A and homologs in coordinating extracellular matrix protection in epithelial tissues of chitinous invertebrates.     

Adaptive Functions of Vertebrate Molting Cycles

SYNOPSIS Cyclic epidermal cellular prohfeiation,with or withoutkeratinization is a vertebrate characteristic Such activityprobably obeys an autonomous rhythm which is legulated throughneuro humoral S)stcms in response to envnonmental (piox imate)stimuliand related to adaptive (ultimate) factors In seeking causeand effect lelationships, however, it becomes apparent thatthe same environmental parameter may be both an ultimate anda pioximate factor, the latter also regulating the rate of lesponseWith regard to molting in homoio'heims, tempeiatuie acts insuch a capacity in many species Peiiodic shedding of the outer epidermis in fish amphibiansand reptiles does not appear to be coirelated with seasonalfactors to the extent that avian and mammalian molts are The evolution of vertebrate molting cycles has amounted to theentraining of inherent epidermal C)cles with seasonal demandsby the organism itself and the environment,these demands actas regulating mechanisms Pieadapted structures such as feathersand hairs function collectively as plumage and pelage in theirvarious roles but separately in their growth and leplacementcycles which, however, are coordinated for maximum functionalefficiency Molting is also synchionized with the seasonal cycleaccording to the availability of energy resources and time tocomplete the essential functions (in addition to molting) Theevolved molting systems as manifested in the gieat variety ofpatterns and types in the vertebrates, may thus be legardedas almost individual responses to selective piessures actingon a umveisil vertebrate chaiacter The basic regulatoiy system involves the neuro hvpophyseal complexwhich contiols target endocrines affecting various functionswhich themselves influence epidermal mitosis and, ultimately,molting 1 he mechanism in its simplest form controls the animalsmetabolism through the thyroid acting independently in a permissivecapacity or synergistically with the adrenal and gonadal hormoneswhich are regulated directly and/or indirectly through negativefeedback     

Ultrastructural studies of epidermis keratinization in grass snake embryos Natrix natrix L. (Lepidosauria, Serpentes) during late embryogenesis

The changes and biochemical features of the epidermis that accompany the differentiation and embryonic shedding complex formation in grass snake Natrix natrix L. embryos were studied ultrastructurally and immunocytochemically with two panels of antibodies (AE1, AE3, AE1/AE3; anti-cytokeratin, pan mixture, Lu-5 and PCK-26). All observed changes in the ultrastructure of the cells forming the epidermal layers were associated with the physiological changes that occurred in the embryonic epidermis, such as changing of the manner of nutrition and keratinization leading to the embryonic shedding complex formation. The layers that originated first (basal, outer and inner periderm and clear layer) differentiated very early and rapidly. Rapid differentiation was also observed in the layers that are very important for the functioning of the epidermis in Natrix embryos (oberhäutchen and beta-layers). They started to differentiate at developmental stage IX, and then fused and formed the embryonic shedding complex at developmental stage XI. During the embryonic development of the grass snake the smallest changes appeared in the ultrastructure of the cells in the mesos and alpha-layers because they perform supplementary functions in the process of embryonic molting. They were undifferentiated until the end of embryonic development and started to differentiate just before the first adult molting. AE1/AE3, anti-cytokeratin, pan mixture, Lu-5 and PCK-26 antibodies immunolabeled clear layer, oberhäutchen and beta-layers at the latest phase of developmental stage XI. It should be noted that these antibodies did not immunolabel the alpha-layer until hatching. The presence of alpha-keratin immunolabeling in layers that were keratinized, particularly in the oberhäutchen and beta-layers in embryos, indicated that they were not as hard as in fully mature individuals.