Ecdysteroid as a mediator in the regulation of silk protein synthesis and its influence on silkworm (Bom., Lepidoptera) genome

Abstract:  Ecdysteroid is one of the two most important insect hormones, which controls growth and developmental activities of insect. In silkworm, Bombyx mori L., basically ecdysteroid induces molting and metamorphosis in larvae and exogenous administration hastens the silk synthetic activity and cocoon spinning process but it strictly depends on the time of administration. In the present study, we administered phytogenous ecdysteroid to the 48-h-old 5th instar silkworm, B. mori at a single dose of 2  μ g per larva to study its effects on the larval growth, cocoon and silk variables. The possible role of ecdysteroid in altering the developmental sequence of silkworm and thereby its effect on cocoon and silk production at molecular level have been tried to get elucidated. The genomic DNA was isolated from the posterior silk gland on day 5 and 7 of the 5th instar from the ecdysteroid treated and the control larvae and was randomly amplified with arbitrary primers. The result presented notable variation in the amplified product suggesting the participation of ecdysteroid in regulating the silk gene. The feeding period of treated larvae was unaffected while the cocoon characters exhibited considerable improvement. The filament traits also were improved notably in the treated larvae. The participation of ecdysteroid in the silk biosynthetic process with its physiological and molecular implications was discussed.     

Changes in the Gut Microbiome of the Sea Lamprey during Metamorphosis

Vertebrate metamorphosis is often marked by dramatic morphological and physiological changes of the alimentary tract, along with major shifts in diet following development from larva to adult. Little is known about how these developmental changes impact the gut microbiome of the host organism. The metamorphosis of the sea lamprey (Petromyzon marinus) from a sedentary filter-feeding larva to a free-swimming sanguivorous parasite is characterized by major physiological and morphological changes to all organ systems. The transformation of the alimentary canal includes closure of the larval esophagus and the physical isolation of the pharynx from the remainder of the gut, which results in a nonfeeding period that can last up to 8 months. To determine how the gut microbiome is affected by metamorphosis, the microbial communities of feeding and nonfeeding larval and parasitic sea lamprey were surveyed using both culture-dependent and -independent methods. Our results show that the gut of the filter-feeding larva contains a greater diversity of bacteria than that of the blood-feeding parasite, with the parasite gut being dominated by Aeromonas and, to a lesser extent, Citrobacter and Shewanella. Phylogenetic analysis of the culturable Aeromonas from both the larval and parasitic gut revealed that at least five distinct species were represented. Phenotypic characterization of these isolates revealed that over half were capable of sheep red blood cell hemolysis, but all were capable of trout red blood cell hemolysis. This suggests that the enrichment of Aeromonas that accompanies metamorphosis is likely related to the sanguivorous lifestyle of the parasitic sea lamprey.     

Induction of metamorphosis in the sand dollar Peronella japonica by thyroid hormones

The larva of the sand dollar Peronella japonica lacks a mouth and gut, and undergoes metamorphosis into a juvenile sand dollar without feeding. In the present study, it was found that thyroid hormones accelerate the metamorphosis of P. japonica larvae. The contents of thyroid hormones in larvae increased gradually during development. Thiourea and potassium perchlorate, inhibitors of thyroid hormone synthesis, delayed larval metamorphosis and simultaneously repressed an increase in the content of thyroxine in the larval body. These results suggest that the P. japonica larva has a system for synthesis of thyroid hormones that act as factors for inducing metamorphosis.     

A gastric-brooding asteroid, Smilasterias multipara

The gastric-brooding asterinid sea star, Smilasterias multipara, broods from late August to early November in the shallow sublittoral zone of southeastern Australia. We observed males and females spawning in the laboratory. They shed gametes through gonopores on the sides of the arms. The eggs were orange, about 1.0 mm in diameter, and heavier than seawater. They were externally fertilized by sperm, and placed into the stomach of the female by the tube feet. Twenty-four hours after fertilization, the first cleavage occurred. Cleavage was equal, total, and radial. Development via a non-feeding lecithotrophic brachiolaria was direct, there being no planktrotrophic bipinnaria or brachiolaria larva. Embryos developed, through wrinkled blastula and gastrula stages, into brachiolariae with arms. All of the surfaces of the brachiolaria were covered by cilia. At metamorphosis, a starfish rudiment appeared on the posterior portion of the larval body, while the anterior portion of the larval body was absorbed. Two months after fertilization, metamorphosis was complete. After metamorphosis, juveniles in the stomach grew six pairs of tube feet in each arm. Juveniles, 3 mm in diameter, emerged from the mouth of the mother in early November. Developmental evidence suggests that this asteroid has evolved mechanisms for the protection of larvae and juveniles from gastric digestion.     

Hemps, a novel EGF-like protein, plays a central role in ascidian metamorphosis

All chordates share several characteristic features including a dorsal hollow neural tube, a notochord, a pharynx and an endostyle. Unlike other chordate taxa, ascidians have a biphasic life-history with two distinct body plans. During metamorphosis, the larval nerve cord and notochord degenerate and the pharyngeal gill slits and endostyle form. While ascidians, like other marine invertebrates, metamorphose in response to specific environmental cues, it remains unclear how these cues trigger metamorphosis. We have identified a novel gene (Hemps) which encodes a protein with a putative secretion signal sequence and four epidermal growth factor (EGF)-like repeats which is a key regulator of metamorphosis in the ascidian Herdmania curvata. Expression of Hemps increases markedly when the swimming tadpole larva becomes competent to undergo metamorphosis and then during the first 24 hours of metamorphosis. The Hemps protein is localised to the larval papillae and anterior epidermis of the larva in the region known to be required for metamorphosis. When the larva contacts an inductive cue the protein is released, spreading posteriorly and into the tunic as metamorphosis progresses. Metamorphosis is blocked by incubating larvae in anti-Hemps antibodies prior to the addition of the cue. Addition of recombinant Hemps protein to competent larvae induces metamorphosis in a concentration-dependent manner. A subgroup of genes are specifically induced during this process. These results demonstrate that the Hemps protein is a key regulator of ascidian metamorphosis and is distinct from previously described inducers of this process in terrestrial arthropods and aquatic vertebrates.     

Hemolymph ecdysteroid titer and ecdysteroid-dependent developmental events in the last-larval stadium of the silkworm,Bombyx mori: role of low ecdysteroid titer in larval-pupal metamorphosis and a reappraisal of the head critical period

The endocrine regulation of larval-pupal metamorphosis was studied in the silkworm, Bombyx mori, by measuring the following changes: hemolymph ecdysteroid titer, the secretory activity of prothoracic glands and the responsiveness of larvae to ecdysteroids and prothoracicotropic hormone (PTTH), with regard to developmental events such as the occurrence of spinneret pigmentation, initiation of cocoon spinning and onset of wandering stage as indicated by gut purge. These measurements were concentrated especially on the time before and after the head critical period (HCP) which falls 3-4 days before the gut purge ([Sakurai, 1984]). A small increase in the hemolymph ecdysteroid titer was first found during the HCP, and then the titer increased with daily fluctuations. Small but significant titer peaks were found prior to the occurrence of both spinneret pigmentation and gut purge, indicating that an individual titer peak could possess a specific role in development. Responsiveness of larvae to exogenous 20-hydroxyecdysone (20E) after the HCP was markedly higher than that before the HCP. The sensitivity of the prothoracic gland to PTTH also changed during the HCP. The results thus showed that the HCP is not the period after which an additional PTTH release is not required for the developmental events occurring on schedule, but rather it is the period during which complex events occur not only in the endocrine glands but also in the peripheral tissues. In addition, various developmental phenomena before gut purge are brought about by the hemolymph ecdysteroid whose concentration gradually increased with daily fluctuations, and these precise changes in the titer appeared to be important for the sequential occurrence of developmental events in the larval-pupal metamorphosis.     

Normal and cocoon-forming peritrophic membrane in larvae of the beetle Gibbium psylloides

Larvae of Gibbium psylloides secrete a peritrophic membrane (PM) which has a mainly orthogonal fibrillar structure, but this merges freely with hexagonal and random arrangements of microfibres. The random arrangement predominates in PM used for cocoons. Shortly before the cocoon is constructed the PM no longer forms a tube but collapses and is compressed in the gut and emerges from the anus as a flat thread. This thread is wound around the larva and forms the cocoon ‘silk’. Both normal and cocoon-forming PMs are produced mainly in the posterior midgut and their constituent microfibres appear first at the tips of the microvilli which form the brush border of the midgut cells.     

转Bt基因水稻对二化螟绒茧蜂生物学特性的影响

用转Bt基因 (cry1Ab) 水稻KMD1饲喂3龄、4龄和5龄二化螟Chilo suppressalis一定时间后, 作为二化螟绒茧蜂Apanteles chilonis的寄主,研究了转基因水稻经寄主对绒茧蜂生物学特性的影响。结果发现：KMD1处理后,三个龄期幼虫的寄生率都显著下降,其中4龄和5龄达极显著水平;3龄和4龄上的结茧率显著低于对照;蜂蛹历期均短于对照,但仅3龄差异显著;从5龄幼虫所羽化的雄蜂寿命显著短于对照;蜂茧长显著短于对照;而对卵＋幼虫期、茧块茧数、蜂羽化率及性比均无显著影响。     

The biology, egg and larvae of Acaenitus dubitator (Panzer) (Hymenoptera, Ichneumonidae: Acaenitinae)

Acaenitus dubitator (Panzer) is found to be a koinobiont endoparasitoid of the larva of an endophytic beetle, Cleonis piger (Scopoli) (Curculionidae), in Britain, suggesting a similar mode of development for the ichneumonid subfamily Acaenitinae as a whole. The parasitoid can overwinter in its cocoon in one of two ways. Individuals overwintering as essentially unaltered mature larvae do not become adult the following summer, while those that overwinter as morphologically distinct prepupae are committed to pupate and become adult immediately afterwards. The change from mature larva to prepupa takes place in late summer, soon after the time of cocoon formation, but a proportion of mature larvae lie over in the first year, and perhaps subsequently. This appears to be an adaptation to life in a particularly harsh and uncertain environment. The egg, prepupa, and first, second and final instar larvae are described and figured. Previous interpretations of the cephalic sclerites of final instar acaenitines are revised.     

Morphological chimeras of larvae and adults in a hydrozoan--insights into the control of pattern formation and morphogenesis

In the marine hydroid Hydractinia echinata, metamorphosis transforms the spindle-shaped larva into a primary polyp. It bears a hypostome with a ring of tentacles at its apical end, a gastric region in the middle and stolons at the base. In nature, metamorphosis is induced in response to external stimuli provided by bacteria. These stimuli can be replaced by artificial inducers, one of which is heat shock. Among heat shock treated stages are those undergoing complete metamorphosis but also specimens forming chimeras of different developmental stages. In the chimeric larvae, the posterior is transformed into the apical hypostome of the adult polyp while the anterior part of the larva persists as larval tissue. After transverse sectioning, these stage chimeras regenerate the missing body parts with respect to the nature of the tissue at the wound surface. This shows that the decision to make larva or polyp morphology depends not on the majority of the tissue in the original body section, but on stage specificity within the regenerating animal part. Single cells can escape from this general rule, since RFamide nerve cells which usually differentiate in polyp tissue appear in regenerated larval tails of sectioned stage chimeras. The results indicate that the pattern-forming system of the larva and of the adult have features in common. The primary signals controlling patterning along the anterior-posterior axis in larvae and the apical-basal axis in polyps arethus likelyto be the same while the interpretation of these primary signals by the individual cells changes during metamorphosis.     

The nonfeeding auricularia of Holothuria mexicana (Echinodermata,Holothuroidea)

Among echinoderms, nonfeeding larvae usually are simplified in body shape, have uniform ciliation, and have lost the larval gut. A few species have nonfeeding larvae that express some remnant features of feeding larvae like ciliated bands and larval skeleton or larval arms, but typically their larval mouth never opens and their gut does not function. Still other species have retained the feeding larval form, a functional gut, and can feed, but they do not require food to metamorphose. The present note describes the development of a tropical holothurian, Holothuria mexicana, which hatches as a gastrula that is already generating coelomic structures. A translucent auricularia forms with a mouth that opens but becomes reduced soon thereafter. In form and ciliation this auricularia resembles a feeding larva, but it does not respond to food. A doliolaria forms on day 4 and the pentactula on day 6 post‐fertilization. Further study of this larva and that of its closely related congener, Holothuria floridana, is warranted.     

Interrelationship between the silk gland and other tissues in protein metabolism in the latest larval stage of the silkworm, Bombyx mori

Gamma irradiation at scheduled embryonic stages of silkworm eggs caused some disturbances in biological activities, i.e. cell proliferation of the silk gland, growth of larva and larval tissues, and cocoon production. The source of precursors for silk formation at the latest age of the fifth instar was found to be mainly in the ‘integument’ in its disintegrating state. Radioactivity in the tissues of the control and irradiated larvae labelled with ¹⁴C-glycine or ¹⁴C-leucine was used for analysis. Disturbance of synthesis of silk protein and of fat body protein with gamma irradiation decreased the degrading ability of the ‘integument’ and gut proteins.     

Behavior,metamorphosis, and muscular organization of the predatory rotifer Acyclus inquietus (Rotifera,Monogononta)

Abstract. The atrochid rotifer, Acyclus inquietus, is a sedentary predator that lives within the colonies of its prey, the rotifer Sinantherina socialis. After larvae infiltrate and become associated with the colony, they secrete a permanent gelatinous tube and undergo metamorphosis to the adult stage. We followed settlement and metamorphosis using bright-field microscopy to document specific larval behaviors after eclosion, and used epifluorescence and confocal microscopy of phalloidin-labeled specimens to visualize some of the morphological changes that occur during metamorphosis. Upon eclosion, larvae possess paired eyespots and a ciliated corona that functions strictly in locomotion. After leaving the parent's gelatinous tube, larvae eventually settle on unoccupied colonies of S. socialis or on other substrates if colonies are unavailable. Settlement involves a period of gliding among colony members before attachment with the foot and the secretion of a gelatinous tube. After settlement, there is a drastic reconfiguration of the corona that involves loss of the eyespots, loss of the coronal cilia, and the formation of the cup-shaped infundibulum, a deep depression in the anterior of the head that leads to the mouth. The development of the infundibulum involves the expansion of tissues around the mouth and is accompanied by a reorientation of the underlying musculature that supplies the infundibulum and allows its use in prey capture. The arrangement of the muscles in the trunk and foot regions, which contain outer circular (complete and incomplete) and inner longitudinal bands, remains unchanged between ontogenetic stages, and reflects the condition characteristic of other rotifers.     

Gastrulation in Calcareous Sponges: In Search of Haeckel's Gastraea

Haeckel's studies of development in calcareous sponges (1872)led him to develop the "Gastraea Theory," which proposes thatthe ancestral mode of germ layer formation, or gastrulation,was by invagination to produce a functional gut. His observationsthat gastrulation in the Calcarea occurs by invagination ofa ciliated larva upon settlement and metamorphosis were supportedby remarkable photomicrographs of the stage by Hammer in 1908.Although no later work found the same stage, these conceptsare repeated in texts today. We have re-examined embryogenesisand metamorphosis in Sycon sp. cf. S. raphanus in order to understandwhen gastrulation occurs. Almost all larvae settle on theirciliated anterior pole and metamorphose into a bilayered juvenilewhose interior cells rapidly differentiate into choanocytesand other cells of the young sponge. After a four-year searchwe have found the transitory stage shown by Hammer in whichthe anterior cells invaginate into the posterior half of thelarva. The hole closes and it is not until some days later thatthe sponge forms an osculum at its apical pole. To understandwhether invagination comprises gastrulation and if the holecan be considered to be a blastopore we have carried out a reviewof the literature dealing with this brief moment in calcaroneansponge development. Despite the intrigue of this type of metamorphosis,we conclude that gastrulation occurs earlier, during formationof the two cellular regions of the larva, and that metamorphosisinvolves the reorganization of these already differentiatedregions. Considering the pivotal position occupied by the Calcareaas the possible sister-group to all other Metazoa, these resultscall for a reassessment of germ layer formation and of the relationshipsof the primary germ layers among basal metazoan phyla.     

Does aggregation behavior of codling moth larvae,Cydia pomonella,increase the risk of parasitism by Mastrus ridibundus?

Mastrus ridibundus is a specialist hymenopteran parasitoid that parasitizes last-instar larvae or prepupae of the codling moth, Cydia pomonella. Foraging females eavesdrop on an aggregation pheromone produced by cocooning larvae. We investigated whether larvae that cocoon in aggregation experience a greater rate of parasitism than larvae that cocoon in isolation. In wind tunnel experiments, 10 larvae in aggregations were more readily located by female M. ridibundus than 10 larvae well separated from each other. Similarly, aggregations of 30 larvae were more attractive to female M. ridibundus than those of 3 larvae. In cage experiments, larval cocooning in aggregation or isolation had no effect on the mean rate of parasitism and the mean number of eggs deposited per parasitized host. In Petri-dish experiments, the location of larvae within an aggregation significantly affected their rate of parasitism, with those in the center of an aggregation completely shielded from parasitism. Our data suggest that aggregation behavior by C. pomonella larvae does not appear to increase the rate of parasitism. The increased risk of aggregated larvae to be detected by M. ridibundus is likely offset by diluted parasitism risk and structural refugia effects that larvae in aggregation experience. As an egg-limited parasitoid, female M. ridibundus can parasitize on average only one larva in an aggregation, with the likelihood of parasitism for each larva being inversely proportional to the number of larvae in that aggregation.     

Larvalentwicklung und Metamorphose vonPhoronis psammophila (Phoronida,Tentaculata)

The larval development ofPhoronis psammophila Cori is divided into 6 phases (on the basis of increasing pairs of larval tentacles); furthermore an initial and a ripe phase are distinguished. Specific aspects of the development are described: Formation and structure of larval tentacles; anlage of adult tentacles as a thickening in the larval tentacle base; late development of the metasome (larva with 4–6 tentacles); formation of the metasome pouch in the larva with 8 tentacles; enlargement of the apical plate; differentiation of the gut; differentiation of larval nephridia; formation of pigment particles in the larva with 6 tentacles (storage function of pigments and its significance for larval identification); different types of discoflagella in various regions of the body. The larval development shows the following tendencies: Improvement of locomotion; intensification of food filtration; anlage of adult organs in the larva leading to a shortening of metamorphosis duration. The larva ofP. psammophila is compared with those ofP. pallida, P. hippocrepia, andP. vancouverensis. Earlier larval determinations ofP. psammophila (e.g.Actinotrocha sabatieri, A. hatschekii) are shown to have been mistakes. Termination of the postembryonic phase (metamorphosis) can be induced experimentally by bacteria and also by cations. Pure or mixed bacteria cultures must be present at the beginning exponential growth phase. The bacteria density required is 20–94×10⁶ bact.ml^?1 for pure cultures and on the average 28×10⁶ bact. ml^?1 for mixed cultures. Metamorphosis initiation by cations can be induced with CsCl (0.06 M) and RbCl (0.035 M). Metamorphosis ofP. psammophila occurs in 6 phases: larva, ready for metamorphosis; larva, activated by bacteria or ions; evagination of the metasome diverticle, dislocation of gut; losing and swallowing of episphaere and larval tentacles; formation of the youngP. psammophila. All developmental phases are described and compared with those ofP. muelleri; imperfect metamorphosis is characterized and the youngP. psammophila compared with older stages and the adult Phoronis.     

Changes in biochemical composition and energy utilization during metamorphosis of leptocephalous larvae of the bonefish (Albula)

Synopsis Energy use and changes in whole-body content of lipid, protein, nitrogen, carbohydrate and ash were followed during metamorphosis of leptocephalous larvae of the bonefish (Albula). During metamorphosis, which requires about 8–12 days, larvae lost about 3–4 mg of lipid, or about 50% of the total lipid content. Lipid levels, calculated on a dry weight basis, showed no discernible trends, with values ranging from 138–185 mg (g dry wt)^–1. Protein content was 8.4 mg per larva and showed no significant change. However, protein levels increased from 147 to 329 mg (g dry wt)^–1. Nitrogen content decreased slightly from about 3.5 to 3.2 mg per larva. A comparison of protein and nitrogen values, expressed as % dry weight, showed that, in larvae which were just beginning to metamorphose, 70% of the total nitrogen was non-protein nitrogen (NPN). The NPN decreased to 58% of the total nitrogen towards the end of metamorphosis. Carbohydrate content fell from about 3.5 to 0.6 mg per larva, which represents an 83% loss. Carbohydrate levels also fell from about 81 to 32 mg (g dry wt)^–1. In addition, most of the carbohydrate appears to be bound to protein. Ash content decreased by 52%, from 4.6 to 2.2 mg per larva. Caloric content fell slightly from about 182 to 141 calories per larva whereas caloric density showed no discernible trends, with values ranging from 4.180 to 4.725 kcal (g dry wt)^–1. These results indicate that metamorphosing leptocephali, which apparently do not feed, probably derive most of their energy requirements from metabolizing endogenous lipid and carbohydrate stores formed during the premetamorphic interval.     

Effects of applaud on the growth of silkworm (Lepidoptera: Bombycidae)

An experiment was carried out to evaluate the effect of the insecticide Applaud (buprofezin 25% WP) on the silkworm Bombyx mori (L.). This insecticide belongs to the class of insect growth regulators (IGR). The larvae were fed on leaves treated with 3 different concentrations (0.5, 1, 2 g/liter) of Applaud on the 1st d of each instar. Analysis of data with the Tukey-Kramer test at 1% significant level revealed that mortality and larval duration did not differ among the treatments. On the contrary, the larval weight, which was estimated just before mounting (procedure during which the mature larva climbing on a branch or other material to spin the cocoon), differed among the treatments. Also, cocoon weight, shell weight, and cocoon sericin and fibroin content were different among the treatments, except the shell cocoon ratio. Maximum weight was observed in the controls and minimum in the last instar treatments. Our data suggest that supplementation of Applaud through food to larvae does not affect their mortality rate. On the contrary, it affects larval growth and cocoon parameters.