A medium for the maintenance of Chironomus tentans salivary glands in vitro

A synthetic medium based upon the chemical composition of fourth instar Chironomus haemolymph was formulated for the in vitro culture of Chironomus tentans salivary glands.Salivary glands maintained in the medium for up to 4 days appeared morphologically normal. Secretion-free glands, obtained from pilocarpine-treated larvae, accumulated proteinaceous material in the gland lumen and exhibited a 46% increase in total gland protein after 24 hr in the medium. Cycloheximide almost totally inhibited the accumulation of secretion material and the increase in total gland protein by cultured glands.Glands cultured for up to 4 days continued to incorporate ¹⁴C-leucine into acid-insoluble total protein and ³H-uridine into total RNA, but at reduced levels. The incorporation of both isotopes was almost completely inhibited by cycloheximide.Autoradiographic squash preparations of glands pulse-labelled with ³H-thymidine after 3 days in culture revealed a normal pattern of asynchronous chromosomal DNA replication. Glands cultured for up to 4 days exhibited ³H-uridine incorporation into nucleoli and into distinct chromosomal regions which corresponded with sites of cytochemically demonstrable acidic protein.The chromosomes of cultured glands appeared morphologically and cytochemically normal, except for some regression of the Balbiani rings. Addition of ecdysterone to media containing glands previously cultured for 3 days resulted in puff induction at the IV-2-B chromosomal locus.     

The effect of juvenile hormone on prothoracic gland function during the larval-pupal development of Manduca sexta: An in situ and in vitro analysis

The application of juvenile hormone I or ZR 512 to neck-ligated, day-5 fifth instar (V₅) larvae reduced the time to pupation in a dose-dependent manner when compared to neck-ligated controls treated with methyl epoxy stearate. Haemolymph ecdysteroid titres determined by radioimmunoassay (RIA) reflected the ability of juvenile hormone I and ZR 512 to stimulate larval-pupal development, i.e. the ecdysteroid titres were similar to those of normally developing larvae although the ecdysteroid peak elicited by ZR 512 lagged that in the normal titre by 1 day, while that elicited by juvenile hormone I lagged the ecdysteroid peak in normal larvae by 2 days. Neck-ligated V₅ larvae that were untreated ultimately pupated and the haemolymph ecdysteroid peak eliciting pupation in these animals was 7 μg/ml haemolymph, almost double that of normal animals and ZR 512- and juvenile hormone I-treated, ligated larvae. The data indicated that juvenile hormone I does stimulate the prothoracic glands but to determine whether this stimulation was direct or indirect, an in vitro approach was taken. Prothoracic glands from V₅, V₆ and V₇ larvae were incubated in vitro under conditions in which they could be stimulated by prothoracicotropic hormone, and were exposed to concentration of free juvenile hormones I, II, III or ZR 512 ranging from 10^?5M to 10^?10M. In no case were the prothoracic glands stimulated in a dose-dependent manner that would be indicative of hormone activation. Similar results were obtained when juvenile hormone bound to binding protein was incubated with the prothoracic glands. Studies with the acids of the three juvenile hormone homologues revealed them to be ineffective in activating prothoracic glands, although juvenile hormone III acid does appear to inhibit the synthesis of ecdysone by day-0 pupal prothoracic glands. The significance of the latter effect is unknown. It is concluded from these data that juvenile hormone can, indeed, activate late larval prothoracic glands in situ, but does so indirectly.     

Effects of the parasitization of a braconid, Apanteles, on the blood of its host, Pieris

Parasitization of a braconid wasp, Apanteles glomeratus, of larvae of a common cabbage butterfly, Pieris rapae crucivora, caused changes in differential haemocyte count (DHC), total haemocyte count (THC), and encapsulative capacity against dead eggs of Apanteles in the fourth and fifth instar host larvae.However, no correlation could be found between the number of Apanteles eggs deposited and THC of the middle fourth instar host larvae or between the number of parasitoid larvae and specific gravity of the haemolymph from the late fifth instar host larvae.From the changes in DHC and in THC of both non-parasitized and parasitized Pieris larvae, an increase in the number of plasmatocytes of non-parasitized Pieris larvae in the early fourth instar period was supposed to be due to transformation of prohaemocytes into plasmatocytes, and a low population of plasmatocytes of parasitized larvae in the comparable period was assumed to be due to a suppression of transformation of prohaemocytes by some factor released from the parasitoid eggs.Failure of the parasitized fourth instar Pieris larvae to encapsulate injected dead eggs of Apanteles indicated that the parasitoid embryos were, in some way, actively inhibiting the encapsulation reactions of the host.The increase in THC of the parasitized fifth instar larvae could not be ascribed to a decrease in the volume of host haemolymph. Rather it could be interpreted by a suppression of adhesive capacity of haemocytes in the host haemocoel to tissue surfaces.Reduced encapsulative capacity of the parasitized fifth instar larvae might be attributed either to a depression of the adhesive activity of plasmatocytes resulting from a depletion of energy source for haemocytes in the host haemolymph by parasitization, or from an active suppression of adhesiveness of the plasmatocytes by secretions from ‘giant cells’ (teratocytes) originated from the parasitoid.     

Relationships between the parasitoid Hyposoter exiguae and Trichoplusia ni: Parasitoid-induced histo- and cytopathology

The histology and cytology of Trichoplusia ni larvae were studied for evidence of abnormality or pathology induced by the solitary ichneumonid endoparasitoid, Hyposoter exiguae. Sample control and parasitized larvae were fixed every other day, and sections of these larvae were stained with mercuric-bromophenol blue. The fat body of parasitized larvae failed to show many of the changes characteristic of normally developing controls and, on the last day of parasitism, revealed extensive pathological changes. Spermatogenesis continued normally until the end of the association in parasitized hosts even though their development was halted in the fifth larval stadium. Parasitoid larvae seemed to secrete a proteinaceous material from their salivary and rectal glands into the host hemocoel. This material may be responsible for the pathological changes reported here. The parasitoids apparently fed on hemolymph alone until about 24 hr before emergence and pupation.     

Factors affecting change in sensitivity of prophoracic glands to juvenile hormone in Mamestra brassicae

The prothoracic glands of the early last-instar larva of Mamestra brassicae (day 0–3) were found previously to be insensitive to stimulation by juvenile hormone, whereas those later in the instar (from day 4 on) were activated by this hormone. When neck-ligatured young larvae (day-1, day-2 and day-3) were given juvenile hormone 5–10 days after ligation, pupation was induced. Similarly, juvenile hormone induced pupation of isolated abdomens which contained prothoracic glands taken from neck-ligatured day-3 larvae 5 days after ligation. If the glands were exposed to prothoracicotropic hormone (PTTH) from implanted brains before they were transplanted to isolated abdomens, their sensitivity to juvenile hormone activation was enhanced. Ecdysone but not 20-hydroxyecdysone given every 3 hr for 12 hr also slightly enhanced sensitivity. These results suggest that prothoracic glands from either day-1, day-2 or day-3 larvae can slowly acquire a sensitivity to juvenile hormone activation by prolonged incubation in the absence of factors from the head. The acquisition of sensitivity occurs more rapidly in the presence of both a factor from the brain, presumably PTTH, and ecdysone released from the prothoracic glands themselves.     

Juvenile hormone coordinates the regulation of the hemolymph ecdysteroid titer during pupal commitment in Manduca sexta

The timing and magnitude of the pupal commitment peak in the hemolymph ecdysteroid titer of fifth instar Manduca sexta larvae are controlled by the combined effects of prothoracicotropic hormone (PTTH), a prothoracic gland-stimulating factor present in the hemolymph, and the biosynthetic competence of the prothoracic glands themselves. The present data indicate those individual effects are coordinated by juvenile hormone (JH): (1) Treatment of larvae with the JH analog (7S)-hydroprene prevents the normal precommitment drop in the titer of the stimulatory factor; (2) treatment of larvae with (7S)-hydroprene suppresses in a dose- and time-dependent manner the biosynthetic competence of the prothoracic glands; and (3) (7S)-hydroprene acts directly on the brain to inhibit the release of PTTH in vitro. Thus, during Manduca development, a drop in the JH titer early in the fifth instar results in a rapid drop in the titer of the stimulatory factor, the gradual acquisition by prothoracic glands of biosynthetic competence, and lastly, the gated release of PTTH into the hemolymph. The resulting increase in ecdysone synthesis by the prothoracic glands gives rise to the small peak in the ecdysteroid titer that drives pupal commitment.     

Larval-pupal transformation of the prothoracic glands of Mamestra brassicae

The sensitivity of the prothoracic glands to juvenile hormone and prothoracicotropic hormone (PTTH) of penultimate (5th)-instar larvae of Mamestra brassicae was compared with that of the same-instar larvae destined for pupal ecdysis by allatectomy. The activity of the prothoracic glands was assessed using either moulting of isolated abdomens or ecdysone radioimmunoassay. Juvenile hormone application immediately after neck-ligation (which removes brain-corpora cardiaca-corpora allata complex) prevented prothoracic gland function in larvae at all stages. When larvae were allatectomized 12 hr after ecdysis, followed by neck-ligation at different times and given juvenile hormone immediately, the hormone inhibited the prothoracic glands of young larvae, but activated the prothoracic glands from day-5 or older larvae. Juvenile hormone I, juvenile hormone II and methoprene activated the prothoracic glands, but juvenile hormone III was relatively ineffective. Brain implantation instead of juvenile hormone application led to activation of the prothoracic glands at all stages.Allatectomy thus caused changes leading to metamorphosis including a transformation of the prothoracic glands from ‘larval’ to ‘pupal’ type. After this change these prothoracic glands were able to respond not only to PTTH but also to juvenile hormone just as in last-instar larvae.     

Activation of the prothoracic gland by juvenile hormone and prothoracicotropic hormone in Mamestra brassicae

The effects of JHA (ZR-515) application or brain implantation on metamorphosis and adult development were examined in the last instar larvae and pupae of Mamestra brassicae. When JHA was applied to neck-ligated 4- or 5-day-old larvae or to the isolated abdomens of 5-day-old larvae containing implanted prothoracic glands taken from 5-day-old larvae, the insects pupated. Dauer pupae and diapausing pupae treated with JHA showed adult development. By contrast, pupation could not be induced by the application of JHA to 2- or 3-day-old neck-ligated larvae or to the isolated abdomens of 5-day-old larvae containing implanted prothoracic glands from 0-day-old larvae. Implantation of a brain into neck-ligated 3- or 5-day-old larvae (at the beginning of gut emptying and wandering) caused pupation of the host. A similar result was obtained when both a brain and the prothoracic glands from 0- or 5-day-old larvae were implanted into the isolated abdomens of 5-day-old larvae. These results indicate that activation of the prothoracic glands by application of JHA is temporally restricted to the last part of the last larval instar and to the pupal stage, while the activation by prothoracicotropic hormone (PTTH) can occur throughout the last larval instar and the pupal stage. In addition, the implantation of brains or application of JHA to neck-ligated 5-day-old larvae 25 days after ligation seldom induced pupation of the hosts, a result which suggests that larval prothoracic glands maintained under juvenile hormone (JH) or PTTH-free conditions for long periods of time may become insensitive to reactivation by both hormones.     

Prothoracic glands in the regulation of ecdysone titres and metabolic fate of injected labelled ecdysone in Locusta migratoria

In the absence of the prothoracic glands, fifth instar larvae of Locusta migratoria contain no demonstrable quantities of ecdysone and ecdysterone (assayed together in the Calliphora bioassay), whereas normal larvae show a high peak of ecdysone activity. The metabolic fate of injected radiolabelled ecdysone is found to be very similar in prothoracectomized larvae to that of normal larvae (hydroxylation rate, dehydrogenation of ecdysone and ecdysterone, inactivation rate). However, in the absence of the prothoracic glands, the larvae excrete radiolabelled ecdysone in their faecal material at a rate which is considerably higher than that of normal insects of the same age. These results are discussed in view of the regulation of the ecdysone titres by the prothoracic glands in L. migratoria.     

Activity of the prothoracic gland and its sensitivity to prothoracicotropic hormone in the penultimate and last-larval instar of Bombyx mori

The time course of secretion of ecdysone in vitro by the prothoracic glands of Bombyx mori was studied through the penultimate and last-larval instars. Ecdysone was produced by the glands in high amounts by the penultimate instar at 72 and 84 h while the glands in the last instar exhibited a high activity over 4 days around the time of gut purge and thereafter. The glands in the penultimate instar produced ecdysone at a low level throughout the instar before the sharp peak of activity, when they became inactive and remained so for the first 3 days of the last instar after when they regained secretory activity. Sensitivity of the glands to prothoracicotropic hormone varied in accord with the changes in their secretory activity. Inactive glands were not stimulated by 22K-prothoracicotropic hormone. In addition, glands with maximal activity in the penultimate instar were insensitive to 22K-prothoracicotropic hormone. These results suggest that the prothoracic glands in the penultimate and last-instar larvae are physiologically different.     

Regulation of Heliothis virescens prothoracic glands by Cardiochiles nigriceps polydnavirus

Heliothis virescens (F.) Larvae parasitized by the endophagous braconid Cardiochiles nigriceps Viereck fail to attain the pupal stage. This developmental alteration is caused by both an inactivation of prothoracic glands of last-instar larvae and an altered ecdysone metabolism. Decrease in ecdysteroidogenesis in vitro was already evident in glands explanted from larvae that have attained the early cell formation stage (day 4 of fifth instar), 6 h after parasitoid oviposition. Ecdysteroidogenesis nearly ceased by 24 h after parasitoid oviposition. The degree of this biosynthetic depression increased as the time between parasitization and gland dissection increased. A time-course study allowed us to determine if both the degree of phosphorylation of regulatory target proteins, the rate of general protein synthesis and ecdysteroidogenesis decreased in concert over time. The results provide further evidence in support of the hypothesis that these cellular activities in prothoracic gland cells are functionally correlated in steroidogenic responses. Treatment with calyx fluid and venom of C. nigriceps duplicates the parasitism-induced inactivation of host prothoracic glands. A 6-h conditioning in vitro of pupally committed host prothoracic glands with these parasitoid female reproductive secretions resulted in a significant depression of their ecdysteroid production. However, glands lost their sensitivity to calyx fluid and venom treatment when explanted from hosts that had already attained the cell formation stage. This was further supported by the fact that nearly all the host larvae parasitized on day 4 of fifth instar (cell formation stage) pupated, while parasitization on day 3 resulted in only 11% pupation. The coupled trioxsalen/UV irradiation treatment of C. nigriceps calyx fluid and venom eliminated their negative effect on biosynthetic activity in vitro by host prothoracic glands. This result indirectly demonstrates that C. nigriceps polydnavirus is the major regulating factor involved in the host prothoracic gland inactivation. Arch. Insect Biochem. Physiol. 38:1–10, 1998. © 1998 Wiley-Liss, Inc.     

Utilization of fatty acids by Pieris brassicae reared on artificial and natural diets

The fatty acid composition of Pieris brassicae was measured from larvae reared on four different diets. Pieris can alter the composition of fatty acids in the diet through selective incorporation and synthesis. Oleate is preferentially accumulated on artificial diets (15·9 per cent in diet, 43·8 per cent in neutral lipid (NL) of fifth instar larvae), but not equally on natural diets (18·1 per cent in Brassica napus, 25·6 per cent in the NL of fifth instar larvae). Incorporation of linolenate appears to depend on the concentration of both linolenate and linoleate in the diet. With dietary levels of 35·7% linolenate and 32·2% linoleate, fifth instar larvae contain 12·2 and 16·0 per cent, respectively, of these acids. With 45·8% linolenate and 12·5% linoleate in the diet, fifth instar larvae contain 44·1 and 11·6 per cent of these acids, respectively, in the NL. Palmitoleate is actively synthetized on the artificial diets; with trace amounts of dietary palmitoleate, fifth instar larvae have 9·3 per cent of this acid in the NL. Pieris regulates the uptake of linoleate from the diet at the intestinal wall as was shown by linoleic acid-1-¹⁴C, and is unable to convert dietary linoleate to any of the 18-carbon analogues. The female apparently accumulates linolenate into egg phospholipids on the artificial diet, but in general the fatty acid composition of the eggs resembles that of the fat body.     

Uric acid levels during last larval instar of Manduca sexta, an abrupt transition from excretion to storage in fat body

Levels of uric acid in the whole body of the tobacco hornworm, Manduca sexta increased steadily for the 9 days of the fifth instar. However, concentrations in the haemolymph were lowest during the transition from the feeding stage to the wandering stage (days 3, 4), the time when there was a switch from uric acid excretion by the Malpighian tubule-hindgut system to storage in the fat body. Haemolymph volumes, determined for larvae between 2 and 6 days into the fifth instar by isotope dilution with [¹⁴C]-inulin, were used to calculate rates of incorporation of uric acid into Malpighian tubules and fat body of larvae injected with [¹⁴C]-uric acid. These labelling studies indicated that the Malpighian tubules ceased to remove uric acid from the haemolymph some time between the last 6 hr of day 3 of the fifth instar and the first 18 hr of day 4. At the same period, fat body removed significant quantities of uric acid from the haemolymph. The times of initial decreases and increases in levels of uric acid in haemolymph and fat body, respectively, indicated that storage in the fat body started before cessation of elimination via the Malpighian tubule-hindgut system.     

Growth and respiratory enzyme activity in the prothoracic glands of Galleria

In the penultimate-larval instar, the total volume of the prothoracic gland and the activities of some oxidative mitochondrial enzymes (cytochrome oxidase, NADH: cytochrome c oxidoreductase, succinate: cytochrome c oxidoreductase) undergo cyclic variations associated with larval growth. These specifically larval-larval growth cycles are absent in the prothoracic glands of normal last-instar larvae. Here the cycles can be induced artificially by implantation of brain or corpora cardiaca-allata complexes or, by exogenous application of juvenile hormone. The smallest size of the prothoracic gland in relation to the size of the body, as well as the minimal activity of all the three mitochondrial enzymes in the gland, have been found exactly at the moment of the pre-pupal peak of ecdysteroid in the body. The possibility that the prothoracic glands alone can synthetize ecdysteroid during the peak is questioned.     

Indirect stimulation of the prothoracic glands of Manduca sexta by juvenile hormone: Evidence for a fat body stimulatory factor

Juvenile hormone or ZR512 applied topically to day-5, fifth-instar, neck-ligated Manduca sexta larvae results in the acceleration of pharate pupal development when compared to neck-ligated, untreated larvae. This occurs as a result of an increase in the haemolymph ecdysteroid titre. Juvenile hormone, therefore, appears to stimulate ecdysone synthesis by the prothoracic glands of these animals, but not directly as shown by in vitro analysis. When ecdysone synthesis by the prothoracic glands of these ZR512- or juvenile hormone-treated animals was analyzed in vitro, increased gland activity was demonstrated but this did not occur until at least 2 days after treatment. This time lag in response supports the concept of an indirect stimulation of the prothoracic glands. Incubation of fat body from these ZR512- or juvenile hormone-treated, neck-ligated, larvae in 19AB culture medium revealed that the resulting pre-conditioned medium was capable of stimulating prothoracic glands in vitro up to 9-fold in a dose-dependent manner. A developmental profile was generated of the amount of this stimulatory factor released into the medium by fat body of untreated larvae representing each day of the last instar, and revealed that maximal release occurred with fat body from day-9 animals. The alterations in the amount of factor release by the fat body during larval-pupal development roughly correlated with the juvenile hormone titre and suggested a possible role for this factor in the regulation of the ecdysteroid titre. In contrast to the prothoracicotropic hormone, the fat body stimulatory factor is heat labile and has an apparent mol. wt in the 30,000 Dalton range. These data, particularly the kinetics of prothoracic gland stimulation, suggest that the factor may be a protein transporting a substrate for ecdysone biosynthesis to the prothoracic glands.     

Regulation of insect prothoracic glands: Existence of a haemolymph stimulatory factor in Manduca sexta

The primary regulator of ecdysone biosynthesis by insect prothoracic glands is the prothoracicotropic hormone. However, it now appears that other factors, secondary regulators, may modulate prothoracic gland activity. One such factor has been isolated from the haemolymph of Manduca larvae. This haemolymph factor stimulates in vitro ecdysone synthesis by larval and pupal prothoracic glands by approx. 5-fold. It has an apparent mol. wt of ～330 kD, is protease-sensitive and is heat labile, the latter clearly distinguishing it from the prothoracicotropic hormone. Further, its steroidogenic effects and those of prothoracicotropic hormone are additive. Treatment of larval or pupal prothoracic glands with both moieties simultaneously effects an approx. 10-fold increase in ecdysone synthesis. The haemolymph titre of the stimulatory factor is low at commitment of the last-larval instar, then increases by approx. 3-fold later in the instar during pharate-pupal development. This increase in the titre is sufficient to effect a significant increase in prothoracic gland activity that could be physiologically important. Thus, it appears that the fluctuating level of this haemolymph stimulatory factor may act in conjunction with prothoracicotropic hormone to regulate the haemolymph ecdysteroid titre by modulating the ecdysone biosynthetic activity of the prothoracic glands.     

Rôle of labelled dietary fatty acids and acetate in phospholipids during the metamorphosis of Pieris brassicae

The incorporation of labelled dietary palmitic, linoleic, and linolenic acids into neutral (NL) and phospholipids (PL) during the metamorphosis of Pieris brassicae was studied, and the ability of the fat body to incorporate acetate into PL determined. Thirty-three per cent of total lipid in early fifth instar larvae (minus haemolymph) is PL, while the corresponding value in female 4-day pupae is 13·0 per cent and in the fat body of 4-day pupae 6·3 per cent. Incorporation of label into PL was studied more closely and in all cases the label was recovered from phosphatidylcholine (PTC) and phosphatidylethanolamine (PTE). The label from palmitate was also found in sphingomyelin and possibly phosphatidylserine. Specific activity of PL in the case of palmitic and linolenic acids was greatest in late fifth instar larvae. In early fifth instar larvae on palmitic acid-1-¹⁴C 39·0 per cent of label was in PTC, 52·8 per cent in PTE, and 2·0 per cent in sphingomyelin. In late fifth instar 45·0 per cent was in PTC, 45·5 per cent in PTE, and 6·5 per cent in sphingomyelin, while in 4-day female pupae 45·2 per cent was in PTC, 41·3 per cent in PTE, and 13·5 per cent in sphingomyelin. The label from linolenic acid only varied a little from early fifth instar to 4-day pupae, 51·8 per cent being in PTC and 48·2 per cent in PTE in early fifth instar larvae. The label from linoleic acid is incorporated in fat body PL almost exclusively in PTC and PTE, 55·8 and 43·2 per cent respectively in 4-day female pupae. Injected acetate is distributed after 1 hr between PTC (58·6 per cent), PTE (24·4 per cent), and sphingomyelin (17·0 per cent). It was concluded that the polyunsaturated acids are proportionately more common in PTE than in other PL types, and that the fatty acids of sphingomyelin are mainly those that the insect is capable of synthesizing from acetate. Palmitic acid is desaturated by Pieris to palmitoleic acid and the latter possibly utilized in PTE to compensate for a deficiency of linolenic acid in the artificial diet. No saturation of linoleic or linolenic acid was found. The rates of PL and NL synthesis during development and the rôle of the investigated fatty acids in the biosynthesis of PL are discussed.     

Endocrine events during pre-diapause and non-diapause larval-pupal development of the tobacco hornworm, Manduca sexta

The haemolymph ecdysteroid titre and in vitro capacities of prothoracic glands and corpora allata to synthesize ecdysone and juvenile hormone, respectively, during the last-larval instar of diapause-destined (short-day) and non-diapause-destined (long-day) Manduca sexta were investigated. In general, the ecdysteroid titres for both populations of larvae were the same and exhibited the two peaks characteristic of the haemolymph titre during this developmental stage in Manduca. The only difference in the titre occurred between day 7 plus 12 h and day 7 plus 20 h, when the short-day larval titre did not decrease as quickly as the long-day titre. The in vitro synthesis of ecdysone by prothoracic glands of short- and long-day larvae during the pharate pupal phase of the instar were also essentially the same. Activity fluctuated at times which would support the idea that ecdysone synthesis by the glands is a major contributing factor to the changes in the haemolymph ecdysteroid titre. There was one subtle difference in prothoracic gland activity between the two populations, occurring on day 7 plus 2 h. By day 7 plus 10 h, however, rates of ecdysone synthesis by the short- and long-day glands were comparable. This elevated activity of the short-day glands occurred just prior to the period the haemolymph ecdysteroid titre remained elevated in these larvae. The capacities of corpora allata to synthesize juvenile hormone I and III in vitro were not markedly different in long- and short-day last-instar larvae. At the time of prothoracicotropic hormone release in the early pupa, activity of corpora allata from short- and long-day reared animals was low and also essentially the same. There were a few differences in the levels of synthesis at isolated times, but they were not consistent for both homologues. Overall, there are no compelling differences in the fluctuations of ecdysteroids and juvenile hormones between diapause-destined and non-diapause-destined Manduca larvae. Since these hormones do not appear to play any obviously significant role in the induction of pupal diapause in this insect, the photoperiodic induction of diapause in Manduca appears to be a predominantly brain-centred phenomenon not involving endocrine effectors.     

Utilization of uridine in developing ovarioles of the kelp fly, Coelopa

The fate of ³H-uridine in ovaries of the kelp fly C. frigida after injection into the female is followed by autoradiography and by thin layer chromatography over a time period of 4 hr. Autoradiography demonstrates that the label is incorporated initially into nuclear material in the nurse cells and follicle cells, and is transported from the nuclei into the cytoplasm within the first hour after injection. Reduced incorporation into nuclear material, after the first 2 hr following injection, is interpreted as depletion of exogenous precursor. Only a very small amount of label is found over the nuclei after 4 hr when the nurse cell cytoplasm is densely labeled. This indicates that most of the label is retained in long-lived products and is not available for the salvage pool.Analysis of the relative distribution of radioactivity in derivatives over a 4 hr time span corroborates the autoradiographic observations. The amount of radioactivity present in uridine, cytidine, and sugar nucleotides increases rapidly, though with different velocity for each nucleotide. The pattern of utilization during the first 2 hr, particularly of UTP, suggests preferential utilization of the exogenous precursor. After depletion of the salvage pool, labeled precursors provide low levels of specific activity for the nucleotide pool. The macromolecules synthesized after this time period do not show radioactivity.     

Involvement of PI3K/Akt signaling in PTTH-stimulated ecdysteroidogenesis by prothoracic glands of the silkworm, Bombyx mori

The prothoracicotropic hormone (PTTH) stimulates ecdysteroidogenesis by prothoracic gland in larval insects. Previous studies showed that Ca²⁺, cAMP, extracellular signal-regulated kinase (ERK), and tyrosine kinase are involved in PTTH-stimulated ecdysteroidogenesis by the prothoracic glands of both Bombyx mori and Manduca sexta. In the present study, the involvement of phosphoinositide 3-kinase (PI3K)/Akt signaling in PTTH-stimulated ecdysteroidogenesis by B. mori prothoracic glands was further investigated. The results showed that PTTH-stimulated ecdysteroidogenesis was partially blocked by LY294002 and wortmannin, indicating that PI3K is involved in PTTH-stimulated ecdysteroidogenesis. Akt phosphorylation in the prothoracic glands appeared to be moderately stimulated by PTTH in vitro. PTTH-stimulated Akt phosphorylation was inhibited by LY294002. An in vivo PTTH injection into day 6 last instar larvae also increased Akt phosphorylation of the prothoracic glands. In addition, PTTH-stimulated ERK phosphorylation of the prothoracic glands was not inhibited by either LY294002 or wortmannin, indicating that PI3K is not involved in PTTH-stimulated ERK signaling. A23187 and thapsigargin, which stimulated B. mori prothoracic gland ERK phosphorylation and ecdysteroidogenesis, could not activate Akt phosphorylation. PTTH-stimulated ecdysteroidogenesis was not further activated by insulin, indicating the absence of an additive action of insulin and PTTH on the prothoracic glands. The present study, together with the previous demonstration that insulin stimulates B. mori ecdysteroidogenesis through PI3K/Akt signaling, suggests that crosstalk exists in B. mori prothoracic glands between insulin and PTTH signaling, which may play a critical role in precisely regulated ecdysteroidogenesis during development.