Tryptophan metabolism during development of the stick insect,Carausius morosus Br. tissue distribution and interrelationships of metabolites of the kynurenine pathway

Summary During larval development ofCarausius morosus kynurenic acid is the major end product of tryptophan metabolism. Tryptophan and kynurenic acid have been found in the fat body, haemolymph and gut contents but only traces of kynurenine have been detected. The ommochromes ommin and xanthommatin are formed in relatively small amounts in the epidermis during larval development. 3-hydroxykynurenine was found only in the epidermis, the site of ommochrome deposition.During larval development, the amount of free tryptophan increases with body dry weight. The amount of kynurenic acid excreted also corresponds to the increase of body weight but is significantly reduced in the faeces of adults. This is related to a high tryptophan content of yolk proteins. The concentration of tryptophan in the haemolymph decreases immediately before ecdysis, whereas that in the gut increases during this time and falls sharply at the start of ecdysis.     

Die Redoxpigmente von Carausius morosus und ihre Bedeutung für den morphologischen Farbwechsel

Summary From the epidermis of Carausius morosus two ommochromes were isolated, and identified by various means as Xanthommatine and Ommine. Their amount was determined by photometry for animals of different colour.Morphological colour change results mainly from changes in ommochrome content.If the lower part of their compound eyes is blackened, green specimens become brown by an increase of ommochrome production.This colour change can be evoked within a single larval instar.It can also be evoked in adult specimens, although to a small degree only.Dark specimens with unblinded eyes become paler under normal illumination in consequence of an increase of bright pigments and of the increase in bodysize, while the amount of ommochrome increases only very slightly.A decrease of ommochrome content or a loss of ommochrome by faeces or offshed cuticles was never observed.At high temperature (28° C) both, ommochrome production in the epidermis and melanin formation in the cuticle are increased.Implantation of supernumerous Corpora allata causes the ommochrome content to increase. After extirpation of the Corpora allata no decrease of ommochrome content is found but the green pigment, insectoverdin vanishes. Apparently in Carausius ommochrome may deposited but is never removed from the integument, which may explain the similar coloration after both experiments.     

Endocrine manipulations and ontogenesis of male sexual behaviour in Locusta: studies on azadirachtin-induced over-aged nymphs

ABSTRACT. Dose-response relations of the moult-inhibitory and lethal effects of azadirachtin (AZA) injected into fifth and fourth instar hoppers of Locusta migratoria migratorioides are presented. The optimal dose for obtaining maximum number of long-surviving over-aged nymphs is 1.6 and 1.0 μg of AZA per insect for young fifth and fourth instar nymphs, respectively. Over-aged male nymphs are capable of exhibiting sexual behaviour. The mating behaviour of fifth instar over-aged male nymphs, and of chemically allatectomized but otherwise similar over-aged male nymphs (obtained by combined precocene treatment and injection of AZA), with and without injections of exogenous Juvenile Hormone III (JH), is investigated quantitatively; the results are compared with those obtained for normal, chemically allatectomized, and chemically allatectomized plus JH-injected adult males. Over-aged fifth instar male nymphs show a low intensity of mating behaviour and in chemically allatectomized ones this intensity is even lower. Injections of JH intensify the mating behaviour of chemically allatectomized fifth instar over-aged male nymphs in a dose-dependent way, but less markedly so than in chemically allatectomized adult males. We conclude that the intensity of male mating behaviour of the over-aged nymphs is subnormal and their response to the mating behaviour intensifying effect of the JH is weaker than that of adult males. The relations between endocrine factors and ethological ontogenesis of male sexual behaviour in locusts are discussed.     

Morphological colour change: Stage independent, optically induced ommochrome synthesis in larvae of the stick insect,Carausius morosus Br.

Summary The eyes of 4th, 5th, and 6th instar larvae of the stick insect,Carausius morosus, were partially covered with black varnish, and the ommochrome content of treated and untreated animals was determined throughout the instar. In untreated animals kept at 20°C in 16:8 LD the ommochrome content of the integument remains at the level found in newly hatched larvae (10 g/animal), up to the third moult, and increases only slightly (to 30 g) until the adult moult. Darkening the dorsal halves of the eyes does not influence the ommochrome content. Darkening the ventral halves, thus imitating the visual situation of an animal in light on a dark ground, causes after a lag of 3–4 days, a continuous increase of ommochrome content by about 5 g per day. The increase is equal at the beginning and during the second half of the 4th instar, and is also equal in the three instars investigated. Ommine and xanthommatine equally contribute to the increase.     

The precocious commitment of wing Anlagen in Tenebrio molitor revealed by the addition of 20-hydroxyecdysone

An injection of 20-hydroxyecdysone (10 mug per animal) 6-13 days after the moult of the last larval instar of Tenebrio molitor induces the development of prothetelic larvae and larval-pupal intermediates. The state of larval-pupal switchover, or commitment, is only disclosed at the time of injection of the moulting hormone. Prothetelic A and B larvae, with small and medium sized wing Anlagen, undergo another larval or pupal instar. Prothetelic C larvae with bigger Anlagen are unable to moult, but the adult programme is expressed. Ecdysed larval-pupal intermediates give more or less perfect adults, while unecdysed mealworms, imprisoned in their larval cuticle, also expressed the adult programme. The commitment of Tenebrio is not a global switchover because a significant asynchronisation is noted between the development of organs considered. Animal crowding induces a delay in the appearance of wing Anlagen.     

Endocrine manipulations,juvenile hormone and ontogenesis of male sexual behaviour in locusts

By injection of azadirachtin (AZA) to 5th instar hoppers of Locusta migratoria migratorioides, “over-aged” nymphs were produced, some of which survived for long periods without moulting to adults. Such over-aged male nymphs exhibited mating behaviour belatedly, though at a lower intensity than normal adults. Juvenile hormone (JH) markedly intensifies male sexual behaviour in crowded adult (6th instar) Locusta; thus, the lower intensity of sexual behaviour of the over-aged nymphs might have been caused by a low endogenous JH titre, or by a weaker response to the hormone. To clarify this point, chemically allatectomized over-aged 5th instar nymphs were produced by combined treatment with precocene and AZA. These exhibited a very low intensity of mating behaviour. Injections of exogenous JH III intensified the mating behaviour of the chemically allatectomized over-aged 5th instar male nymphs in a dose-dependent way, but the effect was weaker than in chemically allatectomized adult males. AZA-induced over-aged 4th instar male Locusta hoppers also exhibited mating behaviour. By injection of AZA, 5th instar over-aged hoppers of Schistocerca gregaria were also produced. Males showed mating behaviour belatedly, despite the fact that JH completely controls male sexual behaviour in this species. The intensity of this behaviour was again lower than in adults. Interrelations between integumental morphogenesis, “ethogenesis” of male sexual behaviour, and endocrine factors in locusts are discussed.     

Effects of previous diet and frequency of feeding on development of larval damselflies

SUMMARY. 1. Food availability during instar F-3 affected duration of instar F-3 of larval Ischnura vertiealis (Say) maintained in the laboratory but did not affect the increase in head width at the moult to instar F-2.
2. Food availability during instar F-2 altered both duration in instar F-2 and weight per unit head width of newly moulted F-l larvae, but not the increase in head width at the moult to instar F-1.
3. Food availability during instar F-3 had no effect on instar duration, weight per unit head width, or increase in head width of F-2 larvae at the moult to instar F-l.
4. Survival of larval Coenagrion resolution (Hagen) reared in the laboratory was dependent on mean number of Daphnia offered per day. In addition, larvae fed less frequently, but on the same mean number of Daphnia per day. had lower survival rates than larvae fed more frequently.     

Induction of perfect superlarvae by the application of juvenile hormone analogue to starved larvae of the silkworm,Bombyx mori

Topical application of juvenile hormone analogue, methoprene, induced a supernumerary larval moult in the silkworm, Bombyx mori. The incidence changed greatly depending on developmental stages and physiological states of the methoprene-treated larvae. When methoprene was applied to feeding larvae, only those treatments from the middle of the 2nd instar until the middle of the 4th instar were effective. An 18-h starvation period from the beginning of the 4th instar and a dose of 1 μg of methoprene per larva were required for 100% incidence of the perfect superlarvae. Allatectomy had no effects on the induction of superlarvae by methoprene. The treated 4th-instar larvae ecdysed to the 5th instar without any delay compared to the controls, and underwent an additional larval ecdysis 4.5 days later. The induced 6th-instar larvae took 8.5 days until the onset of cocoon spinning. The induced superlarvae showed reduced growth rates but an increase of final mass due to prolonged feeding period. A sharp but reduced peak in ecdysteroid titre in the haemolymph appeared one and a half days prior to each larval ecdysis in the treated larvae, suggesting that methoprene provokes the extra larval moult through an additional release of ecdysteroids.     

Regulation and significance of ecdysteroid titre fluctuations in lepidopterous larvae and pupae

The last larval moult of Galleria mellonella is induced by an elevation of ecdysteroid titre to more than 200 ng/g. After ecdysis the titre remains very low until 70 hr of the last-instar when a slight elevation in ecdysteroid concentration initiates the onset of metamorphosis. An ecdysteroid peak (275 ng/g), which occurs between 108 and 144 hr, is associated with wandering and cocoon spinning. Pupal ecdysis follows about 20 hr after a large ecdysteroid peak (780 ng/g) with a maximum in slowly-mobile prepupae (160 hr of the last larval instar). The ecdysteroid decrease between the two peaks coincides with the period when the larvae exposed to unfavourable conditions enter diapause. The pupal-adult moult is initiated by a high ecdysteroid peak (1500–2500 ng/g) in early pupae and imaginal cuticle is secreted in response to a smaller peak (ca. 500 ng/g) in the middle of pupal instar.Until early pupae, the ecdysteroid content is regulated by the prothoracic glands. In decapitated larvae the glands become spontaneously active after 30–40 days and the body titre of ecdysteroids undergoes an increase; the glands revert to inactivity when the insects accomplish secretion of pupal cuticle. A similar ecdysteroid increase occurs within 10 days when the decapitated larvae receive implants of brains releasing the prothoracicotropic neurohormone (PTTH). In either case, the pupation-inducing increase of ecdysteroids is 3 times higher than the large ecdysteroid peak in the last-instar of intact larvae. This indicates that the function of prothoracic glands in intact larvae is restrained, probably by the juvenile hormone (JH). Exogenous JH suppresses the spontaneous activation of the prothoracic glands in decapitated larvae and reduces the ecdysteroid concentration in those larvae (both decapitated and intact), whose glands were activated by PTTH. Furthermore, JH influences the PTTH release from the brain in situ: depending on JH concentration and the age and size of treated larvae, the PTTH liberation is either accelerated or delayed.Neither in G. mellonella larvae, nor in the diapausing pupae of Hyalophora cecropia and Celerio euphorbiae, does JH directly activate the prothoracic glands. It is suggested that the induction of the moult by JH in decerebrate insects, which has been observed in some species, is either due to indirect stimulation of ecdysteroid production or to increased sensitivity of target tissues to ecdysteroids. In G. mellonella, a moult occurs at a 5–15 times lower than usual ecdysteroid concentration when the last-instar larvae are exposed to JH.     

Nonshivering thermogenesis and cold resistance during seasonal acclimatization in the Djungarian hamster

Summary The absence of juvenile hormone (JH) at the time of head capsule slippage during the molt to the fifth (final) instar of the tobacco hornworm was found to cause ommochrome (primarily dihydroxanthommatin) synthesis in the epidermis during the first two days after ecdysis. Then synthesis decreased until its transient reappearance during the wandering stage. Either JH-I (ED₅₀=8x10^–4 g) or methoprene (ED₅₀=1.4x10^–2 g) applied at this critical time during the molt prevented the first synthesis. A comparison of developmental profiles of tryptophan and its metabolites, kynurenine and 3-hydroxykynurenine, in normal and allatectomized wild type larvae showed that JH at this critical time prevented both the conversion of kynurenine to 3-hydroxykynurenine and 3-hydroxykynurenine to ommochromes. A similar study in normal and methoprene-treatedblack mutant larvae showed that only the latter conversion was inhibited by JH. The accumulation of 3-hydroxykynurenine in the epidermis of the JH-treatedblack mutant is thought to be due to the altered tryptophan metabolism in these mutants in previous instars due to lower JH levels. Neither starvation of theblack mutant nor injection of 3-hydroxykynurenine significantly affected ommochrome synthesis by the epidermis. Preliminary studies of the enzymes involved showed that JH at the critical period suppressed the later activity and/or production of kynurenine 3-hydroxylase in the wild type larva, but had little effect on the particulate ommochrome synthetase activity of the epidermis.Abbreviations CA corpora allata - JH juvenile hormone - PTTH prothoracicotropic hormone     

Stimulated synthesis of the female-specific storage protein in male larvae of the silkworm Bombyx mori treated with juvenile hormone analog

Application of methoprene to fourth (penultimate) instar larvae of the silkworm Bombyx mori induced the appearance of the feeding dauer larvae at the fifth (last) instar and prevented pupal metamorphosis. Methoprene also increased the protein concentrations of hemolymph last instar larvae by preventing sequestration of storage proteins by the fat body. Usually, the female-specific storage protein 1 (SP1)* disappears from the male hemolymph at the time of the last larval instar. However, exposure of male larvae to methoprene at the penultimate instar enhanced the accumulation of SP1 in the hemolymph. The SP1 accumulated in males did not differ in molecular weight and immunoreactivity from the SP1 produced in female larvae. Both sexes of fourth instar larvae allatectomized on day 1 instantly accumulated SP1 in the hemolymph, and methoprene application after allatectomy suppressed the hemolymph accumulation of the SP1. In contrast, if allatectomy was carried out at a later stage of the fourth larval instar, SP1 concentration in hemolymph of fifth instar larvae did not increase, suggesting the different juvenile hormone action for regulation of SP1 synthesis in the penultimate instar larvae of silkworms.     

Hypertrehalosaemic and hyperlipaemic responses to adipokinetic hormone in fifth larval instar locusts,Locusta migratoria

In fifth instar larvae of Locusta migratoria the haemolymph lipid concentration is elevated after injection of adipokinetic hormone (AKH). This hyperlipaemic response in larvae remains substantially lower than in adults; over 75% of the mobilized lipid consists of diacylglycerol. In addition, unlike adult locusts, fifth instar larvae also exhibit a consistent, though moderate, hypertrehalosaemic response to AKH. The increases of both lipid and carbohydrate concentrations in larvae are dose-dependent, showing a significant linear regression on log dose in the range 0.2–20 pmol AKH.Glycogen phosphorylase in the fat body of fifth instar larvae as well as young adults is activated on injection of AKH, the percentage active phosphorylase increasing linearly with log dose in the range 0.04–20 pmol AKH. For a given response, a somewhat higher dose of AKH is needed in larvae than in young adults.Fat body glycogen phosphorylase is strongly activated during the period of the larval-adult ecdysis, when active phosphorylase accounts for almost half of the total enzyme, which is approximately ten times more than it is two days before, and two days after the ecdysis.The corpora cardiaca of fifth larval instar locusts already possess the potencies to elevate carbohydrate and lipid concentrations in larval haemolymph, and to activate fat body glycogen phosphorylase.     

Precocious reprogramming of eupyrene-apyrene spermatogenesis commitment induced by allatectomy of the penultimate larval instar of the moth Actias selene

A possible causal relationship between the switch-over from eupyrene to apyrene spermatogenesis and pupation in Lepidoptera was examined in Actias selene. Precocious pupation, 11 days earlier than in the controls, was induced by allatectomy on the first day of the penultimate larval instar. The course of the eupyrene spermatogenesis, until nuclear elongation in the spermatid, is not related to pupation. In both allatectomized and control individuals, eupyrene metaphases appear 8 days after ecdysis of the fourth larval instar. Nuclear elongation, however, is triggered in the allatectomized individuals earlier than in the controls, probably by the premature decline of the juvenile hormone titre following allatectomy. Apyrene commitment, on the other hand, is directly related to pupation, as apyrene spermatogenesis begins 2 days after pupation in both control and allatectomized individuals.     

Changes in body-length, and in shape of the furcal ramus, of a freshwater cyclopoid copepod

Some morphological relationships during larval development of a freshwater cyclopoid copepod (Crustacea), Cyclops strenuus abyssorum Sars (Gurney, 1933) have been studied. The proportion which the cephalothorax forms of total length decreases at each copepodid moult whilst that which the furcal ramus forms increases. However, within each instar, each of these ratios is a constant at different seasons and in different lakes. The amount by which total length in one instar is greater than that in the preceding instar tends to decrease at each moult from a maximum of 1.31 in the first copepodid moult to lower values, especially in males. The furcal ramus is twice as long as wide in the first copepodid instar but seven times as long as wide in the adult female. This change is enhanced in the last two moults not only by a proportionately greater increase in length over width but by an absolute reduction in width itself.     

Influence of juvenile hormone on growth and digestion in fifth instar larvae and adults of Locusta migratoria

Food utilization was measured in female fifth instar larvae and adults of the migratory locust by following the weight of food ingested, the weight of faeces produced, and the increase in body weight. These parameters were measured in normally developing locusts, in locusts that had been implanted with a pair of active corpora allata (CA) in the beginning of the fifth instar period, and in allatectomized locusts, operated on the first day after adult ecdysis.A high titre of corpus allatum hormone results in a considerably higher water content of the insects; allatectomy reduces this content. The dry weight of the locusts is not essentially influenced by excess or absence of juvenile hormone.Food consumption in corpora-allata-implanted locusts does not differ from that in normally developing insects. Within each developmental period the digestive capacity remains constant, but the absolute value of this capacity may differ between the two developmental periods. The approximate digestibility is somewhat higher after CA-implantation and lower after allatectomy. The efficiency of conversion of digested food into body substance is greater in normally developing larvae than in adults. CA-implantation lowers this efficiency in developing larvae. Allatectomy slightly raises the efficiency of conversion in adult locusts.In the second half period of larval development, CA-implantation raises the respiratory rate, as estimated by measuring oxygen consumption. During adult development no significant influence of CA-implantation on respiration was established. Relations between the amount of food digested, the efficiency of conversion of digested food into body substance, and the respiratory activity are discussed.     

The role of eclosion hormone in the larval ecdyses of Manduca sexta

Each larval moult in Manduca sexta consists of an identical series of developmental and behavioural events leading up to ecdysis. Injections of eclosion hormone into staged larvae in any instar resulted in the premature elicitation of the larval pre-ecdysis behaviour, comprising a rhythmic sequence of muscle contractions, followed by the larval ecdysis behaviour.A marked depletion of eclosion hormone stores form the ventral chain of ganglia coincided with each larval ecdysis and in the moult to the fifth instar, eclosion hormone activity appeared in the blood at the onset of the pre-ecdysis behaviour.Responsiveness to eclosion hormone for pre-ecdysis and ecdysis behaviour developed about 12 and 6 hr before normal ecdysis, respectively. Elicitation of ecdysis behaviour by exogenous hormone inhibited both subsequent behavioural responses to eclosion hormone and endogenous hormonal release.In conclusion, the behavioural programme involved in each larval ecdysis appears to be controlled by the eclosion hormone.     

Allatectomy and food selection in males of Locusta

Removing the corpora allata from young males of Locusta does not alter the overall amount of food they consume or the quantity of faeces they produce. However, allatectomized males eat less fresh grass and more dry bran than the control males. This observation is discussed in relation to the maturation process and other events in the adult male.     

Der Tryptophanstoffwechsel und die Ommochromsynthese während der Embryonalentwicklung der Stabheuschrecke Carausius morosus

The synthesis of ommochromes, ommin, and xanthommatin, was studied during the embryonic development of Carausius morosus. Ommochrome synthesis begins in the epidermis of the embryo at the 46th day after egg laying. The ommochrome accumulation is directly related to the continuous increase of pigment spots on the epidermis of the pharate larva.The concentration of free tryptophan increases progressively from the germ band formation (15th day), until the final position of the embryo in the egg, with the head immediately beneath the operculum (44th day). Subsequent decrease in concentration of tryptophan coincides with the appearance of ommochrome in the epidermis of the embryo. The tryptophan levels decrease considerably from 44th day till the 60th day. During the stage of the pharate first instar larva tryptophan levels remain low until hatching. The concentrations of the intermediates, kynurenine and 3-HO-kynurenine, show no accumulation and remain low during the whole of ommochrome synthesis.     

Food utilization and metabolic efficiency in larval and adult house crickets

The most rapid growth of the fat body, ovaries and residual body occurred only at the time of maximal feeding, which was the time of highest metabolic rate. Larvae ceased feeding before the next moult and lost weight. Adult females did not cease feeding and never lost weight. Mated females maintained a high feeding rate that corresponded to a constant oviposition rate with no gonotrophic cycles. Virgin females maintained a lower feeding rate and maintained fully mature eggs in a viable state for life.Growth during the last larval stadium was entirely somatic and characterized by a great accumulation of a lipid rich (65%) fat body. Net growth during the first 10 days of adult life was entirely gonodal, because the small amount of residual body growth was matched by the amount of fat body loss. However, since the residual body was 60% protein and the fat body was 60% lipid, some of the somatic protein growth had to come from the diet and some of the fat body lipid went for ovarial growth.The 20% dietary protein was more than sufficient for all somatic and ovarial growth, and some protein was catabolized for energy. The amount of uric acid in larval faeces accounted for almost all protein catabolism, but in adult females half of the catabolized protein nitrogen did not appear in the faeces. With only 5% dietary lipid both larvae and adults had to synthesize additional lipids from carbohydrates to supplement absorbed lipids for growth demands. Almost all absorbed and synthesized lipids were used for somatic growth in the larvae and for ovarial growth in the adults, because the per cent of food calories used for growth greatly exceeded the per cent dry weight of food used for growth. Based on the calories and dry weight of available fuel, almost all energy production was based on carbohydrate oxidation. Some carbohydrate was used for lipid synthesis but very little was used for growth.Probably the absorption efficiency (72%) and growth efficiency (28%) was the same for both the last instar larvae and virgin females because they ate exactly the same food. However, the larval metabolic efficiency (42%) was higher than that of females (37%), which indicated that more of the absorbed food was converted to tissue during larval growth (somatic) than during adult growth (ovarial).Of the dry weight of food eaten during the last larval stadium, 30% was egested, 32% was oxidized, 28% appeared as growth, and 10% was condensed to lipid and became part of the 28% growth. Of the dry weight of food eaten during the first 10 days of adult life, 27% was egested, 41% was oxidized, 25% appeared as growth, and 6% was condensed to lipid.     

The hormonal regulation of the larval diapause in the codling moth, Laspeyresia pomonella (Lep. Tortricidae)

The hormonal control of the facultative diapause of the codling moth has been investigated. The diapause can be divided into 4 phases or periods: (1) diapause induction by short-day conditions (SD) in young larvae, (2) initiation of the diapause in the early last larval instar by a high titre of juvenile hormone, (3) onset and maintenance of diapause with inactivity of the neuroendocrine system, as evidenced by the results of neck-ligation experiments, (4)termination of diapause by the production of ecdysteroid.Diapause-induced larvae pupated after spinning the cocoon, if the state of induction was changed by injection with the anti-juvenile hormone precocene II at the beginning of the last larval instar and subsequent results of neck-ligation experiments, (4) termination of diapause by the production of ecdysteroid. treated with juvenile hormone during the first 1.5 days after the last larval moult and subsequently reared under SD. Under LD, continuous application of juvenile hormone during the last larval instar and after spinning did not prevent the insects from moulting to either a supernumerary larva, a pupa or a larval-pupal intermediate. Termination of diapause, i.e. pupation, was achieved by injecting diapausing larvae with 20-hydroxyecdysone. Although juvenile hormone was found to have a prothoractropic effect in diapausing larvae, no pupal moult could be induced by the application of the hormone. Contrary to the hormonal situation before pupation of nondiapausing larvae, no juvenile hormone could be detected before or during the pupation of larvae after diapause.