Steroid induction of a peptide hormone gene leads to orchestration of a defined behavioral sequence.

At the end of each molt, insects shed the old cuticle by performing preecdysis and ecdysis behaviors. Regulation of these centrally patterned movements involves peptide signaling between endocrine Inka cells and the CNS. In Inka cells, we have identified the cDNA and gene encoding preecdysis-triggering hormone (PETH) and ecdysis-triggering hormone (ETH), which activate these behaviors. Prior to behavioral onset, rising ecdysteroid levels induce expression of the ecdysone receptor (EcR) and ETH gene in Inka cells and evoke CNS sensitivity to PETH and ETH. Subsequent ecdysteroid decline is required for peptide release, which initiates three motor patterns in specific order: PETH triggers preecdysis I, while ETH activates preecdysis II and ecdysis. The Inka cell provides a model for linking steroid regulation of peptide hormone expression and release with activation of a defined behavioral sequence.     

The endocrine regulation of wing polymorphism in insects: state of the art, recent surprises, and future directions

The endocrine mechanisms controlling the development and reproduction of flight-capable (long-winged) and flightless (short-winged or wingless) morphs of wing-polymorphic insects have been intensively investigated. The "classical model," put forward in the early 1960s, postulates that morph-specific differences in development and reproduction are caused by variation in the titers of juvenile hormone (JH) and/or ecdysone. Despite decades of study, the importance of these hormones in regulating wing polymorphism in aphids and planthoppers remains uncertain. This uncertainly is largely a consequence of technical and size constraints which have severely limited the types of endocrine approaches that can be used in these insects. Recent studies in wing-polymorphic crickets (Gryllus) have provided the first direct evidence that the in vivo blood titers of juvenile hormone and ecdysone, and especially the activity of the JH regulator, juvenile hormone esterase, differ between nascent morphs. Morph differences are largely consistent with the classical model, although some types of data are problematic, and other explanations are possible. Adult morphs differ dramatically in the JH titer but titer differences are more complex than those proposed by the classical model. Detailed endocrine information is thus far available only for a few species of crickets, and the hormonal control of wing polymorphism for insects as a whole remains poorly understood. Future studies should continue to investigate the role of JH and ecdysteroids in morph development and reproduction, and should expand to include studies of morph-specific differences in hormone receptors and neurohormones.     

昆虫卵黄发生研究进展

昆虫卵黄发生研究进展李乾君,龚和,管致和（中国科学院动物研究所北京１０００８０）（北京农业大学植保系北京１０００９４）昆虫卵的成熟一般分为三个时期－－卵黄发生前期（Ｐｒｅｖｉｔｅｌｌｏｇｅｎｉｃｓｔａｇｅ）、卵黄发生期（ｖｉｔｅｌｌｏｇｅｎｉｃｓｔａ...     

The roles of central and peripheral eclosion hormone release in the control of ecdysis behavior in Manduca sexta

1. Ecdysis, a behavior by which insects shed the old cuticle at the culmination of each molt, is triggered by a unique peptide hormone, eclosion hormone (EH). In pupal Manduca sexta, EH is released into the hemolymph just prior to ecdysis, and circulating hormone is sufficient to elicit this behavior. 2. Removal of the proctodeal nerves in prepupal animals eliminated the appearance of blood-borne EH, but ecdysis behavior occurred on schedule. Therefore, circulating EH is not necessary for the triggering of ecdysis. 3. In contrast, a set of dermal glands failed to show their expected bout of secretion after proctodeal nerve removal. Injection of exogenous EH rescued this secretion. Thus, circulating EH appears necessary for action on peripheral but not central targets. 4. A major reduction in EH immunostaining is seen in the proctodeal nerves just preceding ecdysis; this coincides with a greater than 90% reduction in extractable EH from this structure and the appearance of circulating EH. A similar, concomitant reduction was seen in central EH cell processes, suggesting release of peptide within the CNS. 5. Antidromic stimulation of the proctodeal nerve stumps following proctodeal nerve removal triggered precocious ecdysis. This result further supports the conclusion that centrally released EH is sufficient to trigger the motor program.     

Ecdysteroid and juvenile hormone changes in Bombyx mori eggs, related to the initiation of diapause

We describe a method for the routine determination of changes in juvenile hormone levels in insect eggs. The hormones are first converted into their diol derivatives, then they are purified from other lipids and separated by high-performance liquid chromatography (HPLC). The radioimmunoassay of the fractions was then determined. The method permits the simultaneous assay of ecdysteroids, and it was used for determining the hormonal changes in Bombyx eggs during the pre-diapause development. Our major finding is that the hormonal content of eggs dramatically increased prior to the initiation of diapause. This hormonal rise included ecdysone, 20-OH-ecdysone and 3 juvenile hormones. The HPLC retention time of the latter corresponded to JH₁ JH₂ and JH₃. Subsequently, the embryos entered diapause and the hormonal content of eggs was reduced to traces of ecdysteroids. These dramatic changes in juvenile hormone levels during early embryogenesis raise a number of issues which are developed in the discussion.     

昆虫蜕皮行为的生理生化和分子生物学研究进展

羽化激素与蜕皮触发激素诱发昆虫蜕皮行为及蜕皮末期的其它生理变化。羽化激素在一些特定的脑神经分泌细胞中合成,在蜕皮激素的调控下,释放到中枢神经系统和血淋巴中。蜕皮触发激素是由Inka细胞分泌的,直接作用于中枢神经系统,触发前蜕皮和蜕皮行为。越来越多的证据表明羽化激素可能存在于所有的昆虫中,并作为一种调节蜕皮的一般性激素机制。     

Hormonal regulation of gametogenesis in insect

The review discusses the role of juvenile hormone (JH), ecdysone and brain in the regulation of oogenesis and spermatogenesis in insects. The early period of gametogenesis (gonial mitoses, the meiotic prophase) in both sexes is controlled mainly by ecdysone and neurosecretory cells of the brain. In periods of cytoplasmic growth of oocytes and vitellogenesis the main role in the regulation belongs to JH. The modern views on hormonal regulation of vitellogenin synthesis and follicular epithelium differentiation are under consideration with a special reference of the role of ecdysteroids in Diptera and Lepidoptera oogenesis.     

Molecular-genetic mechanisms of the effect of developmental hormones in insects

A review of the available data on molecular mechanisms underlying the regulation of gene expression by the developmental hormone ecdysone and juvenile hormone. Heterodimer ESP/USP is the main ecdysone receptor in D. melanogaster. Structures similar to ESP/USP were found in other insects. The information about molecular-genetic mechanisms of the effect of juvenoids is less definite. It has been proposed that the juvenile hormone in insects is a modulator of the ecdysone effect.     

Inhibition of the larval ecdysis and emergence behavior of the parasitoid Cotesia congregata by methoprene

Parasitism of the tobacco hornworm, Manducasexta, by the braconid wasp Cotesiacongregata, induces developmental arrest of the host in the larval stage. During the final instar of the host, its juvenile hormone (JH) titer is elevated, preventing host metamorphosis. This study investigated the effects of hormonal manipulation of the host on the parasitoid’s emergence behavior. The second larval ecdysis of the wasps coincides with their emergence from the host, and application of the juvenile hormone analogue methoprene to day 4 fifth instar hosts either delayed or totally suppressed the subsequent emergence of the wasps. Effects of methoprene were dose-dependent and no parasitoids emerged following treatment of host larvae with doses >50 μg. Parasitoids which failed to emerge eventually succumbed as unecydsed pharate third instar larvae in the hemocoel of the host. Effects of host methoprene treatment on parasitoid metamorphosis were also assessed, and metamorphic disruption occurred at much lower dosages compared with doses necessary to suppress parasitoid emergence behavior. The inhibitory effect of methoprene on parasitoid emergence behavior appears to be mediated by effects of this hormone on the synthesis or release of ecdysis-triggering hormone (ETH) in the parasitoid, the proximate endocrine cue which triggers ecdysis behavior in free-living insects. ETH accumulated in the epitracheal Inka cells of parasitoids developing in methoprene-treated hosts, suggestive of a lack of hormone release. Thus, the hormonal modulation of parasitoid emergence behavior appears to be complex, involving a suite of hormones including JH, ecdysteroid, and peptide hormones.     

Deficiency of prohormone convertase dPC2 (AMONTILLADO) results in impaired production of bioactive neuropeptide hormones in Drosophila

Peptide hormones synthesized by secretory neurons in the CNS are important regulators of physiology, behavior, and development. Like other neuropeptides, they are synthesized from larger precursor molecules by a specific set of enzymes. Using a combination of neurogenetics, immunostainings, and direct mass spectrometric profiling, we show that the presence of Drosophila prohormone convertase 2 encoded by the gene amontillado (amon) is a prerequisite for the proper processing of neuropeptide hormones from the major neurohemal organs of the CNS. A loss of amon correlates with a loss of neuropeptide hormone signals from the larval ring gland and perisympathetic organs. Neuropeptide hormone signals were still detectable in the adult corpora cardiaca of older amon-deficient flies which were amon heat-shock-rescued until eclosion. A semiquantification by direct peptide profiling using stable isotopic standards showed, however, that their neuropeptide hormone levels are strongly reduced. Targeted expression of GFP under the control of amon regulatory regions revealed a co-localization with the investigated peptide hormones in secretory neurons of the brain and ventral nerve cord. The lack of AMON activity resulted in a deficiency of L3 larva to enter the wandering phase. In conclusion, our findings provide the first direct evidence that AMON is a key enzyme in the production of neuropeptides in the fruitfly.     

Changes in ecdysteroid and juvenile hormone levels in developing eggs of Bombyx mori

It is well-known that insect eggs can contain very high concentrations of ecdysteroids, which undergo drastic changes during embryogenesis. We found that this is equally valid for juvenile hormones. Three juvenile hormone-immunoreactive compounds were observed in developing Bombyx mori eggs. They were assumed to be juvenile hormones 1, 2 and 3 according to their retention time in HPLC. These hormones underwent drastic and sudden changes. In the space of one day their concentration was seen to rise rapidly from an undetectable level up to as high as 4 × 10^?6 micromoles per mg of eggs. Their presence was detected as early as the first day of embryonic development, as well as during the blastokinesis period (day 5 to day 9) and in late embryos (day 12 to day 14). Their relative concentrations varied greatly. On two occasions, day 1 and day 8, all three hormones were simultaneously present. Moreover, juvenile hormone 3 was present during the blastokinesis period, either alone or in combination with hormone 2. The latter was the only hormone present in late embryos, before hatching. Thus, with regard to both ecdysteroids (ecdysone and 20-hydroxyecdysone) and juvenile hormones, each day of embryonic development displayed a different hormonal pattern. These patterns undoubtedly constitute a “hormonal code” of embryogenesis control. While 20-hydroxyecdysone can be assumed to trigger cuticulogenesis in embryos as it does in larvae, the effects of the other hormones as well as their possible interactions are questionable.     

Molecular-genetic mechanisms of the effect of developmental hormones in insects

A review of the available data on molecular mechanisms underlying the regulation of gene expression by the developmental hormone ecdysone and juvenile hormone. Heterodimer ESP/USP is the main ecdysone receptor in D. melanogaster. Structures similar to ESP/USP were found in other insects. The information about molecular-genetic mechanisms of the effect of juvenoids is less definite. It has been proposed that the juvenile hormone in insects is a modulator of the ecdysone effect.     

Ecdysone,juvenile hormone and oögenesis in Rhodnius prolixus

Oviposition and oögenesis can be inhibited in female Rhodnius prolixus by ecdysone given by the digestive tract. The inhibition is dose-dependent, and doses higher than 4.0 ng ecdysone/mg body weight drastically reduce the size and shape of the whole ovaries. In ecdysone-treated insects, normal oviposition and oögenesis can be re-established by a subsequent blood meal without ecdysone, or by the application of a juvenile hormone analogue.These results suggest that ecdysone inhibits juvenile hormone production.     

Structure-activity relationship of ETH during ecdysis in the tobacco hornworm, Manduca sexta

In insects, ecdysis or shedding of the old cuticle, consists of a series of behaviors that are regulated by the coordinated actions of a number of neuropeptides, one of which is ecdysis triggering hormone (ETH). ETH acts directly on central pattern generators of the abdominal ganglia to trigger onset of pre-ecdysis behaviors, as well as indirectly to activate release of eclosion hormone, thereby inducing onset of ecdysis behaviors through a cGMP-mediated mechanism. We assessed the minimal C-terminal amino acids required for biological activity of ETH, by assessing: (i) onset of pre-ecdysis and ecdysis behaviors in vivo, after injection of peptide analogs, (ii) onset of fictive pre-ecdysis and ecdysis motor patterns in vitro, as recorded extracellularly, after incubation of the CNS with the peptide analogs, and (iii) accumulation of cGMP within cells of the abdominal ganglia, as assessed immunohistochemically. Amidation of ETH at the C-terminus was required to elicit a biological response in vivo and in vitro, as well as an accumulation of cGMP within the CNS. The five amino acid amidated C-terminus of ETH (NIPRMamide) was the minimal moiety able to induce a robust pre-ecdysis response in vivo and in vitro, while a seven amino acid core (NKNIPRMa) was required for induction of ecdysis, including accumulation of cGMP immunoreactivity within the CNS. Analogs smaller than 12 amino acids in length were only active at very high concentrations in vivo, suggesting that smaller fragments might be susceptible to hemolymph degradation. Some alanine substitutions or removal of internal amino acids altered the activity of ETH, as well as the time of onset of ecdysis behaviors, suggesting that internal amino acids play a role in maintaining proper folding of the peptide for successful binding or activity at the ETH receptor.     

The Circadian Control of Eclosion

Eclosion is the stage in development when the adult insect emerges from the shell of its old cuticle. The sequence of behaviors necessary for eclosion is coordinated by an integrated system of hormones and is activated by hormones that relay developmental readiness. The circadian clock, which controls the timing of behaviors such as the rest:activity rhythm of adult insects, also controls eclosion timing. A number of groups are actively investigating the mechanisms by which the circadian clock restricts or gates eclosion to a particular time of day. Data from these studies are beginning to reveal details of the molecular and physiological basis of the eclosion rhythm.     

The circadian control of eclosion

Eclosion is the stage in development when the adult insect emerges from the shell of its old cuticle. The sequence of behaviors necessary for eclosion is coordinated by an integrated system of hormones and is activated by hormones that relay developmental readiness. The circadian clock, which controls the timing of behaviors such as the rest:activity rhythm of adult insects, also controls eclosion timing. A number of groups are actively investigating the mechanisms by which the circadian clock restricts or gates eclosion to a particular time of day. Data from these studies are beginning to reveal details of the molecular and physiological basis of the eclosion rhythm.