Prothoracicotropic Hormone Acts as a Neuroendocrine Switch between Pupal Diapause and Adult Development

Diapause is a programmed developmental arrest that has evolved in a wide variety of organisms and allows them survive unfavorable seasons. This developmental state is particularly common in insects. Based on circumstantial evidence, pupal diapause has been hypothesized to result from a cessation of prothoracicotropic hormone (PTTH) secretion from the brain. Here, we provide direct evidence for this classical hypothesis by determining both the PTTH titer in the hemolymph and the PTTH content in the brain of diapause pupae in the cabbage army moth Mamestra brassicae. For this purpose, we cloned the PTTH gene, produced PTTH-specific antibodies, and developed a highly sensitive immunoassay for PTTH. While the hemolymph PTTH titer in non-diapause pupae was maintained at high levels after pupation, the titer in diapause pupae dropped to an undetectable level. In contrast, the PTTH content of the post-pupation brain was higher in diapause animals than in non-diapause animals. These results clearly demonstrate that diapause pupae have sufficient PTTH in their brain, but they do not release it into the hemolymph. Injecting PTTH into diapause pupae immediately after pupation induced adult development, showing that a lack of PTTH is a necessary and sufficient condition for inducing pupal diapause. Most interestingly, in diapause-destined larvae, lower hemolymph titers of PTTH and reduced PTTH gene expression were observed for 4 and 2 days, respectively, prior to pupation. This discovery demonstrates that the diapause program is already manifested in the PTTH neurons as early as the mid final instar stage.     

Role of the brain in post-diapause adult development in the swallowtail, Papilio xuthus

The role of the brain in adult development was examined by brain removal in unchilled and chilled diapausing pupae of Papilio xuthus. Chilling was effective in shortening the pupal duration and synchronizing adult emergence, although photoperiod had little effect on diapause development. The brain played a role of shortening the pupal duration and synchronizing adult emergence in both unchilled and chilled individuals, although it was not essential for post-diapause adult development. The stimulus of low temperature was recorded even in the absence of the brain, because chilling shortened the pupal duration in brainless individuals. The brain showed activity which affected subsequent adult development in chilled pupae within one day after chilling in males. This period was less limited in females.     

Endocrine Mechanisms Regulating Post-Diapause Development in the Cabbage Armyworm,Mamestra brassicae

Diapause, a programmed developmental arrest at a specific stage, is common in insects and is regulated by hormones. It is well established that in pupal diapause, cessation of ecdysteroid secretion from the prothoracic glands (PGs) after pupal ecdysis leads to diapause initiation, while resumption of its secretion induces post-diapause development. However, what regulates the activity of the glands is poorly understood, especially for the glands of diapause-terminated pupae. In the present study, we investigate the mechanisms by which post-diapause development is regulated in the cabbage armyworm Mamestra brassicae. We demonstrate that the brain is necessary for the initiation of post-diapause development and that the factor in the brain responsible for the activation of the PGs is the prothoracicotropic hormone (PTTH). Further, through measuring the hemolymph PTTH titers by time-resolved fluoroimmunoassay, we show that PTTH is actually released into the hemolymph prior to the activation of the PGs. Although its peak titer is much lower than expected, this low concentration of PTTH is most likely still effective to activate the PGs of post-diapause pupae, because the responsiveness to PTTH of the glands at this stage is very high compared to that of nondiapause pupal PGs. These results strongly suggest that in M. brassicae, PTTH serves as a trigger to initiate pupa-adult development after diapause termination by stimulating the PGs to secrete ecdysteroid.     

Ecdysteroids and diapause in pupae of Heliothis punctiger

Most pupae of H. punctiger enter diapause when reared at 19°C, 12L:12D. When pharate pupae were treated for only 12 hr at 28°C about 50% developed at 19°C. The proportion of non-diapausing pupae increased as the temperature at which the pharate pupal stage was spent increased.The quantity of injected 20-hydroxyecdysone necessary to promote development in diapausing pupae varied from about 1 μg g^?1 soon after pupation to about 4 μg g^?1 after 50 days. It fell somewhat after 150 days.Removing brains from non-diapausing pupae showed that the brain secreted its hormone at the time of pupation (or just before). However, if the pupae were kept at 19°C development did not occur unless the brain remained in situ for at least 20 hr at 28°C. Implanting brains from non-diapausing pupae into diapausing ones had no measurable effect.These results may be explained by postulating that the prothoracic gland is ‘activated’ by exposure to high temperature, but that it reverts to inactivity over a period at 19°C. The ‘active’ gland must then be stimulated by brain hormone for a long period to trigger secretion of its hormone, which results in development. Diapause is thus the result of the failure of the prothoracic gland to secrete.     

Post-embryonic functions of HSP90 in Tribolium castaneum include the regulation of compound eye development

Heat shock protein 90 (HSP90) belongs to a family of conserved chaperons with multiple roles in stress adaptation and development, including spermatogenesis, oogenesis and embryogenesis in insects. In the red flour beetle, Tribolium castaneum, we found that HSP90 is transiently upregulated during larval development, in prepupae, in female pupae and in adults, suggesting multiple post-embryonic roles. We found that silencing HSP90 expression by RNA interference was lethal within 10 days at all developmental stages. Titration experiments revealed that larvae were more susceptible than pupae or beetles. Interestingly, HSP90 silencing in final instar larvae resulted in abnormal pupal phenotypes lacking compound eyes and exhibiting prepupal features, suggesting developmental arrest at the prepupal stage. Our results suggest that HSP90 functions can be expanded beyond the known ones in insect embryogenesis to include roles in post-embryonic development such as the regulation of compound eye development.     

Comparative studies of oxidative enzyme systems in epidermis and fat body of diapausing and non-diapausing silkmoths

The activities of four oxidative enzyme systems, including NADH oxidase, succinate-cytochrome c reductase, NADH-cytochrome c reductase, and cytochrome c oxidase, were compared in mitochondrial-microsomal preparations from wing epidermis and fat body of diapausing Samia cynthia pupae, presumptively non-diapausing S. cynthia ricini pupae which were caused to diapause by removal of the brain, and non-diapausing S. cynthia ricini during the pupal and pharate adult period. In diapausing pupae the activities of all enzyme systems were low and presented a profile similar to that previously reported for the Cecropia silkmoth. By contrast, in non-diapausing individuals the activities showed substantially higher levels, and an essentially unchanging pattern from just after the larval-pupal ecdysis through most of adult development. These events are functionally correlated with the patterns of biosynthetic activity in diapausing and non-diapausing silkmoths and are discussed in relation to the endocrine control of diapause and development.     

Hormonal control of seasonal morphs by the timing of ecdysteroid release in Araschnia levana L. (Nymphalidae: Lepidoptera)

Araschnia levana L. occurs in two seasonal morphs. Larvae reared under short-day conditions become diapause pupae and emerge as red spring-morph butterflies. Long-day larvae become non-diapause pupae, which emerge as black and white summer morphs. Pupae reared under these different conditions were joined in parabiosis. Both underwent adult development without diapause and the long-day animals developed into the summer morph as normal. The morph of short-day animals depended on the time of parabiosis. When they were joined to fresh long-day pupae 1 day after their own pupation, summer morphs resulted. When parabiosis began 4 days after pupation or later, spring morphs resulted. Extirpation of the brain-corpora cardiaca-allata complex from long-day pupae affected neither non-diapause development nor the summer morph. Adult development could be prevented by removal of head and prothorax. When adult development was initiated in the remaining bodies by 20-hydroxyecdysone 14 days after pupation, the spring morph resulted.—Injection of 20-dydroxyecdysone into 3-day-old short-day pupae initiated adult development and led to the summer morph. Injections into 10-day-old short-day pupae led to the spring morph. The same was true in diapause pupae deprived of their brain-corpora cardiaca-allata complex. These results indicate that seasonal diphenism in A. levana is controlled only by the timing of ecdysteroid release, which initiates adult development. There is no direct influence of the brain on wing coloration.     

Role of the brain and ring gland in regulation of pupal diapause in the flesh fly Sarcophaga crassipalpis

Larvae of Sarcophaga crassipalpis photoperiodically programmed for pupal diapause pupariate later than larvae programmed for continuous development. Pupariation time is determined by the brain-ring gland complex as evidenced by transplantation experiments in which the timing of pupariation was transferred from one larva to another by transplantation of the brain-ring gland complex. The developmental commitment (diapause or nondiapause) of the larva also can be transferred with the brain-ring gland complex if the recipient's own neuroendocrine system is suppressed by ring gland extirpation. Thus, photoperiodic programming of the brain-ring gland complex is not only responsible for developmental commitment but also for determining the duration of the prepupal period. Surgical experiments with pupae indicate that an intact brain-ring gland complex is required for diapause termination and initiation of adult development. Pupae fail to break diapause if either the brain or the ring gland is removed or if their nervous connections are severed.     

Ecdysteroid levels during post-diapause development and 20-hydroxyecdysone-induced development in male pupae of Mamestra configurata Wlk.

Post-diapause development in male pupae of Mamestra configurata Wlk. was characterized by the appearance of large, transitory peaks of ecdysone (2.8 μg/g live wt) at day 8 and 20-hydroxyecdysone (2.2 μg/g) at day 12 which declined to low levels prior to adult eclosion at day 28.Treatment of diapausing pupae with 20-hydroxyecdysone elicited a progression of dose-dependent physiological and pathological effects, including termination of diapause, development, accelerated development, and accelerated development leading to malformation and death. At a dose of 7.5 μg 20-hydroxyecdysone/g, all treated pupae terminated diapause, developed with little mortality and produced a high proportion of morphologically perfect adults. However, there were no large peaks of ecdysone or 20-hydroxyecdysone in treated pupae, possibly due to feedback inhibition by 20-hydroxyecdysone.At doses greater than 7.5 μg/g, development was accelerated markedly, survival decreased precipitously (0% at 15 μg/g) and the proportion of malformed adults increased sharply. Pupae that received a lethal dose of 20-hydroxyecdysone died almost synchronously after undergoing accelerated development for 18–20 days, indicating that they encounter a common, hormone-induced developmental block. Pupae receiving 15 μg/g also showed no edcysone or 20-hydroxyecdysone peaks, but had a prolonged period of hyperecdysonism which likely caused their accelerated development and death.     

Effects of caffeine and aminophylline on adult development of the Cecropia silkmoth

Caffeine and aminophylline were potent inhibitors of adult development in the moth, Hyalophora cecropia, when administered prior to initiation of pharate adult development. A dose of 1 mg/g live weight was 100 per cent effective in bringing about this arrest. Cyasterone and α-ecdysone induced development in arrested animals and arrested dauer pupae. Brain transplant and perfusion experments indicated that synthesis or release of brain hormone was disrupted by these drugs. In addition, the effects of ecdysone and perfusion on arrested animals suggested that methylxanthines may also act at other sites in the sequence of events leading to adult development.     

The biology ofHyperaspis jucunda [Col.: Coccinellidae] an exotic predator of the cassava mealybugPhenacoccus manihoti [Hom.: Pseudococcidae] in southern Nigeria

The biology ofHyperaspis jucunda (Muls.) was studied at 27°C and the incubation period averaged 5.1 days. The 1st, 2nd, 3rd and 4th larval instar averaged 2.5; 2.8; 3.4 and 5.0 days respectively. Larval development was completed in about 13.8 days while it took 7.1 days for the pupae. The total developmental time averaged 26.4 days. Mean longevity was 100 and 101 days for males and females respectively. The premating period was 19–24 h while the preoviposition period averaged 6.3 days. The generation cycle (egg to egg) averaged 32.8 days. The oviposition period was about 93 days during which an average female laid 456 eggs.     

The Apis mellifera pupal melanization program is affected by treatment with a juvenile hormone analogue

Apis mellifera treated during different developmental phases with pyriproxyfen, a juvenile hormone analogue, show profound alterations in cuticular pigmentation and sclerotization. When the treatment is effected during the feeding phase of the fifth larval instar (LF5), the pupal development is blocked and pigmentation does not occur. Treatment of older larvae, at the spinning phase of the fifth larval instar (LS5), of prepupae (PP) or pupae at the beginning of the pupal period (Pw, white-eyed, unpigmented cuticle pupae) does not impair pigmentation, but, instead, this process is accelerated, intensified and abnormal. Hormonal treatment during these developmental phases (LS5, PP and Pw) induces earlier activity of phenoloxidase, an enzyme of the reaction chain leading to melanin synthesis. Treated pupae have significantly higher enzymatic levels and show a graded response in phenoloxidase activity after treatment with 0.1, 1 or 5&mgr;g pyriproxyfen. Besides pigmentation, other developmental events were also altered in treated bees: pupal development was shortened, and the expression of esterase-6 activity, the onset of which coincides with the beginning of pigmentation, was shifted with the precocious initiation of this process in treated pupae. The significance of these results is discussed in relation to the mode of hormonal action on cuticular pigmentation in insects.     

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.     

家蚕胚后发育中过氧化氢的代谢及其意义(英文)

活性氧参与生物体内复杂的代谢过程。本文对它在家蚕个体发育过程中的生物学功能进行了初步探讨。 取１岁龄家蚕蛹分别注射Ｈ２Ｏ２、脱皮激素（Ｅｃｄｎ）、保幼激素（ＪＨ）和还原型谷胱苷肽（ＧＳＨ）,培养;定期取样测定家蚕体内Ｈ２Ｏ２含量。 对家蚕整个幼虫期（Ｆｉｇ．１）,尤其是大眠期（Ｆｉｇ．２）、化蛹期（Ｔａｂｌｅ１）、蛹期（Ｆｉｇ．３－ａ,ｂ,ｃ）以及成虫期（Ｆｉｇ．４, Ｔａｂｌｅ ２）的研究结果表明,家蚕体内Ｈ２Ｏ２代谢具有如下特点：（１）入眠、化蛹、化蛾和死亡前Ｈ２Ｏ２含量都显著下降;（２）幼虫期１－３龄Ｈ２Ｏ２含量逐步下降,４～５龄Ｈ２Ｏ２含量回升,蛹期和成虫期Ｈ２Ｏ２含量与４～５龄接近;（３）每个龄期的中期Ｈ２Ｏ２含量最高;（４）ＣＡＴ活性与Ｈ２Ｏ２含量呈负相关变化,前者迟于后者;另外,ＣＡＴ活性远远大于ＳＯＤ活性;（５）Ｅｃｄｎ、ＧＳＨ处理可以降低家蚕蛹期Ｈ２Ｏ２含量,并使其提前下降,ＪＨ、Ｈ２Ｏ２处理含量下降,并相应地提早推迟化蛾;（６）成虫期雄蛾Ｈ２Ｏ２含量、ＳＯＤ和ＣＡＴ活性都显著高于同时期雌蛾。家蚕体内Ｈ２Ｏ２含量的变化与其发育密切相关。Ｈ２Ｏ２含量下降是变态的信号;家蚕成虫期Ｈ２Ｏ２ 在性别上的     

Developmental arrest induced by juvenile hormone in larvae of Bombyx mori

Injection of the juvenile hormone analog (JHA) methoprene into day 3, fifthinstar larvae of Bombyx mori induced developmental arrest. Feeding activity declined, and the larvae remained as larvae for more than 2 weeks, after which they died. After JHA injection, the hemolymph ecdysteroid titer was low, and the prothoracic glands were almost inactive for 7 days. During this period, prothoracic glands were stimulated by prothoracicotropic hormone (PTTH) in vitro, indicating that JHA did not inhibit the competence of the glands to respond to PTTH. When brain-corpora cardiaca-corpora allata complexes were removed from intact fifth-instar larvae on day 4, the prothoracic glands became autonomously active and produced enough ecdysone for pupation. When PTTH injections were given to larvae previously injected with JHA (7 days before), the larvae recovered feeding activity, purged their guts, and pupated. Injections of 20-hydroxyecdysone into larvae that had been injected with JHA 7 days earlier induced larval molting. These results suggest that JHA affects both the brain and the prothoracic gland.     

Comparison of the circadian eclosion rhythm between non-diapause and diapause pupae in the onion fly,Delia antiqua

The influence of pupal diapause on adult eclosion rhythm of Delia antiqua was investigated. When non-diapause and diapause pupae were exposed to various photoperiods at 15, 20 and 25 °C, both of them emerged as adults close to the light-on time, but the phase of eclosion varied with photoperiod and temperature. Moreover, there was a significant difference in the eclosion time between non-diapause and diapause pupae; the eclosion peak of diapause pupae was earlier than that of non-diapause pupae. When non-diapause and diapause pupae were transferred to constant darkness (DD) after having experienced LD 12:12 at 15, 20 and 25 °C, both showed circadian rhythmicity in eclosion. Although the free-running period (τ) decreased slightly as temperature increased in both non-diapause and diapause pupae, the latter tended to show shorter τ than the former. This observation suggests that the observed difference in eclosion time in LD cycles between non-diapause and diapause pupae is due to differences in τ.     

Ecdysteroids control eyespot size and wing color pattern in the polyphenic butterfly Bicyclus anynana (Lepidoptera: Satyridae)

The strongly polyphenic African butterfly, Bicyclus anynana, shows conspicuous ventral eyespots and a transverse band in the wet-season form and small eyespots and no band in the dryseason form. These forms are produced when larvae are reared at high and low temperatures, respectively. Truncation selection was applied to a stock population (UNSELECTED-LINE) to produce lines which, at a constant intermediate temperature of 20 °C, always produced the dry season form (LOW-LINE) and the wet-season form (HIGH-LINE) in addition to a line of fast development (FAST-LINE). A relationship between wing pattern and development time was apparent: the FAST-LINE displayed larger eyespots and HIGH-LINE pupae developed faster (mean = 12.5 days) than LOW-LINE pupae (14.1 days). Differences were found among the lines in ecdysteroid titers after pupation. Hemolymph ecdysteroids in HIGH-LINE pupae increased earlier and reached twice the level of those in LOW-LINE pupae during the first 3 days after pupation. FAST-LINE pupae developed faster (11.7 days) than UNSELECTED-LINE pupae (12.8 days) and ecdysteroids in the FAST-LINE increased more quickly and reached higher levels. In the four LINES, ecdysteroid titers in 3 day old pupae were in the order UNSELECT ≈ LOW ⪡ FAST ⪡ HIGH. Thereafter the titers overlapped.An injection of 20-hydroxyecdysone (20E) inhibited pupal development at a dose between 2.5 and 5 μg when it was injected into pupae within 24 h after pupation. At lower doses (0.25–0.5 μg 20E) 22–100% of the pupae in different experimental groups in the LOW- as well as in the HIGH-LINE developed successfully. The pupal stage was significantly shortened, especially in the LOW-LINE. Additionally, 0.25 and 0.5 μg 20E injected into 0–12 h LOW-LINE pupae shifted the wing color pattern towards the wet season form: eyespots increased in size and the transverse wing band appeared in the more conspicuous pattern characteristic of the wet season form. The results demonstrate that ecdysteroids appearing early in the young pupa produce the wet season form of the wings. The same hormonal system mediates both developmental time and wing pattern determination.     

Comparison of the circadian eclosion rhythm between non-diapause and diapause pupae in the onion fly,Delia antiqua: the effect of thermoperiod

When non-diapause and diapause pupae of Deliaantiqua were exposed to various thermoperiods where thermophase (T) was 25 °C and the cryophase (C) was 15 or 20 °C (TC₁₅ or TC₂₀) in constant darkness (DD), the majority of both types of flies emerged before the rise in temperature. Eclosion time was delayed at the lower cryophase temperature. Moreover, there was a significant difference in the time of adult eclosion between non-diapause and diapause pupae; diapause pupae eclosed earlier than non-diapause pupae. When the two types of pupae were transferred to a constant low temperature (15 or 20 °C) after having experienced TC₁₅ or TC₂₀ 12:12 h, they showed circadian rhythmicity in eclosion. The free-running period (τ) of the eclosion rhythm changed after transfer to constant low temperatures in both non-diapause and diapause pupae, suggesting that this change represents a transient cycle until the temperature-sensitive oscillator is coupled again to the temperature-insensitive pacemaker. However, diapause pupae tended to show a shorter τ than non-diapause pupae. This observation suggests that the difference in adult eclosion time under thermoperiodic conditions between non-diapause and diapause pupae is related to their different τ s.