Changes in the amount of the diapause factor in the subesophageal ganglion during development of the silkworm, Bombyx mori

Changes in the diapause factor content of the subesophageal ganglion of the silkworm were examined from the viewpoint of sex and voltinism differences. The diapause factor content was comparatively low from the 4th larval ecdysis to the larval-pupal ecdysis, irrespective of sex and voltinism. However, remarkable changes occurred after the larval-pupal ecdysis. An interesting finding is that the diapause factor content in the female diapause egg-producer decreased gradually with pupal-adult development, but in the male diapause egg-producer as well as in the non-diapause egg-producer it increased up to the half-way stage in the pupal-adult development. This suggests that the diapause factor is not secreted from the subesophageal ganglion of the male pharate adult of the diapause egg-producer. This finding was confirmed by implantation experiments using brain-subesophageal ganglion complex or only subesophageal ganglion.     

Induction of egg diapause by implantation of corpora cardiaca and corpora allata in Bombyx mori

Diapause egg production was examined in non-diapause egg producers by implantation of various cephalic organs into pharate adults 4 days after larval-pupal ecdysis. The implantation of five pairs of corpora cardiaca or corpora allata induced a great amount of egg diapause. Implantation of these organs was effective in inducing egg diapause even when the suboesophageal ganglion of the recipients had been removed, although the effect of the corpora allata decreased moderately. The injection of juvenile hormone into 4-day-old pharate adults did not greatly increase production of diapause eggs.     

Induction of Non-diapause Eggs by Imidazole Derivative KK-42 in the Diapause Type of Bombyx mori Silkworm

The injection of an imidazole compound, KK-42, into fifth instar larvae of a silkworm (Bombyx mori, Daizo strain), which had been destined to produce diapause eggs, induced the moths to lay non-diapause eggs. The critical period for KK-42 injection in the induction of non-diapause eggs was 24 h to 72 h after the fourth ecdysis. Topical application of KK-42 to 48 h-old fifth instar larvae also induced non-diapause eggs.     

Control of diapause-factor secretion from the suboesophageal ganglion in the silkworm,Bombyx mori: The roles of the protocerebrum and tritocerebrum

To localize any functional areas in the brain which control the secretion of the diapause factor from the suboesophageal ganglion in the Bombyx silkworm, various parts of the brain were excised or transected surgically. It was demonstrated that cortices slightly lateral to the median line on the dorsal side of the protocerebrum (Lmdp) are closely related to the inhibitory mechanism in the pupa producing non-diapause eggs. On the other hand, cortices of anterolateral areas on the ventral side of the protocerebrum (Alvp) participate in the stimulatory mechanism in the pupa producing diapause eggs. Moreover, it is suggested that the tritocerebrum is competent to stimulate secretion of the diapause factor from the suboesophageal ganglion not only in the pupae producing diapause eggs but also in the pupae producing non-diapause eggs. From these results, we propose a possible relationship between the Alvp, Lmdp and tritocerebrum concerning regulation of diapause-factor secretion from the suboesophageal ganglion.     

Relationship between photoperiod and secretion of the diapause hormone during larval stages of the silkworm, Bombyx mori L., reared on an artificial diet

The suboesophageal ganglion of the silkworm, Bombyx mori synthesizes sufficient diapause hormone to produce diapause eggs, regardless of the photoperiodic conditions experienced during the larval stages. When larvae destined to produce non-diapause eggs are implanted with the brain-suboesophageal ganglion complex from larvae which have been reared under short-day conditions, the resulting adults lay diapause eggs. The larvae receiving the complex from larvae reared under long-day conditions gave rise to adults which did not produce any diapause eggs. The brains from pupae which have been reared under long-day conditions show an activity inhibiting the secretion of diapause hormone by the suboesophageal ganglion. The mechanism through which the brain controls the secretion of diapause hormone from the suboesophageal ganglion can be modified by photoperiodic conditions during the larval stages.     

Light and electron microscopic studies on the neurosecretory control of diapause incidence in Pieris rapae crucivora

The incidence of diapause was shown to be determined humorally during the larval-pupal ecdysis by means of brain extirpation experiments.On the basis of this observation, light and electron microscopic changes in the neurosecretory type II cells in the pars intercerebralis-corpus cardiacum system during pharate pupal and early pupal stages were examined in insects reared under long day-length (non-diapause individuals) and in insects reared under short day-length (diapause individuals). In the diapause individuals, neurosecretory granules in NS-II cells increased during the pupal instar and large aggregates of granules packed the cytoplasm. Thereafter, inclusion bodies showing cytoplasmic breakdown of the granules appeared.In the non-diapause individuals, on the contrary, electron micrographs suggesting the release of neurosecretory material from axon terminals were obtained just after the pupal ecdysis. There were very few granules, with many Golgi bodies and much rough ER 8 to 12 hr after the ecdysis.It is concluded that adult development is determined by the release of neurosecretory material from the axon terminals of NS-II cells at the larval-pupal ecdysis. If release does not occur, the pupae enter diapause. It is also thought that differences in day-length during the larval stages influence the activities of NS-II cells before pupation.     

In vivo and in vitro photoperiodic induction of diapause using isolated brain-suboesophageal ganglion complexes of the silkworm,Bombyx mori

By use of a bivoltine silkworm race which shows a long-day photoperiodic response after induction during the last (5th) instar, we tried to programme photoperiodic induction in the isolated brain-suboesophageal ganglion complex in vivo and in vitro. A pair of the complexes from a newly ecdysed 5th-instar female was transplanted into the abdomen of a late 5th-instar larva and exposed to long-day (20 h light: 4 h dark) or short-day (8 h light: 16 h dark) conditions for 3 cycles. The short-day-exposed complexes elicited the production of diapause eggs in the recipient silkworms destined to become non-diapause egg producers, whereas the long-day-exposed brain complexes produced non-diapause eggs. Transplant experiments of the brain-suboesophageal ganglion complex using isolated abdomens showed a similar result. The brain complexes from newly ecdysed females of the 5th-instar were cultured in Grace's insect medium under 20 h light: 4 h dark or 8 h light: 16 h dark for 4 cycles, respectively. After in vitro culture, a pair of complexes was implanted into the abdomen of a late 5th-instar larva destined to become a non-diapause egg producer, and the diapause incidence in the resultant moths was examined. The brain complexes which received the short-day cycles induced a large portion of diapause eggs, whereas those which received the long-day conditions induced non-diapause eggs. The connection of corpora cardiaca and corpora allata with the brain complex had no influence on the result. Suboesophageal ganglia which had been cultured in vitro and implanted elicited a remarkable production of diapause eggs, but cultured brains were ineffective in producing diapause eggs, regardless of the photoperiod experienced. These results demonstrate that photoperiodic induction of the silkworm can be programmed in in vivo and in vitro culture systems, and that components of the photoperiodic clock (photoreceptor, clock, and counter system) are located in the brain-suboesophageal ganglion complex, possibly in the brain itself.     

Immunoreactive intensity of FXPRL amide neuropeptides in response to environmental conditions in the silkworm, Bombyx mori

In the silkworm Bombyx mori, the diapause hormone-pheromone biosynthesis activating neuropeptide gene, DH-PBAN, is a neuropeptide gene that encodes a polypeptide precursor consisting in five Phe-X-Pro-Arg-Leu-NH₂ (FXPRL) amide (FXPRLa) neuropeptides; DH (diapause hormone), PBAN (pheromone-biosynthesis-activating neuropeptide) and α-, β- and γ-SGNPs (subesophageal ganglion neuropeptides). These neuropeptides are synthesized in DH-PBAN-producing neurosecretory cells contained within three neuromeres, four mandibular cells, six maxillary cells, two labial cells (SLb) and four lateral cells of the subesophageal ganglion. DH is solely responsible, among the FXPRLa peptide family, for embryonic diapause. Functional differentiation has been previously suggested to occur at each neuromere, with the SLb cells releasing DH through brain innervation in order to induce embryonic diapause. We have investigated the immunoreactive intensity of DH in the SLb when thermal (25°C or 15°C) and light (continuous illumination or darkness) conditions are altered and following brain surgery that induces diapause or non-diapause eggs in the progeny. We have also examined the immunoreactivity of the other FXPRLa peptides by using anti-β-SGNP and anti-PBAN antibodies. Pupal SLb somata immunoreactivities seem to be affected by both thermal and light conditions during embryogenesis. Thus, we have been able to identify a close correlation between the immunoreactive intensity of neuropeptides and environmental conditions relating to the determination of embryonic diapause in B. mori.     

Establishment of a sandwich ELISA system to detect diapause hormone, and developmental profile of hormone levels in egg and subesophageal ganglion of the silkworm, Bombyx mori

In the silkworm Bombyx mori, diapause hormone (DH) is produced in the female subesophageal ganglion (SG) and induces embryonic diapause by targeting developing ovaries. DH is processed from a precursor protein consisting of DH, pheromone biosynthesis activating neuropeptide (PBAN) and three other neuropeptides (SGNPs). Because these five neuropeptides share a common sequence, FXPRLamide, at the C-terminus, a direct and specific assay for DH itself is required in order to understand the profile of concentration changes. In this study, we produced a mouse monoclonal antibody (anti-DH[N] mAb) against the N-terminal region of DH and developed a sandwich enzyme-linked immunosorbent assay using the anti-DH[N] mAb and a rabbit polyclonal antibody against the C-terminus of DH. This procedure enabled us to specifically quantify the DH molecule at femtomolar levels (equivalent to 1/10 of SG). We then plotted DH levels in eggs and SGs during embryonic and post-embryonic development. DH was present in late-stage embryos that had been destined for the production of both diapause and nondiapause eggs. DH levels in SG gradually increased in both types during larval development and peaked at the early pupal stage. At the middle pupal stage, DH levels in SG and SG-brain complex decreased markedly in the diapause-egg producing type, thus indicating active release of DH into the hemolymph. From 5th instar larva to adult, no sexual differences in DH levels were observed in SGs or SG-brain complexes from diapause and nondiapause egg-producing types.     

Hormonal control of seasonal morph determination in the swallowtail butterfly, Papilio xuthus L. (Lepidoptera: Papilionidae)

Seasonal morphs (spring and sumer forms) of Papilio xuthus L. are determined coincidentally with diapause and non-diapause in pupae by larval exposure to short days and long days respectively. The neuroendocrine principle underlying seasonal-morph determination was studied using surgical operations in P. xuthus.When recipient 0-day old or chilled diapause pupae were joined to donor 0-day old non-diapause pupae, the recipients developed into summer or intermediate morphs. When the same kinds of recipients used above were joined to 0-day old or chilled diapause pupae, there were no significant effects on the adult morph. In contrast, recipient non-diapause pupae all developed into summer morphs, regardless of groups of the type of donors.Furthermore, when the brain of 5th-instar larvae, pharate pupae or pupae, predetermined to be diapause, was transplanted into the abdomen of 0-day old, 30-day old or chilled diapause pupae, the recipients developed into summer or intermediate morphs.The results indicate that the brain of non-diapause pupae secretes a humoral factor producing the summer morph. In non-diapause pupae, the factor may be secreted at about the stage of larval-pupal ecdysis coincidentally with that of prothoracicotropic hormone.     

Physiological differentiation of DH-PBAN-producing neurosecretory cells in the silkworm embryo

Embryonic diapause of the silkworm, Bombyx mori, is induced by a neuropeptide hormone, the diapause hormone (DH), which is secreted from a limited number of neurosecretory cells in the subesophageal ganglion (SG) at the maternal generation. We examined the developmental fate of the hormone-producing cell (DH-pheromone biosynthesis activating neuropeptide [PBAN]-producing cell) in the embryonic stage at the level of gene expression and cell biology. The DH-PBAN gene expression started at the histogenesis stage and gradually increased toward hatching. DH is an amidated peptide belonging to FXPRLamide family. The immunoreactive somata against anti FXPRLamide antiserum were found in the SG from blastokinesis. Immunoreactive neural processes with varicosites were also found on the corpus cardiacum and the corpus allatum. The implantation of a part of a developing embryo including the SG into the pupae with the SG removed induced diapause eggs in the progeny. These results were obtained from eggs incubated under diapause-averting conditions as well as diapause-inducing conditions. Thus, a neurosecretory system responsible for biosynthesis of FXPRLamide neuropeptides is established as early as histogenesis, although the system to regulate the secretion of neuropeptide hormones has not been fully formed by that time.     

Juvenile hormone regulation of the larval diapause of the Southwestern corn borer,Diatraea grandiosella

The hormonal mechanism which controls the larval diapause of the southwestern corn borer was examined. The onset of this facultative mature larval diapause is marked by a transition from a spotted to an immaculate larval form, and during diapause individuals may undergo one or more stationary larval ecdyses. Experiments were designed to uncover the nature of the humoral mechanism regulating this diapause state. The finding that injecting diapause larvae with 20-hydroxyecdysone only brought about a stationary larval ecdysis suggests that diapause was not maintained by the lack of ecdysone. Neck ligations performed on larvae which had just entered diapause resulted in a premature termination of diapause, and larval-pupal ecdysis occurred in the thoraco-abdominal section, suggesting that a cephalic factor was necessary for the maintenance of diapause. This finding was further supported by the discovery that injecting 20-hydroxyecdysone into the thoraco-abdominal section of previously ligated diapause larvae also resulted in a premature termination of diapause and larval-pupal ecdysis, indicating that ecdysone only initiated the pupal moulting cycle when the cephalic factor was absent.Further experiments led to the conclusion that the juvenile hormone is the cephalic factor. Topical treatment with a juvenile hormone mimic caused non-diapause mature larvae to become immaculate and enter diapause. Periodical topical application of this mimic to diapause larvae prolonged diapause and increased the number of stationary larval ecdyses. These findings suggest that the initiation and maintenance of diapause are regulated by juvenile hormone titre. Results indicate that larvae retain a high titre of juvenile hormone until the last stages of diapause. Injection of 20-hydroxyecdysone into early or middiapause larvae only caused stationary larval ecdyses, while the same injection into larvae in the late stages of diapause caused some of them to pupate. Histological studies of the neurosecretory cells, corpus cardiacum-allatum complex, and prothoracic glands showed that the endocrine system was not inactive during diapause. A new hypothesis is therefore proposed which recognizes the existence of hormonal activity during larval diapause and emphasizes the principal regulatory rôle of juvenile hormone.     

Alteration of egg diapause in Bombyx mori by ouabain injected into diapause egg producers

Ouabain, an inhibitor of the active transport of some inorganic cations, functioned to produce non-diapause eggs in diapause egg producers. The effectiveness of this chemical related to non-diapause egg production was evident in 40 nmole injection per 4-day-old pharate adult. Simultaneous injections of ouabain with diapause hormone preparation or K⁺-ion suppressed non-diapause egg production to as a great extent as though they functioned competitively. Other experiments indicate that ouabain does not affect the ovaries directly but appears to inhibit the release of endogenous diapause hormone from the suboesophageal ganglion by affecting the central nervous system. The shortage of 3-hydroxykynurenine in non-diapause eggs produced by ouabain is thought not to be the result of the blockage of active transport at the ovaries but the result of a lack of diapause hormone.     

Dopamine is a key factor for the induction of egg diapause of the silkworm, Bombyx mori.

The silkworm, Bombyx mori, enters diapause in the early embryonic stage. Embryonic diapause is induced by incubating eggs of the maternal generation at high temperature (diapause type), whereas incubation at low temperature results in non-diapausing progeny (non-diapause type). Measurement of catecholamine concentrations in haemolymph and brain-subesophageal ganglia (Br-SGs) showed that only dopamine concentrations in both tissues are consistently higher in diapause-type than non-diapause-type larvae and pupae. In particular, the difference in dopamine concentrations in both tissues increases around pupal ecdysis. During the early pupal stage, Dopa decarboxylase activities and mRNA concentrations in Br-SGs were also much higher in diapause-type than non-diapause-type insects. Elevation of dopamine levels induced by feeding Dopa to penultimate-instar and last-instar larvae, and by injecting Dopa or dopamine into pupae 2 days after pupation made the non-diapause-destined insects lay diapause-destined eggs at 59% and approximately 70% frequencies, respectively. Furthermore, injection of Dopa or dopamine elevated mRNA levels of the diapause hormone in the Br-SGs of non-diapause-type pupae 1 day after injection. Incubation of Br-SGs isolated from non-diapause-type day-2 pupae with Dopa or dopamine also stimulated the expression of diapause hormone mRNA. These data indicate that environmental stimuli during embryonic development increase dopamine levels in both hemolymph and Br-SGs from the larval stage to early pupal stage, which results in laying of diapause-destined eggs by female adults through enhanced expression of the diapause hormone gene.     

Developmental changes in the localization of protein kinase CK2 in non-diapause and diapause eggs of the silkworm, Bombyx mori

To analyze the role of protein kinase CK2 (CK2) during early embryogenesis in non-diapause and diapause of the silkworm, the distribution and localization of Bombyx mori CK2 (BmCK2) were investigated by an immunohistochemical technique using antibodies against the α- and β-subunits of BmCK2. Both were localized in blastoderm cells of non-diapause and diapause eggs until 24 h after oviposition. More than 24 h after oviposition, however, the distribution of BmCK2 was different in non-diapause and diapause eggs. In non-diapause eggs, BmCK2 was mainly localized in yolk cells. In contrast, in diapause eggs, the localization was mainly observed in germ-band cells. Furthermore, we confirmed that the RNA helicase-like protein that was localized together with BmCK2 in non-diapause eggs was phosphorylated by BmCK2 in vitro. These data suggest that the role of BmCK2 is different in non-diapause and diapause eggs.     

Ecdysone Metabolism in Diapause Eggs and Non-Diapause Eggs of the Silkworm, Bombyx mori

In order to compare ecdysone metabolism between diapause eggs and non-diapause eggs of the silkworm, Bombyx mori, (3)H-ecdysone and its derivatives ((3)H-3-epiecdysone and (3)H-ecdysone 22-phosphate) were injected into the eggs at various stages during early embryogenesis, and the resultant labelled metabolites were analyzed by high-performance liquid chromatography. From the quantitative and qualitative changes in the labelled metabolites between diapause eggs and non-diapause eggs, it was demonstrated that epimerization of ecdysone occurred during early embryogenesis irrespective of the embryonic stage in both diapause eggs and non-diapause eggs, and that phosphorylation of ecdysone was a major metabolic step in diapause eggs, whereas dephosphorylation of ecdysone 22-phosphate and its subsequent hydroxylation at the C-20 and C-26 positions were characteristic in non-diapause eggs.     

Differential gene expression during early embryonic development in diapause and non-diapause eggs of multivoltine silkworm Bombyx mori

Quantification of the differential expression of metabolic enzyme and heat-shock protein genes (Hsp) during early embryogenesis in diapause and non-diapause eggs of the silkworm B. mori was carried out by semi-quantitative RT-PCR. Data analysis revealed that, the phosphofructokinase (PFK) expression started at a higher level in the early stage (6 h after oviposition) in non-diapause eggs, while in diapause induced eggs, it started at a lower level. However, the PFK gene expression in diapause eggs was comparatively higher than in non-diapause eggs. PFK facilitates use of carbohydrate reserves. The lower level of PFK gene expression in the early stage of diapause induced eggs but comparatively higher level of expression than in non-diapause eggs is due to enzyme inactivation via protein phosphorylation during early embryogenesis followed by de-phosphorylation in later stage. The sorbitol dehydrogenase-2 (SDH-2) gene was down regulated in diapause induced eggs up to 24 h and its expression levels in diapause induced eggs coincided with that of PFK gene at 48h in non-diapause eggs. During carbohydrate metabolism, there is an initial temporary accumulation of sorbitol which acts as protectant. The down regulation of SDH-2 gene during the first 24 hours in diapause induced eggs was due to the requirement of sorbitol as protectant. However, since the diapause process culminates by 48 h, the SDH-2 gene expression increased and coincided with that of PFK gene expression. The trehalase (Tre) gene expression was at a lower level in diapause induced eggs compared to non-diapausing eggs. The induction of Tre activity is to regulate uptake and use of sugar by the tissues. The non-diapause eggs revealed maximum expression of GPase gene with major fluctuations as well as an overall higher expression compared to diapause induced eggs. The diapause process requires less energy source which reflects lower activity of the gene. Heat shock protein (Hsp) genes (Hsp20.4, 40, 70, and 90) revealed differential levels of expression in both the eggs at all stages of embryonic development. The present study thus provides an overview of the differential expression levels of metabolic enzyme and Hsp genes in non-diapause and diapause induced eggs of multivoltine silkworm B. mori within 48 h after oviposition, confirming the major role of in early embryogenesis.     

Genome‐wide microarray screening for Bombyx mori genes related to transmitting the determination outcome of whether to produce diapause or nondiapause eggs

The bivoltine silkworm Bombyx mori (Lepidoptera: Bombycidae) exhibits a maternally controlled embryonic diapause. Maternal silkworms decide whether to lay diapause or nondiapause eggs depending on environmental factors such as the temperature and photoperiod during the egg and larval stages, and then induce diapause eggs during the pupal stage. However, little is known about the molecular mechanism that conveys the outcome of whether to produce diapause or nondiapause eggs from the egg or larval stages to the pupal stage. This study used microarray analysis to investigate differentially expressed genes in the larval brains of diapause‐ and nondiapause‐egg producers, to which bivoltine silkworms were destined by thermal or photic stimulation during the egg stage. The cytochrome P450 18a1 and Krüppel homolog 1 genes were upregulated in producers of diapause eggs compared with those of nondiapause eggs under both experimental conditions. Cytochrome P450 18a1 encodes a key enzyme for steroid hormone inactivation and Krüppel homolog 1 is an early juvenile hormone‐inducible gene that mediates the repression of metamorphosis. The upregulation of these genes during the larval stage might be involved in the signaling pathway that transmits information about the diapause program from the egg stage to the pupal stage in the silkworm.     

A novel RNA helicase-like protein during early embryonic development in silkworm Bombyx mori: molecular characterization and intracellular localization

In order to understand the molecular mechanism of development during early embryogenesis in diapause and non-diapause of the silkworm, mRNA from diapause and non-diapause eggs was compared using the differential display technique. We cloned the full length of a cDNA encoding a novel RNA helicase-like (RHL) protein by the RACE method using a cDNA fragment which was one of the specific cDNAs in the non-diapause eggs. A BLAST search using the predicted amino acid sequence of RHL revealed a low homology (21–25% identity of its partial length) with that of the DEAD-box RNA helicase. Gene expression of the RHL gene of the diapause and non-diapause eggs was investigated by RT-PCR until 60 h after oviposition. Amplified RHL cDNA was observed through all the stages in the non-diapause eggs, while in the diapause eggs, cDNA was found in eggs 0–12 h after oviposition but disappeared 24–60 h after oviposition. When the diapause eggs were activated by HCl treatment after chilling at 4 °C for 6 days from 48 h after oviposition (artificial diapause termination), cDNA was observed from 12 h after HCl treatment. We also investigated the immunohistochemical distribution and localization of RHL in non-diapause eggs using anti-recombinant His-tag RHL antiserum. RHL was distributed in blastoderm cells and yolk cells and was localized in the nucleus and the cytosol of yolk cells. These data suggest that RHL has an important role in the early embryo of the silkworm.     

Possible involvement of ecdysteroids in embryonic diapause of Locusta migratoria

In the Ibaraki population (Japan) of Locusta migratoria, adult locusts produce diapause eggs under short-day (SD) conditions and non-diapause eggs under long-day (LD) conditions. The identity and titre of ecdysteroids in the ovaries and eggs from LD and SD adult females were investigated by RIA/HPLC. Maternal ecdysteroids accumulated in the developing ovaries represented about 90% polar conjugates, 5% free ecdysteroids and 5% non-hydrolyzable metabolites. Before oviposition the quantity of ecdysteroids reached 29.8±1.85 ng 20-hydroxyecdysone equiv. per mg tissue ovaries from LD females and 13.1±3.55 ng 20E equiv./mg in ovaries from SD females. The sum of RIA-positive materials in newly laid eggs was more than three times higher in non-diapause eggs than in diapause eggs. Ecdysteroids present in egg extracts comprised about 85% polar conjugates, 5% free ecdysteroids and 10% non-hydrolyzable metabolites. On the other hand, after diapause termination the amount of ecdysteroids increased drastically. Also, the composition of ecdysteroids differed from that observed during diapause and became comparable to that of non-diapause eggs. The significant differences in the ecdysteroids between non-diapause and diapause eggs may suggest the possible involvement of these compounds in the control of embryonic diapause of this locust.