Prothoracicotropic activity of SBRPs, the insulin-like peptides of the saturniid silkworm Samia cynthia ricini

Synthesis and secretion of the insect molting hormone ecdysteroid in the prothoracic glands (PGs) are stimulated by the prothoracicotropic hormone (PTTH) secreted by the brain. Bombyxins, insulin-like peptides of the silkworm Bombyx mori, show prothoracicotropic activity when administered to the saturniid silkworm Samia cynthia ricini, but they are inactive to B. mori itself. Recently, the genes for the bombyxin homologs of S. cynthia ricini (referred to as Samia bombyxin-related peptides, SBRPs) were cloned. To examine the prothoracicotropic activity of SBRPs on S. cynthia ricini, we synthesized two representative molecules, SBRP-A1 and -B1. They promoted pupa-to-adult development with ED(50) of 50 and 10 ng/pupa (EC(50) of 5 and 1 nM), respectively.     

Prothoracicotropic hormone of Rhodnius prolixus: partial characterization and rhythmic release of neuropeptides related to Bombyx PTTH and bombyxin

Summary

The brain-retrocerebral complex (br-complex) of Rhodnius prolixus was found both to contain and release neuropeptides related to Bombyx mori PTTH and bombyxin. A > 10 kDa peptide fraction obtained from extracts and incubation media of br-complex exhibited high steroidogenic activity on Rhodnius prothoracic glands and reacted with a Bombyx PTTH antibody on dot blots. The release from the Br-complex of this immunoreactive peptide fraction showed a daily rhythm: high release during the night and little on no release during the day. On Western blots, a single 68 kDa peptide in the > 10 kDa peptide fraction was recognized by the Bombyx PTTH antibody and was also released rhythmically during a day. This peptide was reduced to a doublet of about 17 kDa that retained immunoreactivity. Double immunoprecipitation of the > 10 kDa peptide fraction from brain media using the Bombyx PTTH antibody and agarose-bound secondary antibody removed the steroidogenic activity in this fraction; it also removed the 68 kDa peptide on Western blots. A bombyxin antiserum recognized a 3–5 kDa peptide in a <10 kDa peptide fraction; this peptide fraction was also released with a daily rhythm but possessed weak steroidogenic activity. The natural PTTH of Rhodnius, therefore, appears to be a 68 kDa peptide, possibly composed of several 17 kDa subunits, that is related to Bombyx PTTH.     

Developmental changes in hemolymph ecdysteroid level and prothoracicotropic hormone activity during the fifth larval instar of the Eri silkworm, Samia cynthia ricini

Developmental changes in hemolymph ecdysteroid level, ecdysteroid synthesis by prothoracic glands （PGs） in vitro, prothoracicotropic hormone （PTTH） activity in brain extracts, and PTTH activity in the hemolymph were measured during the fifth larval instar of the Eri silkworm, Samia cynthia ricini. The changing patterns of hemolymph ecdysteroid level and ecdysteroid synthesis by laGs in vitro are similar to each other, with maximums on day 9. However, on this day, hemolymph ecdysteroid level was substantially higher than ecdysteroid synthesis by PGs in vitro suggesting a high PTTH activity in the hemolymph on day 9. Moreover, the changing pattern of PTTH activity in brain extracts is also similar to that of PTTH activity in the hemolymph, both peaking on day 9. However, on this day, activity in brain extracts was much smaller than PTTH activity in the hemolymph implying that most PTTH synthesized by the brain is secreted to the hemolymph and the brain stores a very little amount of PTTH. This study provides unique insights onto the hormonal regulation of ecdysteroid synthesis in the Eri silkworm and is useful for our future studies on signal transduction of insect neurolaelatides.     

Bombyxin: An Insect Brain Peptide that Belongs to the Insulin Family

Bombyxin is a 5 kDa secretory brain peptide that belongs to the insulin family. Bombyxin of the silkmoth Bombyx mori can induce adult development when injected into brain-removed dormant pupae of the saturniid moth Samia cynthia ricini by activating the prothoracic glands to synthesize and release ecdysone. Bombyx bombyxin has been shown to lower the concentration of the major haemolymph sugar, trehalose, and to elevate the trehalase activity in the midgut and muscles in Bombyx, but the doses required to be effective are higher than the amounts in the feeding larvae. The exact physiological function of bombyxin in Bombyx itself is therefore still obscure, but its insulin-like structure suggests it has important roles. Bombyxin comprises a mixture of highly heterogeneous molecular forms whose amino acid sequences have 40% identity with human insulin. The Bombyx bombyxin gene encodes a precursor consisting of the signal peptide, B chain, C peptide, and A chain, in that order from the N terminus. So far, 32 bombyxin genes have been identified in Bombyx, and they are classified into 7 families, A to G, according to their sequence similarity. The bombyxin genes have no introns and cluster in unique distribution patterns. The gene arrangement in the cluster has been classified into three categories: gene pairs, gene triplets, and single genes. Nucleotide sequence analysis indicates that equal and unequal crossings-over and duplications may have generated these unique distribution patterns. The Bombyx bombyxin genes are expressed predominantly in the brain and at low levels in a number of other tissues. Genes of all 7 families are expressed in four pairs of the medial neurosecretory cells of the brain. Detailed examination indicated that only a limited number of genes in the A, B and C family members are expressed and that their expression shows a gene-arrangement-dependent pattern.     

The cycling and distribution of PER-like antigen in relation to neurons recognized by the antisera to PTTH and EH in Thermobia domestica

The cephalic nervous system of the firebrat contains antigens recognized by antisera to the clock protein period (PER), the prothoracicotropic hormone (PTTH) and the eclosion hormone (EH). The content of the 115 kDa PER-like antigen visualized on the western blots fluctuates in diurnal rhythm with a maximum in the night. The oscillations entrained in a 12:12 h light/dark (LD) cycle persist in the darkness and disappear in continuous light. They are detected by immunostaining in 14 pairs of the protocerebral neurons and are extreme in four suboesophageal neurons and two cells in each corpus cardiacum that contain PER only during the night phase. No circadian fluctuations occur in three lightly stained perikarya of the optic lobe. Five cell bodies located in each brain hemisphere between the deuto-and the tritocerebrum retain weak immunoreactivity under constant illumination. In all cells, the staining is confined to the cytoplasm and never occurs in the cell nuclei. The cells containing PER-like material do not react with the anti-PTTH and anti-EH antisera, which recognize antigens of about 50 and 20 kDa, respectively. The anti-PTTH antiserum stains in each brain hemisphere seven neurons in the protocerebrum, eight in the optic lobe, and 3–5 in the posterior region of the deutocerebrum. The antiserum to EH reacts in each hemisphere with just two cells located medially to the mushroom bodies. No cycling of the PTTH-like and EH-like antigens was detected.     

Molecular cloning of the prothoracicotropic hormone from the tobacco hornworm,Manduca sexta

A cDNA encoding a putative precursor of prothoracicotropic hormone (PTTH) from the tobacco hornworm, Manduca sexta, was isolated and sequenced. This clone contains an open reading frame encoding a 226-amino acid prepropeptide hormone. The deduced amino acid sequence is composed of a signal sequence, a precursor domain and a mature hormone and shows similarities to the other PTTHs that have been cloned from closely related lepidopteran species, Bombyx mori, Samia cynthia ricini, Antheraea peryni, and Hyalophora cecropia. Although these cDNAs showed slightly less similarities in predicted amino acid sequences, seven cysteine residues and the hydrophobic regions within those mature peptides were conserved. In situ hybridization using a cDNA probe encoding the Manduca PTTH showed that PTTH mRNA was in two pairs of neurosecretory cells in the Manduca brain. The recombinant putative Manduca PTTH produced in E. coli was biologically active, both causing a larval molt in neck-ligated Manduca 4th instar larvae (ED(50)=50 pM) and the adult molt of diapausing Manduca pupae (ED(50)=79 pM), but was unable to stimulate molting of debrained Bombyx pupae.     

The cycling and distribution of PER-like antigen in relation to neurons recognized by the antisera to PTTH and EH in Thermobia domestica

The cephalic nervous system of the firebrat contains antigens recognized by antisera to the clock protein period (PER), the prothoracicotropic hormone (PTTH) and the eclosion hormone (EH). The content of the 115 kDa PER-like antigen visualized on the western blots fluctuates in diurnal rhythm with a maximum in the night. The oscillations entrained in a 12:12 h light/dark (LD) cycle persist in the darkness and disappear in continuous light. They are detected by immunostaining in 14 pairs of the protocerebral neurons and are extreme in four suboesophageal neurons and two cells in each corpus cardiacum that contain PER only during the night phase. No circadian fluctuations occur in three lightly stained perikarya of the optic lobe. Five cell bodies located in each brain hemisphere between the deuto-and the tritocerebrum retain weak immunoreactivity under constant illumination. In all cells, the staining is confined to the cytoplasm and never occurs in the cell nuclei. The cells containing PER-like material do not react with the anti-PTTH and anti-EH antisera, which recognize antigens of about 50 and 20 kDa, respectively. The anti-PTTH antiserum stains in each brain hemisphere seven neurons in the protocerebrum, eight in the optic lobe, and 3–5 in the posterior region of the deutocerebrum. The antiserum to EH reacts in each hemisphere with just two cells located medially to the mushroom bodies. No cycling of the PTTH-like and EH-like antigens was detected.     

Ecdysteroidogenic action of Bombyx prothoracicotropic hormone and bombyxin on the prothoracic glands of Rhodnius prolixus in vitro

An in-vitro assay for ecdysteroid synthesis by the prothoracic glands (PGs) of fifth instar Rhodnius prolixus has been employed to evaluate the actions of prothoracicotropic neuropeptides from the silkmoth, Bombyx mori. Crude prothoracicotropic hormone (PTTH) extracts of recently emerged adult brain complexes of Bombyx induced a dose-dependent stimulation of ecdysteroid synthesis by Rhodnius PGs, which was similar to that obtained using crude Rhodnius PTTH. In both cases, maximum stimulation was obtained with one brain equivalent. Rhodnius PGs were then challenged with incremental doses of recombinant Bombyx PTTH and synthetic bombyxin-II. Dose-response curves for the action of both peptides on Rhodnius PGs were very similar to those obtained for their action on the pupal PGs of Bombyx in vitro. Bombyx PTTH stimulated the PGs of Rhodnius at concentrations comparable to those effective on Bombyx. The curve for Bombyx PTTH showed a steep ascending region from 3 to 8ng/ml and a sharp peak. For bombyxin, concentrations 40-fold higher were required to elicit the same amount of stimulation as obtained using Bombyx PTTH. Therefore, Rhodnius PGs possess recognition sites for both Bombyx PTTH and bombyxin. This is the first study of the ecdysteroidogenic properties of the Bombyx peptides on a heterologous species. It is suggested that the function and conformation of PTTH may be conserved between distantly related insect groups.     

Species Specificity of the Insect Prothoracicotropic Hormone (PITH): the Presence of Bombyx-and Samia-Specific PTTHs in the Brain of Bombyx mori

Crude extracts of Bombyx mori brains can provoke adult development when injected into brain-removed dormant pupae of Bombyx mori and Samia Cynthia ricini. From this fact the prothoracicotropic hormone (PTTH) of Bombyx has long been thought to be species-nonspecifically active on Samia. Chemical fractionation of Bombyx brain or head extracts by fractional precipitation with acetone, Sephadex G-50 gel-filtration, and DEAE-Sepharose CL-6B chromatography, however, separated the fractions which activated Bombyx brainless pupae from those which activated Samia. Those results reveal the existence of two species-specific PTTHs.     

Immunohistochemical Localization of Prothoracicotropic Hormone-Producing Neurosecretory Cells in the Brain of Bombyx mori

A monoclonal antibody that recognized the Bombyx prothoracicotropic hormone (PTTH) was produced by immunizing mice with a synthetic pentadecapeptide corresponding to the amino-terminal portion of Bombyx PTTH. The antibody recognized both intact and reduced forms of PTTH. Immunohistochemistry with this antibody has demonstrated that PTTH is produced by two pairs of dorso-lateral neurosecretory cells of the brain and transported to the corpora allata by axons running through the contralateral hemisphere of the brain. Immunoreactive axon terminals in the corpora allata were localized between the glandular cells, suggesting that PTTH is released at the inner part of this organ.     

The development of identified neurosecretory cells in the tobacco hornworm, Manduca sexta

The prothoracicotropic hormone (PTTH) is a principal neuropeptide regulator of insect postembryonic molting and metamorphosis. In the tobacco hornworm, Manduca sexta, PTTH is produced by two neurosecretory cells (NSC) located in each protocerebral lobe of the brain. The development of these neurons, the L-NSC III, has been investigated immunocytologically to establish the time course of their morphological differentiation. PTTH may be one of the earliest neuropeptides expressed in insect embryos. PTTH-immunoreactivity was initially detected in the somata at 24 to 30% of embryonic development. Neurites sprouted shortly thereafter and began to grow medially through the brain anlage. By 42% embryonic development, the neurites had decussated to the contralateral brain lobe. As development progressed, the L-NSC III neurites grew along specific tracts through the contralateral brain lobe reaching the ventrolateral regions of the brain by approximately 60% development. The axons exited the brain through a retrocerebral nerve, the nervi corporis cardiaci I + II. At approximately 63% development, the axons innervated the corpus allatum and began branching to form neurohemal terminals for PTTH release. At 60% development, short collaterals began extending in the protocerebral neuropil. During the remainder of embryogenesis, both the dendritic collaterals and the terminal neurohemal varicosities continued to elongate and arborize. By 85% embryonic development, the basic architecture of the L-NSC III was established.     

GFP labeling of neurosecretory cells with the GAL4/UAS system in the silkmoth brain enables selective intracellular staining of neurons

The microbrain of the silkmoth, Bombyx mori, is a model system for analyzing the neural mechanisms underlying stimulus-driven behavior, and numerous studies using physiological and morphological methods have accumulated. However, one of the limitations of this system is a lack of methodology for labeling specific subsets of neurons. Targeted gene expression with the GAL4/UAS system, which was recently developed, may overcome this disadvantage. To test the GAL4/UAS system in the silkmoth brain, we generated two GAL4 driver lines in which GAL4 expression was under the control of either the bombyxin or prothoracicotropic hormone (PTTH) promoter. Crosses of moths from these lines with a UAS-GFP line showed that green fluorescent protein (GFP) was exclusively expressed in bombyxin or PTTH neurosecretory brain cells. Using these lines, we developed a visually guided method to selectively insert an electrode into and intracellulary stain GFP-expressing cells using fluorescence as a landmark. This work provides a novel method to visualize specific subsets of neurons in the silkmoth brain and to observe detailed structures in a single identified neuron from different individuals.     

Circadian clock and prothoracicotropic hormone secretion in relation to the larval-larval ecdysis rhythm of the saturniid Samia cynthia ricini

Observations on the timing of ecdysis and neck ligation experiments on larvae of Samia cynthia ricini under various light-dark conditions show that an endogenous circadian clock controls the timing of larval ecdysis and prothoracicotropic hormone (PTTH) secretion preceding it. The clock, upon reaching a specific phase point, causes the brain to secrete PTTH provided that the brain has acquired the secretory competence. This time may vary, in relation to a previous ecdysis, according to the light-dark conditions by which the clock phase is specifically determined, but is fixed relative to a subsequent ecdysis. Thus, in the case of the ecdysis to the 5th instar, PTTH is secreted [15+nτ] hr (τ: free-running period, slightly less than 24 hr) after the clock has started when the rhythm is free-running, and in the second and third nights of the 4th instar under a photoperiod of 12 hr light and 12 hr dark. Full secretion of ecdysone occurs 6 hr after PTTH secretion and ecdysis ensues 34 hr thereafter to complete the ultimate sequence of ecdysis.     

The development of identified neurosecretory cells in the tobacco hornworm, Manduca sexta

The prothoracicotropic hormone (PTTH) is a principal neuropeptide regulator of insect postembryonic molting and metamorphosis. In the tobacco hornworm, Manduca sexta, PTTH is produced by two neurosecretory cells (NSC) located in each protocerebral lobe of the brain. The development of these neurons, the L-NSC III, has been investigated immunocytologically to establish the time course of their morphological differentiation. PTTH may be one of the earliest neuropeptides expressed in insect embryos. PTTH-immunoreactivity was initially detected in the somata at 24 to 30% of embryonic development. Neurites sprouted shortly thereafter and began to grow medially through the brain anlage. By 42% embryonic development, the neurites had decussated to the contralateral brain lobe. As development progressed, the L-NSC III neurites grew along specific tracts through the contralateral brain lobe reaching the ventrolateral regions of the brain by approximately 60% development. The axons exited the brain through a retrocerebral nerve, the nervi corporis cardiaci I + II. At approximately 63% development, the axons innervated the corpus allatum and began branching to form neurohemal terminals for PTTH release. At 60% development, short collaterals began extending in the protocerebral neuropil. During the remainder of embryogenesis, both the dendritic collaterals and the terminal neurohemal varicosities continued to elongate and arborize. By 85% embryonic development, the basic architecture of the L-NSC III was established.     

Further Evidence for the Presence of a Circadian Clock in the Prothoracic Glands of the Saturniid Moth Samia cynthia ricini: Decapitated Larvae Can Respond to Light-Dark Changes

A small peak of haemolymph ecdysteroid titre precedes the gut purge that characterizes larval-prepupal transition of the saturniid moth Samia cynthia ricini. This peak shifts its phase in parallel with the phase shifts of gut purge according to the changes in light-dark conditions preceding gut purge. Decapitated larvae responded to these light-dark changes as intact larvae did, as assessed by the phase shifts of the haemolymph ecdysteroid peak. This indicates that the brain-centred PTTH clock is not prerequisite for realization of the circadian-clock-controlled timing in the initiation of prepupal development, and supports indirectly our previous notion that the prothoracic glands of Samia possess a circadian clock dictating gut purge timing.     

Cell-specific expression of enhanced green fluorescence protein under the control of neuropeptide gene promoters in the brain of the silkworm,Bombyx mori,using Bombyx mori nucleopolyhedrovirus-derived vectors

Using the larvae of the silkworm, Bombyx mori, we examined the baculovirus expression vector system for the expression of the enhanced green fluorescence protein (EGFP) gene under the control of several gene promoters in vivo. To investigate the gene-delivery efficiency of the baculovirus into various larval tissues, we constructed two recombinant baculoviruses carrying the EGFP gene downstream of the Drosophila melanogaster hsp70 gene promoter from B. mori nucleopolyhedrovirus (BmNPV) and Autographa californica nucleopolyhedrovirus (AcNPV). After injection of these recombinant baculoviruses into newly ecdysed 5th instar larvae, hsp70::EGFP-BmNPV, but not hsp70::EGFP-AcNPV, caused intense expression of EGFP not only in various non-neural tissues, but also in the neural organs including the brain 5 days postinfection. To investigate the cell-specific expression in the brain, we constructed recombinant C4/B3::EGFP-BmNPV and PTTH::EGFP-BmNPV which carry the EGFP gene under the control of bombyxin B3 and prothoracicotropic hormone (PTTH) gene promoters, respectively. Injection of these recombinant baculoviruses caused specific expression of EGFP with a high gene-expression efficiency in the neurosecretory cells of the brain depending on the neurohormone gene promoters. Present results indicate that this in vivo gene-expression system mediated by the baculovirus can serve as an efficient system permitting gene delivery into neural tissues in insects.     

The Prothoracicotropes: Source of the Prothoracicotropic Hormone

SYNOPSIS. An in vitro assay for the insect prothoracicolropichormone (PTTH) has been developed which measures the rate ofecdysone synthesized by Manduca sexta prothoracic glands (PG)stimulated in vitro by PTTH. This assay has been used to quantifyPTTH in single neurosecretory cells (NSC) resulting in the identificationof one NSC in each hemisphere of the brain as the prothoracicotrope,source of PTTH. The axonal and dendritic distribution of theprothoracicotrope has been determined by cobalt filling withsilver intensification. From a comparison of the titers of PTTHin brains, corpora cardiaca and corpora allata during larval-pupaldevelopment, the corpus allatum has been identifiedas the neurohemalorgan for PTTH. Electron microscopic analyses suggest that theacellular sheath surrounding the corpus allatum contains theaxon terminals of the prothoracicotropes. There is at least one form of PTTH, {small tilde}22,000 molwt (big PTTH), and possibly a smaller form of about 7,000 molwt (small PTTH). Bioassay and PTTH hemolymph titer data duringthe head critical period (HCP) for larval-larval developmentreveal that big PTTH is released as a single peak lasting {smalltilde}6 hr. By contrast, during the first HCP of the last larvalinstar PTTH is released over a period of {small tilde}18 hrin three bursts, but its molecular weight has not been establishedwith certainty. The kinetics of PG activation by these two formssuggest that big PTTH may function to activate the PG dramaticallyand thereby elicit molting, while small PTTH may activate thePG minimally at the time of cellular reprogramming.     

利用纳米孔测序鉴定蓖麻蚕病害

蓖麻蚕Samia ricini为大蚕蛾科樗蚕属的绢丝与食用的非滞育型经济昆虫,且是少数可以室内大量圈养的绢丝昆虫,全年可累代饲养.在蓖麻蚕室内大批量圈养的生产过程可能遭受毁灭性病害的侵害,包括蓖麻蚕微粒子病、脓病、软化病等,且随着累代对病原物的不停积累蚕病会呈现愈发严重的趋势,病原愈发难以清除.因此,对蚕病的监测是防控蚕病爆发的重要手段之一.掌上纳米孔测序仪MinION是一款便携式高通量测序平台,便于实地进行DNA测序并对病原物进行检测.本文通过MinION测序仪对蓖麻蚕病蚕DNA进行测序,并对未知病原物DNA序列进行分析,探讨了利用MinION测序仪鉴定蓖麻蚕病原的可行性,对蚕病的监测提供了保障.