Immunocytochemical distribution of pigment-dispersing hormone in the cephalic ganglia of polyneopteran insects

Material detectable with antisera to the pigment-dispersing hormone (PDH) is regarded as a component of the circadian clock residing in some insects in the optic lobe. This paper demonstrates that the position of the PDH-positive neurones and the course of their processes are similar in all representatives of the insect cohort Polyneoptera. A basic morphological pattern, which includes the proximal frontoventral (Pfv), distal posteriodorsal (Dpd) and posterioventral (Dpv) clusters of PDH-positive neurones, was found in the examined species of locusts, crickets, walking sticks, cockroaches, earwigs and termites. The Pfv cluster is located close to the accessory medulla and usually consists of a set of smaller and a set of larger perikarya. The Dpd and Dpv clusters occupy a dorsal and a ventral position, respectively, at the distal edge of the medulla. These clusters are lacking in stonefly and praying mantid species. The fan-like arrangement of PDH-positive fibres within the frontal medulla face (the locusts and the praying mantid have an additional, smaller fan on the posterior medulla face) is another characteristic feature of Polyneoptera. One (two in the locusts and the praying mantid) nerve bundle runs from the optic lobe to the lateral protocerebrum where it ramifies. One branch gives rise to a fibre network frontally encircling brain neuropile in the area of mushroom bodies. One thin fibre in the crickets and the earwig, and several thicker and anastomosing fibres in the other insects, connect the brain hemispheres. The arrangement of other PDH-positive structures specifies taxa within Polyneoptera. Specific features comprise the presence of PDH-positive perikarya in protocerebrum (walking stick and termite), deutocerebrum (cricket, walking stick, and one cockroach species), tritocerebrum (another cockroach species), and the suboesophageal ganglion (cricket, walking stick and termite). In the walking stick and the termite, PDH-positive fibres pass from the cephalic to the frontal ganglion and from there via the recurrent nerve to the corpora cardiaca where they make varicosities indicative of peptide release into the haemolymph.     

Distribution of corazonin and pigment-dispersing factor in the cephalic ganglia of termites

Distribution of neurones detectable with antisera to the corazonin (Crz) and the pigment-dispersing factor (PDF) was mapped in the workers or pseudergates of 10 species representing six out of seven termite families. All species contained two triads of Crz-immunoreactive (Crz-ir) neurones in the protocerebrum. Their fibres were linked to the opposite hemisphere, formed a network in the fronto-lateral protocerebrum, and projected to the corpora cardiaca (CC); in most species the fibres also supplied the deuto- and tritocerebrum and the frontal ganglion. Some species possessed additional Crz-ir perikarya in the protocerebrum and the suboesophageal ganglion (SOG). The PDF-ir somata were primarily located in the optic lobe (OL) and SOG. OL harboured a group (3 groups in Coptotermes) of 2-6 PDF-ir cells with processes extending to the medulla, connecting to the contralateral OL, forming 1-2 networks in the protocerebrum, and in most species running also to CC. Such a PDF-ir system associated with the OL was missing in Reticulitermes. Except for Mastotermes, the termites contained 1-2 PDF-ir cell pairs in the SOG and two species had additional perikarya in the protocerebrum. The results are consistent with the view of a monophyletic termite origin and demonstrate how the Crz-ir and PDF-ir systems diversified in the course of termite phylogeny.     

Distribution of circadian clock-related proteins in the cephalic nervous system of the silkworm, Bombyx mori

In the circadian timing systems, input pathways transmit information on the diurnal environmental changes to a core oscillator that generates signals relayed to the body periphery by output pathways. Cryptochrome (CRY) protein participates in the light perception; period (PER), Cycle (CYC), and Doubletime (DBT) proteins drive the core oscillator; and arylalkylamines are crucial for the clock output in vertebrates. Using antibodies to CRY, PER, CYC, DBT, and arylalkylamine N-acetyltransferase (aaNAT), the authors examined neuronal architecture of the circadian system in the cephalic ganglia of adult silkworms. The antibodies reacted in the cytoplasm, never in the nuclei, of specific neurons. A cluster of 4 large Ia(1) neurons in each dorsolateral protocerebrum, a pair of cells in the frontal ganglion, and nerve fibers in the corpora cardiaca and corpora allata were stained with all antibodies. The intensity of PER staining in the Ia(1) cells and in 2 to 4 adjacent small cells oscillated, being maximal late in subjective day and minimal in early night. No other oscillations were detected in any cell and with any antibody. Six small cells in close vicinity to the Ia(1) neurons coexpressed CYC-like and DBT-like, and 4 to 5 of them also coexpressed aaNATlike immunoreactivity; the PER- and CRY-like antigens were each present in separate groups of 4 cells. The CYC- and aaNAT-like antigens were further colocalized in small groups of neurons in the pars intercerebralis, at the venter of the optic tract, and in the subesophageal ganglion. Remaining antibodies reacted with similarly positioned cells in the pars intercerebralis, and the DBT antibody also reacted with the cells in the subesophageal ganglion, but antigen colocalizations were not proven. The results imply that key components of the silkworm circadian system reside in the Ia(1) neurons and that additional, hierarchically arranged oscillators contribute to overt pacemaking. The retrocerebral neurohemal organs seem to serve as outlets transmitting central neural oscillations to the hemolymph. The frontal ganglion may play an autonomous function in circadian regulations. The colocalization of aaNAT- and CYC-like antigens suggests that the enzyme is functionally linked to CYC as in vertebrates and that arylalkylamines are involved in the insect output pathway.     

Comparative anatomy of pigment-dispersing hormone-immunoreactive neurons in the brain of orthopteroid insects

Summary In a comparative study, the anatomy of neurons immunoreactive with an antiserum against the crustacean -pigment-dispersing hormone was investigated in the brain of several orthopteroid insects including locusts, crickets, a cockroach, and a phasmid. In all species studied, three groups of neurons with somata in the optic lobes show pigment-dispersing hormone-like immunoreactivity. Additionally, in most species, the tritocerebrum exhibits weak immunoreactive staining originating from ascending fibers, tritocerebral cells, or neurons in the inferior protocerebrum. Two of the three cell groups in the optic lobe have somata at the dorsal and ventral posterior edge of the lamina. These neurons have dense ramifications in the lamina with processes extending into the first optic chiasma and into distal layers of the medulla. Pigment-dispersing hormone-immunoreactive neurons of the third group have somata near the anterior proximal margin of the medulla. These neurons were reconstructed in Schistocerca gregaria, Locusta migratoria, Teleogryllus commodus, Periplaneta americana, and Extatosoma tiaratum. The neurons have wide and divergent arborizations in the medulla, in the lamina, and in several regions of the midbrain, including the superior and inferior lateral protocerebrum and areas between the pedunculi and -lobes of the mushroom bodies. Species-specific differences were found in this third cell group with regard to the number of immunoreactive cells, midbrain arborizations, and contralateral projections, which are especially prominent in the cockroach and virtually absent in crickets. The unusual branching patterns and the special neurochemical phenotype suggest a particular physiological role of these neurons. Their possible function as circadian pacemakers is discussed.     

Efficient folding of the insect neuropeptide eclosion hormone by protein disulfide isomerase.

Eclosion hormone is an insect neuropeptide that consists of 62 amino acid residues including three disulfide bonds. We have previously reported its hypothetical 3D structure consisting mainly of three alpha-helices. In this paper, we report the effects of chaperone proteins on the refolding of denatured eclosion hormone in a redox buffer containing reduced and oxidized glutathione. Urea-denatured eclosion hormone was spontaneously reactivated within 1 min with a yield of more than 90%, while beta-mercaptoethanol-denatured eclosion hormone was reactivated in a few minutes with a yield of 75%. Under the same experimental conditions, eclosion hormone treated with beta-mercaptoethanol and urea was reactivated slowly with a yield of 47% over a period of 2 h. Protein disulfide isomerase, a eucaryotic chaperone protein, markedly increased the reactivation yield and rate of the totally denatured hormone. GroE oligomers slightly improved the reactivation yield but peptidyl prolyl isomerase had no influence on yield or rate. We propose that the folding pathway of eclosion hormone involves at least two rate-limiting steps, and that protein disulfide isomerase is likely to be involved in the folding in insect neuronal cells.     

Characterization of synaptosomes from the central nervous system of insects

Nerve terminals from the head ganglia of Locusta migratoria were isolated by means of a modified microscale flotation technique. Enzymatic, ultrastructural and chemical analysis revealed that the synaptosomal fraction was highly enriched in well-preserved nerve endings containing almost no free mitochondria. Cholinergic activities (choline acetyltransferase, acetylcholinesterase, acetylcholine receptors) were found to be concentrated in the synaptosomal fraction. The cholinergic nature and the functional integrity of nerve endings isolated from locusts were further supported by the existence of a high affinity choline uptake system, which is abolished by hemicholinium-3 as well as by low temperature, is essentially sodium dependent and inhibited by elevated potassium concentrations. After slight modifications of the gradient densities, synaptosomes could also be isolated from other insect species.     

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.     

Structural characterization and expression analysis of prothoracicotropic hormone in the corn earworm, Helicoverpa zea

The cDNA encoding prothoracicotropic hormone (PTTH), the brain neuropeptide that stimulates the prothoracic glands to synthesize ecdysone, was cloned from the corn earworm Helicoverpa zea (Hez). The amino acid sequence deduced from the cDNA indicates a molecular structure that is distinct from the PTTH's reported in other Lepidoptera, but all contain an identical proteolytic cleavage site and the seven cysteine residues that are essential for activity. Northern hybridization shows a single mRNA present in the brain-subesophageal ganglion complex. Using RT-PCR, we observed constant amounts of PTTH mRNA during larval development but large fluctuations at pupation and prior to adult eclosion.     

Distribution of prosaposin in the rat nervous system

Prosaposin is the precursor of four sphingolipid activator proteins (saposins A, B, C, and D) for lysosomal hydrolases and is abundant in the nervous system and muscle. In addition to its role as a precursor of saposins in lysosomes, intact prosaposin has neurotrophic effects in vivo or in vitro when supplied exogenously. We examined the distribution of prosaposin in the central and peripheral nervous systems and its intracellular distribution. Using a monospecific antisaposin D antibody that crossreacts with prosaposin but not with saposins A, B, or C, immunoblot experiments showed that both the central and peripheral nervous systems express unprocessed prosaposin and little saposin D. Using the antisaposin D antibodies, we demonstrated that prosaposin is abundant in almost all neurons of both the central and peripheral nervous systems, including autonomic nerves, as well as motor and sensory nerves. Immunoelectron microscopy using double staining with antisaposin D and anticathepsin D antibodies showed strong prosaposin immunoreactivity mainly in the lysosomal granules in the neurons in both the central and peripheral nervous systems. The expression of prosaposin mRNA, examined using in situ hybridization, was observed in these same neurons. Our results suggest that prosaposin is synthesized ubiquitously in neurons of both the central and peripheral nervous systems. Funding: This study was supported by the Ehime University INCS and in part by grants-in-aid for Scientific Research to S.M. (Exploratory Res. 19659380) from the Japan Society for the Promotion of Science and to AS (Priority Areas 18023029) from the Ministry of Education, Culture, Sports, Science and Technology of Japan.     

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.     

Corazonin and corazonin-like substances in the central nervous system of the Pterygote and Apterygote insects

Antisera against corazonin were used to investigate distribution of immunoreactive cells in the central nervous system (CNS) of representatives of six insect orders: Ctenolepisma lineata (Zygentoma), Locusta migratoria (Orthoptera), Oxya yezoensis (Orthoptera), Gryllus bimaculatus (Orthoptera), Pyrrhocoris apterus (Hemiptera), Arge nigrinodosa (Hymenoptera), Athalia rosae (Hymenoptera), Bombyx mori (Lepidoptera) and Anomala cuprea (Coleoptera). Corazonin-like immunoreactive (CLI) cells were detected in the brain and ventral ganglia of all insects studied except for the albino strain of L. migratoria and the beetle A. cuprea. Implantation of the brain or different ganglia from insects with detected immunoreactivity induced dark coloration in the albino locust, providing further evidence for the presence of authentic corazonins [His(7)- and Arg(7)-isoforms] in these insects. The protocerebral lateral neurosecretory cells projecting into the ipsilateral retrocerebral neurohemal organs and bilateral longitudinal tracts extending and branching throughout the entire CNS seem to be a well-conserved part of the corazonin system in insects. The bilateral longitudinal tracts were formed by species-specific numbers of bilateral interneurons segmentally distributed in the ventral ganglia. Additional immunoreactive somata, mostly interneurons, were detected in the CNS of various insects. The distribution of corazonin in the cephalic neurosecretory system and in the bilateral interneurons suggests that corazonin acts as a hormone as well as a neurotransmitter or a neuromodulator. An ancient origin of corazonin is suggested by the presence of a corazonin-like substance in the primitive insect, C. lineata. These results support previous findings on the common occurrence of corazonin among insects, except for the albino strain of L. migratoria and the Coleoptera.     

Isolation and primary structure of the eclosion hormone of the tobacco hornworm, Manduca sexta

Eclosion hormone was isolated from trimmed pharate adult heads of Manduca sexta by an eight step purification procedure using a Heliothis virescens in vivo bioassay. The neuropeptide was active in second stadium M. sexta. The primary structure was determined by sequence analyses of the intact peptide and fragment peptides generated by lysyl endopeptidase, endoproteinase Glu-C, and proline-specific endopeptidase. The nature of the carboxyl terminus as a free acid was elucidated by analysis of amino acids from digestion of the intact peptide with lysyl endopeptidase, which liberated leucine, but no leucine amide. The complete primary structure of M. sexta closion hormone is H-Asn-Pro-Ala-Ile-Ala-Thr-Gly-Tyr-Asp-Pro-Met-Glu-Ile-Cys-Ile-Glu-Asn-Cy s-Ala- Gln-Cys-Lys-Lys-Met-Leu-Gly-Ala-Trp-Phe-Glu-Gly-Pro-Leu-Cys-Ala-Glu-Ser- Cys-Ile Lys-Phe-Lys-Gly-Lys-Leu-Ile-Pro-Glu-Cys-Glu-Asp-Phe-Ala-Ser-Ile-Ala-Pro- Phe-Leu-Asn-Lys-Leu-OH.     

Transneuronal uptake of horseradish peroxidase in the central nervous system of dipterous insects

Summary Horseradish peroxidase (HRP) applied to lesioned neurons in the retina and thoracic ganglia of the flies Musca, Calliphora and Drosophila labeled axon terminals, dendrites and perikarya of the severed neurons after anterograde or retrograde passage. In addition, HRP reaction product secondarily labeled intact neurons that are contiguous with injured nerve cells. In many cases labeling of optic lobe neurons remote from primarily filled ones was also seen (here called tertiary labeling). HRP labeling was extensive and both primarily and transneuronally filled neurons could be resolved in almost as much detail as Golgi-impregnated or cobalt-silver-labeled cells. Electron microscopy showed that in both primarily and secondarily filled neurons, reaction product was distributed diffusely in the cytoplasm.Transneuronal uptake of HRP was specific to certain types of neurons in the brain and thus displayed certain pathways. The pathways resolved by transneuronal labeling with HRP extend from the optic lobes to the thoracic ganglia and include visual neurons previously identified electrophysiologically and anatomically.Transneuronal HRP uptake, although believed to occur in vivo, could not be shown to be dependent on synaptic activity. Three other heme peptides tested were taken up by injured neurons, but showed no transneuronal labeling: lactoperoxidase, cytochrome c, and microperoxidase.     

Substitution of norleucine for methionine residues in a crustacean pigment-dispersing hormone

In order to evaluate the structural/functional roles of Met residues in an octadecapeptide pigment-dispersing hormone (PDH: Asn-Ser-Gly-Met-Ile-Asn-Ser-Ile-Leu-Gly-Ile-Pro-Arg-Val-Met-Thr-Glu-Ala- NH2), first described as light-adapting distal retinal pigment hormone (DRPH) from Pandalus, three analogs were synthesized: Nle4-PDH, Nle15-PDH, and Nle4,15-PDH. When tested for melanophore pigment-dispersing activity in destalked Uca, all three Nle-analogs were more potent than unsubstituted PDH. Performic acid oxidation caused a marked loss of potency of PDH, Nle4-PDH, and Nle15-PDH. The analog Nle4,15-PDH was resistant to oxidation and displayed 6-fold higher potency than PDH. Thus Met4 and Met15 are not essential for the PDH activity. The oxidation-induced loss of activity of unsubstituted PDH may result from introduction of oxygen (in methionine sulfone) and a consequent conformational change in the octadecapeptide.     

Expression of a silkworm eclosion hormone gene in yeast

Recombinant silkworm eclosion hormone was produced for the first time in yeast which was transformed with a shuttle plasmid containing a construct coding a signal peptide and the mature sequence of the silkworm eclosion hormone. Successfully transformed yeast processed recombinant silkworm eclosion hormone I (EH-I) and transported it to periplasm at the concentration of 60 micrograms per liter of culture. The biological activity of the purified recombinant silkworm eclosion hormone exhibited the ED50 value of 0.2 ng which is the same as that of the authentic hormone isolated from the silkworm brain.     

Localization of pigment-dispersing hormone (PDH) immunoreactivity in the central nervous system of Carcinus maenas and Orconectes limosus (Crustacea), with reference to FMRFamide immunoreactivity in O. limosus

Summary By use of antisera raised against synthetic pigment-dispersing hormone (PDH) of Uca pugilator and FMRFamide, the distribution of immunoreactive structures in the central nervous system (CNS) of Carcinus maenas and Orconectes limosus was studied by light microscopy. In both species, a total of 10–12 PDH-positive perikarya occur amongst the anterior medial, dorsal lateral and angular somata of the cerebral ganglion (CG). In C. maenas, one PDH-perikaryon was found in each commissural ganglion (COG) and several more in the thoracic ganglion. In O. limosus, only four immunopositive perikarya could be demonstrated in the ventral nerve cord, i.e., two somata in the anterior and two in the posterior region of the suboesophageal ganglion (SOG). PDH-immunoreactive tracts and fiber plexuses were present in all central ganglia of both species, and individual axons were observed in the connectives. FMRFamide-immunoreactivity was studied in O. limosus only. Neurons of different morphological types were found throughout the entire CNS, including numerous perikarya in the anterior medial, anterior olfactory, dorsal lateral and posterior cell groups of the CG. Four perikarya were found in the COG, six large and numerous smaller ones in the SOG, and up to eight cells in each of the thoracic and abdominal ganglia. In each ganglion, the perikarya form fiber plexuses. Axons from neurons belonging to the CG could be traced into the ventral nerve cord; nerve fibers arising from perikarya in the SOG appeared to project to the posterior ganglia. In none of the structures examined colocalization of PDH- and FMRF-amide-immunoreactivity was observed.Dedicated to Prof. K.-E. Wohlfarth-Bottermann on the occasion of his 65th birthday