Octopamine and cyclic AMP mediate release of adipokinetic hormone I and II from isolated locust neuroendocrine tissue

Octopamine serves as a neurotransmitter in the glandular lobe of the locust corpus cardiacum where it regulates adipokinetic hormone (AKH) secretion from intrinsic neurosecretory cells. Two AKHs (AKH I and II) from the corpus cardiacum of Locusta have been sequenced and synthesized. We have now demonstrated that octopamine mediates release of both AKH I and II from Locusta corpora cardiaca in vitro. Octopamine, IBMX, and forskolin have previously been shown to elevate levels of cAMP in the glandular lobe. In this paper we demonstrate that IBMX and forskolin mediate secretion of AKH I and AKH II thus mimicking the effects of octopamine in this tissue. The cAMP analogs dibutyryl cAMP and 8-bromo cAMP also elicit release of AKH and a subthreshold concentration of IBMX potentiates the effects of octopamine. These observations demonstrate that cAMP participates in regulating AKH release and support the hypothesis that octopamine mediates hormone release at least in part via changes in intracellular levels of cAMP. The release of AKH I and AKH II is apparently regulated by similar mechanisms. The hyperlipemic activity of AKH II released into the perfusates following stimulation by octopamine and agents which elevate cAMP levels is significantly lower than that of AKH I. This differential response is probably due both to the reduced lipid-mobilizing effect of AKH II relative to AKH I, as well as to the release of greater amounts of AKH I.

CL-proteins and the regulation of lipoprotein lipase activity in locust flight muscle

Lipoprotein lipases in the flight muscles of Locusta migratoria show a marked substrate specificity: diacylglycerols associated with the adipokinetic hormone (AKH)-induced lipoprotein, A+, are hydrolysed at 4 to 5 times the rate of those associated with the lipoprotein in resting (non-hormone-stimulated) locusts, Ayellow. To determine the basis for this discrimination, the effect on the activity of flight muscle lipoprotein lipase of CL-proteins, a major constituent of lipoprotein A+, but not of Ayellow, has been investigated; they inhibit the flight muscle enzyme in a competitive manner whether activity is measured with a natural lipoprotein substrate, a lipid emulsion or a water soluble substrate. Experiments in vivo suggest that the flight muscle enzyme is normally inhibited in resting (non-AKH-stimulated) locusts but, interestingly, injection of synthetic AKH-I relieves the inhibition and increases the activity by 30 to 40%. This is not a direct effect of the hormone on the enzyme, but appears to be related to the hormone-induced formation of lipoprotein A+, so that the majority of CL-proteins in the haemolymph become bound to this lipoprotein and the concentration of free CL-proteins is markedly reduced. We suggest that CL-proteins play a major role in the regulation of lipoprotein lipase in locust flight muscle.

Hormonal control of fat-body glycogen mobilization for locust flight

Fat-body phosphorylase in locusts injected with adipokinetic hormone (AKH I) is highly activated, as revealed by the relative proportions of the three forms present. Activation of phosphorylase during flight is strongly reduced when locusts are ligated at the neck, indicating that this activation is due to a factor from the head, which upon flight is released into the hemolymph. Flight-induced activation of phosphorylase is prevented when the release of AKH from the corpus cardiacum is blocked by the presence of high trehalose levels in the hemolymph, and also when the production of AKH is made impossible by prior removal of the corpus cardiacum glandular lobe. These results are discussed in relation to the possible involvement of AKH in the control of fat-body phosphorylase activity during flight.

Regulation of prothoracicotropic hormone release by juvenile hormone in the penultimate and last instar larvae of Mamestra brassicae

The penultimate instar larvae of Mamestra brassicae have one ecdysteroid peak 2 days after ecdysis which induces larval ecdysis. Allatectomy deleted this peak and caused a larger peak 7 days later just before precocious pupation, in a pattern similar to the ecdysteroid titer of the last instar. Application of juvenile hormone (JH) immediately after allatectomy restored the normal larval pattern and larval ecdysis. The brain of the normal Day 1 or 2 penultimate instar larva had higher prothoracicotropic hormone (PTTH) activity than that of the allatectomized larva. Therefore, JH in the penultimate instar activates the brain to secrete and/or produce PTTH. Allatectomy of last instar larvae prolonged the period from gut purge to pupation by causing a delay of the ecdysteroid peak necessary for pupation. Application of JH restored the normal timing of ecdysteroid release. Thus, JH is important for the occurrence of the ecdysteroid surge on Day 7, since its absence delayed this surge by a day.

Identification of the cerebral neurosecretory cells that contain eclosion hormone in the moth Manduca sexta

Eclosion hormone (EH) is an insect neuropeptide that is released at the end of metamorphosis from the CNS and triggers the stereotyped motor program of adult emergence. Using three distinct experimental approaches, we have identified a discrete set of neurosecretory cells in the brain of the moth Manduca sexta that contains and releases EH. By isolating the neurosecretory somata and testing them with a sensitive behavioral bioassay, we identified a cluster of ipsilaterally projecting cells (Group Ia) that contain EH. Intracellular stimulation of individual cells within this group induced the release of bioactive EH into the hemolymph surrounding the neurohemal organs of the brain, whereas stimulation of cells in the other cerebral neurosecretory clusters did not. We also developed a polyclonal antiserum against purified EH that precipitated all bioactive material from samples containing the peptide. This antiserum selectively stained 5 of the Group Ia cells on either side of the brain, as well as their central and terminal processes. Preincubation of the serum with EH dramatically reduced its ability to bind the peptide subsequently. The combined application of these physiological and immunological techniques has led to the unequivocal identification of the EH neurons in the moth brain.

Diversity of neurohormonal release sites in insects: coexistence of two different (alpha and beta) types of neurohemal structure in the perisympathetic organs

A comparative ultrastructural study of insects was made whose primitive perisympathetic organs consisted either of a single median neurohemal formation per segment (Periplaneta americana) or of two transverse formations (Carausius morosus), or again, of three--one median and two transverse--as in Locusta migratoria. The results showed that the perisympathetic organs always comprised two types of structure (alpha and beta), even when a single formation exists. In Periplaneta and Carausius, both types were seen to coexist in the same neurohemal formation. In Locusta, however, they were separated, the alpha structure constituting the median organ and the beta structure, the two transverse organs. Each of the two structures have special features: the beta structure displays the usual characteristics of a loose neurohemal organ, i.e., it is penetrated by sinuses and has neurosecretory endings devoid of a glial coat; the alpha structure, on the contrary, forms dense compact organs whose endings are covered with a continuous glial layer. During the evolution, this last structure gradually separated from the other neurohemal formations. It was observed to correspond to a single type of neurosecretory cell, distinct from all other cell types by the particular mode of its release. These results for primitive perisympathetic organs confirm earlier findings for advanced organs. They indicate that both the alpha and beta structures are generally present in insects, thus showing their importance in the physiology of these animals.

Developmental changes in choline uptake and acetylcholine metabolism in the larval brain of the tobacco hornworm, Manduca sexta

The larval brain of the tobacco hornworm, Manduca sexta, was maintained in vitro and the uptake of labelled and unlabelled choline as well as their subsequent metabolism were measured by high-voltage paper electrophoresis. Significant levels of choline lipid metabolites, phosphorylcholine and acetylcholine (ACh) were noted. Unbound choline reached equilibrium after 6-8 h of incubation, while ACh accumulation continued to increase after 24 h indicating that the rate of synthesis exceeded the rate of breakdown. An apparent Km could not be determined for these whole-organ studies; however, the Vmax for ACh accumulation for days 5 (70 pmol/brain/h) and 6 (105 pmol/brain/h) of the last larval instar did vary significantly while the level of unbound choline in the brain did not change. The level of choline uptake was dependent upon the presence of Na+ and Ca2+, while the amount of ACh accumulated was affected specifically by the presence of Mg2+, the latter ion activating acetylcholinesterase. The determination of levels of unbound choline and ACh accumulation in the developing brain during the last two larval instars demonstrated increases in acetylcholine accumulation at previously reported times of the release of the hormone that initiates the molting process, prothoracicotropic hormone. These changes in the patterns of ACh accumulation occur during 4-8 h time intervals; this is the first report of such short-range changes in neurotransmitter metabolism in whole brains. The intensity of the ACh accumulation shift is equivalent to the intensity of the hormone burst. Other fluctuations in the levels of ACh accumulation and free choline correlate with the development of the brain.

Control of neurosecretion in the moth Manduca sexta: physiological regulation of the eclosion hormone cells

Metamorphosis in the moth Manduca sexta culminates with the secretion of the peptide eclosion hormone (EH), which triggers the stereotyped behavior of adult emergence (eclosion) from the pupal cuticle. In restrained but spontaneously behaving animals, the release of EH occurred shortly before the onset of subjective night (Fig. 3) and coincided with a depletion of EH from the neurohemal organs of the brain, the corpora cardiaca-corpora allata complex (CC-CA; Fig. 4). EH is produced by neurons within a bilaterally paired group of brain neurosecretory cells (Group Ia) which project to the CC-CA via the nervi corporis cardiaci- 1 + 2 (NCC-1 + 2; Fig. 1). Electrical stimulation of the NCC-1 + 2 caused a marked increase in the levels of EH secreted from isolated CC-CA (Fig. 2), while stimulation of the other nerves innervating the neurohemal organs did not. Electrical activity in the NCC-1 + 2 paralleled that of the cerebral neurosecretory cells (Fig. 1). Chronic extracellular recordings revealed a sudden increase in the tonic firing of several units within this nerve approximately 2 to 3 h before normal eclosion (Fig. 5), coincident with the release of EH bioactivity from the CC-CA (Fig. 6). The Group Ia neurons were electrically inactive on the day before eclosion (Day-1), but on the day of eclosion (Day 0) a subgroup of these cells exhibited both enhanced synaptic input and elevated rates of tonic firing during the normal time of EH release (Fig. 7). No significant differences in resting membrane potential or spike waveform characteristics were detected among the various subsets of Group Ia cells on either Day-1 or Day 0, while a significant increase in the resting input resistance was seen in the active subgroup on Day 0 (Fig. 8). This increase may be due to the regulatory effects of the steroid 20-hydroxyecdysone, which inhibits the release of EH and may act by preventing the synaptic activation of the EH neurons until the final day of adult development.

The pupal cuticle of Drosophila: differential ultrastructural immunolocalization of cuticle proteins

Precise ultrastructural localization of Drosophila melanogaster pupal cuticle proteins (PCPs) was achieved by the immunogold labeling of frozen thin sections. PCPs were found in lamellate cuticle and intracellular vesicles but, curiously, were absent from the assembly zone of the cuticle. Antibodies that distinguish between the two classes of PCPs--low molecular weight (L-PCPs) and high molecular weight (H-PCPs)--revealed that the morphologically distinct outer lamellae contained L-PCPs and the inner lamellae contained H-PCPs. The sharp boundary between these two antigenic domains coincides with the transition from the outer to the inner lamellae, which in turn is correlated with the cessation of L-PCP synthesis and the initiation of H-PCP synthesis in response to 20-hydroxyecdysone (Doctor, J., D. Fristrom, and J.W. Fristrom, 1985, J. Cell Biol. 101:189-200). Hence, differences in protein composition are associated with differences in lamellar morphology.

The release of the prothoracicotropic hormone in the tobacco hornworm, Manduca sexta, is controlled intrinsically by juvenile hormone

Pupal development is elicited early in the last larval instar of the tobacco hornworm, Manduca sexta (Johannson), by a precise temporal and quantitative increase in the haemolymph titre of 20-hydroxyecdysone. This increase in the titre is referred to as the pupal commitment peak, and it occurs once the titre of juvenile hormone (JH) has dropped. If the haemolymph titre of JH remains elevated at this time due to topical application of the hormone or of its analogue ZR512, commitment is delayed or inhibited in a dose-dependent manner. This delay or inhibition is due to the curtailment of the commitment peak in the ecdysteroid titre, which results from a failure of the prothoracic glands (PG) to increase the synthesis/secretion of the premoulting hormone, ecdysone. Since the PG from ZR512- and JH 1-treated larvae are capable of being activated in vitro by the prothoracicotropic hormone (PTTH), the effect of JH on the PG does not involve suppression of gland sensitivity to PTTH. The locus of the JH effect was determined to be the brain-retrocerebral complexes (Br-CC-CA), on the basis of experiments which tested the effect of implanted Br-CC-CA from pre-commitment larvae treated with JH on the occurrence of pupal commitment in head-ligated larval hosts. The implanted, JH-treated Br-CC-CA exhibited a delayed release of PTTH, and the effect was at concentrations of JH that were physiological. These results argue that JH functions to control the time during the last larval instar when pupal commitment occurs by dictating when PTTH will undergo gated release.

Intracellular stimulation of an identified neuron evokes cardioacceleratory peptide release

The central nervous system of the tobacco hawkmoth, Manduca sexta, is known to contain two cardioacceleratory peptides (CAP's), both of which function in vivo as cardioregulatory neurohormones. Intracellular electrical stimulation of a single abdominal ganglion neuron evokes the release of CAP-like bioactivity. This stimulation-evoked bioactivity is destroyed by prior treatment with protease. The possibility that intracellular stimulation of a CAP-containing neuron synaptically activated additional spiking neurons is eliminated.

Properties of an in vitro bioassay for hypertrehalosemic hormone of Blaberus discoidalis cockroaches

The ability of the fat body to respond to the hypertrehalosemic action of corpora cardiaca-allata (CC + CA) extracts was measured in vitro with tissue from adult, male Blaberus discoidalis cockroaches. Only trehalose increased in the hemolymph when gland extracts were injected in vivo; likewise, only trehalose levels responded when fat bodies were exposed to gland extracts in vitro. Although fat bodies from 0-day-old animals gave the least response to gland extracts, all animals 5 or more days old showed elevated responses. A linear dose-response occurred between 0.02 and 0.08 CC + CA pair. Fat bodies did not show an in vitro, hypertrehalosemic response to insulin, glucagon, proctolin, dopamine, epinephrine, norepinephrine, serotonin, octopamine, or tyramine. A strong hypertrehalosemic response was found to both synthetic adipokinetic hormone and red-pigment concentrating hormone; however, reversed-phase, thin-layer chromatography of CC + CA extracts and adipokinetic hormone indicated that the hypertrehalosemic effect and the adipokinetic hormone were separate. This in vitro system comprises a relatively rapid, simple, and accurate bioassay for the hypertrehalosemic neurohormone of insects.

The metabolism of insecticides: the role of monooxygenase enzymes

In summary, it can be said that advances have been made in understanding the range and significance of monooxygenase reactions involving insecticides in both target and non-target species and that some specific aspects emerge that should command the attention of insecticide toxicologists and others in the immediate future. The role of co-oxidation of insecticides during prostaglandin synthesis has just emerged as an issue but, if we can extrapolate from other xenobiotics (126), we can predict with some confidence that it will assume major proportions. It is also apparent that both activation and detoxication reactions are catalyzed by the FAD-containing monooxygenase and that many of these reactions were formerly attributed to the cytochrome P-450-dependent monooxygenase system. Since any particular substrate may be oxidized by either or both of these two routes, it is essential that studies be conducted to define their relative contributions to xenobiotic oxidation in microsomal preparations and ultimately in vivo. The area of interactions and the mechanisms behind them is also of importance, from the public health point of view in the case of multiple exposures, and from the practical viewpoint in the case of insecticide synergists. While the above aspects are not the only ones of future importance, they should contribute to the ultimate goal of insecticide toxicology: practical, safe use of chemicals for the control of insect pests.

Characterization of inhibitor A, a protease from Bacillus thuringiensis which degrades attacins and cecropins, two classes of antibacterial proteins in insects

The insect pathogen Bacillus thuringiensis produces an exoprotease, inhibitor A, at the beginning of the stationary growth phase. In vitro, the enzyme selectively destroys cecropins and attacins, two antibacterial proteins found in immune hemolymph from Hyalophora cecropia. The specificity of this enzyme was investigated using cecropin A(1-33) and HPLC for separation and characterization of the fragments obtained. A maximum of 12 different peptides were produced and their positions in the known sequence of cecropin A(1-33) were deduced from their amino acid compositions. The enzyme did not show a stringent requirement for a specific amino acid sequence at the cleavage site but prefers a hydrophobic residue on the C-terminal side. The specificity of the enzyme is explained in terms of the open structure of the cecropins and a pronounced inability of inhibitor A to attack globular proteins.

Correlations between endocrine gland ultrastructure and hormone titers in the fifth larval instar of Manduca sexta

Correlations were made between endocrine gland ultrastructure and circulating hormone titers of Manduca sexta to investigate the mechanisms of hormone biosynthesis and secretion. Both the prothoracic glands (PTG), which secrete ecdysone, and the corpora allata (CA), which secrete juvenile hormone (JH), were studied. In the prothoracic glands, the intracellular spaces increase in area and reach their maximum size following the major ecdysteroid peak in the fourth and fifth larval instars. Within the intercellular spaces are multivesicular sacs (MVS), structures which are clusters of vesicles bounded by another membrane. Since these sacs are largely depleted of their internal vesicles after the second cycle of tropic hormone stimulates the PTG to secrete ecdysone, the MVS probably release a gland cell product at this time. In the CA, concentric whorls of smooth endoplasmic reticulum are present in larval glands, when the JH titer is high, but are absent from pupal CA when the JH titer is low. The peak of JH at Days 6-8 of the fifth larval instar occurs after an increase is seen in the neurosecretory cell axon diameters suggesting that the CA are stimulated by a brain hormone to release JH. The number of Golgi complexes increases in pupal CA and dense bodies are present in pupal but not larval glands. These Golgi complexes may be involved in the manufacture of lysosomal enzymes which degrade JH within the gland itself.

Immunohistochemical investigations of neuropeptides in the brain, corpora cardiaca, and corpora allata of an adult lepidopteran insect, Manduca sexta (L)

In the brain of adult specimens of the tobacco hornworm moth, Manduca sexta (L), cells immunoreactive for several kinds of neuropeptides were localized by means of the PAP procedure, by use of antisera raised against mammalian hormones or hormonal peptides. In contrast, no such neurosecretory cells were found in the corpora cardiaca and corpora allata (CC/CA); in the CC/CA, however, immunoreactive nerve fibres were observed, reaching these organs from the brain. The neurosecretory cells found in the brain were immunoreactive with at least one of the following mammalian antisera, namely those raised against the insulin B-chain, somatostatin, glucagon C-terminal, glucagon N-terminal, pancreatic polypeptide (PP), secretin, vasoactive intestinal polypeptide (VIP), glucose-dependent insulinotropic peptide (GIP), gastrin C-terminus, enkephalin, alpha- and beta-endorphin, Substance P, and calcitonin. No cells were immunoreactive with antisera specific for detecting neurons containing the insulin A-chain, nerve growth factor, epidermal growth factor, insulin connecting peptide (C-peptide), polypeptide YY (PYY), gastrin mid-portion (sequence 6-13), cholecystokinin (CCK) mid-portion (sequences 9-20 and 9-25), neurotensin C-terminus, bombesin, motilin, ACTH, or serotonin. All the neuropeptide-immunoreactive cells observed emitted nerve fibers passing through the brain to the CC and in some cases also to the CA. In CC these immunoreactive nerve fibers tended to accumulate near the aorta. It was speculated that neuropeptides are released into the circulating haemolymph and act as neurohormones.

Pharmacology of insecticide-induced release of hyperlipaemic hormone in the locust, Locusta migratoria

1. The mechanism of insecticide-induced release of hyperlipaemic hormone from the glandular lobe of the isolated corpora cardiaca (CC) of locusts has been studied using pharmacological agents. 2. Treatment of isolated CC with various insecticides induces the release of hyperlipaemic hormone as judged by bioassay. 3. Reserpinisation of CC (25 micrograms/locust) or treatment of isolated CC with the alpha-adrenergic-receptor blocker phentolamine had no effect on the action of DDT or bioresmethrin, but partially blocked the action of dieldrin and chlorfenvinphos. 4. Treatment of isolated CC with the postsynaptic cholinergic blocker hexamethonium bromide abolished the effect of dieldrin and chlorfenvinphos, but did not block the action of DDT or bioresmethrin. 5. The effects of all the insecticides tested in this study were completely blocked by treatment of the CC with 10(-6) M tetrodotoxin. 6. The results indicate that DDT and bioresmethrin may act directly on the glandular cells via a sodium-dependent mechanism. The results with dieldrin and chlorfenvinphos suggest the presence of two distinct cholinergic pathways, one of which acts via the pre-synaptic aminergic terminals which control the glandular cells, whereas the other acts elsewhere in the CC. Sodium channels are also involved in the ultimate expression of these two insecticides.

Is octopamine a transmitter mediating hormone release in insects?

The release of hyperlipemic hormone from the glandular cells of the corpus cardiacum (CC) of Locusta migratoria is under the synaptic control of axons in nervus corpus cardiacum II (NCC II). The effects of aminergic agonists and antagonists on the release of the hyperlipemic hormone induced by electrical stimulation of NCC II have been examined. CC isolated from reserpine-injected locusts did not release hormone when subjected to electrical stimulation of NCC II but continued to release hormone in response to high-potassium saline. The electrically stimulated release of hormone from isolated CC was abolished by the alpha-adrenergic blocking agent, phenoxybenzamine, but potentiated by the beta-adrenergic blocking agent, propranolol. Phenoxybenzamine did not interfere with release induced by high-potassium saline. It is suggested that the postsynaptic receptors on the glandular cells are similar to the alpha-adrenergic receptors of vertebrates. Octopamine was found to be present in the glandular lobe of the CC at concentrations of 0.62 pmole per gland pair. Reserpine depleted the content to 0.3 pmole per pair. Bathing the CC in 10(-7) M octopamine resulted in the release of hyperlipemic hormone, and this release was blocked by phenoxybenzamine. It is concluded that the neurotransmitter involved in the synapse between axons of NCC II and the cells releasing hyperlipemic hormone is aminergic, possibly octopaminergic. Octopamine may well be a transmitter mediating hormone release in insects.