Release of identified adipokinetic hormones during flight and following neural stimulation in Locusta migratoria

Fractionation of methanol extracts of perfusate and haemolymph on thin-layer chromatography was used to separate hormones associated with haemolymph lipid regulation in Locusta. Electrical stimulation of the nervi corporis cardiaci II (NCC II) of isolated corpora cardiaca resulted in the release of three hormones into the perfusate; hypolipaemic hormone and two adipokinetic hormones. The two adipokinetic hormones co-migrated with synthetic adipokinetic hormone (adipokinetic hormone I) and with the R_F value similar to Carlsen's peptide (adipokinetic hormone II).These two adipokinetic hormones were also present in small amounts in the haemolymph of unflown Locusta, and shown to be released during a 30-min flight. The adipokinetic hormone II fraction from the NCC II-stimulated perfusate and haemolymph also possessed hyperglycaemic activity when assayed in ligated locusts.It is concluded that NCC II controls the release of adipokinetic hormones during flight and that two adipokinetic hormones are released during flight. One of these hormones adipokinetic hormone II also acts as a hyperglycaemic hormone illustrating that a hyperglycaemic hormone is released, during flight.     

The role of the glandular lobes of the corpora cardiaca during flight in Locusta

ABSTRACT. Flight performance in Locusta is reduced following severance of the major afferent nerves to the corpora cardiaca or removal of the glandular lobes of the corpora cardiaca. These operations prevent the release of adipokinetic hormone and the consequent mobilization of stored lipid. However, locusts deprived of about 90% of their glandular lobe tissue, while flying poorly, did mobilize lipid. It is suggested that the remaining glandular parenchyma cells are capable of secreting enough hormone to stimulate lipid mobilization, but that the concentration may be inadequate to encourage lipid utilization. After removal of all the glandular lobe parenchyma, the blood carbohydrate concentration was temporarily depressed. Nevertheless flight performance was equally poor, both when haemolymph carbohydrate levels were low and when they had returned to normal. After the injection of trehalose into operated control locusts and locusts deprived of their glandular lobes, flight was still markedly poorer in the operated insects, even though the injection of trehalose prevented adipokinetic hormone release in the intact locust. It seems that the poor flight performance of locusts deprived of their glandular lobes cannot be fully explained by the simple absence of adipokinetic hormone.     

In vivo studies on the release of hormones from the corpora cardiaca of locusts

Summary Sectioning of the afferent nerves (NCCl and NCCll) to the locust corpus cardiacum prevents thein vivo release of adipokinetic hormone from the glandular lobes. This failure to release the hormone during flight and the consequent lack of lipid mobilisation brings about an impairment of flight performance which can be corrected by injections of corpus cardiacum extracts. Sectioning of the NCCl and NCCll reduces markedly the activity of the corpora allata. However, the poor flight performance of allatectomised locusts is not related to an inability to mobilise lipid since injections of corpus cardiacum extract which will mobilise fat body lipid in these locusts have no effect on flight performance. The results of individual sectioning of the NCCl and NCCll suggest that a double innervation of the glandular lobes functionsin vivo to control adipokinetic hormone release but that the NCCl alone may control the release of the diuretic hormone.     

Quantitative studies on the release of locust adipokinetic hormone

Fractionation of methanolic extracts of haemolymph on Sephadex LH-20 made possible the measurement of the titre of adipokinetic hormone in the haemolymph of locusts. Experimentally produced high concentrations of haemolymph carbohydrate caused a delay in the mobilization of lipid during flight, and very low titres of the hormone were present in the haemolymph of locusts injected with trehalose immediately before a 25 min flight. In these locusts flight speed was higher than saline-injected controls. Although delayed lipid mobilization during flight was also seen in locusts injected with sucrose, sucrose is not utilized for flight metabolism and flight speed was not increased by the injection. Tentative estimates of the release rate (c. 1000pg/20min flight) and half life (c. 20 min) of adipokinetic hormone during flight are made. The results described suggest that during flight the rate at which trehalose disappears from the haemolymph does not play a major role in the initiation of the release of adipokinetic hormone.     

Cerebral neurosecretory cells and flight in the locust

The effect on flight performance of various superficial lesions of the pars intercerebralis in and around the area of the MNSC (median groups of cerebral neurosecretory cells) have been studied 18 hr after surgery. Only lesions involving areas immediately lateral to the MNSC produce an impairment of flight performance. The release of adipokinetic hormone during flight was studied in these locusts by measuring the changes in haemolymph lipid during flight. It has not been possible to identify any of the areas tested as being concerned with the control of the release of adipokinetic hormone since lipid mobilization was not prevented by any of the operations studied.The poor flight performance in locusts in which the MNSC were destroyed by cautery on day 1 of adult life can be prevented by regular topical application of a synthetic juvenile hormone analogue. It is argued that the effects of removal of the MNSC on the development of flight performance are most likely a consequence of reduced activity of the corpora allata.     

Identification and characterization of adipokinetic hormone (Locusta migratoria)-like immunoreactivity in the human cerebrospinal fluid

Using an antiserum raised against locust adipokinetic hormone I, considerable quantity of adipokinetic hormone-like immunoreactivity was demonstrated in the human cerebrospinal fluid. The immunoreactivity was characterized by gel permeation and high performance liquid chromatography. The main immunoreactive component in the cerebrospinal fluid coeluted with adipokinetic hormone I. These results suggest that adipokinetic hormone may contribute to the neuronal function in the human central nervous system.     

Calcium and cAMP are second messengers in the adipokinetic hormone-induced lipolysis of triacylglycerols in Manduca sexta fat body

We have previously shown that stereospecific hydrolysis of stored triacylglycerol by a phosphorylatable triacylglycerol-lipase is the pathway for the adipokinetic hormone-stimulated synthesis of sn -1, 2-diacylglycerol in insect fat body. The current series of experiments were designed to determine whether cAMP and/or calcium are involved in the signal transduction pathway for adipokinetic hormone in the fat body. After adipokinetic hormone treatment, cAMP-dependent protein kinase activity in the fat body rapidly increased and reached a maximum after 20 min, suggesting that adipokinetic hormone causes an increase in cAMP. Forskolin (0.1 micrometer), an adenylate cyclase activator, induced up to a 97% increase in the secretion of diacylglycerol from the fat body. 8Br-cAMP (a membrane-permeable analog of cAMP) produced a 40% increase in the hemolymph diacylglycerol content. Treatment with cholera toxin, which also stimulates adenylate cyclase, induced up to a 145% increase in diacylglycerol production. Chelation of extracellular calcium produced up to 70% inhibition of the adipokinetic hormone-dependent mobilization of lipids. Calcium-mobilizing agents, ionomycin and thapsigargin, greatly stimulated DG production by up to 130%. Finally, adipokinetic hormone caused a rapid increase of calcium uptake into the fat body. Our findings indicate that the action of adipokinetic hormone in mobilizing lipids from the insect fat body involves both cAMP and calcium as intracellular messengers.     

Hormonal regulation of proline synthesis and glucose release in the fat body of the Colorado potato beetle, Leptinotarsa decemlineata

In the adult males of the Colorado potato beetle, Leptinotarsa decemlineata, corpora cardiaca extract injected in vivo gives rise to an increase in glucose and a decrease in alanine concentration of the haemolymph. The regulation of proline synthesis and glucose release in the fat body of the Colorado potato beetle was investigated further in vitro. Proline regulates its own synthesis by a feedback inhibition. Moreover, a factor present in extracts from the corpora cardiaca stimulates synthesis in the fat body in vitro. This effect was demonstrated with corpora cardiaca extracts from beetles, locusts and cokroaches. Also, synthetic adipokinetic hormone stimulates proline synthesis in the fat body of the Colorado beetle. In addition, a release of glucose from the fat body of the beetle could be evoked by the addition of locust and beetle corpora cardiaca extracts or synthetic adipokinetic hormone. The physiological significance of both effects is discussed.     

Isolation and structure elucidation of a novel adipokinetic hormone (Lom-AKH-III) from the glandular lobes of the corpus cardiacum of the migratory locust, Locusta migratoria

A new adipokinetic hormone (named Lom-AKH-III) was isolated from the glandular lobes of the corpora cardiaca of Locusta migratoria. At the N-terminus it is blocked by a 5-oxoproline (pyroglutamic acid) residue (less than Glu). After enzymatic deblocking, the amino acid sequence of the N-terminus was partly established by automatic Edman degradation to be [less than Glu]-Leu-Asn-Phe-Thr-Pro-. Fast-atom-bombardment spectrometry (FAB-MS) revealed that the new hormone is an octapeptide, which is amidated at the C-terminus, and has a relative molecular mass of 1072. Based on the FAB-MS data the complete sequence is less than Glu-Leu-Asn-Phe-Thr-Pro-Trp-Trp-NH2, which was confirmed by chemical synthesis. All characteristics from HPLC, FAB-MS and biological activity of the natural hormone and the synthetic peptide appeared to be identical. Although the structure of this new hormone resembles that of Lom-AKH-I (less than Glu-Leu-Asn-Phe-Thr-Pro-Asn-Trp-Gly-Thr-NH2), its amino acid sequence points to a completely different route for its biosynthesis, involving a third prohormone. High-[K+]-containing media can cause release of all three adipokinetic hormones in vitro. Interestingly, the new hormone is absent in another locust species. Schistocerca gregaria. Based on in vitro biosynthesis experiments the turnover for this hormone is very high, suggesting an important physiological function. Locusta migratoria is the first insect species in which three different adipokinetic hormones have been demonstrated.     

In vitro studies on hormone-stimulated lipid mobilization from fat body and interconversion of haemolymph lipoproteins of Locusta migratoria

Both adipokinetic hormone and octopamine have a stimulating effect on lipid release from locust fat body in vitro, when incubated in diluted haemolymph. The presence of adipokinetic hormone results in the formation of the flight-specific haemolymph lipoprotein A⁺ accepting the increased amount of lipids released into the incubation medium. In contrast, interconversions of lipoproteins do not occur when octopamine is added to the incubation medium, which is in line with the expectations: the lipid-mobilizing effect of octopamine is a limited and short-term effect. When fat body tissue is incubated with isolated haemolymph protein fractions, the lipid-mobilizing effect of adipokinetic hormone only occurs when the incubation medium contains both lipoprotein, A_y and protein fraction C, resulting in the formation of lipoprotein A⁺. In similar control incubations with the hormone omitted, some lipoprotein A⁺ is also formed (concomitant with a slight amount of lipid released), though significantly less than in incubations with hormone. Besides a stimulating function on lipolytic processes in the fat body, adipokinetic hormone is suggested to influence haemolymph lipoprotein rearrangement. A possible counteracting function of another factor in the haemolymph is discussed.     

Hormonal control of diacyl glycerol mobilization from fat body of the desert locust,Schistocerca gregaria

The action of adipokinetic hormone in stimulating mobilization of diacyl glycerol from locust fat body was studied in vitro. For optimum lipid mobilization haemolymph protein and calcium ions were required, and the amount and time course of release were dependent on the hormone concentration. Dibutyryl cyclic AMP or theophylline mimicked the action of the hormone and a synergistic effect of theophylline with hormone was found. Purified adipokinetic hormone with theophylline increased the concentration of cyclic AMP in fat body and stimulated the incorporation of [³H]-adenine into cyclic AMP.A lipase was present in fat body extracts which hydrolysed triacyl glycerol mainly to diacyl glycerol plus fatty acid. The activity of this enzyme was low, and attempts to activate it with hormone were unsuccessful.     

A possible role of Schisto FLRFamide in inhibition of adipokinetic hormone release from locust corpora cardiaca

The distribution and actions of FMRFamide-related peptides (FaRPs) in the corpora cardiaca of the locust Locusta migratoria were studied. Antisera to FMRFamide and SchistoFLRFamide (PDVDHVFLRFamide) label neuronal processes that impinge on glandular cells in the glandular lobe of the corpora cardiaca known to produce adipokinetic hormones. Electron microscopic immunocytochemistry revealed that these FaRP-containing processes form synaptoid contacts with the glandular cells. Approximately 12% of the axon profiles present in the glandular part of the corpus cardiacum contained SchistoFLRFamide-immunoreactive material. Retrograde tracing of the axons in the nervus corporis cardiaci II with Lucifer yellow revealed 25–30 labelled neuronal cell bodies in each lateral part of the protocerebrum. About five of these in each hemisphere reacted with the SchistoFLRFamide-antiserum. Double-labelling immunocytochemistry showed that the FaRP-containing processes in the glandular lobe of the corpora cardiaca are distinct from neuronal processes, reacting with an antiserum to the neuropeptide locustatachykinin. The effect of the decapeptide SchistoFLRFamide and the tetrapeptide FMRFamide on the release of adipokinetic hormone I (AKH I) from the cells in the glandular part of the corpus cardiacum was studied in vitro. Neither the deca- nor the tetrapeptide had any effect on the spontaneous release of AKH I. Release of AKH I induced by the phosphodiesterase inhibitor IBMX, however, was reduced significantly by both peptides. These results point to an involvement of FaRPs as inhibitory modulators in the regulation of the release of adipokinetic hormone from the glandular cells.     

Adipokinetic hormones concentrations in the haemolymph of Schistocerca gregaria,measured by radioimmunoassay

A new procedure for the measurement of adipokinetic hormone (AKH) concentrations in locust (Schistocerca gregaria) haemolymph is described: Haemolymph is extracted with chloroform/methanol/water and the aqueous layer is fractionated with reverse-phase cartridges and HPLC. The fractions corresponding to AKH-I (Lom-AKH-I) and AKH-II (Scg-AKH-II) are then measured in a competitive binding assay using specific antibodies and [3H]AKHs. The procedures could be applied to any peptides containing N-terminal pyroglutamate residues including all members of the adipokinetic/hyperglycaemic/red pigment concentrating hormone family. Results show that the concentrations of both AKH-I and AKH-II increase within 5 min of initiation of flight and are maintained at approx. 15-fold (AKH-I) and 6-fold (AKH-II) the resting levels over flights of at least 60 min. Poisoning of locusts with either the insecticide deltamethrin or with potassium chloride also caused release of hormones. Starvation for 6 h caused elevation of hormone levels in 5th instar nymphs, but starvation for 6 or 20 h had little effect on hormones in adults, despite an increase in haemolymph diacylglycerols at 20 h.     

Adipokinetic hormone and the regulation of carbohydrate and lipid metabolism in a working flight muscle preparation

Trehalose utilisation in a working flight muscle preparation is reduced, in a competitive manner, in the presence of haemolymph lipoprotein. In the presence of trehalose, utilisation of lipid from lipoprotein preparations with high lipid: protein ratios (but not low lipid: protein ratios) is favoured when a tissue extract containing adipokinetic hormone is included in the incubation medium. Under these conditions trehalose utilisation is reduced to a minimum level. This inhibition of trehalose oxidation in the presence of high-lipid lipoprotein and adipokinetic hormone is completely removed by the addition of 2-bromostearic acid to the incubation medium. Glycerol utilisation is not inhibited when lipid oxidation is favoured by the addition of adipokinetic hormone. It is argued that glycolytic flux is reduced (when lipid oxidation is favoured) at a point before the formation of triose phosphates; perhaps at the aldolase reaction.     

Role of neurotransmitters and neuropeptides in the control of gonadotropin release: A review

Rapid progress has been recorded recently in the understanding of the role of neuro-transmitters and neuropeptides in the control of reproduction and on their apparent potential in the regulation of fertility. Peptides, as well as monoamines, are important in the control of lutinizing hormone releasing hormone and gonadotropin release. The input from brainstem noradrenergic neurons as well as dopamine mediated stimulated release of lutinizing hormone. In addition considerable evidence exist for the occurrence of a specific follicle stimulating hormone-releasing factor. A large number of brain peptides affect the secretion of lutinizing hormone releasing hormone and the endogenous opioid peptides appear to have a physiologically important function in restraining the influence on lutinizing hormone releasing hormone release under most circumstances. Vasoactive intestinal peptide and substanceP stimulate whereas cholecystokinin, neurotensin, gastrin, secretin, somatostatin α-melanosite stimulating hormone and vasotocin inhibit lutinizing hormone release. Of the inhibitory peptides, cholecystokinin and arg-vasotocin are the most potent. Inhibin injected into the ventricle selectively suppresses follicle stimulating hormone release by a hypothalamic action. Thus the control of gonadotropin release is complex and a number of aminergic and peptidergic transmitters are involved.     

The hormonal content of the locust corpus cardiacum

Summary The amounts of adipokinetic and diuretic hormone in the separate storage and glandular lobes of the locust corpora cardiaca during the imaginal moult and up to the onset of sexual maturation have been measured. The levels of the hormones are high prior to the imaginal moult, fall at emergence and increase during the somatic growth period. The effects of surgical interference with the neuroendocrine system upon the hormonal content of the corpora cardiaca have been investigated. Cautery of the brain neurosecretory cells or allatectomy in mature locusts has no effect on the content of adipokinetic hormone. Diuretic hormone is absent from the storage lobes of locusts deprived of their cerebral neurosecretory cells but normal levels are present in the corpora cardiaca of allatectomised animals. Severance of the nervus corporis cardiacum I and II reduces the level of diuretic hormone in the storage lobes of the corpora cardiaca but is without effect on the levels of adipokinetic hormone in the glandular lobes. This work is supported by grants from the Science Research Council and the Royal Society.     

Differential location of peptide hormones in the secretory pathway of insect adipokinetic cells

Immunoreactivity of granules containing secretory material in the adipokinetic cells of the insect Locusta migratoria was studied using antisera specific for the adipokinetic hormone-associated peptides (AAP) I, II and III. Immunocytochemical detection of these associated peptides represents a new strategy for studying the intracellular location of the adipokinetic hormones and their prohormones. Fixation with 2% glutaraldehyde and 2% formaldehyde with low-temperature embedding in Lowicryl HM20 allowed highly selective immunogold labelling of both secretory and intracisternal granules. All three associated peptides were co-localized in secretory granules. This indicates that also all three adipokinetic hormones can be co-localized in these granules, which was confirmed by experiments in which, after secretory stimulation, adipokinetic hormone III was released from the adipokinetic cells together with adipokinetic hormones I and II. The immunopositivity of the intracisternal granules was similar to that of the secretory granules, although with the exception that the intracisternal granules did not show any specific reaction with anti-AAP III. The presence of AAP I and AAP II in intracisternal granules indicates that these granules only function as stores of adipokinetic prohormones I and II and not of adipokinetic prohormone III. The observed differences in storage in intracisternal granules among the three adipokinetic prohormones suggest differences in physiological significance of the three adipokinetic hormones in L. migratoria.     

Cyclic AMP in locust fat body: Correlation with octopamine and adipokinetic hormones during flight

The effects of flight upon the level of cyclic AMP in the fat body of Locusta migratoria have been examined. Flight induced two phases of cyclic AMP elevation; the first during the initial 10 min of flight, the second between 20–30 min of flight. Neck-ligated locusts have increased levels of cyclic AMP after 10 min of flight, indicating that the adipokinetic hormones are not necessary for this elevation. Injection of 6 mg trehalose, a procedure known to delay the release of adipokinetic hormones, prevented the increases seen at 10 and 30 min of flight. Injection of synthetic adipokinetic hormone I increased the levels of cyclic AMP within 5 min, and these were maintained for up to 15 min. The roles of octopamine and the adipokinetic hormones in increasing fat body cyclic AMP, and thereby regulating haemolymph lipid, during flight are discussed.     

A new member of the AKH/RPCH family that stimulates locomotory activity in the firebug, Pyrrhocoris apterus (Heteroptera)

A new member of the AKH/RPCH family was isolated and identified from the corpora cardiaca of the firebug Pyrrhocoris apterus. The peptide was isolated in a single step by reversed phase HPLC and the structure deduced from the multiple MS (MS(N)) electrospray mass spectra and amino acid analysis as that of an octapeptide with the sequence pGlu-Leu-Asn-Phe-Thr-Pro-Asn-Trp-NH(2): this sequence was confirmed by synthesis. The synthetic peptide induced lipid mobilisation and stimulated locomotory activity in macropterous females. This peptide, designated as Pyrrhocoris apterus adipokinetic hormone (Pya-AKH), is the first identified adipokinetic hormone described in a representative species of the suborder Heteroptera.     

The hormonal control of haemolymph lipid during flight in Locusta migratoria

Fractionation of methanolic extracts of haemolymph on thin layer chromatography, followed by bioassay, has been used to measure the titres of adipokinetic hormones I and II in the haemolymph of flown locusts. These titres have been correlated with the elevation in haemolymph lipid. Haemolymph lipid elevates in a biphasic manner during locust flight. A rise in lipid occurs during the first 10 min of flight. Lipid levels then plateau between 10 and 20 min. A second, more pronounced elevation begins at 20 min and continues for up to 60 min. The titre of adipokinetic hormone I elevates 10–15 min after flight commences while that of hormone II elevates between 15–30 min. Adipokinetic hormone I contributes 80% of the activity at 30 min but only 45% at 60 min. It is suggested that the elevation in haemolymph lipid during the first 10 min of flight may not be induced by adipokinetic hormone I or II. The role of octopamine in this initial elevation is proposed and discussed.