The effects of linear and cyclic analogs of Locmi-DH, Dippu-DH(46) and Dippu-DH(31) on appetitive behavior in Locusta migratoria

The effects of analogs of the diuretic peptides Locmi-DH, Dippu-DH(46) and Dippu-DH(31) on two aspects of appetitive behavior are investigated in previously food-deprived nymphs of Locusta migratoria. The analogs tested are the C-terminal 15-mer and nonapeptides and their corresponding cyclic analogs. At a nominal dose of 1pmol injected per nymph, the linear fragments and their cyclic analogs of Dippu-DH(46) display no significant effects on the latency to feed or on the length of the first meal in nymphs. However, at the same dose, the linear fragments of Dippu-DH(31) and their cyclic analogs, and analogs of Locmi-DH modulate appetitive behavior: they are anorexigenic in reducing the duration of the first meal, and generally increasing the latency to feed. The cyclic analogs of Dippu-DH(31) are at least as effective as their linear counterparts in influencing these aspects of appetitive behavior in locust nymphs.

Immune responses of locusts to challenge with the pathogenic fungus Metarhizium or high doses of laminarin

Two isolates of Metarhizium anisopliae var acridum were tested for their effects on the locust immune system and for comparison with the effects of challenge by injection with laminarin. Isolate IMI 330189 (referred to hereafter as Met 189) is highly pathogenic whether applied topically as conidia or injected as blastospores. However, isolate ARSEF 728 (referred to hereafter as Met 728) is pathogenic only when injected as blastospores, suggesting that the lack of pathogenicity of topically applied conidia from this isolate is due to a failure to penetrate the insect cuticle and gain access to the haemocoel. After topical application of conidia from Met 189, no activation of prophenoloxidase is detected, but injection of blastospores from Met 189 brings about a transient increase in phenoloxidase activity in the haemolymph in both adult locusts and 5th instar nymphs, although this does not prevent fungal-induced mortality. Co-injection of adipokinetic hormone-I (AKH-I) with blastospores prolongs the activation of prophenoloxidase in the haemolymph of adult locusts, and enhances it in nymphs. It is argued that the lack of activation of prophenoloxidase in nymphs shown previously (Mullen, L., Goldsworthy, G., 2003. Changes in lipophorins are related to the activation of phenoloxidase in the haemolymph of Locusta migratoria in response to injection of immunogens. Insect Biochemistry and Molecular Biology 33, 661-670), reflects differences in the sensitivity of the immune system between adults and nymphs rather than distinct qualitative differences, and this is confirmed in this study by the demonstration that doses of laminarin higher than those used previously (>or=100 microg) do activate the prophenoloxidase cascade in 5th instar nymphs. Nodules are formed in locusts of all ages in response to fungal infection or injection of laminarin, although there is wide variation in the number, size and distribution of nodules formed. During the examination of 5th instar nymphs for nodule formation, a previously unknown phenomenon was observed in which the salivary glands melanise in response to injections of blastospores or high doses of laminarin. In c. 85% of such nymphs, this reaction is so strong that the whole salivary gland is intensely black. Such a response is not observed in the salivary glands of mature adult locusts.

Adipokinetic Hormone and the Immune Responses of Locusts to Infection

Injections of Bacillus, or of blastospores from the entomopathogenic fungus, Metarhizium anisopliae, activate the prophenoloxidase (PPO) cascade, and coinjection of adipokinetic hormone-I (AKH) enhances and prolongs these responses. When injected concurrently with an immunizing dose of live bacteria, AKH suppresses the appearance of antimicrobial activity and, after a short delay, increases the growth of bacteria within the hemocoel. Injections of live Escherichia coli or Pseudomonas aeruginosa into locusts fail to activate PPO in the hemolymph, even when coinjected with AKH. The coinjection of bacteria and hormone is rarely lethal to the locust. However, if locusts are injected with AKH when they are infected with Metarhizium, they die more rapidly than if no AKH is administered.

Induced hyperlipaemia and immune challenge in locusts

Injections of immunogens, such as beta-1,3-glucan or lipopolysaccharide (LPS), bring about a marked hyperlipaemia with associated changes in lipophorins and apolipophorin-III in the haemolymph of Locusta migratoria. These changes are similar to those observed after injection of adipokinetic hormone (AKH). The possibility that endogenous AKH is released as part of the response to these immunogens is investigated using passive immunisation against AKH-I, and measurement of AKH-I titre in the haemolymph after injection of immunogens. The data presented show that, despite the similarity of the changes brought about by the presence of immunogens in the haemolymph to those brought about by AKH, there is no release of endogenous AKH after injection of laminarin or LPS. A direct effect of the immunogens on release of neutral lipids by the fat body cannot be demonstrated in vitro, and the mechanism by which hyperlipaemia is induced during immune challenge remains uncertain.

The synthesis of an analogue of the locust CRF-like diuretic peptide, and the biological activities of this and some C-terminal fragments

The synthesis is described of an analogue of the locust CRF-like diuretic peptide in which methionine in positions 1,3, and 13 is replaced by isosteric methyl-homoserine residues. This analogue has been tested for biological activity on Malpighian tubules in vitro, and feeding behavior in vivo. It is highly active in stimulating fluid secretion and accumulation of cAMP in tubules, and on increasing the latency to feed and reducing meal duration. A 15 residue fragment from the C-terminus of the CRF-like peptide, Locmi-DP(32-46), is fully active in the feeding assay, but has only weak ability to stimulate the accumulation of cAMP in tubules. Two smaller fragments, Locmi-DP(32-37) and Locmi-DP(41-46), were tested but neither had consistent biological activity in any of the assays used here. None of the peptides tested have any substantive activity in increasing cGMP in tubules.

Insect peptide hormones: a selective review of their physiology and potential application for pest control

Our knowledge on primary structure, synthesis, release, receptor binding, structure-activity relationships, mode of action and degradation of, mainly, neuropeptides from insects has increased dramatically during the last 10 years or so. Here, five case studies are presented, which deal selectively with effects on: reproduction (trypsin modulating oostatic factor in mosquito); energy metabolism, locomotion and the immune system (adipokinetic hormones); water and ion balance, and feeding behaviour (diuretic hormones, kinins, sulfakinins); sex attraction (pheromone biosynthesis activating neuropeptide); and growth and development, and muscle activity (allatostatins). The literature is reviewed in the context of how the knowledge on neuropeptides has been and can be used for the design of novel, safe and selective compounds to control pest insects in the foreseeable future.

Potencies of naturally-occurring AKH/RPCH peptides in Locusta migratoria in the acetate uptake assay in vitro and comparison with their potencies in the lipid mobilisation assay in vivo

The biological potencies of a number of naturally-occurring octa- and decapeptides of the large AKH/RPCH family of peptides were determined in Locusta migratoria using the lipid-mobilising assay in vivo and the acetate uptake assay in vitro. The most potent of the newly-tested peptides in the in vitro assay, Phl-CC, differs from the endogenous major locust peptide, Lom-AKH-I, only by an exchange of serine versus threonine at position 10. However, the most active peptide in the in vitro assay remains Lom-AKH-III. At the other extreme is the peptide Mem-CC which contains a tyrosine residue at position 4 rather than the more typical phenylalanine. This peptide is over 20,000 times less potent than Lom-AKH-III in the in vitro assay, and also results in an unusual dose-response curve in the in vivo assay. Only a few peptides are approximately equipotent in both assays, but mostly the bioanalogues have a higher potency in vitro. The majority of them are 2- to 10-fold more potent in vitro, but Ani-AKH and Lom-AKH-III are 19- and 48-fold more potent. The results are discussed in relation to either the actions of proteases or of possible preferential binding of different receptors involved in the different assays.

Mathematical modelling of insect neuropeptide potencies. Are quantitatively predictive models possible?

The potencies of natural adipokinetic hormones and synthetic variants have been determined in Locusta migratoria using the lipid mobilisation assay in vivo, and/or the acetate uptake assay in vitro. These data are combinations of previously published and unpublished data (a total of sixty-nine analogues), and form data sets for the construction of mathematical models of the hormone potencies. The sequence variations of amino acids in both natural and artificial adipokinetic hormone analogues were described using continuous descriptor scales z(1)', z(2)', and z(3)', each previously published scale being derived from various properties of the amino acids. By means of these z'-scales and partial least squares regression we attempted to model the potencies in Locusta migratoria of adipokinetic hormones in the two assays. Correlations (r(2) values) between predicted and actual potencies of the different peptides were up to 0.73. We discuss the potential of the partial least squares method for formulating quantitative relationships between different hormone structures and their potencies, and describe how the procedure might be used in structure-activity prediction with the construction of an optimised peptide data set.

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.

Synthesis and biological activity of adipokinetic hormone analogues with modifications in the 4-8 region

Several structural characteristics in the molecule of the locust adipokinetic hormone, AKH-I, have been investigated in terms of their importance in determining biologic activity. All modifications tested in this study resulted in analogues with decreased potency in comparison with the parent molecule. However, all analogues that were found to be active gave a full response, although often only at very high doses of peptide. This study has highlighted for the locust receptor(s) the vital role of the side chain of Thr(5), and the importance of positions 4 and 8. For example, when Trp(8) and Phe(4) were exchanged, the resulting analogue (Trp(4),Phe(8)-AKH-I) was one of the least active analogues tested in this study. Although Trp is tolerated quite well as a substitute for Phe(4), with only a 10-fold loss of potency, Phe is not favored as a substitute for Trp(8) (>300 times decrease in potency). On the other hand, 3-[2-napthyl] alanine (Nal) is a better substitute for Trp(8) (only a 100-fold loss in potency). We conclude that position 4 requires a phenyl ring in the side chain, and position 8 an indole ring.

Chloromethyl ketones are insulin-like stimulators of lipid synthesis in locust fat body

N alpha-tosyl-L-lysine chloromethyl ketone (TLCK) stimulates lipid synthesis in locust fat body in vitro, and is able to reverse the inhibitory effects of AKH-I on lipid synthesis. Effective stimulatory concentrations of TLCK were in the range of 0.2-1.0 mM. Similar stimulatory effects were also achieved with phenylalanine chloromethyl ketone (PheCK) and leucine chloromethyl ketone (LeuCK), but not with tosyl-phenylalanine chloromethyl ketone (TPCK), dansyl-glu-gly-arg-CK, chloroacetone, chloroacetic acid, chloroacetamide, chloroacetaldehyde, chloroacetyl-L-leucine or acetylated or fluorescamine-labelled TLCK, PheCK, and LeuCK. The level of stimulation caused by TLCK was dependent on incubation time, so that after a 5-h preincubation of fat body tissue with TLCK the stimulated rate was severalfold higher than the control. TLCK also increased the rate of uptake of trehalose and uridine, but not glucose, deoxyglucose or glycine. Increasing concentrations of bovine serum albumin (BSA) in the incubation medium caused a reduction in the rate of TLCK-stimulated acetate uptake, such that levels of uptake were no higher with 1% BSA than in the controls. A range of more specific protease and kinase inhibitors was tested, but none caused stimulation; thus the mode of action of TLCK on the stimulation of acetate uptake has yet to be identified. Elucidation of the mode of action of TLCK may facilitate the development of novel compounds for insect pest control.

Structures, assays and receptors for locust adipokinetic hormones

This review is concerned mainly with the adipokinetic hormones (AKHs) of locusts: their molecular conformations, actions and functions and the development of microfiltration assays in vitro. The physiological significance of having multiple hormones with overlapping actions whose efficacy changes during development is discussed in relation to the possibility that these reflect variations in populations of receptors and/or the pharmacokinetics of the peptides. The involvement of second messengers in the transduction mechanism of AKHs is reviewed, and we describe hormone-induced changes of intracellular calcium in single dispersed fat body cells. The structure activity relationships of the three locust AKHs and a number of analogues with variations at the N- and C-termini are discussed. A number of areas are identified where there are gaps in our understanding of these hormones, and some of these will be the focus of our future research.

N-terminal modifications to AKH-I from Locusta migratoria: assessment of biological potencies in vivo and in vitro

To investigate the receptor tolerances to N-terminal variation, novel analogues to Locusta AKH-I (adipokinetic hormone) have been synthesized with modifications at the N-terminus. Analogues were made where the N-terminal pyroglutamyl residue was spaced further from the remainder of the molecule by the insertion of glycine residues between either pGlu1 and Leu2 (Gly1a-AKH-I, or Leu2 and Asn3 (Gly2a-AKH-I and Gly2ab-AKH-I). Other modified hormones with N-terminal extensions were: (Ahx)n-AKH-I (Ahx. aminohexanoic acid); HPP(Ahx)n-AKH-I (HPP. hydroxyphenyl propionate) and Ac(Ahx)n-AKH-I (where n = 0-3). Finally, acetylated and non-acetylated amino acids were substituted for pGlu1: Glu, Pro, Ala and Tyr. The effects of these modifications on biological potency were tested in the lipid mobilization assay in vivo and acetate uptake assay in vitro. The potency of AKH-I was reduced much more by insertion of glycine between pGlu1 and Leu2, than between Leu2 and Asn3, perhaps suggesting that a hydrophobic residue is required adjacent to the pGlu for biological activity. In addition, a residue N-terminal to Leu2 is necessary for activity (i.e., [despGlu]-AKH-I is inactive) unless the free N-terminus is acetylated: Ac[despGlu]-AKH-I is active, but has low potency. The potencies of HPP(Ahx)0-3-AKH-I, Ac(Ahx)1-3-AKH-I and glycine-inserted analogues decreased consistently with increasing extension of the N-terminus away from the remainder of the molecule. However, potencies of the unblocked (Ahx)n-AKH-I analogues did not, and potency in either assay did not appear related to the number of aminohexanoic residues. Similarly, while hormonal activity was retained by substitution of pGlu1 by Tyr, Pro, Ala or Glu in both assays, acetylation of the resulting analogues did not provide a consistent increase in potency, but actually decreased for AcGlu1-AKH-I compared with its unblocked analogue. HPP1-AKH-I was the most potent of the modified peptides tested, with almost the same potency in the assay in vitro as the natural peptide.

Quantification of Locusta diuretic hormone in the central nervous system and corpora cardiaca: influence of age and feeding status, and mechanism of release

Locusta-DH is known to have a hormonal function in the control of post-feeding diuresis in the migratory locust. This study has quantified Locusta-DH in tissues from V(th) instar nymphs and adults, and investigated the K+-induced release of the peptide from corpora cardiaca. Locusta-DH is present in thoracic and abdominal ganglia, but the amounts are small (25-200 fmol) compared with brain (approximately 1 pmol) and corpora cardiaca ( > 5 pmol) from 14-day old locusts. About 50% of the immunoreactive material in corpora cardiaca coelutes with Locusta-DH on reversed-phase HPLC. An earlier eluting fraction is also biologically active, suggesting locusts have a second, previously undetected, CRF-related peptide. The amount of peptide stored in corpora cardiaca varies with age and physiological status. Reductions on day 1 of the adult instar and immediately after feeding suggest Locusta-DH controls post-eclosion as well as post-feeding diureses. Locusta-DH is released by a Ca2+-dependent mechanism from corpora cardiaca held in salines containing > or =40 mM K+. This is blocked by verapamil, implicating L-type Ca2+ channels. Release is most rapid shortly after transfer to a high K+ saline, and more peptide is released from glands allowed to recover in normal saline between successive K+ depolarisations.

Circulating levels of Locusta diuretic hormone: the effects of feeding

A radioimmunoassay was developed using 125I-labeled-[TyrO]Locusta-DH and polyclonal antibodies raised against Locusta-DH (29-46). The assay had a detection limit of 50 pM, and displayed limited cross-reactivity for other CRF-related peptides, but not for unrelated peptides. About 60% of the total immunoreactive material in locust hemolymph was attributable to Locusta-DH. The circulating level of diuretic hormone increases fivefold in fed insects, sufficient to stimulate primary urine production, and is correlated with the duration of the meal. This is consistent with the role of Locusta-DH in the control of postfeeding diuresis.

Locusta-AKH-III and related peptides containing two tryptophan residues have unusual CD spectra

Locusta adipokinetic hormone-III (AKH-III, < QLNFTPWWa) and three analogues have been studied by CD spectroscopy. The AKH peptides examined in which the tryptophan residues are adjacent present a distinctive negative-positive CD signature, in aqueous solution, that increases at low temperatures in ethanediol/water. In the presence of 0.6% SDS, a positive-minus CD is observed. The separation of the two tryptophan residues by an aliphatic amino acid results in a CD, in aqueous solution inverted from negative to positive CD at approximately 225nm. For the peptides with two adjacent tryptophan residues, the bisignate nature of this tryptophan-based CD at lower temperatures or in SDS indicates that the indole/indole orientation can adopt two limiting conformations. There is a correlation between the size of the negative CD at 225 nm and the AKH peptide potency which may indicate a preferred indole/indole orientation by the receptor.

Modified adipokinetic peptides containing two tryptophan residues and their activities in vitro and in vivo in Locusta

Locusta migratoria has three adipokinetic hormones, adipokinetic hormone-I, II and III. Adipokinetic hormone-III (<QLNFTPWWa) is surprisingly potent (EC50 = 1.33 x 10(-10)mol x 1(-1)) compared with other adipokinetic hormones (EC50 > or = 5.33 x 10(-10)mol x 1(-1)) at inhibiting acetate uptake into locust fat body in vitro, especially so when it is only moderately potent in mobilizing lipid in vivo. The Trp7 in adipokinetic hormones-III, alongside the Trp8 characteristic of adipokinetic hormones, is not seen in any other adipokinetic hormones. To test whether this is hormone-III in the assay in vitro, novel peptides were synthesised to include or remove this structural motif. Thus <QLNFTPWWGTa (Trp7-Locusta-adipokinetic hormone-I or [Gly8a-Thr8b]-Locusta-adipokinetic hormone III); <QLNFTPNWa (des[Gly9-Thr10]- Locusta-adipokinetic hormone-I or Asn7-Locusta-adipokinetic hormone III); <QLNF-SAWWa (Trp7-Locusta-adipokinetic hormone-II) and <QVNFSTWWa (Trp7-Acheta-adipokinetic hormones) were tested both in vitro and in vivo. Except for Trp7-adipokinetic hormone-I in the acetate uptake assay, each of these analogues is less potent then its respective parent, irrespective of the assay. However, the acetate uptake response is highly tolerant of peptides containing Trp7-Trp8, whereas this motif markedly reduces potency in the lipid assays. The different responses exploited in these assays may be exerted through different receptor populations.

Synthesis and biological activity of adipokinetic hormone analogues modified at the C-terminus

A series of Locusta adipokinetic hormone I (AKH-I), < QLNFTPNWGTa, analogues, were synthesized with modifications at the C-terminal threonine residue using a combination of solid- and liquid-phase methodology and evaluated in Locusta migratoria, in a lipid mobilization assay in vivo and an acetate uptake assay in vitro. Modifications at Thr10 of AKH-I involved replacement of its C-terminal amide by the groups -OH, -OCH3, -NHCH3, -N(CH3)2, and -NHC6H5; the last three groups were also applied to the amide of AKH-I-[Thr(Bzl)10]. The methyl ester, monomethyl, and dimethyl analogues were all of lower activity than the parent in the lipid mobilization assay, but lost less than two orders of potency. In the acetate uptake assay, again the methyl ester analogue showed the greatest retention of biological activity of all modified peptides. A cyclic analogue, cyclo (PLNFTPNWGT), was active in both assays, but only at very high concentrations. Almost all analogues were more active in the acetate uptake assay than in the lipid assay, but unusually, AKH-I-NHCH, and AKH-I-N(CH3)2, together with cyclo(PLNFTPNWGT), were more active in the lipid mobilization assay. In addition, the acid AKH-I analogue did not suffer as large a loss in potency in the lipid mobilization assay as in the acetate uptake assay, although it was less potent in the former. The relative potencies of these two methyl analogues contrast with those for AKH-I[Thr(Bzl)10]-NHCH3 and AKH-I-[Thr(Bzl)10]-N(CH3)2, which, together with both phenyl analogues, were significantly more active in the acetate uptake assay. We conclude that the acetate uptake assay has a greater preference for a hydrophobic C-terminus, compared with the lipid mobilization assay.

The preparation and use of dispersed cells from fat body of Locusta migratoria in a filtration plate assay for adipokinetic peptides

A method is described for the preparation of metabolically active and hormone-sensitive dispersed cells from fat body of Locusta migratoria and their subsequent use in a filtration plate assay. This assay measures the uptake of radiolabelled acetate into the cells, and the use of dispersed cells reduces the time and labor involved in preparing dose-response curves to different test peptides and increases the precision of the estimate of potency. As a consequence of the reduced variability, fewer replicates per dose are required and, when operated as a plate assay, up to eight dose-response curves can be constructed per plate. The method described here for measuring metabolite uptake into cells and thus determining the potencies of adipokinetic hormones could be applied to the assay of both catabolic (glucagon-like) and anabolic (insulin-like) substances, not only in other insects, but also in mammalian cells. It could be used, therefore, as a suitable screening method for novel active compounds.

Properties of achetakinin binding sites on malpighian tubule membranes from the house cricket, Acheta domesticus

A biologically active 125I-labeled analogue of AK-II (3'-hydroxyphenyl propionic-Gly-Gly-Gly-Phe-Ser-Pro-Trp-Gly-NH2) was used to investigate the properties of achetakinin binding sites on plasma membranes from Malpighian tubules of Acheta domesticus. With optimized conditions, binding was rapid, reversible, and specific, and saturation studies revealed a single class of binding sites with Kd 0.55 nM and Bmax 39.9 fmol/mg membrane protein. The affinities of achetakinins for binding sites on tubule membranes ranked AK-V > AK III > AK-II > AK-I > or = AK-IV, in general agreement with their potencies in functional assays. However, IC50 values were several orders of magnitude higher than corresponding values for EC50, which suggests a considerable receptor reserve.

Isolation, characterization and biological activity of a CRF-related diuretic peptide from Periplaneta americana L

A diuretic peptide (Periplaneta-DP) has been isolated from extracts of whole heads of the cockroach, Periplaneta americana. The purified peptide increases cyclic AMP production and the rate of fluid secretion by isolated Malpighian tubules in vitro. In the fluid secretion assay, the response to native Periplaneta-DP is comparable to that obtained with crude extracts of cockroach corpora cardiaca, and the EC50 lies between 10(-8) and 10(-9) M. The primary structure of Periplaneta-DP was established as a 46-residue amidated peptide: T G S G P S L S I V N P L D V L R Q R L L L E I A R R R M R Q S Q D Q I Q A N R E I L Q T I-NH2. Periplaneta-DP is a further member of the recently established family of CRF-related insect diuretic peptides.

Characterization of a diuretic peptide from Locusta migratoria

A diuretic peptide Locusta-DP, identified by its ability to increase cyclic AMP production in locust Malpighian tubules in vitro, has been isolated and characterized from whole heads of Locusta migratoria. The purified peptide stimulates fluid secretion by Malpighian tubules maximally in vitro. The primary structure of Locusta-DP was established as a 46 residue amidated peptide: MGMGPSLSIVNPMDVLRQRLLLEIARRRLRDAEEQIKANKDFLQQI-NH2. Locusta-DP has 48% sequence identity with Acheta-DP and 49% identity with Manduca-DH, and provides further evidence for the presence of a family of diuretic peptides in insects.

Isolation and characterization of a diuretic peptide from Acheta domesticus. Evidence for a family of insect diuretic peptides

A diuretic peptide (Acheta-DP) has been isolated from extracts of whole heads of the house cricket, Acheta domesticus. The native peptide increases both cyclic AMP production and the rate of fluid secretion by isolated Malpighian tubules in vitro to an extent comparable with those responses obtained with supra-maximal amounts of crude extracts of corpora cardiaca. The primary structure of Acheta-DP was established as a 46-residue amidated peptide: TGAQSLSIVAPLDVLRQRLMNELNRRRMRELQGSRIQQNRQLLTSI-NH2. Acheta-DP has 41% sequence identity with a diuretic peptide isolated from Manduca sexta, providing direct evidence for the presence of a family of diuretic peptides in insects.

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.

Sequence analyses of adipokinetic hormones II from corpora cardiaca of Schistocerca nitans, Schistocerca gregaria, and Locusta migratoria by fast atom bombardment mass spectrometry

Structures of the second adipokinetic hormones (AKH II's) from three locust species have been assigned by fast atom bombardment mass spectrometry. The AKH II hormone is identical in two Schistocerca species, S. nitans and S. gregaria, but is different in Locusta migratoria. Both AKH II's are related to red pigment-concentrating hormone (RPCH) from prawns, Schistocerca AKH II being [Thr6]-RPCH and Locusta AKH II being [Ala6]-RPCH. Schistocerca AKH II is also bioactive in Locusta individuals.

Specificity and localisation of lipoprotein lipase in the flight muscles of Locusta migratoria

Using natural lipoproteins as substrates, lipase activity has been measured in leg muscle, fat body, midgut and flight muscles of Locusta migratoria. The enzymic activity in the flight muscles is higher than in those other tissues tested, confirming the potential of the flight muscles to utilise lipids at high rates. In addition, a membrane-bound lipoprotein lipase can be extracted from flight muscle. The flight muscle enzyme activity shows a marked substrate specificity; at lipoprotein concentrations equivalent to those found normally in flown or resting locusts respectively, the enzyme hydrolyses diacylglycerols associated with lipoprotein A+ (present in the haemolymph of flown or adipokinetic hormone-injected locusts) at about 4 times the rate of those associated with lipoprotein Ayellow (which is the major lipoprotein in resting locusts). In addition, the hydrolysis of lipids carried by lipoprotein Ayellow is dramatically reduced in the presence of lipoprotein A+. These observations indicate that the enzyme plays a specific role in the uptake of lipids at the flight muscles to ensure a smooth transition from carbohydrate to lipid based metabolism during flight.

Single step purification of locust adipokinetic hormones I and II by reversed-phase high-performance liquid chromatography, and amino-acid composition of the hormone II

Locust adipokinetic hormones I (AKH I) and II (AKH II) are separated by reversed-phase high-performance liquid chromatography using a mu-Bondapak phenyl column with a trifluoroacetic acid/acetonitrile gradient. The eluant was monitored at 210 nm and the hyperlipaemic activity was detected using a bioassay. The amino-acid composition of AKH II was determined after acid hydrolysis with HCl or methane-sulfonic acid. It contained the following amino-acid residues in almost equimolar amounts: Asp, Ser, Glu, Gly, Ala, Leu, Phe and Trp.

The effects of removal of the cerebral neurosecretory cells on haemolymph and tissue carbohydrate in Locusta migratoria migratorioides R. & F

In Locusta, removal of the cerebral neurosecretory cells results in a marked accumulation of carbohydrate in both the haemolymph and tissues. It is suggested that this is not due to a lack of carbohydrate-mobilizing factor, but is most likely the result of metabolic changes brought about in the absence of cerebral neurosecretion.