Adipokinetic hormone-induced lipid mobilization and lipophorin interconversions in fifth larval instar locusts

The response of fifth larval instar locusts to injected adipokinetic hormone (AKH) is only poor, as is reflected in both a very moderate elevation of the haemolymph lipid concentration and the slight occurrence of the haemolymph lipophorin interconversions characteristic for adult locusts, resulting in formation of only small quantities of the low density lipophorin (A⁺). However, an additional lipophorin fraction (A′) is induced, which is intermediate in density and size between high and low density lipophorin and which is not identified in adult haemolymph. As in adults, larval A⁺ formation includes association of the resting high density lipophorin with a non-lipid containing protein (C₂), the haemolymph concentration of which is only one-fifth relative to adults. However, the larval haemolymph protein composition is not the primary cause of the incomplete adipokinetic response, as elevation of the concentration of protein C₂ by injection of isolated adult C₂, whether or not in combination with adult high density lipophorin, did not increase lipophorin conversions nor haemolymph lipid elevation.In vitro incubation of larval fat bodies in adult haemolymph showed that competency to both the AKH-induced lipid release and the haemolymph lipophorin conversions of the larval fat body are reduced compared to equal amounts of adult tissue. Reciprocal incubation of adult fat body in larval haemolymph resulted in only a very moderate adipokinetic response, demonstrating that larval haemolymph protein composition is restrictive for full development of hormone action.Both immunoblotting experiments and enzyme-linked immunosorbent assays (ELISA), using monoclonal antibodies specific for the adult lipophorin apoproteins, indicated that the larval lipophorins closely resemble the adult forms. Apparently the structure of locust lipophorins is remarkably constant throughout development despite changes in metabolic functions.     

Dynamics of energy substrates in the haemolymph of Locusta migratoria during flight

In the two-fuel system for flight of the migratory locust, the haemolymph carbohydrate concentration falls during flight periods of up to 1 hr, the decrease being greater in case the pre-flight carbohydrate level is higher. The increase in the lipid concentration from the onset of flight is virtually independent of the initial lipid concentration. Flight intensity affects these changes in substrate concentrations: the carbohydrate level decreases more rapidly if flight speed is higher, whereas the increase in lipid concentration is delayed at higher flight speeds. Respiratory carbon dioxide production is elevated rapidly during flight and reaches over eight times the resting level. From the rate of ¹⁴CO₂ production after labelling of the haemolymph diglyceride pool it is concluded that diglycerides contribute to providing the energy for flight from the earliest stage of flying activity; diglyceride oxidation increases until maximum utilization is attained after some 45 min of flight. The decline in haemolymph carbohydrate concentration due to flying activity results in a decrease of haemolymph osmolarity. Free amino acids, particularly taurine, increase markedly in the haemolymph during flight; yet their concentration only partially counterbalances the fall in haemolymph osmolarity.     

Feeding causes the appearance of a factor in the haemolymph that stimulates protein synthesis

Soon after a locust (Locusta migratoria) begins to feed, an increase in protein synthesis can be detected in the animal. Isolation of fat body shows that this tissue synthesizes protein at a faster rate in recently fed animals than it does in fasting insects. Fasting locusts injected with haemolymph from fed insects increased protein synthesis when compared with locusts injected with haemolymph from fasting locusts. The factor causing this increase was present in the haemolymph within 5 min of feeding. Feeding or direct contact with the food was not essential to increase protein synthesis. Exposure of fasting locusts to feeding insects was sufficient to elevate the rates of protein synthesis in the fasting animals.The increase inprotein synthesis was not a result of general excitation or an increase in the concentration of tryptophan or isoleucine in the haemolymph. Ecdysteroid titres were uniformly low during the first ten days of adult life. Gel filtration of the fed haemolymph revealed a low molecular weight fraction (about 600 daltons) which stimulated protein synthesis upon injection into fasting locusts.     

Factors affecting concentrations of acetoacetate and d-3-hydroxybutyrate in haemolymph and tissues of the adult desert locust

The ketone bodies acetoacetate and d-3-hydroxybutyrate are found in the haemolymph, the fat body, and the flight muscles of the adult desert locust. Acetoacetate is the major ketone body in the haemolymph and the flight muscles, but in the fat body d-3-hydroxybutyrate usually predominates. The concentration of acetoacetate in the haemolymph varies with age, and increases during starvation and flight and also after the injection of corpus cardiacum homogenate; it is little affected by stress and there are no differences between the sexes. Ketone bodies appear to be formed in the fat body and are oxidized by the fat body, the flight muscles, and the testes. All the tissues oxidize acetoacetate much more readily than d-3-hydroxybutyrate, and the flight muscles of fed locusts oxidize acetoacetate much more readily than the fat body or the testes. In starved locusts the ability of the fat body and the flight muscles to oxidize ketone bodies is greatly reduced, but utilization by the testes remains normal. Thus the flight muscles appear to be the major consumers of ketone bodies in fed locusts, and the testes the major consumers in starved locusts. It is suggested that ketone bodies are formed in the fat body during the mobilization of the triglyceride lipid reserves, and are either oxidized by the fat body or transported by the haemolymph to the flight muscles and other tissues to be used as a respiratory fuel.     

The relationships between corpora allata and fat body and haemolymph lipids in the adult female desert locust

Allatectomy of 1-day-old female desert locusts resulted in an accumulation of lipid in the fat body. This accumulation of lipid was due to the continuation of lipid deposition in the fat body after the period of somatic growth. Somatic growth and feeding activity were unaffected by allatectomy, and so could not be indirect causes of fat body lipid accumulation. Lipid accumulation in allatectomized locusts is more likely to be related directly to a lack of juvenile hormone. Implantation of active corpora allata into 1-day-old adult female locusts resulted in a premature development of oöcytes and a decrease in fat body lipid accumulation; somatic growth was not inhibited. Implantation of active corpora allata into old allatectomized locusts resulted in a decrease in the fat body lipid content and the onset of oöcyte development. The lipid synthetic activity of the fat body, measured by the incorporation of ¹⁴C-actate into total fat body lipid, was greatly increased in allatectomized locusts after the period of somatic growth. The protein synthetic activity of the fat body, measured by the incorporation of ³H-leucine into total fat body protein, remained low after the period of somatic growth in allatectomized insects. Juvenile hormone might thus have a dual effect on fat body metabolism, that is suppressing lipid synthesis and stimulating vitellogenic protein synthesis. Increased synthesis of lipid by the fat body would then account for the accumulation of lipid in the fat body after allatectomy. Inhibition of release of lipid from the fat body is unlikely to play a part in the accumulation as allatectomy had no effect on haemolymph lipid concentrations.     

Diacylglycerol-transporting lipoproteins and flight in Locusta

Evidence from chromatographic and heparin precipitation studies shows that the ‘heparin-soluble’ lipoprotein, A⁺, forms in the haemolymph during flight. In locusts flown continuously for 60 min, lipoprotein A⁺ occurs in the haemolymph at low concentrations but accumulates during a short rest period following flight. After injections of tissue extracts containing adipokinetic hormone (AKH), A⁺ accumulates in the haemolymph but disappears more rapidly in flying locusts than in resting locusts. This difference in the rate of disappearance of diacylglycerol from the lipoprotein A⁺ can be used to estimate its rate of utilization during sustained flight (approx. 100μg. min^?1 from 45–90 min of flight). It is suggested that lipoprotein A⁺ is the major carrier of diacylglycerol from the fat body to the flight muscles during prolonged flight. The steady state concentrations of total diacylglycerol and ‘heparin-soluble’ diacylglycerol during continuous flight are unaffected when tissue extracts containing AKH are injected before flight. This suggests that there is a close homeostatic control over the steady state concentration of haemolymph lipid during flight.     

Diglyceride-transporting lipoproteins inLocusta

Summary The majority of haemolymph proteins obtained from resting mature locusts are soluble in 50% saturated (NH₄)₂SO₄ solution. Chromatographically, these proteins may be resolved on Sepharose 6B into three partially included fractions. The leading high molecular weight fraction, A, is predominant and all the diglyceride in resting blood is associated with it. An additional higher molecular weight fraction, A⁺, is present in the haemolymph of locusts injected with extracts of the glandular lobes of the corpora cardiaca (elevated blood), and this fraction carries all the increased diglyceride. Fraction A⁺ is better resolved on Ultrogel ACA 22. A useful rapid technique for studying the formation of A⁺ lipoprotein during lipid mobilization has been developed by the use of lipoproteinpolyanion-metal ion complex formation. A⁺ is soluble after heparin treatment whereas the yellow leading edge of fraction A precipitates. Concomitant with the appearance of A⁺ there is a marked depletion of a lower molecular weight non lipid-carrying protein fraction, C. The ability to form fraction A⁺ after injections of glandular lobe extract cannot be demonstrated in fledglings (immature locusts within 2 or 3 days after the imaginal moult) where fraction C is virtually absent. It is suggested that during lipid mobilization, some lipoprotein from fraction A combines with protein from fraction C to form A⁺. A direct effect of adipokinetic hormone on the process of A⁺ formation cannot be excluded.     

Effects of starvation and dehydration on ionic balance in Schistocerca gregaria

This study describes the effects that prolonged dehydration has on ionic balance in Schistocerca gregaria. When adult locusts are dehydrated for 7 days the body weight reduces by 10–20% and the haemolymph volume by 35–50%, but haemolymph concentrations of Na⁺, K⁺ and Cl⁻ change only slightly. On dehydration Na⁺ and Cl⁻ are removed from the haemolymph; 25% of the removed ions is excreted and 75% is evenly distributed in the body of the locust. The amount of potassium excreted always exceeds that removed from the haemolymph. Mature adults control more effectively than young ones the haemolymph ionic composition during dehydration, but young adults show a smaller reduction in haemolymph volume. In the normal state of hydration, 76% of the total body Na⁺ and 56% of the total body Cl⁻ is present in the haemolymph. These fall to 62 and 42% respectively on dehydration and increase to 77 and 50% on rehydration.     

Juvenile hormone titres and metabolism during starvation-induced supernumerary larval moulting of the tobacco hornworm, Manduca sexta L.

When tobacco hornworm (manduca sexta) larvae are starved for 5 days immediately after ecdysis to the 5th instar, then fed normal diet, they undergo a supernumerary moult instead of metamorphosis. During starvation the titre of juvenile hormone in the haemolymph increased to a maximum of 3 ng juvenile hormone I equivalents/ml (determined by the black Manduca larval bioassay) on the fourth day of starvation, then began a decline which continued through the subsequent feeding period. The changes in juvenile hormone titre were not attributable to changes in haemolymph volume during starvation (only a 5% decrease) and subsequent feeding. During starvation the esterase activity of the haemolymph declined 4-fold with a 2-fold larger decrease in the DFP-insensitive, presumably juvenile hormone specific, esterase activity. Both the total and the juvenile hormone-specific esterase activity then increased as a function of larval weight during the subsequent feeding period. As growth was slow in the prolongedly starved larvae, sufficient juvenile hormone was present at the time of prothoracicotropic hormone (PTTH) and ecdysteroid release at the beginning of the fourth day of feeding to prevent metamorphosis.     

Turnover of protein and diacylglycerol components of lipophorin in insect haemolymph

Lipophorin, radiolabelled in the protein or diacylglycerol moiety, was purified from adult locusts injected previously with [¹⁴C]protein hydrolysate or sodium[1-¹⁴C]palmitate. The radiolabelled lipophorin was injected into adult male locusts and haemolymph samples taken periodically to determine the rate of disappearance of radioactivity from the haemolymph. Lipophorin was also purified from locusts that had been injected four days previously with ([¹⁴C]protein)-lipophorin to demonstrate that the radioactivity observed in the haemolymph at this time is due to radiolabelled lipophorin. The results indicate that the half-life of the protein component of lipophorin in resting insects is about 5–6 days whereas that of the diacylglycerol component is only about 2–3 hr.The results are consistent with the hypothesis that lipophorin functions as a “reusable shuttle” to transport a variety of lipid classes between sites of absorption, storage and utilisation.     

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.     

Côntrole neuroendocrine des protéines sanguines vitellogenes d'Anacridium aegyptium sain et parasite

The changing patterns of haemolymph proteins were followed in male and female adults of normal and parasitized Anacridium aegyptium during diapause (autumn, winter) or during activity (spring) of their endocrine system without or with electrostimulations of the pars intercerebralis (PI).The haemolymph protein concentration is high in winter and decreases in spring. It is comparatively depleted in locusts infected by the fly Metacemyia calloti. However, the depletion is significant only in ‘castrated’ females.Fifteen protein fractions were resolved by polyacrylamide disk gel electrophoresis in haemolymph of normal and infected locusts during diapause and activity. Some fractions decrease in quantity during activity in males, normal females, and parasitized females with complete ovarian development. One fraction disappears in females with mature eggs and seems correlated with formation of the eggshell. Eight others protein fractions exhibit electrophoretic mobility identical to the 7 protein fractions of homogenates of eggs. There is little doubt that these haemolymph protein fractions are involved in yolk synthesis and are thus ‘vitellogenic’. One of these ‘vitellogenic’ fractions (band 6) is larger in yolk than in blood.Five protein fractions were demonstrated by electrophoresis of homogenates of parasites. Their electrophoretic mobilities are similar to those of 5 of the 8 haemolymph ‘vitellogenic’ fractions of the host. There is little doubt that these 5 haemolymph protein fractions (one of them is the band 6) are involved in the nutritional requirements of the parasite.Electrostimulation of the PI, during diapause and activity, increase the haemolymph protein concentration and chiefly the protein concentration of the blood band 6. Thus, the median neurosecretory cells of the brain (M-NSC) regulate protein synthesis and chiefly the synthesis of ‘vitellogenic’ proteins.In parasitized females, the increase of the haemolymph protein concentration after electrostimulations of the PI is associated with an enhancement of ovarian development. The depletion of the haemolymph protein concentration in ‘castrated’ females is thus involved in the inability of the oöcytes to sequester available proteins from the haemolymph. The haemolymph protein deficiency may be attributed to (1) an impairment of protein synthesis, attendant upon the hypoactivity of the M-NSC, and (2) the nutritional requirements of the parasite.     

Neuroendocrine control of blood lipids in the locust, Locusta migratoria

In order to determine the best conditions, the influence of various parameters on the haemolymph lipid concentration were studied. These parameters are the age, the sex and the feeding of the animals, the time and the number of the haemolymph sample-taking and the temperature of the locust culture. A large in vivo increase in haemolymph lipid concentration was obtained in locusts which received extracts of the whole CC and of their glandular or neurohemal lobes. Reversely, a decrease in this concentration was obtained in locusts operated 7 days before (cardiacectomy or glandular lobe removal). Moreover the pars intercerebralis extracts increased the level of haemolymph lipids. We conclude that adipokinetic factors are present, both in the glandular lobes of the CC and in their neurohemal lobes. It is likely that the latter partly originate from the pars intercerebralis. Results of allatectomy and injections of corpora allata extracts led to the conclusion that corpora allata contain an adipokinetic factor, the juvenile hormone. and factors that inhibit the haemolymph lipid concentration. Finally, from different injections of neurotransmitters and drugs it is argued that it is mainly octopamine which is involved in the mechanism governing the increase of the level of haemolymph lipids.     

The metabolism of glycerol in the locust Schistocerca gregaria during flight

The concentration of glycerol in locust haemolymph increases 10-fold during 1 hr flight but decreases rapidly when flight ceases. [¹⁴C]Glycerol is rapidly metabolized by locusts in vivo. Trehalose and diacyl glycerol are the main products to appear in the haemolymph but the proportion of diacyl glycerol is increased in flown insects or when adipokinetic hormone is injected. Trehalose and diacyl glycerol are also the main products formed when isolated fat body is incubated with [¹⁴C]glycerol. Adipokinetic hormone increases the proportion of diacyl glycerol formed.It is proposed that during flight glycerol is produced by hydrolysis of diacyl glycerol in the flight muscles. It is then transported to fat body for esterification with fatty acid produced during conversion of triacyl glycerol stores to diacyl glycerol.     

Haemolymph lipids and fat body lipases of the southern armyworm moth

The haemolymph lipid of the southern armyworm moth, Prodenia eridania, is chiefly diglyceride with smaller amounts of triglyceride, monoglyceride, and free fatty acid also present. The stored lipid of moth fat body is almost all triglyceride. Although flight muscle contains a very active monoglyceride lipase, its ability to hydrolyse tri- and diglycerides is very low. The fat body contains enzymes able to hydrolyse tri-, di-, and monoglycerides. These data do not support the suggestion that fat body triglyceride is converted to diglyceride, which is carried in the haemolymph to the flight muscle and then hydrolysed to free fatty acid for oxidation during flight; rather, they indicate that triglyceride can be completely hydrolysed in the fat body, and the resulting free fatty acid is carried to the flight muscle to provide energy for flight.     

Hormonal control of lipid synthesis in the fat body of the adult female tsetse fly, Glossina morsitans

Aqueous extracts of brain, thoracic ganglion or corpora cardiaca of female Glossina morsitans were shown to contain a substance which inhibited the synthesis of lipid from l[U-¹⁴C] leucine by fat cells incubated in vitro. The highest concentration of this substance was found in the corpora cardiaca; approximately 1 × 10^?6 gland pairs μl^?1 were required for maximum inhibition. At concentrations greater than 1 × 10^?4 gland pairs μl^?1 the lipid synthesis inhibiting factor (hereafter referred to as the LSIF) was inactivated by the presence of a substance which could be removed by gel filtration. The concentration of LSIF in the corpora cardiaca and midbrain varied throughout the reproductive cycle of the female. Net release of LSIF from the midbrain occurred between the 2nd and 7th day of the 9-day reproductive cycle. Net release from the corpora cardiaca began on day 5 and continued until the end of the interlarval period on day 9. Results are consistent with the hypothesis that LSIF is synthesised mainly in the medial neurosecretory cells of the midbrain whereas the corpora cardiaca are the site of storage and release into the haemolymph. LSIF was present in midbrain and corpora cardiaca extracts from male G. morsitans but at lower concentrations than in females. No variation in LSIF concentration could be correlated with the feeding cycle. LSIF activity was not detected in fresh haemolymph but was found at high concentration in boiled haemolymph, suggesting the presence of an inhibitor which was inactivated at high temperature. Preliminary investigations into the nature of LSIF have shown it to be inactivated by proteolytic enzymes and to be recoverable in a single peak from a Sephadex G15 column.Results support the view that LSIF is a peptide hormone which, in conjunction with an inhibitor, controls the lipid synthetic ability of the fat cells of the adult female tsetse fly throughout the reproductive cycle.     

The influence of canavanine and related compounds on the water balance system of locusts

In vivo increase in haemolymph volume of canavanine-treated locusts substantiates our previous in vitro findings that canavanine inhibits fluid secretion by locust Malpighian tubules. Furthermore when diuretic hormone is applied in vivo after canavanine treatment haemolymph volume is drastically reduced below levels retained in locusts untreated with canavanine. Again this is in accord with canavanine potentiation of semi-isolated Malpighian tubules and enhanced fluid secretion in vitro. The response is specific to canavanine; compounds similar in structure (arginine, argininic acid, citrulline, canaline, ornithine and homoserine) have no effect on the rate of fluid secreted by Malpighian tubules. Only partial competition is obtained with uridine homoserine.     

A carrier lipoprotein for juvenile hormone in the haemolymph of Locusta migratoria

In the haemolymph of adult female locusts six different lipoprotein fractions have been demonstrated by means of isoelectric focusing. One of these binds injected ³H-Cecropia juvenile hormone. The carrier protein is a yellow lipoprotein with a molecular weight of approximately 220,000 daltons and an isoelectric point of pH 6·8. The binding of the hormone to the protein is stable during gel filtration over Sephadex G-25 and during dialysis for 24 hr against phosphate buffer pH 7·0.The hormone is quickly metabolized in the locusts. In the haemolymph were found more polar compounds such as 10-epoxy-7-ethyl-3,11 dimethyl-2,6-tridecadienoic acid and the corresponding dioldienoic acid.Both compounds were not bound by the pH 6·8 carrier lipoprotein under in vivo conditions.     

Pharmacokinetics of chlorogenic acid and rutin in larvae of Heliothis zea

Studies using [³H]chlorogenic acid and [³H]rutin demonstrated that the kinetics of uptake of these plant phenolics into the haemolymph of 5th-instar Heliothis zea (Boddie) following actue oral administration is a first-order process. The total quantity of either phenolic present in the haemolymph within 1 hr amounts to 5% or less of the total ingested dose. Based on TLC analyses, 80% or more of the radioactivity in the haemolymph occurs as the parent phenolic. Retention of [³H]-chlorogenic acid or [³H]-rutin in H. zea following chronic feeding from 1st to 3rd-instar larvae is also linearly related to dietary dose. Chlorogenic acid and rutin are both equitoxic and equivalent in bioavailability to H. zea.Loss of [³H]-rutin from the haemolymph of 5th-instar larvae following injection is biphasic. One half of the injected dose is excreted in the frass in the first 6 hr after injection; the other half is thereafter eliminated at 1/20th of the initial rate. Analyses of extracts of frass by thin-layer chromatography indicate that after either chronic or acute feeding 90% of the ingested phenolic is excreted unchanged. Possible sites and modes of action of phenolics in insects are discussed in light of these findings.     

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.