Isolation and characterization of lipophorin from Drosophila melanogaster larvae

The hemolymph lipoprotein lipophorin has been isolated from third-instar Drosophila melanogaster larvae by a technique that involves homogenization of whole larvae in a medium containing protease inhibitors and purification of the lipoprotein by density gradient centrifugation. Drosophila lipophorin has a density of 1.16 g/ml and is composed of 62.5% protein, 23.1% phospholipid, 7.4% diacylglycerol, 5.4% triacylglycerol, 0.9% hydrocarbon, and 0.7% sterol. As is the case with other insect lipophorins, Drosophila lipophorin contains two apolipoproteins, apolipophorin-I (M_r ≈ 275,000) and apolipophorin-II (M_r ≈ 76,000). Drosophila apolipophorin-I does not crossreact with antibodies prepared against apolipophorin-I from Manduca sexta.     

Changes in lipoprotein composition during larval-pupal metamorphosis of an insect, Manduca sexta

During the transition from the last feeding larval stage to the pupal stage of the tobacco hornworm, Manduca sexta, significant changes occur in the properties of lipophorin, the major hemolymph lipoprotein. Within the first 24 h after cessation of feeding, the larval lipophorin (HDLp-L) is first converted to a higher density form (HDLp-W2) and then HDLp-W2 is converted to a lower density form (HDLp-W1). HDLp-W1 remains in the hemolymph until pupation, when another form, HDLp-P, with a density between HDLp-W1 and HDLp-L, is present. Although all the lipophorins contain identical apoproteins, they differ in lipid content and composition; the differences in density being primarily related to diacylglycerol content. The conversion of HDLp-L to HDLp-W1 is accompanied by a loss of hydrocarbon and uptake of carotenes. These latter changes in lipophorin composition reflect alterations in cuticular lipid composition. HDLp-L was radiolabeled in the apoproteins by injecting animals with 3H-amino acids early in the last larval stage. Subsequently HDLp-L was isolated at the end of the larval stage, HDLp-W2 and HDLp-W1 were isolated during the wandering stage, and HDLp-P was isolated after pupation. The specific activity of the apoproteins in the four lipophorins was not significantly different, suggesting that the observed alterations in lipophorin properties do not require synthesis of new apoproteins but result from retailoring the lipid composition of preexisting molecules. Examination of the hemolymph of individual animals during these transitions showed that only one species of lipoprotein was present, never a mixture of two or more species. These observations suggest that the lipoprotein conversions are precisely timed and that lipoprotein metabolism during larval development and pupation cannot be considered a static process. The unique finding of these studies was that synthesis of lipophorin apoproteins proceeds actively during the first part of the fifth instar but then ceases and does not recommence during the wandering or early pupal stages.     

In vivo and in vitro loading of lipid by artificially lipid-depleted lipophorins: evidence for the role of lipophorin as a reusable lipid shuttle.

Lipid transport in the hemolymph of Manduca sexta is facilitated by a high density lipophorin in the resting adult insect (HDLp-A, d approximately 1.109 g/ml) and by a low density lipophorin during flight (LDLp, d approximately 1.060 g/ml). Lipophorin presumably shuttles different lipids between sites of uptake or storage, and sites of utilization. In order to shuttle lipid, a lipid-depleted lipophorin should be able to reload with lipid. To test this hypothesis, we used HDLp-A particles that were artificially depleted of either phospholipid (d approximately 1.118 g/ml) or diacylglycerol (d approximately 1.187 g/ml) and subsequently radiolabeled in their protein moiety. Upon injection into adult moths, both particles shifted their density to that of native HDLp-A, indicating lipid loading. Also, upon subsequent injection of adipokinetic hormone, both particles shifted to a lower density (d approximately 1.060 g/ml) indicating diacylglycerol loading and conversion to LDLp. Both phospholipid and diacylglycerol loading were also studied using an in vitro system. The lipid-depleted particles were incubated with fat body that had been radiolabeled in either the phospholipid or the triacylglycerol fraction. Transfer of radiolabeled phospholipid and diacylglycerol from fat body to lipophorin was observed. During diacylglycerol loading, apoLp-III associated with lipophorin, whereas phospholipid loading occurred in the absence of apoLp-III. The results show the ability of lipid-depleted lipophorins to reload with lipid and therefore reaffirm the role of lipophorin as a reusable lipid shuttle.     

An insect lipid transfer particle promotes lipid loading from fat body to lipoprotein

The role of Manduca sexta lipid transfer particle (LTP) in the transport of lipid from fat body to lipophorin was investigated in vitro. Fat body that contained radiolabeled lipid was incubated with either high density lipophorin or low density lipophorin, and it was shown that lipid was transferred from fat body to lipophorins. The transfer of diacylglycerol was blocked by preincubating fat body with LTP antibody. Furthermore, transfer was restored by the addition of LTP, indicating that LTP promotes the transfer of lipid from fat body to lipophorins. Using lipophorins radio-labeled in their lipid moiety, transfer of lipid from lipophorin to fat body was demonstrated. This transfer was not mediated by LTP. The adipokinetic hormone induced diacylglycerol mobilization from the fat body and the concomitant interconversion of high density lipophorin to low density lipophorin were performed in vitro and were shown to require the presence of LTP.     

Lipophorin in the larval and adult stages of Musca domestica

The major Musca domestica hemolymph lipoprotein, lipophorin, was purified from larval and from adult animals. The housefly lipophorin is composed of two apoproteins, apolipophorin I (M_r ∽ 253,000) and apolipophorin II (M_r ∽ 85,000). The lipophorin contains about 3.9% carbohydrates and reacts positively with concanavalin A. The density of larval lipophorin is equal to 1.152 g/ml and of adult lipophorin to 1.106 g/ml. The amount of lipophorin per animal increases during the larval stage, is constant during pupal stage, and suffers a great reduction at the pharate adult stage. The amount of lipophorin remains stable during the whole first gonotrophic cycle of the housefly. Lipophorin is not detected in the eggs of this insect.     

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.     

Lipoprotein interconversions in an insect, Manduca sexta. Evidence for a lipid transfer factor in the hemolymph

Hemolymph lipoproteins (lipophorins) of adult Manduca sexta are disinct from larval forms in density, lipid content, composition, and the presence of a third, low molecular weight apoprotein. Generally, only one lipoprotein species exists in M. sexta hemolymph during any given life stage. Progression through the life cycle results in alterations of existing lipoproteins to produce new forms, without new protein synthesis. The observed alterations in lipoprotein density could result from facilitated lipid transfer in insect hemolymph. An in vitro assay of facilitated lipid transfer was developed which employs a high density lipophorin from the wandering larva (density = 1.18 g/ml) as acceptor and adult low density lipophorin (density = 1.03 g/ml) as donor. Adult lipophorin-deficient hemolymph was shown to catalyze a time-dependent equilibration of the starting lipoproteins to produce a new intermediate lipophorin, Lp-I. Hydrodynamic experiments on the donor, acceptor, and product lipoproteins excluded fusion as the mechanism whereby Lp-I is produced. Thus, it is concluded that Lp-I results from facilitated net lipid transfer from low to high density lipoprotein. Furthermore, experiments conducted with radioiodinated donor and radioiodinated acceptor lipoproteins demonstrated that apoprotein exchange does not occur during the lipid transfer reaction. When donor lipoprotein was labeled in the lipid moiety with carbon-14, evidence of diacylglycerol and phospholipid exchange was obtained. Partial characterization of the lipid transfer factor revealed a relationship between incubation time, donor concentration, acceptor concentration, lipophorin-deficient hemolymph concentration, and transfer activity, as measured by Lp-I production. It is concluded that lipophorin-deficient hemolymph contains one or more factor(s) that catalyze net lipid transfer as well as diacylglycerol and phospholipid exchange between lipophorins to produce a single form at equilibrium.     

Lipophorin conversions during flight of the death's-head hawkmoth Acherontia atropos

Flight activity or injection of the death's-head hawkmoth Acherontia atropos with locust synthetic adipokinetic hormone (AKH I) results in a dramatic increase in the concentration of hemolymph diacylglycerol which is carried by specific lipophorins. In resting hawkmoths diacylglycerols are associated with a high-density lipophorin (HDLp, density ∼1.13 g/ml) consisting of two major apolipophorins (apoLp-I and -II, mol. wt ∼240,000 and 70,000, respectively). During flight or after AKH injection the formation of a new low-density lipophorin is induced (LDLp, density ∼1.03 g/ml), exhibiting a much higher lipid loading and consisting of HDLp subunits and an additional subunit (apoLp-III, mol. wt approx. 20,000). This subunit is a regular constitutent of hemolymph proteins in resting hawkmoths and consists of two protein components with slightly different molecular weights. The component with the lowest molecular weight seems to be preferentially incorporated into the newly generated LDLp. In the resting situation the HDLp already contains some apoLp-III.In spite of some minor differences, the overall mechanism of lipophorin rearrangements upon flight activity in the hawkmoth appears to be very similar to the known systems established for both Locusta migratoria and Manduca sexta.     

Locust adipokinetic hormone stimulates lipid mobilization in Manduca sexta

Adipokinetic hormone, a decapeptide isolated from the locust, stimulates mobilization of diacylglycerols from the locust fat body and loading of the lipid transport protein, lipophorin. Injection of the synthetic locust adipokinetic hormone into a sphinx moth, Manduca sexta, causes lipid loading of lipophorin. The lipophorin decreases in density from 1.11 to 1.06 g/ml, and a soluble protein from the hemolymph (apolipophorin III) associates with the lipophorin particle. Administration of intermediate doses of hormone indicates that lipophorin is converted directly to the low density form; no appreciable amounts of intermediate density particles are formed.     

Lipophorin density variation during oogenesis in Rhodnius prolixus

The density of lipophorin was determined in adult females of Rhodnius prolixus on different days after a meal. Several populations of lipophorins, differing in density but always in the range of HDL, were found in the hemolymph. The density of the major population was analyzed and a complex profile of density variation was found associated with the principal metabolic events in these insects digestion and oogenesis. During the initial three days after the blood meal, with the onset of the digestive process, the density of lipophorin decreased from 1.1185 g/l to 1.1095 g/l, associated with the transfer of lipids from midgut to the lipophorin particles. During the period of intense vitellogenesis and lipid uptake by the ovary, the lipophorin density started to increase and reached the value, 1.1322 g/l, and remained stable up to the end of oogenesis. As soon as the requirement of lipids to build up the oocytes ceased, the density of lipophorin decreased to its initial value associated with the transfer of lipids from fat body to lipophorin. Soon after the blood meal the midgut was the main source of lipids capable of replenishing the lipophorin particles, while the fat body assumed this function during the succeeding days and reached its maximum capacity around day 10, as estimated by the rate of lipid transfer. The principal lipids transferred were phospholipids and diacylglycerols. Except in the protein/lipid ratio no major changes were observed among different lipids isolated from lipophoin of different densities. Arch. Insect Biochem. Physiol. 35:301-313, 1997.© 1997 Wiley-Liss, Inc.     

Wax moth,Galleria mellonella fat body receptor for high-density lipophorin (HDLp)

To identify and characterize the HDLp (high-density lipophorin) receptor from Galleria mellonella (LpRGm), we used techniques of ligand blotting. This method was, to our knowledge, first used to characterize the lipophorin receptor (LpR) in insects. LpRGm had an approximate molecular weight of 97 kDa under non-reducing conditions and bound the HDLp specifically. The time-course of lipophorin binding to their receptor protein was rapid. The binding of lipophorins to their receptors was saturable with a Kd of 34.33+/-4.67 microg/ml. Although Ca2+ was essentially required in the binding of HDLp to their receptors, interestingly increasing concentration of Ca2+ has shown to have a slight inhibitory effect. EDTA was used here as Ca2+ chelating reagent, because Mg2+ in the binding buffer did not affect the binding of HDLp to their receptors, and inhibited the binding of HDLp and LpRGm absolutely. Suramin (polysulfated polycyclic hydrocarbon), known to inhibit the binding of lipoproteins to their receptors, effectively abolished the binding of HDLp to their receptors. LpRGm showed the stage specific binding activity especially in day 1-3 last instar larval, prepupal, and day 1-3 adult stages.     

Adipokinetic response of a flightless grasshopper (Barytettix psolus): Functional components,defective response

The mature flightless grasshopper Barytettix psolus shows a very small adipokinetic response when injected with extracts of its own corpora cardiaca, although the fat body contains enough lipid for a strong response. When these extracts were injected into Melanoplus differentialis, a grasshopper capable of flight, or the moth Manduca sexta, much stronger adipokinetic responses were observed. Upon analysis of B. psolus extracts by HPLC, two components with adipokinetic activity were obtained. The major component appears to be identical to locust adipokinetic hormone (AKH) I. Extracts of B. psolus corpora cardiaca also activated fat body glycogen phosphorylase in B. psolus. This activation, however, did not result in an increase in hemolymph sugar, probably because of low levels of glycogen in the fat body. B. psolus hemolymph contains a high-density lipophorin (HDLp) consisting of the apolipophorins (apoLp) I and II and lipid. Both apoproteins are glycosylated. The hemolymph also contains apoLp-III, although this apoprotein apparently does not associate with HDLp to form a low-density lipophorin (LDLp) following AKH or corpora cardiaca extract injections. When B. psolus lipophorin and AKH were injected into Schistocerca americana, lipophorin took up lipids and combined with apoLp-III, forming LDLp. ApoLp-III from B. psolus injected into S. americana can also form LDLp, demonstrating that the components are functional. A lipid transfer particle isolated from M. sexta and injected into B. psolus does not improve the adipokinetic response. Thus, it appears that the adipokinetic response of B. psolus is not deficient because of the lack of AKH or functional lipophorins, but may be caused by the lack of a full response to AKH by fat body or the deficiency in hemolymph of some as yet unknown factor.     

A lipid transfer particle in Musca domestica haemolymph

• 1.1. In Musca domestica haemolymph a lipid transfer particle (LTP) is present.
• 2.2. Musca domestica LTP is able to catalyze the transfer of lipids between different housefly lipophorin forms and also between lipophorins of Diptera and Lepidoptera.
• 3.3. The lipophorin of larval Dione juno (Lepidoptera) was purified and is composed of two apolipoproteins, apolipophorin I (M_{r = 209,000}) and apolipophorin II (M_{r = 85,000}) with a density of 1.124 g/ml.
• 4.4. The density of housefly lipophorin undergoes variations during the gonotrophic cycle.
• 5.5. The lipophorin density variation results suggest that when a high rate of lipid utilization occurs, the lipophorin has a higher density value.

     

Isolation and fluorescence studies on a lipophorin from the weevil diaprepes abbreviatus

Lipophorin was isolated from larvae of a root weevil, Diaprepes abbreviatus (Coleoptera: Curculionidae), using density gradient ultracentrifugation. D. abbreviatus lipophorin contained two apoproteins, apolipophorin-I (M_r = 226,000) and apolipophorin-II (M_r = 72,100) and had a density of 1.08. Relative to other larval lipophorins, D. abbreviatus lipophorin contained little cysteine (determined as cysteic acid) and methionine. Fluorescence spectroscopy of intrinsic tyrosine and tryptophan residues excited at 290 nm revealed a single broad emission peak at 330 nm. Upon denaturing and delipidating lipophorin in guanidine HCl, this peak resolved into two peaks with maxima at 305 and 350 nm. Excitation spectra suggested that the two peaks were due to tyrosine and tryptophan, respectively. Fluorescence quenching agents, iodide and acrylamide, were used to determine accessibility of tyrosine and tryptophan residues to the aqueous environment. Iodide, a polar quenching agent, did not quench fluorescent emission from native lipophorin; quenching by iodide increased to moderate levels when lipophorin was denatured in guanidine HCl. Acrylamide quenched the fluorescence of native lipophorin moderately and very efficiently quenched fluorescence of denatured lipophorin. No difference was observed between fluorescence quenching of denatured vs. denatured and delipidated lipophorin by either iodide or acrylamide.     

In vitro release of lipophorin from the fat body of nondiapause and diapause larvae of the Southwestern corn borer,Diatraea grandiosella

The release of lipophorin and total protein was examined from the fat body of nondiapause and diapause larvae of the southwestern corn borer, Diatraea grandiosella, incubated in vitro in Grace's medium. The characteristics of the released lipophorin were compared to those of the high-density lipophorin present in the hemolymph of nondiapause and diapause larvae. Over a 4 h incubation period, the fat body of nondiapause larvae released about 1.5 times more total protein and 2 times more lipophorin per mg dry weight than did that of diapause larvae. Lipophorin isolated from the medium in which fat bodies of nondiapause and diapause larvae had been incubated and from the plasma of nondiapause and diapause larvae had similar mean densities of 1.115, 1.112, 1.117 and 1.119 g/ml, respectively. Although the lipid classes detected in lipophorin isolated from the fat body incubation medium and hemolymph were identical, more polar lipids and less diacylglycerol were associated with lipophorin isolated from fat body incubation medium then were associated with lipophorin isolated from the hemolymph. Sterols accounted for about 11% of the total lipids of lipophorin isolated from the fat body incubation medium, whereas they accounted for about 20% of the total lipids of lipophorin from hemolymph. We conclude that the fat body of feeding nondiapause larvae and nonfeeding diapause larvae releases high-density lipophorin.     

alpha-cyclodextrin extracts diacylglycerol from insect high density lipoproteins

alpha-Cyclodextrins are water-soluble cyclic hexamers of glucose units with hydrophobic cavities capable of solubilizing lipophiles. Incubating alpha-cyclodextrin with high density lipophorin from Manduca sexta or Bombyx mori resulted in a cloudy, turbid solution. Centrifugation separated a pale yellowish precipitate. Thin-layer chromatography analysis of the lipid extract of the precipitate showed that the major lipid was diacylglycerol, while KBr density gradient analysis of the supernatant demonstrated the presence of a lipid-depleted very high density lipophorin. Transfer of diacylglycerol from lipophorin to cyclodextrin was specific to alpha-cyclodextrin and was not observed with beta- or gamma-cyclodextrins. pH had no effect on diacylglycerol transfer to alpha-cyclodextrin. However, the transfer was strongly dependent on the concentration of alpha-cyclodextrin and temperature. Increasing the concentration of alpha-cyclodextrin in the incubation mixture was associated with the formation of increasingly higher density lipophorins. Thus, at 20, 30, and 40 mm alpha-cyclodextrin, the density of B. mori lipophorin increased from 1.107 g/ml to 1.123, 1. 148, and 1.181 g/ml, respectively. At concentrations greater than 40 mm, alpha-cyclodextrin had no further effect on the density of lipophorin. alpha-Cyclodextrin removed at most 83;-87% of the diacylglycerol present in lipophorin. Temperature played an important role in altering the amount of diacylglycerols transferred to alpha-cyclodextrin. At 30 mm alpha-cyclodextrin, the amount of diacylglycerol transferred at different temperatures was 50% at 4 degrees C, 41% at 15 degrees C, 20% at 28 degrees C, and less than 3% at 37 degrees C. We propose that diacylglycerol transfers to alpha-cyclodextrin via an aqueous diffusion pathway and that the driving force for the transfer is the formation of an insoluble alpha-cyclodextrin-diacylglycerol complex.     

Environmental control of larval behaviour and its consequences for ecdysteroid content and pupation in Ephestia kuehniella

ABSTRACT. The behaviour of postfeeding larvae of Ephestia kuehniella Zell. (Lepidoptera, Pyralidae) depends on environmental conditions. Long day and high larval density (LG) stimulate larvae to spin the outer envelope of the pupal cocoon which, in turn, accelerates pupal ecdysis. Constant darkness and isolation in a limited space (DS) inhibit spinning of the outer envelope, and cause extension of the wandering stage and a delay in pupation. This behaviour was also observed in larvae confined in the diet.
In postfeeding LG larvae, an increase in ecdysteroid content coincides with spinning of the outer envelope. In DS larvae, which fail to spin the outer envelope, the ecdysteroid content remains low during the wandering stage, and rises to a prepupal peak after a considerable delay. Wandering larvae inserted into empty outer envelopes showed a premature rise of ecdysteroids, and it is thus concluded that sensory stimulation from the outer envelope is a cue promoting further development.     

Lipophorin lipase from the yolk of Manduca sexta eggs: identification and partial characterization.

In the hawkmoth Manduca sexta high density lipophorin from adult insects (HDLp-A) delivers lipids to developing oocytes. During this lipid delivery HDLp-A is taken up by the oocyte and converted to a very high density lipophorin (VHDLp), which is stored in protein storage granules (yolk bodies). A membrane-free lysate of isolated M. sexta yolk bodies was demonstrated to contain lipoprotein lipase activity that hydrolyses the diacylglycerol of HDLp-A. With HDLp-A as a substrate yolk body lipophorin lipase (YBLpL) activity was shown to be maximal between pH 9 and pH 9.5. NaCl concentration was optimal between 0.7 M and 1 M. YBLpL activity required neither bovine serum albumin nor calcium ions but appeared to be stimulated by 5 mM EDTA. Diisopropyl fluorophosphate effectively inhibited YBLpL activity, indicating the presence of a serine in the active site of the enzyme. The identified lipase activity co-eluted with lipophorins and vitellins from the yolk in the void volume of a Sephadex G-75 gel filtration column. This observation suggests that the lipase has a Mr of more than 80,000, or that the enzyme is associated with the lipoproteins. Incubation of HDLp-A with yolk body lysate converted HDLp-A to two classes of higher density lipophorins. The highest density lipophorins produced during this incubation approached the density of VHDLp as it is isolated from mature eggs. The possible role of YBLpL activity in the delivery of lipids to developing oocytes is discussed.     

A strategy for solubilizing delipidated apolipoprotein with lysophosphatidylcholine and reconstitution with phosphatidylcholine

The apolipoproteins of insect lipophorin were dissociated in guanidinium chloride and isolated by gel permeation chromatography. Over 98% of the total lipid in lipophorin was associated with apolipophorin I (apoLp-I), thus suggesting this apolipoprotein to be the lipid binding component of the particle. ApoLp-I was delipidated with ethanol/ether and solubilized in buffer that contained radioactive lysophosphatidylcholine ([3H]LPC) above the critical micellar concentration. Sonic irradiation of radioactive phosphatidylcholine ([14C]PC) with [3H]LPC-solubilized apoLp-I at a molar ratio of 318 resulted in reconstituted lipophorin (RLp-I). [3H]LPC was bound to fatty acid free bovine serum albumin and was separated from RLp-I by density gradient ultracentrifugation and gel permeation chromatography. Negatively stained RLp-I particles were quasispherical with an average radium of 55 A, and their overall morphology and secondary structure were similar to those of native hemolymph lipophorin. The RLp-I particle had a rho = 1.137 g/mL, a Mr approximately 5.2 X 10(5), and a [14C]PC:apoLp-I molar ratio of 308. From the compositional analysis, molecular size, trypsinization, and lipolysis with phospholipase A2, we concluded that each RLp-I particle contained one molecule of apoLp-I and a monomolecular layer of [14C]PC. When injected into the hemolymph of adult moths in vivo, RLp-I was loaded with lipid, as judged by a decrease in its density both in the presence and in the absence of adipokinetic hormone. The similarities in morphology and immunology of RLp-I and native lipophorin, together with the ability of RLp-I to load lipid, suggest that reconstituted lipophorins may serve as models to probe lipophorin structure and function.     

Sexual dimorphism and the impact of temperature on the pupal and adult stages of Sepedon spinipes spinipes, a potential biological control agent of fascioliasis

The malacophagous feeding behaviour of larvae of members of the family Sciomyzidae makes the group ideal for the selection of potential biological control agents of snail hosts of trematode diseases. The aim of this study was to investigate the effects of temperature (14 °C, 17 °C, 20 °C, 23 °C, and 26 °C) on the pupal and adult stages of Sepedon spinipes spinipes (Scopoli) (Diptera: Sciomyzidae). Larval prey density effects on the pupal stage and the extent of sexual dimorphism within the species are also assessed. Optimum growth conditions for the pupal stage and pre‐oviposition/oviposition periods, and female fecundity are identified for mass culturing purposes. The tendency of mature third instar larvae to engage in wandering behaviour is highlighted, and the biological control implications of such behaviour are discussed. Female puparia were significantly (P<0.001) heavier than males for both larval prey densities. Such sexual dimorphism would enable the prediction of adult sex from puparial weight prior to eclosion, thereby facilitating culture establishment. The effect of three food types [honey/yeast mixture only, crushed Radix balthica (L.) (Gastropoda: Pulmonata: Lymnaeidae) only, and honey/yeast mixture plus a crushed snail] on adult longevity (laboratory conditions) was also determined and the results suggest that adults live longest when provided with a crushed snail and a honey/yeast mixture.