Purification and characterization of a lipid transfer particle in Rhodnius prolixus: phospholipid transfer.

In this study we report the purification and characterization of a lipid transfer particle (LTP) from Rhodnius prolixus hemolymph, and its participation in phospholipid and diacylglycerol transfer processes. (3)H-diacylglycerol labeled low density lipophorin from Manduca sexta ((3)H-LDLp) was incubated with R. prolixus lipophorin (Lp) in the presence of Rhodnius hemolymph. Following incubation and isolation, both lipoproteins showed equivalent amounts of (3)H-labeled lipids. Hemolymph was subjected to KBr gradient ultracentrifugation. SDS-PAGE analysis of gradient fractions showed the enrichment of bands with molecular masses similar to the M. sexta LTP standard. LTP containing fractions were assayed and lipid transfer activity was observed. Purification of LTP was accomplished by (i) KBr density gradient ultracentrifugation, (ii) size exclusion, (iii) Cu(++) affinity and (iv) ion exchange chromatographies. LTP molecular mass was estimated approximately 770 kDa, comprising three apoproteins, apoLTP-I (315 kDa), apoLTP-II (85 kDa) and apoLTP-III (58 kDa). Phospolipid content of (32)P-LTP was determined after two-dimensional TLC. (32)P-phospholipid-labeled and unlabeled lipophorins, purified from R. prolixus were incubated in the presence of LTP resulting in the time-dependent transfer of phospholipids. LTP-mediated phospholipid transfer was not a selective process.

Biosynthesis of Aedes aegypti lipophorin and gene expression of its apolipoproteins.

The biosynthesis of lipophorin of the yellow fever mosquito, Aedes aegypti, was investigated. Fat bodies were incubated in vitro with radiolabeled methionine and cysteine, and radiolabeled proteins secreted into the medium were analyzed by density gradient ultracentrifugation, SDS-PAGE and fluorography. Lipophorin was synthesized in the fat body and secreted into the medium. Its density was 1.114 g/ml, similar to that of lipophorin circulating in hemolymph. Three peptides of a tryptic digest of apolipophorin II were sequenced and degenerate oligonucleotide primers were designed based on the amino acid sequences. With these primers, a cDNA product of 1.2 kb was amplified by RT-PCR using as template RNA extracted from adult female mosquitoes 24 h after ingestion of a blood meal. This cDNA was cloned, sequenced and used as a probe for Northern blot analysis, which revealed that the apoproteins of lipophorin were coded for by a single mRNA of approximately 10 kb. The expression of the apolipophorins was induced by blood feeding. From the data presented we concluded that Aedes aegypti lipophorin is synthesized in the fat body and that the expression of its apolipophorins is induced by blood feeding.

Lipophorin levels in the yellow fever mosquito, Aedes aegypti, and the effect of feeding.

High density lipophorin (HDLp) is the major lipid transport vehicle in insect hemolymph. Using an indirect ELISA, levels of HDLp were measured in the yellow fever mosquito, Aedes aegypti. The level of lipophorin, when normalized to the total weight of the insect, was similar in the different developmental stages. Starvation (access to water only) of adult females did not affect the level of HDLp nor its density when compared to sugar-fed females. On the other hand, blood feeding (of normally sugar-fed females) resulted in a three-fold increase of the HDLp level at 40 h after feeding. This increase was accompanied by a slight but significant increase in the density of HDLp at 24 h after feeding. Ingestion of a lipid-free protein meal or a lipid-supplemented protein meal induced changes in HDLp level and density that were comparable to those induced by ingestion of a blood meal. Ingestion of a blood meal, following starvation (access to water only) from the moment of adult emergence, did not induce an increase in HDLp level. The results presented indicate that, in contrast to other insect species, A. aegypti responds to an increased need for lipid transport in the hemolymph by increasing the amount of HDLp. Arch. Insect Biochem.

Lipid transfer from insect fat body to lipophorin: comparison between a mosquito triacylglycerol-rich lipophorin and a sphinx moth diacylglycerol-rich lipophorin.

Two insect lipoproteins, triacylglycerol-rich Aedes aegypti lipophorin and diacylglycerol-rich Manduca sexta lipophorin, were compared in their ability to load neutral lipid from fat body. When fat body of M. sexta was incubated in vitro with [3H]oleic acid, all radiolabeled fatty acids were esterified, predominantly to triacylglycerol. In A. aegypti fat body, however, half of the label remained as free fatty acids. When A. aegypti fat body was radiolabeled with [3H]glycerol, most of the radiolabel was incorporated in triacylglycerol. When either A. aegypti or M. sexta lipophorin was incubated with A. aegypti fat body, labeled with [3H]oleic acid, both lipophorins incorporated mainly radiolabeled free fatty acids, while almost no radiolabeled glycerides were transferred. When the same experiment was performed with A. aegypti fat body, radiolabeled with [3H]glycerol, very little transfer of radiolabeled glycerides was detected. In contrast, when either M. sexta or A. aegypti lipophorin was incubated with M. sexta fat body, both lipophorins incorporated neutral lipids, predominantly diacyglycerol. A. aegypti lipophorin incorporated half the amount of radiolabeled lipid, compared to M. sexta lipophorin. Lipophorins from both species were treated with triacylglycerol lipase of the yeast Candida cylindracea. Although this lipase readily delipidated M. sexta HDLp, it was not able to remove triacylglycerol from A. aegypti HDLp. The data presented suggest that, under the conditions used, lipid transfer from fat body to lipophorin in A. aegypti is not as efficient as in M. sexta.

Manduca sexta lipid transfer particle: synthesis by fat body and occurrence in hemolymph.

Lipid transfer particle (LTP) is present in hemolymph of the tobacco hornworm Manduca sexta. Biosynthesis of LTP, occurrence in hemolymph, and the role of LTP-apoproteins in the lipid transfer reaction were investigated using antibodies specific for LTP or for each of the apoproteins. In vitro protein synthesis followed by immunoprecipitation demonstrated that LTP is synthesized by the fat body and secreted into the medium. In contrast to apolipophorin III, an exchangeable apoprotein of lipophorin (the major lipid transport protein in hemolymph), apoLTP-III could not be detected free in hemolymph. LTP concentrations in the hemolymph were measured by a sandwich ELISA using a mouse monoclonal antibody against apoLTP-III as capturing antibody and rabbit polyclonal antibody against apoLTP-I as detecting antibody. LTP concentration increased during the late fifth instar larval stage, followed by a decrease in the wandering stage. Subsequently, LTP concentrations were strongly increased in hemolymph of adult moths. The role of the three apoproteins of LTP in the lipid transfer reaction was analyzed using apoprotein-specific antibodies. All three, apoLTP-I, -II, and -III, appeared to be important for lipid transfer activity, as shown by inhibition of lipid transfer by antibodies specific for each of the three apoproteins.

Identification of the major lipoproteins in crayfish hemolymph as proteins involved in immune recognition and clotting.

Lipid-containing hemolymph proteins from males of the crayfish Pacifastacus leniusculus were isolated by density gradient ultracentrifugation. Two major lipoproteins, one high density lipoprotein (HDL) and one very high density lipoprotein (VHDL), were characterized. The HDL and the VHDL were found to be identical to two proteins previously studied for their roles in immune recognition and hemolymph clotting, namely the beta-1,3-glucan binding protein and the clotting protein. These results imply that crayfish lipoproteins have dual functions, and that they are involved in immunity, hemolymph clotting, and lipid transport in these animals. Also, the oxygen-transporting protein hemocyanin was found to have a small lipid content.

Triglyceride-rich lipophorin in Aedes aegypti (Diptera: Culicidae).

A lipoprotein was isolated from Aedes aegypti (L.) larvae. This lipoprotein resembled the typical lipoprotein responsible for lipid transport in insect hemolymph, also called lipophorin. The mosquito lipophorin had a hydrated density of 1.113 g/ml and contained 49% lipid and 3.2% carbohydrate. In contrast to all other insect species studied thus far, the major lipid component of the mosquito lipophorin was triacylglycerol. The native lipophorin had an apparent molecular weight of 480 kd and contained two subunits, apolipophorin I (238 kd) and apolipophorin II (73 kd), that were both glycosylated. The lipoproteins from two other mosquito species, Anopheles albimanus (Wiedemann) and Culex quinquefasciatus (Say), also were shown to be high-density lipophorins that contained triacylglycerol, as major neutral lipid.

Characterization and identification of a lipoprotein lipase from Manduca sexta flight muscle.

Lipoprotein lipase (LpL) activity in Manduca sexta flight muscle tissue was measured using in vivo radiolabeled lipophorin as a substrate. LpL hydrolyses diacylglycerol in the low density lipophorin (that occurs during flight) at a higher rate than diacylglycerol in the high density lipophorin (present in the resting insect). LpL has a pH-optimum of 7.5 and is less sensitive to NaCl than mammalian LpL. LpL is inhibited by bovine albumin and chicken ovalbumin. LpL is inhibited by the serine protease inhibitors diisopropylfluorophosphate (DFP) and phenylmethanesulfonyl fluoride (PMSF), which indicates the presence of an active site serine similar to mammalian LpL. Flight muscle LpL shows affinity for immobilized copper as well as for immobilized heparin. Using radiolabeled DFP, a protein of 37 kDa was identified (after SDS-PAGE) as the DFP-binding protein in a partially purified preparation of LpL. This 37 kDa protein is proposed to be the LpL or a subunit thereof.

Lipophorin structure analyzed by in vitro treatment with lipases.

Adult Manduca sexta high density lipophorin (HDLp-A) is composed of three apolipoproteins (apoLp-I, -II, and -III) and 52% lipid. The flight-specific low density lipophorin (LDLp) contains 62% lipid and is associated with several additional molecules of apoLp-III. The amount of phospholipid remains constant in lipophorin (140 mol/mol of lipophorin), while the diacylglycerol content varies between different lipophorin species (310 mol/mol HDLp up to 1160 mol/mol LDLp). Both lipophorin particles were enzymatically depleted of phospholipid or diacylglycerol by in vitro incubation with either phospholipase A2 or triacylglycerol lipase. Albumin was used to remove free fatty acids generated during the reaction. Treatment with phospholipase A2 removed all phospholipids (except sphingomyelin) and the resulting particles were stable. Triacylglycerol lipase hydrolyzed large fractions of diacylglycerol. The resulting particles were smaller in size, higher in density, and devoid of apoLp-III. The particles retained apoLp-I and -II and the other lipid components, including a substantial amount of diacylglycerol. Structural integrity of diacylglycerol-depleted lipophorin was confirmed by electron microscopical analysis. When treated with both phospholipase A2 and triacylglycerol lipase, lipophorin precipitated. From these results we conclude that: 1) all phospholipid and apoLp-III are located at the surface of lipophorin, whereas diacylglycerol is partitioned between the sublayers and the surface of the particle; 2) both diacylglycerol and phospholipid play a role in stabilizing lipophorin in the aqueous medium; and 3) lipophorin can be extensively unloaded and still retain its basic structure, a necessary feature for its function as a reusable lipid shuttle.

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.

Purification of insect vitellogenin and vitellin by gel-immobilized ferric chelate.

Vitellogenin and vitellin of Manduca sexta and some other insect species were purified by immobilized metal ion affinity chromatography. Ferric ion was chosen as the immobilized metal ion. Agarose-bound carboxymethylpicolylamine was used as the chelating adsorbent for the ferric ion. Vitellogenin and vitellin, both phosphorylated lipoproteins, were shown to bind specifically to the iron. The general applicability of immobilized ferric ion affinity chromatography for the purification of insect vitellogenin and vitellin is suggested.

Interaction of lipophorin with the plasma membrane of locust flight muscles.

Binding of high-density lipophorin (HDLp) to a plasma membrane preparation of locust flight muscle tissue was studied using a radiolabelled ligand binding assay and ligand blotting techniques. Analysis at 33 degrees C of the concentration-dependent total binding of tritium-labelled HDLp ([3H]HDLp) to the membrane preparation revealed the presence of a single specific binding site with an equilibrium dissociation constant of Kd = 9 (+/- 2) X 10(-7) M and a maximal binding capacity of 84 (+/- 10) ng X (micrograms protein)-1. Unlabelled HDLp as well as unlabelled low-density lipophorin (LDLp) competed with [3H]HDLp for binding to the identified binding site. In addition, ligand blotting demonstrated that both HDLp and LDLp bind specifically to a 30-kDa protein in the plasma membrane preparation, suggesting the involvement of this protein in the binding of lipophorins to the isolated membranes. A possible relationship between the identified binding of lipophorins and the observed co-purification of lipophorin lipase activity with the plasma membranes is discussed.

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.

An insect lipoprotein hybrid helps to define the role of apolipophorin III.

Insects transport lipid for flight in the form of diacylglycerol-rich low density lipoproteins (low density lipophorin (LDLp)). A hybrid LDLp has been produced in vitro by using Locusta migratoria fat body, locust high density lipophorin, locust adipokinetic hormone, and Manduca sexta apolipophorin III (apoLp-III). The hybrid is similar in size and density to locust LDLp, contains several molecules of M. sexta apoLp-III, and lacks locust apoLp-III, as shown by immunochemical methods. Under the same conditions an apoLp-III from Thasus acutangulus is poorly incorporated into the locust lipoprotein. The role of apoLp-III as a recognition signal/activator of flight muscle lipoprotein lipase was assayed with labeled hybrid LDLp produced in vitro using M. sexta apoLp-III radiolabeled with 35S. In addition, hydrolysis of diacylglycerol was determined with lipid-labeled hybrid LDLp produced in vitro using [U-14C]glycerol incorporated into the diacylglycerol moiety. In vitro incubations of the labeled hybrid LDLp with L. migratoria flight muscles show that the lipase efficiently utilizes hybrid LDLp as a substrate and demonstrate that the carbohydrate moiety of locust apoLp-III (which is lacking in the M. sexta protein) is not required for interaction with the lipase. It also suggests that specific antigenic determinants of L. migratoria apoLp-III are not required for lipase activation since M. sexta apoLp-III lacks immunological cross-reactivity with L. migratoria apoLp-III.

Partial purification of locust flight muscle lipoprotein lipase (LpL): apparent differences from mammalian LpL.

1. An attempt was made to purify lipoprotein lipase (LpL) from the flight muscle of the migratory locust based on affinity for heparin, which is known to avidly bind mammalian LpL. 2. However, locust LpL appeared to completely lack this property, which indicates that the suggested membrane-binding of locust LpL is very different from that of mammalian LpL: a heparin-like glycosaminoglycan is not involved. 3. Since locust LpL lacks heparin affinity, other purification methods were assayed. Solubilization of locust LpL was obtained by the detergent Tween 20. 4. Though both anion and cation exchange chromatography resulted in the complete loss of enzyme activity, partial purification of locust LpL was achieved by gel filtration chromatography.