Biosynthetic route of locust apolipophorin III isoforms.

Insect apolipophorin III (apoLp-III) plays a key role in the enhanced diacylglycerol transport during insect flight. For apoLp-III of the migratory locust, two different isoforms have been described (apoLp-IIIa and -b), displaying different N-termini and isoelectric points; each of the isoforms is however equally well capable to perform its function in lipid transport. In the present report the biosynthetic route of the apoLp-III isoforms is elucidated. Immunoprecipitation of media from in vitro fat body incubations and analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis demonstrated that the locust fat body synthesized and secreted apoLp-III. ApoLp-III levels in the hemolymph showed that in young adults, apoLp-III concentrations were only very low (1-3 mg/ml). During adult maturation, however, the apoLp-III concentration increased rapidly to approximately 17 mg/ml. During apoLp-III elevation, the apoLp-IIIa:-b ratio remained equal or in the favour of the a-isoform, while in adults from approximately 12 days after adult ecdysis apoLp-IIIb was the most abundant isoform. Analysis of the protein by native polyacrylamide gel electrophoresis showed that only the apoLp-IIIa form was secreted. Injection of radiolabeled apoLp-IIIa into the hemolymph of adult locusts resulted in a slow conversion into apoLp-IIIb.

Role of fatty acid-binding protein in lipid metabolism of insect flight muscle.

Since insect flight muscles are among the most active muscles in nature, their extremely high rates of fuel supply and oxidation pose interesting physiological problems. Long-distance flights of species like locusts and hawkmoths are fueled through fatty acid oxidation. The lipid substrate is transported as diacylglycerol in the blood, employing a unique and efficient lipoprotein shuttle system. Following diacyglycerol hydrolysis by a flight muscle lipoprotein lipase, the liberated fatty acids are ultimately oxidized in the mitochondria. Locusta flight muscle cytoplasm contains an abundant fatty acid-binding protein (FABP). The flight muscle FABP of Locusta migratoria is a 15 kDa protein with an isoelectric point of 5.8, binding fatty acids in a 1:1 molar stoichiometric ratio. Binding affinity of the FABP for long-chain fatty acids (apparent dissociation constant Kd = 5.21 +/- 0.16 microM) is however markedly lower than that of mammalian FABPs. The NH2-terminal amino acid sequence shares structural homologies with two insect FABPs recently purified from hawkmoth midgut, as well as with mammalian FABPs. In contrast to all other isolated FABPs, the NH2 terminus of locust flight muscle FABP appeared not to be acetylated. During development of the insect, a marked increase in fatty acid binding capacity of flight muscle homogenate was measured, along with similar increases in both fatty acid oxidation capacity and citrate synthase activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure of the asn-linked oligosaccharides of apolipophorin III from the insect Locusta migratoria. Carbohydrate-linked 2-aminoethylphosphonate as a constituent of a glycoprotein.

The primary structures of the N-linked carbohydrate chains of apolipophorin III from the insect Locusta migratoria have been determined. The glycoprotein was completely deglycosylated with peptide-N4-(N-acetyl-beta-glucosaminyl)asparagine amidase F. Released oligosaccharides were separated from the remaining protein using gel-permeation chromatography on Bio-Gel P-100. Purification of the carbohydrate chains was achieved by a combination of FPLC anion-exchange chromatography on Mono-Q and amine adsorption HPLC on Lichrosorb-NH2. The structures of the carbohydrate chains were deduced with a combination of fast atom bombardment mass spectrometry, 1H- and 31P-NMR spectroscopy, and methylation analysis. The majority of the carbohydrate chains contains 2-aminoethylphosphonate (AEP), which is linked to the 6-position of Man and/or GlcNAc. L. migratoria apolipophorin III is the first example of a glycoprotein containing carbohydrate-linked 2-aminoethylphosphonate. The structures of the major oligosaccharides were established to be the following: [formula: see text]

Biosynthesis and secretion of insect lipoprotein.

Biosynthesis of high density lipophorin (HDLp) was studied in larvae and adults of the migratory locust, Locusta migratoria. In an in vitro system, fat bodies were incubated in a medium containing a mixture of tritiated amino acids. Using SDS-PAGE and immunoblotting, it was shown that larval and adult fat bodies secreted both HDLp apoproteins, apolipophorin I (apoLp-I) and apolipophorin II (apoLp-II). Radiolabel was recovered in both apoproteins, indicative of de novo synthesis. The density of the fractions containing the apoproteins synthesized and secreted by larval and adult fat bodies was determined by density gradient ultracentrifugation. A radiolabeled protein fraction was found at density 1.12 g/ml. Using an enzyme-linked immunosorbent assay for detecting apoLp-I and apoLp-II, it was demonstrated that both apoproteins were present in this fraction, which had a density identical to that of circulating HDLp in hemolymph. Lipid analysis revealed that it contained phospholipid, diacylglycerol, sterol, and hydrocarbons. From these results it is concluded that the fat body of the locust synthesizes both apoLp-I and apoLp-II, which are combined with lipids to a lipoprotein particle that is released into the medium as HDLp.

Insect apolipophorin III: interaction of locust apolipophorin III with diacylglycerol.

In the formation of low-density lipophorin (LDLp) by the loading of diacylglycerol onto high-density lipophorin (HDLp) in insect hemolymph, apolipophorin III (apoLp-III) plays an essential role by binding to the increasing surface of the expanding lipoprotein particle. The present data on the surface properties of apoLp-III from Locusta migratoria demonstrate a preferential interaction with diacylglycerol. Injection of apoLp-III underneath a diacylglycerol monolayer results in a rapid interaction with the lipid; interaction with a phosphatidylcholine monolayer was considerably less. Locust apoLp-III binds with high affinity (Kd = 7.9.10(-9) M) to 1,2-diacylglycerol, which is consistent with its function in the LDLp particle; affinity for phosphatidylcholine is considerably lower. While the molecular area of locust apoLp-III in a monolayer is 2080 A2/molecule at the collapse pressure, in mixed monolayers of apoLp-III and lipid, the mean molecular area is decreased. Deglycosylation of the apoLp-III did not affect its interfacial stability. ApoLp-III from the moth Manduca sexta, which we included for comparison, demonstrated a similar reduction in molecular area resulting from interaction with lipid. These data do not support the hypothesis that interaction of apoLp-III with a lipid surface will lead to doubling of the molecular area of the protein (Kawooya, J.K., Meredith, S.C., Wells, M.A., Kézdy, F.J. and Law, J.H. (1986) J. Biol. Chem. 261, 13588-13591). The area of locust apoLp-III of 12.9 A2/amino acid residue at the collapse pressure is consistent with monolayers of alpha-helical proteins; circular dichroic spectra confirm a high alpha-helix content. The surface properties of apoLp-III reported here enable a high surface concentration of diacylglycerol in the LDLp particle, allowing the lipoprotein to act as an efficient reutilizable lipid shuttle.

Insect lipophorin conversions. Compositional analysis of high- and low-density lipophorin of Acherontia atropos and Locusta migratoria.

The formation of low-density lipophorin (LDLp) in insect hemolymph, resulting from association of high-density lipophorin (HDLp) with both lipid and apolipophorin III, is considered to provide a reutilizable lipid shuttle for flight muscle energy supply. The changes in lipid and apolipoprotein composition of LDLp, isolated after flight activity, compared to that of HDLp in the hemolymph at rest, were studied in two evolutionary divergent insects, the hawkmoth Acherontia atropos and the migratory locust, Locusta migratoria. Using FPLC on Superose 6 prep grade as a novel technique to separate the apolipophorins of HDLp and LDLp, the ratio of apolipoprotein I, II, and III in HDLp of both species was demonstrated to be 1:1:1, whereas flight activity resulted in a ratio of 1:1:10 in LDLp. Injection of adipokinetic hormone into resting moths showed that, depending on the dose, the number of apolipophorin III molecules in LDLp can exceed that recovered after the physiological condition of flight. Analysis of the lipophorin lipids demonstrated that in addition to the considerable increase in diacylglycerol in the LDLp particle, which is consistent with the role LDLp in energy supply, particularly the hydrocarbons were increased compared to HDLp, rendering the mechanism of LDLp formation from HDLp even more complex.

Different isoforms of an apoprotein (apolipophorin III) associate with lipoproteins in Locusta migratoria.

Insects transport lipid for flight in the form of diacylglycerol-rich low-density lipoproteins (low-density lipophorin, LDLp), which in the hemolymph are produced from high-density lipophorin (HDLp) by reversible association with several molecules of an apolipoprotein, apolipophorin III (apoLp-III, Mr approximately 18,000-20,000) during lipid loading. Two isoforms of apoLp-III (a and b) were purified both from adult Locusta migratoria migratorioides hemolymph and LDLp, which have identical apparent Mr but differ in amino acid composition, NH2-terminal amino acid sequence, and isoelectric points (5.35 +/- 0.01 for apoLp-IIIa, 5.10 +/- 0.01 for apoLp-IIIb). The NH2-terminal sequence of apoLp-IIIb is identical to the primary structure of apoLp-III deduced from cloned cDNA [Kanost et al. (1988) J. Biol. Chem. 263, 10,568-10,573], whereas the NH2-terminal sequence of apoLp-IIIa is identical to that of apoLp-IIIb but preceded by Arg-Pro-, which is the C-terminal of the putative signal peptide coded by cDNA upstream from that coding for apoLp-IIIb. The ratio apoLp-IIIa apoLp-IIIb free in hemolymph is identical to that in LDLp (5:9); since 14 molecules of apoLp-III appear to be bound in one molecule of LDLp, an average of 5 molecules of apoLp-IIIa and 9 of apoLp-IIIb are involved in formation of each LDLp particle. In vivo studies using 35S-labeled apoLp-IIIa and b demonstrate that each of the isoforms can associate with HDLp to produce LDLp reversibly; in an in vitro system, production of LDLp containing exclusively apoLp-IIIa or apoLp-IIIb demonstrates independent participation of each isoform in LDLp formation.

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.