Loading of lipophorin particles with phospholipids at the midgut of Rhodnius prolixus

³²P-Labelled midguts (³²P-midguts) of Rhodnius prolixus females were incubated in the presence of nonradioactive purified lipophorin and the release of radioactivity to the medium was analysed. The radioactivity found in the medium was associated with lipophorin phospholipids. When the ³²P-midguts were incubated in the absence of lipophorin, no ³²P-phospholipids were found in the medium. Comparative analysis by thin-layer chromatography of ³²P-phospholipids derived from metabolically labelled ³²P-midgut or lipophorin particles after incubation with ³²P-midgut showed some differences, revealing a possible selectivity in the process of phospholipids transfer. The transfer of phospholipids to lipophorin was linear with time up to 45 min, was saturable with respect to the concentration of lipophorin, and was half-maximal at about 5 mg/ml. The binding of ³²P-lipophorin to the midgut at O°C reached the equilibrium at about 1 h of incubation. The binding of ³²P-lipophorin was inhibited by an excess of nonradioactive lipophorin, which suggests a specific receptor for lipophorin. The capacity of midguts and fat bodies to transfer phospholipids to lipophorin varied during the days following the meal. When lipophorin enzymatically depleted of phospholipids by treatment with phospholipase A² was incubated with ³²P-midguts, the same amount of phospholipids was transferred, indicating a net gain of phospholipids by the particle. © 1995 Wiley-Liss, Inc.     

Transfer of phospholipids from fat body to lipophorin in Rhodnius prolixus

32P-Labeled fat bodies (32P-fat bodies) of Rhodnius prolixus females were incubated in the presence of non radioactive purified lipophorin and the release of radioactivity to the medium was analysed to answer the question of whether lipophorin is a reusable shuttle for phospholipids. The radioactivity found in the medium was associated with lipophorin phospholipids. When the 32P-fat bodies were incubated in the absence of lipophorin, only a small amount of radioactivity was released and it was not associated with lipophorin, indicating that there was no release of pre-labeled 32P-lipophorin by the tissue. Analysis of 32P-phospholipids transferred from fat bodies to the lipophorin particles by thin-layer chromatography revealed a predominance of phosphatidylethanolamine and phosphatidylcholine, with minor amounts of phosphatidylserine, phosphatidylinositol, and sphingomyelin. The transfer of phospholipids to lipophorin was linear with time up to 45 min and the process was inhibited at low temperature and by the metabolic inhibitors azide and fluoride. The transfer of phospholipids from the fat bodies to lipophorin was saturable with respect to the concentration of lipophorin, which was half-maximal at about 8 mg/ml. A directional movement of phospholipids from the fat body to lipophorin was observed. The net gain of phospholipids in 2 h of incubation with fat body was 8.54 nmol per insect, which corresponds to 6.69% of increase in the lipophorin phospholipid content. The rate of 32P-phospholipid transfer from fat body to lipophorin particles varied during the days after a blood meal increasing up to day 10 and then decreasing in parallel with the process of oogenesis.     

Characterization and immunocytochemical localization of lipophorin binding sites in the oocytes of Rhodnius prolixus

Purified lipophorin, metabolically labelled with 32P exclusively in the phospholipid moiety, was used to study the process of phospholipid delivery to the oocyte. The kinetics of phospholipid transfer "in vitro," from lipophorin to the oocytes, was linear at least up to 4 h and was impaired by low temperature. A net transfer of phospholipids from lipophorin particles to the oocytes was observed. The rate of phospholipid uptake was dependent on the concentration of lipophorin in the medium and was shown to be a saturable process. The addition of a molar excess of purified unlabelled lipophorin to the culture medium resulted in a substantial decrease in the transfer of [32P]phospholipids, but no reduction occurred in the presence of a molar excess of albumin. The lipophorin binding sites were localized in the oocytes by immunogold techniques using two different protocols for oocyte fixation. Strong labelling was observed especially at the microvilli. No labelling was detected in the yolk granules.     

Synthesis and release of lipophorin in larvae of the southwestern corn borer,Diatraea grandiosella: An in vitro study

The source of the lipophorin present in the larval haemolymph of the southwestern corn borer, Diatraea grandiosella, was examined in vitro. Although lipophorin was shown to be one of several proteins released from cultured fat body and midgut, only fat body was shown to synthesize lipophorin. Fat body, incubated in a medium containing [³H]leucine, was shown to release radiolabelled lipophorin using immunoprecipitation. Similar studies using midguts incubated in a medium containing [³H]leucine did not reveal any synthesis of lipophorin. Lipophorin was isolated by density-gradient ultracentrifugation from media in which the fat bodies of about 600 diapausing larvae had been incubated for 4 hr. The isolated lipophorin had a peak density of 1.11 g/ml, and contained various lipids including diacylglycerol, triacylglycerol, sterol, hydrocarbon, free fatty acid, phosphatidyl choline, phosphatidyl ethanolamine and sphingomyelin.     

Uptake of long-chain fatty acid methyl esters by mammalian cells

Albumin-bound long-chain fatty acid methyl esters (ME) were taken up and utilized by Ehrlich ascites tumor cells and slices of rat heart, liver, and kidney. Much more ME than albumin was taken up by the tumor cells, indicating that ME dissociated from the carrier protein during their uptake. 70-80% of the radioactivity associated with the cells after 1 min of incubation at 37 degrees C remained as ME. The results of studies with metabolic inhibitors and glucose suggest that uptake of ME is an energy-independent process. Changes in incubation medium pH between 7.8 and 6.5 did not markedly alter uptake of ME. Cells incubated with FFA and methanol did not synthesize ME. These findings indicate that ME are taken up intact, and they suggest that the presence of an anionic carboxyl group is not essential for the binding of a long-chain aliphatic hydrocarbon to a mammalian cell. When incubation with labeled ME was continued for 1 hr, increasing amounts of radioactivity were recovered in FFA, phospholipids, neutral lipid esters, and CO(2). ME radioactivity associated with the cells after a brief initial incubation was released in the form of ME and FFA when the cells were incubated subsequently in a medium containing albumin. If the second incubation medium contained no albumin, most of the ME radioactivity initially associated with the cells was incorporated into phospholipids, neutral lipid esters, and CO(2). These results suggest that much of the ME which is taken up, is hydrolyzed to FFA, and that the fatty acids derived from ME are available for further metabolism.     

Characterization of lipophorin binding to the fat body of Rhodnius prolixus

In insects, lipids are transported by a hemolymphatic lipoprotein, lipophorin. The binding of lipophorin to the fat body of the hematophagous insect Rhodnius prolixus was characterized in a fat body membrane preparation, obtained from adult females. For the binding assay, purified lipophorin was radiolabelled in the protein moiety (125I-HDLp), and it was shown that iodination did not affect the affinity of the membrane preparation for lipophorin. Under incubation conditions used, lipophorin binding to membranes achieved equilibrium after 40-60 min, but this time was longer when a low concentration of lipophorin was present in the medium. The capacity of the fat body membrane preparation to bind lipophorin was abolished when membranes were pre-treated with trypsin, and it was also affected by heat. When 125I-HDLp was incubated with increasing concentrations of membrane protein, corresponding increases in binding were observed. Lipophorin binding was sensitive to pH, and it was maximal between pH 6.0 and 7.0. The specific binding of lipophorin to the fat body membrane preparation was a saturable process, with a Kd of 2.1 +/- 0.4 x 10(-7)M and a maximal binding capacity of 289 +/- 88 ng lipophorin/microgram of membrane protein. Binding to the fat body membranes did not depend on calcium, but it was affected by ionic strength, being totally inhibited at high salt concentrations. Suramin also interfered with lipophorin binding and it was abolished in the presence of 2 mM suramin, but at concentrations of 0.05 and 0.1 mM it seemed to increase binding activity slightly. Fat body membrane preparation from Rhodnius prolixus was able to bind lipophorin from Manduca sexta larvae.     

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.     

Role of lipid transfer particle in delivery of diacylglycerol from midgut to lipophorin in larval Manduca sexta

The present work analyzed the function of lipid transfer particle (LTP) in the process of exporting diacylglycerol from larval Manduca sexta midgut cells to lipophorin. When midgut sacs, which had been prelabeled in vivo with [(3)H]oleic acid, were incubated in vitro with a lipophorin-containing medium, a significant amount of radiolabeled diacylglycerol was transferred to lipophorin. Negligible amounts of diacylglycerol were released into lipophorin-free medium. In contrast, lipid-labeled lipophorin did not transfer diacylglycerol to the midgut sacs. The transfer of diacylglycerol from the midgut sac to lipophorin was blocked by preincubation of midgut sacs with antibody against LTP. Diacylglycerol transfer was restored to control values by the addition of purified LTP to midgut sacs that had been treated with antibody against LTP. Under these conditions the amount of diacylglycerol transferred was a function of the LTP concentration. These are the first results showing that LTP is required to export diacylglycerol from the midgut to lipophorin.     

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.     

Perimicrovillar membrane assembly: the fate of phospholipids synthesised by the midgut of Rhodnius prolixus

In this study, we describe the fate of fatty acids that are incorporated from the lumen by the posterior midgut epithelium of Rhodnius prolixus and the biosynthesis of lipids. We also demonstrate that neutral lipids (NL) are transferred to the haemolymphatic lipophorin (Lp) and that phospholipids remain in the tissue in which they are organised into perimicrovillar membranes (PMMs). 3H-palmitic acid added at the luminal side of isolated midguts of R. prolixus females was readily absorbed and was used to synthesise phospholipids (80%) and NL (20%). The highest incorporation of 3H-palmitic acid was on the first day after a blood meal. The amounts of diacylglycerol (DG) and triacylglycerol synthesised by the tissue decreased in the presence of Lp in the incubation medium. The metabolic fates of 3H-lipids synthesised by the posterior midgut were followed and it was observed that DG was the major lipid released to Lp particles. However, the majority of phospholipids were not transferred to Lp, but remained in the tissue. The phospholipids that were synthesised and accumulated in the posterior midgut were found to be associated with Rhodnius luminal contents as structural components of PMMs.     

In vitro study of the action of adipokinetic hormone in locusts

The in vitro study was performed in order to demonstrate the structural changes of lipophorin induced in vivo by the injection of adipokinetic hormone (AKH) into adult locusts. After many unsuccessful attempts, we have established the reconstructed incubation system in which purified lipophorin and apolipophorin-III (9 mol/mol lipophorin) are incubated with the fat body in the presence of AKH under a supply of excess oxygen. In this system, high density lipophorin (HDLp) originally present in the incubation medium can be transformed entirely into low density lipophorin (LDLp) due to the loading of an increased amount of diacylglycerol from the fat body. The LDLp formed in this incubation system was exactly the same as the LDLp formed in vivo by the injection of AKH, in terms of density, particle size, diacylglycerol content, and the association with apolipophorin-III (apoLp-III). In the absence of apoLp-III, AKH did not exhibit its function to any extent. It was also demonstrated that the transformation of HDLp to LDLp requires calcium ions. Moreover, it appears that, up to a certain limit, the increase of diacylglycerol content of lipophorin and the amount of apoLp-III associated with lipophorin is nearly proportional to the amount of apoLp-III added to the incubation medium.     

Membrane lipid metabolism of Bacillus Calmette-Guerin-induced rabbit alveolar macrophages.

We examined the uptake of radiolabeled lysophospholipids and oleic acid by Bacillus Calmette-Guerin-induced rabbit alveolar macrophages either in the presence or absence of challenge particles. There was no difference in the uptake and metabolism of lysophospholipids by control or challenged cells for incubation periods up to 5 h. When incubated with [3H]oleic acid, challenged cells consistently exhibited a slightly greater uptake of radioactivity. Extraction of the whole cells revealed that the greater amount of radioactivity found in the challenged cells primarily was in triacylglycerol. There was no marked difference in the amount of radioactivity associated with the phospholipids in the whole cell extracts from control and challenged cells. When the macrophages were pre-labeled for 15 min with [3H]oleic acid and then reincubated in fresh medium in the presence or absence of autoclaved Escherichia coli B, more radioactivity was retained by the challenged cells, again in the form of triacylglycerol. Only in isolated plasma membrane fractions did we observe a difference in the amount of radioactivity associated with phospholipids from control and challenged cells. Plasma membranes isolated from Bacillus Calmette-Guerin-induced rabbit alveolar macrophages that had been incubated for 6 h with [3]oleic acid in the presence of E. coli B contained significantly higher level of radioactivity in all lipids than plasma membranes from control cells. Since the greatest and the most consistent difference between control and challenged cells is associated with the triacylglycerol molecule, it is postulated that this molecule may serve as a precursor in the synthesis of alveolar macrophage phospholipids, both by the reacylation pathway and the de novo pathway. It is possible that the high level of radiolabeled phospholipid found in the plasma membrane arose via the de novo pathway following the cleavage of an acyl group as we have found cytidine diphosphocholine phosphotransferase in the plasma membrane fraction (Wang, P., DeChatelet, L.R., and Waite, M. (1977) Biochim. Biophys. Acta 450, 311--321).     

Metabolism of fatty acids and their incorporation into phospholipids of the mitochondria and endoplasmic reticulum in isolated hepatocytes determined by isolation of fluorescence derivatives

Isolated hepatocytes were incubated in the presence of [14C]palmitic, [14C]linoleic or [14C]linolenic acid and the time-courses of incorporation of radioactivity into phosphatidylcholine and phosphatidylethanolamine of microsomes and mitochondria were followed. For this purpose a procedure was developed for HPLC separation of 9-diazomethylanthracene (ADAM) derivatives of fatty acids. When [14C]palmitic acid was used, the major product of elongation and desaturation was octadecadienoic acid, which accounted for 35-65% of the total radioactivity. Labeled palmitoleic, stearic and oleic acids could also be isolated. In fatty acids which do not participate to any large extent in deacylation-reacylation reactions, the pattern of incorporation was characteristic: a high rate of incorporation into microsomal and a low rate of incorporation into mitochondrial phospholipids during the first 40 min, followed by a decrease in the former and an increase in mitochondrial labeling. This pattern is consistent with the fact that de novo synthesis of these two phospholipids occurs in the endoplasmic reticulum in vivo. When cells were incubated in the presence of [14C]linoleic acid, 70-90% of the radioactivity recovered in phospholipids was in this same form, whereas the remaining label was mainly in arachidonic acid and, to some extent, in eicosatrienoic acid. When hepatocytes were incubated in the presence of [14C]linolenic acid, 70-85% of the radioactivity in isolated phospholipids was associated with linolenic acid. As much as 20% of the label was recovered in docosahexanoic acid and 5-10% in arachidonic acid. In the case of the two latter labeled substrates the exchange reactions seem to dominate over de novo synthesis. For phospholipids synthesized de novo the transfer from the endoplasmic reticulum to mitochondria requires about 3 h.     

Exchange of phospholipids between brain membranes in vitro

1. When unlabelled mitochondria from guinea-pig brain were incubated with a (32)P-labelled microsomal fraction from brain there was a transfer of phospholipid to the mitochondria, which could not be accounted for by an aggregation of microsomes and mitochondria or an exchange with microsomes contaminating the mitochondria. Under similar circumstances there was a transfer of phospholipid from (32)P-labelled mitochondria to microsomes, indicating that the process was one of exchange. 2. The transfer from microsomes was greatly stimulated by a non-dialysable heat-labile macromolecular component in the brain supernatant fraction but not by the concentration of the particulate fractions. 3. Phospholipid-exchange processes occurred most readily between pH7 and 7.5 and were inhibited by the presence of myelin and on the addition of lysophosphatidylcholine. 4. The rates of transfer of individual phospholipids from brain microsomes to mitochondria were similar. 5. (32)P-labelled microsomes could slowly donate phospholipid to the isolated synaptosomal (nerve-ending) fraction but the phospholipids of the myelin fraction did not exchange. 6. Subfractionation of the synaptosomal fraction after [(32)P]phospholipid transfer showed that the mitochondria were most actively labelled during the incubation. All of the isolated individual synaptosomal membranes were capable of acquiring phospholipid on incubation with a (32)P-labelled brain supernatant fraction although a greater percentage was again exchanged by the mitochondrial fraction.     

Transfer of phospholipids between mesosomes and protoplasts from Bacillus subtilis

1. Phospholipids were more intensively labelled from ammonium [1-14C]glycerophosphate in mesosomes than in protoplasts isolated from Bacillus subtilis. 2. When mesosomes, containing phospholipids labelled from sodium-[32P] phosphate were incubated with non radioactive protoplasts, labelled phospholipids were recovered in protoplasts after incubation. 3. This transfer of phospholipids from mesosomes toward protoplasts is time-dependent. 4. Soluble proteins obtained from Bacillus subtilis after ammonium sulphate precipitation were separated on a Sephadex G-100 column. 5. The two main fractions were able to accelerate the transfer of phospholipids from mesosomes toward protoplasts. 6. The first peak stimulated more actively the transfer of phosphatidylethanolamine whereas the second one preferentially accelerated the transfer of phosphatidylglycerol and diphosphatidylglycerol.     

Utilization of free fatty acids complexed to human plasma lipoproteins by mammalian cell suspensions

The purpose of this study was to determine whether lipoprotein-bound free fatty acid could be utilized by isolated mammalian cells. Ehrlich ascites tumor cells were incubated in vitro with radioactive free fatty acids that were bound to human plasma lipoproteins. Under these conditions, lipoprotein-bound free fatty acids were readily taken up by the cells. After 2 min of incubation with free fatty acids bound to low density lipoproteins, most of the radioactivity that was associated with the cells was in the form of free fatty acids. As the incubation continued, increasing amounts of radioactivity were incorporated into CO(2) and cell lipids, particularly phospholipids. Most of the free fatty acid uptake was the result of fatty acid transfer from low density lipoproteins to the cell, not from irreversible incorporation of the intact free fatty acid-low density lipoprotein complex. Fatty acid uptake increased as the ratio of free fatty acid to low density lipoprotein was raised. When albumin was added to the medium, free fatty acid uptake decreased. A large percentage of the newly incorporated cellular radioactivity was released into the medium if the cells were exposed subsequently to a solution containing albumin. Most of the released radioactivity was in the form of free fatty acid. The results with this experimental model suggest that lipoprotein-bound free fatty acid, like albumin-bound free fatty acid, is readily available for uptake by isolated cells. The mechanism of free fatty acid utilization by the Ehrlich cell is similar when either low density lipoprotein or serum albumin serves as the fatty acid carrier.     

Metabolism of phosphoinositides in the rat erythrocyte membrane. A reappraisal of the effect of magnesium on the 32P incorporation into polyphosphoinositides

The metabolism of phosphoinositides was investigated in the red blood cell membrane of the rat by measuring 32P-incorporation into phospholipids after incubation of membranes with [gamma-32P]ATP in a medium containing magnesium. A new chromatographic procedure has been developed which facilitates the separation of triphosphoinositide, diphosphoinositide and phosphatidylinositol from the phospholipids present in lipid extracts of incubated 'ghost' under our experimental conditions only two phospholipids, diphosphoinositide and triphosphoinositide, were 32P-labelled. Furthermore, the results indicate that either di-or triphosphoinositide could be labelled preferentially, depending upon the magnesium concentration of the incubation medium. This clarifies some apparent discrepancies reported in the literature between the 32 P labelling of polyphosphoinositides observed in intact erythrocytes and that observed with 'ghost' membranes. In addition, the enzymatic pathways involved in the phosphoinositide metabolism are discussed.     

Role of phospholipids in the lipophorin particles of Rhodnius prolixus.

The lipophorin of Rhodnius prolixus metabolically labelled with 32P exclusively in the phospholipid moiety was purified on a potassium bromide gradient and treated with phospholipase A2 in the presence of an excess of fatty acid-free albumin. The treatment completely removed the phospholipids from the particles and generated [32P]-lysophosphatidylcholine, [32P]-lysophosphatidylethanolamine, and free fatty acids that remained bound to albumin. The phospholipid-depleted lipophorin particles remained soluble, indicating that phospholipids are not essential in maintaining the stability of the particles in aqueous solution. Complete removal of phospholipids did not affect the association of apolipophorin III with lipophorin particles. Lipophorin density increased slightly from 1.120 to 1.134 g/ml after treatment. The phospholipid-depleted particles also retained their ability to be recognized and loaded in vitro with phospholipids delivered by the fat body, thus supporting the concept of lipophorin's role as a reusable lipid shuttle for phospholipids.     

PHOSPHOLIPID METABOLISM IN CULTURED NEUROBLASTOMA AND GLIOMA CELLS INCUBATED WITH CARBAMYLCHOLINE AND NOREPINEPHRINE

Cultures of cloned neuroblastoma cells (N1E) in stationary phase and cloned glioma cells (C2₁) in confluency showed substantial differences in phospholipid composition. As a percentage of lipid P, N1E contained more phosphatidylcholine, less ethanolamine phosphoglycerides and much less sphingomyelin than C2₁. When incubated with ³²P_i both cell lines incorporated comparable amounts of radioactivity into total phospholipids. In NIE, phosphatidylcholine contained much more and phosphatidylinositol and phosphatidic acid somewhat less label as compared to C2₁. The presence in the incubation medium of either norepinephrine or carbamylcholine failed to elicit stimulation of ³²P incorporation into any phospholipid class.