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.     

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.     

Transfer of cholesterol and diacylglycerol from lipophorin to Bombyx mori ovarioles in vitro: role of the lipid transfer particle

The objective of this study was to characterize the transfer of diacylglycerol (DAG) and cholesterol from larval Bombyx mori lipophorin to ovarioles. Transfer studies were carried out by incubating pupal ovarioles (5-day) with [(3)H]-cholesterol and [(3)H]-DAG-labeled lipophorin under different conditions. Transfer of both cholesterol and DAG exhibited hyperbolic dependency on lipophorin concentration with apparent Km values of 0.83 +/- 0.17 mg/ml and 0.74 +/- 0.16 mg/ml, respectively. Pretreatment of ovarioles with anti-lipid transfer particle (LTP) IgG significantly inhibited transfer of labeled DAG to ovarioles (75%) and not cholesterol. Injection of B. mori pupae (day 4) with anti-LTP IgG significantly affected the weight (65%), number of eggs (49%), amount of lipid (74%), and protein (65%) of the adult ovaries. Matured eggs had a very faint yellow color and deformed shape compared to controls. The inhibitory effect demonstrates the active role LTP plays in growth of ovaries, development, and oogenesis. The effect on vitellogenin shortage on egg development and maturation was determined by implanting ovaries in male recipients that lack vitellogenin. An 80% decline in egg production was observed. However, the mature eggs were normal in shape, color, and lipid content. Thus, restricting lipid or protein delivery to developing ovaries would dramatically affect choriogenesis.     

Insect lipid transfer particle catalyzes bidirectional vectorial transfer of diacylglycerol from lipophorin to human low density lipoprotein

Insect plasma lipid transfer particle (LTP) catalyzes vectorial net transfer of diacylglycerol (DAG) from Manduca sexta larval high density lipophorin (HDLp-L) to human low density lipoprotein (LDL) producing an LDL of lower density and lipophorin subspecies of higher density. At equilibrium, a stable DAG-depleted very high density lipophorin species (density = 1.25 g/ml) is formed. Electrophoretic analysis of the substrate and product lipoproteins showed that apoprotein exchange or transfer between human LDL and lipophorin did not occur during the lipid transfer reaction. Facilitated net transfer of cholesteryl ester, free cholesterol, and phospholipid occurred to a much lower extent than DAG net transfer, indicating that under these conditions, LDL serves as a sink for lipophorin-associated DAG. This reaction, therefore, provides a method whereby the mass of lipid associated with human LDL can be modified in vitro without alteration of its apoprotein component. The DAG content of LDL increased in a linear manner with respect to LTP concentration and time during the initial phase of the reaction, demonstrating the utility of this system as a quantitative assay method for LTP-mediated net DAG transfer. When [3H]DAG-labeled LDL was prepared and employed in transfer experiments with unlabeled lipophorin, labeled DAG was recovered in the HDLp-L fraction. The amount of labeled DAG recovered in the HDLp-L fraction was dependent on the ratio of LDL to HDLp-L in the reaction. Thus, in this system, LTP-mediated DAG redistribution is bidirectional, suggesting that the final equilibrium distribution of lipid may be dictated by the properties of potential donor/acceptor lipoproteins rather than by an inherent particle substrate specificity of LTP.     

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.     

Lipid transfer particle in locust hemolymph: purification and characterization

A lipid transfer particle (LTP) from the hemolymph of adult male locusts, Locusta migratoria, was isolated and purified. The locust LTP exhibited its capacity to catalyze the exchange of diacylglycerol between low density lipophorin (LDLp) and high density lipophorin (HDLp). Contrary to the LTP reported for the tobacco hornworm, M. sexta, the locust LTP appeared to lack the capacity to promote net transfer of diacylglycerol to form an intermediate density lipophorin, although it seems premature to conclude the complete lack of such a capacity in locust LTP. The original concentration of LTP in hemolymph is assumed to be extremely low compared to that of lipophorin; only a catalytic amount of LTP may be present in the hemolymph (e.g., only 160 micrograms of LTP was obtained from the original hemolymph containing 400 mg protein). The molecular weight of intact LTP was estimated to be about 600,000 and the LTP was comprised of three glycosylated apoproteins, apoLTP-I (mol wt 310K), apoLTP-II (mol wt 89K), and apoLTP-III (mol wt 68K). The locust LTP contained significant amounts of lipids; the total lipid content amounted to 14.4% and the lipids were comprised of 17% hydrocarbons, 44% diacylglycerol, 8% cholesterol, 13% free fatty acid, and 18% phospholipids. The above molecular properties of locust LTP are essentially similar to those reported for M. sexta LTP.     

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.     

Changes in lipophorin composition during the fourth to fifth instar molt of Manduca sexta

During the feeding stage of the fourth instar of the tobacco hornworm, Manduca sexta, lipophorin has a density of 1.144 g/ml and is comprised of 55% protein and 45% lipid, mainly diacylglycerol and phospholipid. These values are similar to those found during the corresponding period of the fifth instar. However, during the intermolt period the lipid composition of lipophorin changes to 45% protein and 55% lipid and the density decreases to 1.112 g/ml. The onset of these changes in lipid content correspond to the increase in ecdysteroid titer which signals the beginning of molting. At the end of molting both the lipid content and density return to those characteristic of the fifth instar. These data further confirm the complex nature of lipophorin metabolism in M. sexta larva and suggest that ecdysone may be the trigger for lipid mobilization during the intermolt period.     

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 0 degrees 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.     

Lipid transfer particle mediates the delivery of diacylglycerol from lipophorin to fat body in larval Manduca sexta

This work analyzed the process of lipid storage in fat body of larval Manduca sexta, focusing on the role of lipid transfer particle (LTP). Incubation of fat bodies with [(3)H]diacylglycerol-labeled lipophorin resulted in a significant accumulation of diacylglycerol (DAG) and triacylglycerol (TAG) in the tissue. Transfer of DAG to fat body and its storage as TAG was significantly inhibited (60%) by preincubating the tissue with anti-LTP antibody. Lipid transfer was restored to control values by adding LTP to fat body. Incubation of fat body with dual-labeled DAG lipophorin or its treatment with ammonium chloride showed that neither a membrane-bound lipoprotein lipase nor lipophorin endocytosis is a relevant pathway to transfer or to storage lipids into fat body, respectively. Treatment of fat body with suramin caused a 50% inhibition in [(3)H]DAG transfer from lipophorin. Treatment of [(3)H]DAG-labeled fat body with lipase significantly reduced the amount of [(3)H]DAG associated with the tissue, suggesting that the lipid is still on the external surface of the membrane. Whether this lipid represents irreversibly adsorbed lipophorin or a DAG lipase-sensitive pool is unknown. Nevertheless, these results indicate that the main pathway for DAG transfer from lipophorin to fat body is via LTP and receptor-mediated processes.     

Lipid thermotropic transitions in Triatoma infestans lipophorin

The structure and lipid thermotropic transitions of highly purified lipophorin of Triatoma infestans were examined by several techniques: steady-state fluorescence polarization of 1,6-diphenyl-1,3,5-hexatriene (DPH), cis-parinaric acid (cis-PnA) and trans-parinaric acid (trans-PnA), light scattering fluorescence energy transfer between the lipophorin tryptophan residues and the bound chromophores, DPH, trans-parinaric acid cis-parinaric acid, gel electrophoresis, and gel filtration. Fluorescence polarization of PnAs and DPH revealed a reversible lipid thermotropic transition in intact lipophorin at about 20 degrees C and 18 degrees C, respectively. In lipophorin, lipid dispersion fluorescence polarization of DPH detected a lipid transition approximately at 20 degrees C, while trans-PnA showed a gel phase formation at a temperature below 30 degrees C. Similar experiments in which trans-PnA was incorporated into diacylglycerols and phospholipids extracted from the lipophorin revealed gel phase formation below 30 degrees C and 24 degrees C, respectively. Light scattering measurements showed that lipophorin particles aggregate irreversibly at 45 degrees C, increasing the molecular weight, as determined by gel filtration on Sephacryl S-300, from 740,000 to values larger than 1,500,000. The particle aggregation did not change the physical properties of the lipophorin studied by fluorescence polarization, indicating that the aggregation is apparently a non-denaturing process. Energy transfer between the lipophorin tryptophans and the bound chromophores cis-PnA, trans-PnA, and DPA revealed a different location of the fluorescent probes within the lipophorin. Temperature-dependence on the energy transfer efficiency for all probes confirmed a change in the ordering of the lipophorin lipids at 24 degrees C.     

Rhodnius prolixus LIPOPHORIN: LIPID COMPOSITION AND EFFECT OF HIGH TEMPERATURE ON PHYSIOLOGICAL ROLE

Lipophorin is a major lipoprotein that transports lipids in insects. In Rhodnius prolixus, it transports lipids from midgut and fat body to the oocytes. Analysis by thin‐layer chromatography and densitometry identified the major lipid classes present in the lipoprotein as diacylglycerol, hydrocarbons, cholesterol, and phospholipids (PLs), mainly phosphatidylethanolamine and phosphatidylcholine. The effect of preincubation at elevated temperatures on lipophorin capacity to deliver or receive lipids was studied. Transfer of PLs to the ovaries was only inhibited after preincubation of lipophorin at temperatures higher than 55°C. When it was pretreated at 75°C, maximal inhibition of phospholipid transfer was observed after 3‐min heating and no difference was observed after longer times, up to 60 min. The same activity was also obtained when lipophorin was heated for 20 min at 75°C at protein concentrations from 0.2 to 10 mg/ml. After preincubation at 55°C, the same rate of lipophorin loading with PLs at the fat body was still present, and 30% of the activity was observed at 75°C. The effect of temperature on lipophorin was also analyzed by turbidity and intrinsic fluorescence determinations. Turbidity of a lipophorin solution started to increase after preincubations at temperatures higher than 65°C. Emission fluorescence spectra were obtained for lipophorin, and the spectral area decreased after preincubations at 85°C or above. These data indicated no difference in the spectral center of mass at any tested temperature. Altogether, these results demonstrate that lipophorin from R. prolixus is very resistant to high temperatures.     

Manduca sexta lipid transfer particle acts upon a lipoprotein to catalyze lipid and apoprotein disproportionation

A novel reaction, catalyzed by Manduca sexta lipid transfer particle (LTP), transforms low density lipophorin (LDLp) into two distinct lipoprotein species. A population of LDLp particles serves as lipid donor or acceptor in LTP-catalyzed production of a very low density lipophorin (VLDLp) and a high density lipophorin (HDLp) product. The products result from facilitated net transfer of lipid mass from donor LDLp particles to acceptor LDLp particles. Transfer of apolipophorin III (apoLp-III) from donor to acceptor lipoprotein occurs during the reaction to produce a lipid- and apoLp-III-enriched VLDLp species and lipid- and apoLp-III-depleted HDLp species. The VLDLp produced in this in vitro reaction contains more lipid and apoLp-III than any previous lipophorin species reported and further demonstrates the scope of the lipid binding capacity of lipophorin. Lipid analysis and radiolabeling studies confirmed that unidirectional net transfer of lipid mass and apoLp-III from donor to acceptor occurs. When 3H-lipid-LDLp was used as substrate in the LTP-catalyzed disproportionation reaction the density distribution of radioactivity and protein provided evidence of vectorial transfer of diacylglycerol, phospholipid, and free fatty acids. Electron micrographs of the original LDLp population and of the LTP-induced product lipoprotein population provided further support for the interpretation derived from biochemical studies. This LTP-catalyzed disproportionation was observed only with apoLp-III-rich LDLp suggesting that the presence of increased amounts of this apoprotein dramatically affects the properties of the particle and appears to be directly related to the capacity of the lipoprotein to bind lipid.     

Lipid storage and mobilization in insects: current status and future directions

In this paper we review the current status of research on fatty acid absorption and conversion to diacylglycerol in the midgut. We further discuss how diacylglycerol may leave the midgut and associate with lipophorin in hemolymph. We review the present understanding of the role of the lipid transfer particle and lipophorin receptors in lipid delivery between lipophorin and tissues. Finally, we discuss recent studies on the mobilization of diacylglycerol from the fat body in response to adipokinetic hormone. Several suggestions for exciting areas of future research are described.     

Facilitated diacylglycerol exchange between insect hemolymph lipophorins. Properties of Manduca sexta lipid transfer particle

Manduca sexta hemolymph lipid transfer particle (LTP) is a very high density lipoprotein (d = 1.23 g/ml) containing 14% lipid and 5% carbohydrate. Each of three apoprotein components, apoLTP-I (Mr approximately 320,000), apoLTP-II (Mr = 85,000), and apoLTP-III (Mr = 55,000), is glycosylated. Carbohydrate analysis revealed the presence of mannose and N-acetylglucosamine in a ratio of 4.5:1. A native Mr greater than 670,000 was determined by pore limiting gradient gel electrophoresis. Lipid analysis of LTP revealed the presence of phospholipid, diacylglycerol (DAG), free fatty acid, and triacylglycerol. Rabbit polyclonal antibodies directed against LTP were obtained. Anti-LTP serum was employed in experiments which indicated the presence of LTP in larval and adult animals and confirmed that LTP was unrelated to other M. sexta hemolymph proteins and lipoproteins. A quantitative lipid transfer assay measuring facilitated DAG exchange between isolated M. sexta lipoproteins was established. The level of LTP-catalyzed exchange of DAG increased linearly with increasing time and protein during the initial phase of the reaction. Inclusion of anti-LTP serum in the assay inhibited facilitated DAG exchange. Experiments designed to determine if the LTP holoprotein is required for transfer or if a component of LTP is the active principle were performed. Incubation of [3H]DAG labeled high density lipophorin with substrate amounts of LTP resulted in incorporation of labeled DAG into LTP. Subsequent incubation of [3H]DAG-labeled LTP with unlabeled lipophorin resulted in exchange of DAG and the appearance of labeled DAG in lipophorin. Nitrocellulose-bound LTP apoproteins did not facilitate DAG exchange, and pretreatment of LTP with detergents resulted in loss of transfer activity. Extraction of LTP lipids with ethanol/ether also resulted in loss of activity. The results suggest that the lipid component of LTP may be important in the transfer reaction.     

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.     

Trehalose, the insect blood sugar, inhibits loading of diacylglycerol by lipophorin from the fat body in locusts

Trehalose, the insect blood sugar, was found to inhibit diacylglycerol uptake by lipophorin from the fat body in vitro. Trehalose inhibited diacylglycerol uptake by about 40%-50% at various physiological concentrations. This suggests that trehalose may play a dual role in the hemolymph, i.e. serving as the insect's fuel and as a regulator in lipid transport.     

Characterization of cholesterol transport from midgut to fat body in Manduca sexta larvae

Using in vitro methods, we investigated the transfer of cholesterol from larval Manduca sexta midgut to the hemolymph lipoprotein, lipophorin, and the transfer of cholesterol from lipophorin to larval fat body. In the midgut, transfer of free cholesterol shows saturation kinetics, but the apparent Km is higher than the measured Kd for the midgut lipophorin-receptor complex. In addition, the transfer is unaffected by suramin, which binds to the receptor and inhibits lipophorin binding, and by antibodies to the lipid transfer particle, which is required for export of diacylglycerol from the midgut to lipophorin. In the fat body, transfer of free cholesterol also shows saturation kinetics, and the apparent Km is higher than the measured Kd for the fat body lipophorin-receptor complex. Suramin and anti-lipid transfer particle antibodies exert only a small (20%) inhibitory effect. In both tissues it seems that the most likely mode of cholesterol transfer is via aqueous diffusion, which is also an important mechanism in vertebrate cells. Based on these results, we propose that cholesterol homeostasis in larval M. sexta is maintained by a mass action mechanism in which cholesterol is freely transferred between lipophorin and tissues depending on the needs of the tissues. This simple mechanism is ideally suited to insects, which can neither make cholesterol nor internalize lipophorin, the two mechanisms that vertebrate cells use to control their cholesterol content.