The lipoprotein lipase of white adipose tissue. Changes in the adipocyte cell-surface content of enzyme in response to extracellular effectors in vitro.

An indirect labelled-second-antibody cellular immunoassay for adipocyte surface lipoprotein lipase was used to assess the changes that occurred during the incubation of cells in the presence and absence of effectors. In the absence of any specific effectors, the amount of immunodetectable lipoprotein lipase present at the surface of adipocytes remained constant throughout the 4 h incubation period at 37 degrees C. Under such conditions total cellular enzyme activity also remained constant, with no activity appearing in the medium. In the presence of heparin, cell-surface immunodetectable lipoprotein lipase increased by up to 20%, whereas in the presence of cycloheximide they decreased by up to 60%. Thus the obvious turnover of enzyme from this cell-surface site was found to be relatively rapid and dependent for its replenishment, at least in part, on protein synthesis. In the presence of insulin alone, a substantial increase in cell-surface lipoprotein lipase protein occurred, only part of which was dependent on protein synthesis. The total cellular activity of lipoprotein lipase was unaffected by the presence of insulin. The insulin-dependent increase in cell-surface enzyme was potentiated somewhat in the presence of dexamethasone, which was not shown to exert any independent effect. Glucagon, adrenaline and theophylline all produced a significant decline in the cell-surface immunodetectable lipoprotein lipase, which in the case examined (adrenaline) was partially additive with regard to the independent effect of cycloheximide. Cell-surface immunodetectable lipoprotein lipase amounts were decreased significantly when cells were incubated in the presence of either colchicine or tunicamycin. The concerted way in which cell-surface lipoprotein lipase altered during the incubations of adipocytes in the presence of effectors suggested that the translocation of enzyme to and from this cellular site was dependent on hormonal action and the integrity of intracellular protein-transport mechanisms.     

Effects of adrenaline on the turnover of lipoprotein lipase in rat adipose tissue

The mechanisms by which adrenaline brings about a reduction in the lipoprotein lipase activity of adipose tissue in vitro were investigated. The incorporation of [3H]leucine into lipoprotein lipase was measured during 1-h pulse incubations of rat epididymal fat bodies that had been preincubated for 4 h in the presence of glucose, insulin and dexamethasone. When adrenaline was added to the incubation medium at the start of the pulse, the incorporation of [3H]leucine was markedly reduced, suggesting that the rate of the enzyme's synthesis had decreased. On the other hand, the degradation of lipoprotein lipase, as measured by the loss of 3H-labelled enzyme protein during pulse-chase incubations of the epididymal fat bodies, was found to be significantly increased by the addition of adrenaline to the incubation medium at the start of the chase period. It is concluded that adrenaline is able both to inhibit the synthesis of lipoprotein lipase and to stimulate its degradation.     

Regulation of the synthesis of lipoprotein lipase in adipose tissue by dexamethasone

The incorporation of [3H]leucine into lipoprotein lipase during incubations of rat epididymal fat-bodies in vitro was significantly stimulated by dexamethasone, whereas total protein synthesis was unaffected. The stimulation by dexamethasone required the presence of insulin. The results suggest that dexamethasone, in the presence of insulin, may specifically induce lipoprotein lipase synthesis in adipose tissue.     

Lipoprotein lipase activity of rat cardiac muscle. Changes in the enzyme activity during incubations of isolated cardiac-muscle cells in vitro.

1. Isolated cardiac-muscle cells from the hearts of adult rats were shown to retain a high amount of viability during 4 h of incubation when viability was assessed by Trypan Bue stain exclusion and intracellular enzyme leakage. 2. The cells also retained their ability to take up O2 and utilize added substrates over the period of incubation at both 25 and 30 degrees C. 3. When cells from the hearts of fed rats were incubated in a buffered-salts solution at pH 7.4 in the presence of amino acids and heparin, lipoprotein lipase activity in the medium increased progressively. 4. During these incubations the intracellular activity of the enzyme remained constant and the total activity of lipoprotein lipase in the system (cells plus medium) increased by 80% over the 4 h of incubation at 25 degrees C. 5. In the absence of heparin only low amounts of enzyme activity were detectable in the medium and the total lipoprotein lipase activity in the system remained constant. 6. The measurement of lipoprotein lipase activity in either fresh homogenates of the cells or in homogenates of acetone/diethyl ether-dried powders of the cells had no effect on the overall pattern of activity change during the incubations, although as reported previously the total activity detected with acetone/diethyl either-dried preparations was approx. 3-fold higher than with fresh cell homogenates. 7. The observations were compared with published data on lipoprotein lipase activity changes in neonatal heart cell cultures maintained in vitro.     

Influence of some gastrointestinal hormones on adipose tissue lipoprotein lipase activity in vitro: Evidence of a stimulatory effect of pancreozymin and gastrin

At concentrations corresponding to the levels usually reported in the blood of different species in the fed state, gastrin and pancreozymin but not secretin and vasoactive intestinal peptide, stimulate the lipoprotein lipase activity of adipose tissue from fasted rats. The enzyme response to gastrin is, like that to insulin, dependent on the presence of glucose and is not additive with the enzyme response to insulin. On the contrary, the effect of pancreozymin on lipoprotein lipase is glucoseindependent and is additive with the enzyme response to insulin. Both the effects of gastrin and pancreozymin depend on protein synthesis as shown by their suppression by cycloheximide. With isolated fat cells, gastrin increases both the releasable and non-releasable lipase activities whereas pancreozymin increases almost exclusively the non-releasable activity. The mechanisms and the possible physiological significance of these findings are discussed in relationship with the influence of insulin and the nutritional state on adipose tissue lipoprotein lipase.     

The clearing-factor lipase activity of isolated fat-cells.

1. When fat-cells are isolated from the epididymal adipose tissue of 24h-starved rats and incubated at 25 degrees C in the presence of dialysed serum, glucose, insulin, amino acids and heparin, the total clearing-factor lipase acitivity of the incubation system increases progressively over a period of several hours. 2. All of the increase in activity is accounted for by the appearance of enzyme in the appearance of enzyme in the incubation medium and the fat-cell activity does not change significantly. Cycloheximids, at a concentration that prevents protein synthesis, does not affect the appearance of enzyme in the incubation medium, but the fat-cell enzyme activity is decreased in its presence. 3. The magnitude of the increase in total clearing factor lipase activity is unaffected by the omission of heparin from the medium. However, less enzyme is extracted in tis absence and the fat-cell activity increases. Cycloheximide again only affects the rise in cell activity and does not alter the activity in the incubation medium. 4. When serum in the incubation medium is replaced by casein, the distribution of enzyme between the cells and the medium is changed, but the magnitudes of the increases in total enzyme activity are similar. 5. These characteristics of the clearing-factor lipase response of isolated fat-cells differ in several respects from those observed earlier with intact adipose tissue from 24h-starved rats (Robinson & Wing, 1971; Cryer et al., 1973). The differences could be due, in part, to changes in the relative amounts of two different molecular forms of the enzyme that occur during the isolation of the fat-cells.     

Characterization of the lipoprotein lipase in the functional pool of rat heart by immunoblotting

Rat hearts were perfused with heparin for 2 min at 4 degrees C. The lipoprotein lipase activity in the perfusate was inhibited by antiserum to rat adipose tissue lipoprotein lipase. By immunoblotting, the lipoprotein lipase derived from the functional pool of the heart was found to be a protein with an apparent Mr of 69 000. After incubation of the perfusate at 37 degrees C for 24 h an immunologically reactive protein with an apparent Mr of 28 000 was found. This protein is not a physiological derivative of the enzyme but a degradation product.     

Characterization of two triacylglycerol lipase activities in pig post-heparin plasma.

Two triacylglycerol lipase activities were characterized after partial purification from pig post-heparin plasma. These two lipase activities were eluted sequentially with a NaCl gradient from columns containing Sepharose with covalently linked heparin. The first lipase activity, which was eluted at 0.75M-NaCl, was not inhibited at 28 degrees C in the presence of 1M-NaCl and was not further activated by plasma apolipoproteins. The absence of this lipase activity from post-heparin plasma from hepatectomized pigs indicates that the liver plays a role in the synthesis of this enzyme. A second lipase activity, which was eluted at 1.2M-NaCl, was inhibited when assayed in the presence of 1.0M-NaCl and was activated 14-fold by an apolipoprotein isolated from human very-low-density lipoprotein. The characteristics are identical with those of lipoprotein lipase purified from pig adipose tissue.     

Effects of glucose and insulin on the activation of lipoprotin lipase and on protein-synthesis in rat adipose tissue.

Glucose, and certain sugars that can readily be converted to glucose 6-phosphate, bring about an activation of adipose-tissue lipoprotein lipase when epididymal fat-bodies from starved rats are incubated in the presence of cycloheximide. Other substrates do not support the activation. If the tissue is preincubated in the presence of cycloheximide for longer than 2h, the ability of added glucose to activate the enzyme is lost. On the other hand, the addition of glucose still brings about an increase in lipoprotein lipase activity after preincubation in the absence of cycloheximide for as long as 4h. The magnitude of the increase in enzyme activity brought about by the addition of glucose is increased when protein synthesis is stimulated during the preincubation period by insulin. The results are interpreted in terms of the existence in adipose tissue of a proenzyme pool of lipoprotein lipase that is normally maintained by protein synthesis and that is converted to complete enzyme of higher specific activity by a process that specifically requires glucose.     

Regulation of lipoprotein lipase. Induction by insulin.

Lipoprotein lipase activity in intact epididymal adipose tissue of fasted rats increased rapidly after treatment with insulin in vivo. In contrast, lipoprotein lipase activity in adipocytes isolated from the contralateral fat pads remained essentially unchanged. When adipocytes were incubated for 30 min at ambient temperature in vitro, about 2 times more lipoprotein lipase activity was found in the medium of cells from insulin-treated rats than in medium from cells of control animals. Following insulin treatment, extracts of tissue acetone powders separated by gel chromatography showed increases in both enzyme activity fractions obtained (designated lipoprotein lipase a and b). However, no consistent differences were observed between fractions derived from adipocyte acetone powders of insulin-treated and control animals. All the observed effects of insulin on lipoprotein lipase activity were abolished by cycloheximide treatment in vivo. These data indicate that following insulin treatment, increased lipoprotein lipase activity in adipose tissue results from enhanced enzyme secretion by the fat cell and subsequent accumulation in the tissue, thus implicating the adipocyte secretory mechanism as a major site of regulation of lipoprotein lipase activity in adipose tissue.     

The rabbit as an animal model of hepatic lipase deficiency

A natural deficiency of hepatic lipase in rabbits has been exploited to gain insights into the physiological role of this enzyme in the metabolism of plasma lipoproteins. A comparison of human and rabbit lipoproteins revealed obvious species differences in both low-density lipoproteins (LDL) and high-density lipoproteins (HDL), with the rabbit lipoproteins being relatively enlarged, enriched in triacylglycerol and depleted of cholesteryl ester. To test whether these differences related to the low level of hepatic lipase in rabbits, whole plasma or the total lipoprotein fraction from rabbits was either kept at 4 degrees C or incubated at 37 degrees C for 7 h in (i) the absence of lipase, (ii) the presence of hepatic lipase and (iii) the presence of lipoprotein lipase. Following incubation, the lipoproteins were recovered and subjected to gel permeation chromatography to determine the distribution of lipoprotein components across the entire lipoprotein spectrum. An aliquot of the lipoproteins was subjected also to gradient gel electrophoresis to determine the particle size distribution of the LDL and HDL. Both hepatic lipase and lipoprotein lipase hydrolysed lipoprotein triacylglycerol and to a much lesser extent, also phospholipid. There were, however, obvious differences between the enzymes in terms of substrate specificity. In incubations containing hepatic lipase, there was a preferential hydrolysis of HDL triacylglycerol and a lesser hydrolysis of VLDL triacylglycerol. By contrast, lipoprotein lipase acted primarily on VLDL triacylglycerol. When more enzyme was added, both lipases also acted on LDL triacylglycerol, but in no experiment did lipoprotein lipase hydrolyse the triacylglycerol in HDL. Coincident with the hepatic lipase-induced hydrolysis of LDL and HDL triacylglycerol, there were marked reductions in the particle size of both lipoprotein fractions, which were now comparable to those of human LDL and HDL3, respectively.     

Modulation by phenobarbital of the differentiation of 3T3 preadipocytes

The effect of phenobarbital upon the differentiation of two preadipocyte cell lines, 3T3 F442A and 3T3 L-1, was examined by measuring the synthesis and secretion of lipoprotein lipase. Extracellular enzyme was measured by treating intact cells with heparin, and the intracellular enzyme was subsequently assayed in cell homogenates. When confluent cultures of 3T3 F442A cells were treated with insulin, the cells underwent differentiation as indicated by increased activity of lipoprotein lipase within 6 days, followed in turn by increased levels of protein and triglyceride. Addition of phenobarbital with insulin enhanced total lipoprotein lipase, protein, and triglyceride content. The activity of lipoprotein lipase accumulated in the heparin-releasable fraction during differentiation was increased 2- to 3-fold and the intracellular enzyme was enhanced 15- to 20-fold by the addition of phenobarbital. The ability of phenobarbital to modulate differentiation was dependent upon the time of addition. When added early in the postconfluent period, there was a greater increase in lipoprotein lipase activity than when the drug was added at later times. Phenobarbital also stimulated lipoprotein lipase in differentiating 3T3 L-1 cells in the presence of insulin, although lipoprotein lipase activity was moderately enhanced by phenobarbital alone in these cells. These results suggest that phenobarbital may affect the conversion of adipoblasts into preadipocytes and thereby increase the proportion of cells susceptible to the differentiating stimulus.     

Secretion and degradation of lipoprotein lipase in cultured adipocytes. Binding of lipoprotein lipase to membrane heparan sulfate proteoglycans is necessary for degradation

Equilibrium-binding data of highly purified 125I-labeled avian lipoprotein lipase to cultured avian adipocytes demonstrate the presence of a class of high affinity binding sites. Analysis of the binding function yielded an association constant of 0.62 x 10(8)M-1 and a maximum binding capacity of 2.1 micrograms/60-mm dish. From a time course of dissociation of 125I-lipoprotein lipase from adipocytes at 4 degrees C, a dissociation rate constant of 6.1 x 10(-5)s-1 was obtained. Pretreatment of cells with heparinase and heparitinase resulted in a quantitative suppression of the high affinity binding component, establishing that lipoprotein lipase is bound to cell surface heparan sulfate proteoglycans. At 37 degrees C, cell surface-bound 125I-lipoprotein lipase is internalized and either degraded or recycled to the medium. The degradation rate constant for 125I-lipoprotein lipase was estimated to be 0.78 h-1. The degradation rate constant was reduced 6-fold when cells were exposed to 100 microM chloroquine, indicating that most of the degradation occurs within the lysosomal compartment. By using cells that had been pulsed with Trans35S-label for 1 h, it was demonstrated that acute treatment with endoglycosidases for up to 1 h resulted in a new lipoprotein lipase secretion rate which was 6-fold higher than that of control cells. Degradation of newly synthesized lipoprotein lipase was essentially blocked 30 min after the initiation of the chase. In other studies it was observed that there were no additive effects of chloroquine and either endoglycosidase or heparin treatment on total lipoprotein lipase levels (intracellular, cell surface, and medium) in adipocyte cultures. These experiments support the hypothesis that the release of lipoprotein lipase from its receptor prevents its internalization and degradation and enhances enzyme efflux from the adipocyte. A new model of lipoprotein lipase secretion in cultured adipocytes is proposed: Newly synthesized lipoprotein lipase is transported to the cell surface where it binds to specific heparan sulfate proteoglycan receptors. The enzyme is either released to the medium or internalized via the receptor, in which case the enzyme is degraded or recycled to the cell surface. Major determinants of enzyme efflux from the cell surface include the number and integrity of receptors, the association constant of the enzyme-receptor complex, and the presence in the medium of competing molecules with high affinity for lipoprotein lipase. In this model, modulation of lipoprotein lipase degradation rate may be a significant mechanism for acute regulation of enzyme efflux independent of changes in the rate of enzyme synthesis.     

Rapid preparation of a relatively stable, partially purified lipoprotein lipase from perfused rat heart

Rat hearts, extensively washed with cold 0.15 M NaCl solution, were perfused with 5 ml of 0.15 M NaCl containing 16 U of heparin and 10% glycerol to release endothelium-bound lipoprotein lipase. Approximately 100 mU of enzyme activity could be released from each heart (weighing about 1.7 g). Several hearts could be sequentially perfused with the same heparin solution to enrich it in lipase activity. When compared with other equally rapid and frequently used sources of rat lipoprotein lipase (such as heart acetone powder or postheparin plasma), our enzyme preparation had a much higher specific activity suggesting that a greater purification level had been already achieved in a single step. In addition, this lipoprotein lipase preparation contained only trace amounts of lipids, was stable for an hour at 37 degrees C and retained 75% of its activity after 10 days at 4 degrees C. The described procedure is a quick way to prepare a soluble, partially purified and relatively stable lipoprotein lipase that may be useful especially for the in vitro preparation of triacylglycerol-rich lipoprotein remnants.     

Cachectin/tumor necrosis factor decreases human adipose tissue lipoprotein lipase mRNA levels, synthesis, and activity

The effects of the cytokine cachectin/tumor necrosis factor (TNF) on human adipose tissue lipoprotein lipase (LPL) were studied. TNF is produced by activated macrophages and is thought to play a role in mediating hypertriglyceridemia and wasting of adipose tissue triglyceride stores (cachexia) that often accompany infection and malignancy. TNF effects were studied in human adipose tissue fragments maintained in organ culture in the presence of insulin and dexamethasone to induce high LPL activity. Addition of TNF to the culture medium for 20 h caused a dose-dependent inhibition of LPL activity to an average of 37% of controls at 50 U/ml TNF. This inhibition of LPL activity was explained by specific decreases in levels of LPL mRNA (to 40% of controls) and rates of LPL synthesis determined by biosynthetic labeling and immunoprecipitation (to 32% of controls). The decline in LPL synthesis was specific, as it occurred despite a small increase in overall protein synthesis in the presence of TNF. Comparable decreases in LPL activity were observed when TNF was added to adipose tissue cultured solely in the presence of insulin. Thus, similar to results in rodent models, TNF is a potent inhibitor of LPL gene expression in human adipose tissue. TNF may therefore play a role in the disorders of triglyceride catabolism and the pathogenesis of cachexia that occur with stimulation of the immune system in humans.     

Studies of lipoprotein lipase during the adipose conversion of 3T3 cells.

Lipoprotein lipase activity is negligible in exponentially growing 3T3-L1 cells and 3T3-F442A cells, but develops in both lines when they reach a confluent state and undergo adipose conversion. 3T3-C2 cells, which undergo adipose conversion with extremely low frequency, do not develop the enzyme. The lipase activity of 3T3-L1 and 3T3-F442A is greatly enhanced by insulin and increases 80–180 fold during the adipose conversion. The lipase has the following characteristics in common with lipoprotein lipase from adipose and other tissues: it is dependent upon serum, is inhibited by 0.5–1.0 M sodium chloride, is recovered from acetone powders, has an alkaline pH optimum and is released from the cells by heparin. Like the lipoprotein lipase of tissue adipose cells, the enzyme of 3T3-L1 decays in the presence of cycloheximide with a half-time of about 25 min at 37°C.The ability of 3T3-F442A and 3T3-L1 to take up triglyceride from the medium depends almost completely upon lipoprotein lipase. They incorporate the fatty acids of a large fraction of a triglyceride emulsion added to the medium, and this utilization is stimulated by heparin. Very little of the glycerol portion of the triglyceride is incorporated. 3T3-C2, which lacks lipoprotein lipase, utilizes very little of either the fatty acid or the glycerol portion of triglyceride.The relevance of external lipid or lipoprotein to both the adipose conversion and the appearance of lipoprotein lipase was tested using confluent cultures in medium depleted of these components. In the presence of serum whose lipoproteins have been removed by flotation, lines 3T3-F442A and 3T3-L1 undergo adipose conversion as completely as in the presence of untreated serum, and lipoprotein lipase activity appears at essentially the same rate. In medium whose serum supplement has been extracted with acetone:ethanol, 3T3-F442A cells undergo adipose conversion to nearly the same extent as in untreated serum, and develop nearly the same increase in lipoprotein lipase activity.Unless even very low concentrations of lipids or lipoprotein are saturating it can be concluded that the adipose conversion does not depend upon external lipids or lipoproteins for its induction; rather the differentiation program is built into the cell type and comes into operation when growth is arrested even in their absence. The source of fatty acids utilized for triglyceride synthesis, however, may be affected by the amount of lipid provided to the cells.     

Lipolytic activity of whole isolated liver cells in aqueous suspension.

1. Liver contains a lipase which catalyzes in vitro the hydrolysis of esters of short-chain normal primary alcohols and fatty acids. It is shown that this enzymatic activity can be measured by using intact liver cells as source of enzyme. During short-term incubations of suspensions of cells isolated from rat liver, the lipase acts as a membrane-bound enzyme and readily attacks [3H] oleoylethanol added as an emulsion into the bathing medium. The lipolytic reaction proceeds linearly for at least 20 min at 37 degrees C, at the pH optimum of 8.5. [3H] Oleic acid, a reaction product, is mostly retained in the medium and is used to monitor the lipolytic process. 2. In the presence of heparin, the bound lipase is released in the medium in amounts representing one-third to one half the total activity contained in the cells. This release is very rapid and associated in all cases with a concomitant release of lactate dehydrogenase activity. Such effects are consistent with the interpretation that heparin, at concentrations comprised between 10 and 100 mug per ml, causes alterations of the plasma membrane of the isolated cells, resulting in the dispersion of membrane-bound and cytoplasmtic material. This action of heparin is totally blocked by protamine sulfate (1 mg/ml). No specific effect of heparin directed towards the selective release of lipase could be demonstrated under these conditions. 3. During incubations in the presence of heparin, it was observed that the release of monoester lipase was quantitatively related to a simultaneous decrease in membrane-bound as well as in total monoester lipase activity measureable in the cells after homogenization. This, along with the reappearance of membrane-bound activity immediately after heparin withdrawal, suggest that under the experimental conditions, the membrane-bound enzyme is replaced from inside the cell in proportion of its release by heparin.     

Colchicine inhibition of the heparin-stimulated release of clearing-factor lipase from isolated fat-cells.

When isolated fat-cells are incubated at 25 degrees C in serum-based media containing glucose, insulin and heparin, the rise that occurs in the clearing-factor lipase activity of the incubation medium is inhibited by colchicine. The rise in the fat-cell clearing-factor lipase activity that occurs during similar incubations in the absence of heparin is not affected by colchicine.     

Lipoprotein lipase in human milk: compartmentalization and effect of fasting, insulin, and glucose

The object of this study was to investigate the effect of maternal metabolic state on the activity of lipoprotein lipase (LPL) in human milk. Although the total LPL activity in milk was not significantly affected by up to three cycles of freezing and thawing, the amount of LPL associated with the cream fraction of the milk increased from an average of less than 10% to about 70% after this treatment. The enzyme was relatively stable when the milk was stored on ice, losing activity at a rate of about 1% per hour. At 37 degrees C degradation was more rapid, about 7% per hour. When LPL activity was measured in samples taken at hourly intervals by breast pump, using oxytocin to achieve a complete letdown at each pumping, activity was found to double from the first to the third pumping. Thereafter the activity was stable under fasting conditions. Hyperglycemic and euglycemic, hyperinsulinemic glucose clamp protocols were used to evaluate the effects of glucose and insulin. Both high plasma glucose and high plasma insulin in the presence of normal glucose significantly increased LPL activity within 4 hours. We conclude that, like adipose, tissue LPL, mammary LPL is regulated by plasma insulin.     

Effects of heparin-induced lipolytic activity on the structure of rat high-density lipoprotein

Following its secretion into the plasma compartment, the high-density lipoprotein (HDL) is presumed to be acted upon by both soluble enzymes, such as lecithin:cholesterol acyltransferase (LCAT), and membrane-associated enzymes, such as lipoprotein lipase and hepatic lipase. Rats were injected intravenously with heparin to release membrane-associated lipolytic activities into the circulation and the collected plasma was incubated overnight at 37 degrees C in the presence or absence of an LCAT inhibitor or an inhibitor of lipoprotein lipase (1 M NaCl). It was observed that lipoprotein lipase accounted for most of the triglyceride hydrolase activity in the heparin-treated plasma, and that the heparin-releasable activities caused an increase in HDL density but no measurable change in particle size when LCAT was inhibited. Heparin treatment caused about a 60% decrease in plasma triacylglycerol during the interval between injection of heparin and blood collection. Although this caused marked compositional changes in the d less than 1.063 g/ml lipoproteins, no changes were observed in the lipid composition or apoprotein distribution in the HDL. Subsequent incubation for 18 h at 37 degrees C produced marked increases in the apoE content of HDL from heparin-treated plasma even when LCAT was inhibited. Time-course studies showed that in the presence of an LCAT inhibitor there was considerable conversion of phosphatidylcholine to lysophosphatidylcholine in heparin-treated plasma, and that this activity was diminished by 1 M NaCl, but that no phospholipolysis was observed in control plasma. By contrast, both heparin-treated and control plasma possessed substantial triglyceride hydrolase activity. The concurrent action of lipases and LCAT was observed to reduce the maximum level of cholesterol esterification which could be achieved in the absence of lipase activity. It is concluded that changes in HDL particle size are mainly attributable to LCAT, but that lipase activities, which are either free in rat plasma or releasable by heparin, play a role in restructuring the phospholipid moiety and altering the protein composition of the HDL, especially with respect to apoE, a potential ligand to cellular receptors.