Synthesis of inactive nonsecretable high mannose-type lipoprotein lipase by cultured brown adipocytes of combined lipase-deficient cld/cld mice.

Combined lipase deficiency (cld) is a recessive mutation which causes a severe deficiency of lipoprotein lipase and hepatic lipase activities and lethal hypertriacylglycerolemia within 3 days in newborn mice. The effect of this genetic defect on lipoprotein lipase was studied in primary cultures of brown adipocytes derived from tissue of newborn mice. Cells cultured from cld/cld mice replicated, accumulated triacylglycerol, and differentiated into adipocytes at normal rates. Lipoprotein lipase activity in unaffected cells was detectable on Day 0 of confluence and increased to 1.3 units/mg DNA by Day 6, while that in cld/cld cells was less than 4% of that in unaffected cells on Days 4-6. Unaffected cells released 1.2% of their lipase activity in 30 min in the absence of heparin, and 11% in 10 min in the presence of heparin, whereas cld/cld cells released no lipase activity. cld/cld cells contained 2-3 times as much lipoprotein lipase protein as unaffected cells, and released no lipase protein to the medium. Immunofluorescent lipoprotein lipase was not detectable in unaffected adipocytes unless lipase secretion was blocked with monesin, causing retention of the lipase in Golgi. cld/cld adipocytes, in contrast, contained immunofluorescent lipoprotein lipase distributed in a diffuse reticular pattern, indicating retention of lipase in endoplasmic reticulum. Lipoprotein lipase immunoprecipitated from cells incubated 1-3 h with [35S]methionine was digested with or without endoglycosidase H (endo H) or F, and resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Lipoprotein lipase in unaffected cells (Mr = 56,000-58,000) consisted of three glycosylated forms, of which the most prevalent was endo H-resistant, the next was totally endo H-sensitive, and the least was partially endo H-sensitive. In contrast, lipoprotein lipase in cld/cld cells (Mr = 56,000) consisted of a single, totally endo H-sensitive form. Lipoprotein lipase in both groups of cells contained two oligosaccharide chains. Chromatography studies with heparin-Sepharose indicated that at least some of the lipoprotein lipase in cld/cld cells was dimerized. The findings demonstrate that brown adipocytes cultured from cld/cld mice synthesize lipoprotein lipase with two high mannose oligosaccharide chains, but it is inactive and retained in endoplasmic reticulum. Whether the cld mutation affects primarily processing of oligosaccharide chains of lipoprotein lipase in endoplasmic reticulum, transport of the lipase from the reticulum, or some other process, is to be resolved.

Multiple interactions of unsaturated fatty acids with opiate and ouabain binding sites and beta-adrenergic sensitive adenylate cyclase system.

The unsaturated fatty acids oleic, linoleic and arachidonic inhibited binding of ligands to the ouabain, opiate, and beta-adrenergic plasma membrane receptors. Low concentrations of fatty acids slightly increased the binding of ouabain to its binding sites. The effect of these fatty acids on beta-adrenergic sensitive adenylate cyclase was more complex. 0.2-0.3 mM fatty acids increased adenylate cyclase activity, while higher concentrations of arachidonic and linoleic acids, but not oleic acid, inhibited basal, beta-agonist- and NaF-stimulated activities in membranes of A431 and C6 cells. To evaluate which aspects of the unsaturated fatty acid molecules might be responsible for the observed effects, myristic acid, monoolein and taurodeoxycholic acid were studied. They also inhibited binding to the opiate receptor. Myristic acid, did not inhibit ouabain binding, binding to beta-receptor, nor adenylate cyclase activity. Monoolein, had no inhibitory effect on ouabain binding but behaved similar to oleic acid in the beta-receptor/adenylate cyclase system. Taurodeoxycholic acid inhibited binding to all three receptors as well as adenylate cyclase activity. We conclude that the effects of unsaturated fatty acids on ligand binding and adenylate cyclase activity are the result of their multiple interactions with various molecular processes rather than any unique property of long chain unsaturated fatty acids, per se.

Restricted passage of insulin across capillary endothelium in perfused rat adipose tissue.

Passage of insulin across capillary endothelium was monitored in perfused rat parametrial adipose tissue by the effect of intra-arterially infused insulin on oxidation of [U-14C]glucose to CO2. Glucose oxidation was constant at 34 nmol C.g-1.min-1 for 90 min in tissues perfused with 0 or 50 microU/ml. The rate of oxidation was doubled in 90 min at 100 microU/ml and maximal (4 X control) in 40 min at 200 microU/ml and in 20-30 min at 500 microU/ml. The slow decline in oxidation rate when insulin infusion was stopped suggested that insulin was sequestered in the tissue. Although half-maximal response to insulin occurred in perfused tissues at 100 microU/ml, it occurred at 8 microU/ml in incubated adipocytes and at 30 microU/ml in incubated tissue. In addition, the time required for maximal response to insulin was longer in perfused adipose tissue than in incubated cells and tissues. The data indicate that transfer of insulin from blood to parenchymal cells in perfused tissue was restricted. The minimal amount of insulin needed for a response by adipocytes in perfused tissue was estimated to be less than 1% of that in blood. Our findings are consistent with the concept that insulin is transferred across capillary endothelium by a receptor-mediated process.

Effect of heparin on membrane associated clathrin basketwork of cultured cells derived from the stromal-vascular fraction of mouse brown adipose tissue.

The effect of heparin treatment on clathrin basketwork of cell membranes was examined in cultured cells derived from the stromal-vascular fraction of neonatal mouse brown adipose tissue. The cytoplasmic surface of the plasma membrane of ruptured cells was examined with surface replicas. Heparin treatment significantly decreased the extent of clathrin basketwork associated with the membrane from 3.4 to 0.2%. The loss of clathrin basketwork suggests that heparin treatment of these cells affected intracellular sorting processes associated with endocytosis.

Synthesis and secretion of lipoprotein lipase in 3T3-L1 adipocytes. Demonstration of inactive forms of lipase in cells.

3T3-L1 adipocytes in culture incorporated [35S]methionine into a protein which could be immunoprecipitated with chicken antiserum to bovine lipoprotein lipase. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed this protein had an Mr of 55,000, similar to that of bovine lipoprotein lipase, and accounted for 0.1-0.5% of total protein synthesis in the adipocytes. Lipoprotein lipase protein was present in small amounts in confluent 3T3-L1 fibroblasts, and the amount increased many-fold as the cells differentiated into adipocytes. This increase was accompanied by parallel increases in cellular lipase activity and secretion. When cells were grown with [35S]methionine, the amount of label incorporated into lipoprotein lipase increased for 2 h and then leveled off. Pulse-chase experiments showed that half-life of newly synthesized lipase was about 1 h. Turnover of lipoprotein lipase in control cells involved both release to the medium and intracellular degradation. When N-linked glycosylation was blocked by tunicamycin, the cells synthesized a form of lipase that had a smaller Mr (48,000), was catalytically inactive, and was not released to the medium. Radioimmunoassay demonstrated that 3T3-L1 adipocytes contained an unexpectedly large amount of lipoprotein lipase protein. 55% of the enzyme protein in acetone/ether powder of the cells was insoluble in 50 mM NH3/NH4Cl at pH 8.1, a solution commonly used to extract lipoprotein lipase; 27% of the lipase protein was soluble but did not bind to heparin-Sepharose and had very low lipase activity; and the remaining 13% was soluble, bound to heparin-Sepharose, and had high lipolytic activity. About one-half of the lipase released spontaneously to the medium was inactive, and lipase inactivation proceeded in the medium with little loss of enzyme protein. Lipoprotein lipase released heparin, in contrast, was fully active and more stable. When protein synthesis was blocked by cycloheximide, the level of lipoprotein lipase activity in adipocytes decreased more rapidly than the amount of lipase protein in the cells. Most of the inactive lipoprotein lipase in adipocytes probably results from dissociation of active dimeric lipase, but some could be a precursor of active enzyme.

The ouabain receptor in animal tissues and its endogenous ligand.

Cardiac glycosides bind to the Na+,K+-ATPase and inhibit its activity. Low concentrations (less than 10(-7) M) of ouabain stimulate the activity of Na+,K+-ATPase in whole homogenates of rat brain. The magnitude of this stimulation varies from 5 to 70%. The concentration of ouabain which induces maximal stimulation is also highly variable and ranges between 10(-9) to 10(-7) M. This stimulation may be explained by the presence of an endogenous ouabain-like compound (OLC) in the brain homogenate. Mammalian tissues and body fluids including brain, heart, kidney, plasma, urine and cerebrospinal fluid contain a unidentified OLC. An endogenous OLC was also demonstrated in toad skin and plasma. This compound was purified to homogeneity and identified using UV, NMR and Mass spectroscopies to be 3-hydroxy-14, 15-epoxy-20,22-dienolide glycoside (resibufogenin). Several reports have suggested that unsaturated fatty acids are the ouabain-like regulators of the Na+,K+-ATPase. Furthermore, Saline infusion to WKY rats, which was shown to increase OLC in the plasma causes also an elevation of free fatty acids. Thus, the interaction of fatty acids with several plasma membrane components was studied. Ouabain binding, opiate binding and binding to the beta-adrenergic receptor were all inhibited by micromolar concentrations of the unsaturated fatty acids, linoleic, oleic and arachidonic. Binding to the opiate receptor was inhibited with IC50 of 40-90 microM and binding to beta-adrenergic receptor with IC50 of 350-450 microM.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of the combined lipase deficiency mutation (cld/cld) on ultrastructure of tissues in mice. Diaphragm, heart, brown adipose tissue, lung, and liver.

Lipoprotein lipase and hepatic lipase activities are very low in tissues of mice born with genetic combined lipase deficiency (cld/cld). Consequently, if allowed to suckle, the mice develop severe hyperlipemia and die within 3 days. The ultrastructure of capillaries and parenchymal cells in tissues that normally contain lipoprotein lipase and hepatic lipase was studied in tissues from cld/cld and unaffected mice 6 to 24 hours of age. Capillaries in tissues from suckled cld/cld mice were packed with numerous abnormally shaped chylomicrons. There was close contact between surfaces of chylomicrons and the luminal plasma membrane of endothelium. Chylomicrons were sometimes found between endothelial cells and in the subendothelial space in heart, lung, and liver, and in the lumen of lung alveoli. In contrast, capillaries of suckled unaffected mice contained very few chylomicrons, and the subendothelial spaces and lung alveoli were free of chylomicrons. Myocytes of diaphragm and heart from suckled cld/cld mice did not contain lipid droplets, whereas brown adipocytes contained a few small droplets. Parenchymal cells in diaphragm, heart, brown adipose tissue, and lung from suckled unaffected mice contained numerous large lipid droplets. Hepatocytes of suckled cld/cld mice contained small irregularly shaped lipoprotein particles (100 A) in endoplasmic reticulum and Golgi, numerous large lysosomes containing small lipoprotein particles, lipid spheres and lamellar structures, and no intracellular lipid droplets, whereas hepatocytes of suckled unaffected mice contained larger lipoprotein particles (400 A), large lipid droplets, and very few lysosomes. Triacylglycerol of chylomicrons from cld/cld mice was readily hydrolyzed by bovine lipoprotein lipase in vitro, and this effect was not augmented by heat-inactivated serum, indicating that the chylomicrons contained adequate amounts of apoprotein C-II. Thus, the large amount of chylomicrons in capillaries and small amount of lipid droplets in cells of suckled cld/cld mice reflect the very low level of lipoprotein lipase activity in these animals. The findings in hepatocytes indicate that lipoprotein metabolism in liver is markedly disturbed in cld/cld mice.

Effect of combined lipase deficiency (cld/cld) on hepatic and lipoprotein lipase activities in liver and plasma of newborn mice.

Combined lipase deficiency (cld/cld) is a recessive mutation in mice which results in massive hyperlipemia and death within 3 days after birth. We studied the effect of this deficiency on lipolytic activities in liver and in pre- and postheparin plasma of mice less than 2 days old. Anti-hepatic lipase serum inhibited more than 85% of the lipolytic activity in liver and plasma of normal newborn mice when assayed in high-salt medium, validating the use of this medium for measuring hepatic lipase activity in mice. Anti-lipoprotein lipase serum, in contrast, inhibited only two-thirds of the lipolytic activity in liver and plasma when assayed in serum low-salt medium, and anti-hepatic lipase serum inhibited the rest. This indicates that assay with serum low-salt medium alone is not specific for lipoprotein lipase activity in mice. Therefore, immunoinhibition was used, as needed, for measuring lipoprotein lipase activity. The livers of unaffected newborn mice contained high levels of both hepatic and lipoprotein lipase activities, 228 and 187 mU/g, respectively. The plasma of unaffected mice contained a high level of hepatic lipase activity, 244 mU/ml, but practically no lipoprotein lipase activity. Heparin injected intraperitoneally increased plasma lipoprotein lipase activity to 152 mU/ml, but had no effect on plasma hepatic lipase activity, in unaffected mice. Hepatic lipase activity was virtually absent from both liver and plasma of cld/cld mice. Lipoprotein lipase activity was present in the liver at a surprisingly high level, 40% of that in normals, but was barely detectable in plasma. Heparin injection increased plasma lipoprotein lipase activity in cld/cld mice, but the increment was less than 10% of that in unaffected mice. Heparin had no significant effect on plasma hepatic lipase activity in defective mice. These findings confirm preliminary observations that hepatic lipase activity in liver and plasma and lipoprotein lipase activity in plasma are markedly reduced in combined lipase deficiency. The unexpected high level of lipoprotein lipase activity in liver of cld/cld mice suggests that regulation of lipoprotein lipase activity in liver of neonatal mice is different from that in other tissues.

Effect of epinephrine and other lipolytic agents on intracellular lipolysis and lipoprotein lipase activity in 3T3-L1 adipocytes.

3T3-L1 adipocytes were used to test the hypothesis that hormone-sensitive lipolysis and lipoprotein lipase activity might be regulated in a reciprocal manner. Intracellular lipolysis was stimulated by catecholamine, dibutyryl cAMP, and ACTH, but not by glucagon. The effects of epinephrine on lipolysis were blocked by the beta-antagonist propanolol but not by the alpha-antagonist phentolamine. Hormone-stimulated lipolysis was not changed by acute (45 min) or chronic (2 days) treatment of the cells with insulin whereas the latter treatment augmented lipoprotein lipase activity about fivefold. Epinephrine did not affect the lipoprotein lipase activity of insulin-stimulated cells. Withdrawal of glucose from the medium decreased lipoprotein lipase activity and the effect of epinephrine on lipolysis. Effects of lipolytic agents on activity of lipoprotein lipase were variable and concentration-dependent. Lipoprotein lipase activity was decreased only by concentrations of epinephrine greater than those inducing maximal intracellular lipolysis, and the decrease in activity occurred about 30 min after the increase in glycerol release. There seems to be no relationship between the level of activity of lipoprotein lipase and the maximal rate of hormone-stimulated lipolysis in 3T3-L1 cells. Unlike in adipose tissue and adipocytes of rats, hormone-stimulated lipolysis and lipoprotein lipase activity in murine 3T3-L1 adipocytes appear to be regulated independently.

Lipolysis of serum-activated triacylglycerol at the surface of J774.1 macrophages. A biochemical--electron-microscopic study.

Cultured mouse (J774.1) macrophages accumulated triacylglycerol, but no cholesteryl ester or cholesterol, when incubated in albumin-poor medium with serum-activated lipid particles containing 84 mol% trioleoylglycerol and 9 mol% cholesteryl oleate. Accumulation of triacylglycerol by cells was associated with hydrolysis of particulate triacylglycerol to fatty acid and glycerol. Both acyl and glyceryl moieties of particulate triacylglycerol were recovered in cellular triacylglycerol with a molar ratio of 3.6. The cells also accumulated fatty acid and monoacylglycerol. Whether acylglycerol was taken up as a single molecular species, such as monoacylglycerol, or as several species can not be determined by the present findings. Macrophages incubated with lipid particles for 24 h had many lipid particles attached to cell surfaces and numerous intracellular lipid droplets. The surface film of attached particles was continuous with the outer leaflet of plasma membrane of the cells. Particles partially depleted of core triacylglycerol and collapsed surface films were found attached to surfaces of macrophages. There was no morphological evidence that lipid particles were taken up intact by cells, through endocytosis or phagocytosis. Macrophages incubated with lipid particles also contained intracellular lamellar structures. They varied in size and shape, and were located in the periphery of cells, sometimes near lipid droplets and endoplasmic reticulum. Only 3% of the lamellar structures were associated with lysosomes, indicating they probably were not of lysosomal origin. Lipid particles attached to cells decreased in size and number, and lamellar structures developed at the surface of particles, or replaced the particles, when glutaraldehyde-fixed specimens were incubated at 25 degrees C, demonstrating lipolytic activity at the surface of macrophages. Our findings suggest that particulate triacylglycerol was hydrolyzed by lipoprotein lipase at the surface of macrophages, and that fatty acid and monoacylglycerol formed by lipolysis were transported directly into the cells to be reesterified. When lipolytic products were taken up faster than they could be utilized, they accumulated as lamellar structures in the cells.

Effect of pH on visualization of fatty acids as myelin figures in mouse adipose tissue by freeze-fracture electron microscopy.

We studied the effect of pH on visualization of fatty acids as myelin figures in young mouse epididymal adipose tissue. Fatty acid content of the tissue was increased to 12.4 nmol/mg wet weight by treating the tissue with 380 microM isoproterenol at pH 7.4 for 15 min in the absence of glucose and albumin. Myelin figures were found in freeze-fracture replicas of isoproterenol-treated tissue fixed with glutaraldehyde at pH 7.4 and then incubated and glycerinated at pH 8.1. Myelin figures were seen in replicas as concave or convex laminated sheets and long cylindrical multilamellar structures in fat cells and extracellular space. Myelin figures were sometimes seen in cells extending from the surface of intracellular lipid droplets, the site of lipolysis, to the cell surface and extracellular space. Myelin figures were not found in isoproterenol-treated tissue fixed at pH 7.4 and processed at pH 7.0. Smooth-surfaced droplets, instead, were found in these tissues in the extracellular space. Neither myelin figures nor smooth-surfaced droplets were found in tissues treated with insulin and glucose (to reduce fatty acid content to 1.4 nmol/mg), fixed at pH 7.4 and processed at either pH 8.1 or pH 7.0. Lowering pH of the media to 4.5 during processing of tissues treated with isoproterenol at pH 9.0 caused disappearance of myelin figures and appearance of smooth-surfaced droplets in the extracellular space. Myelin figures were found in replicas of tissue treated with isoproterenol for 15 min at pH 7.4, incubated 10 min at pH 8.4, quick-frozen and then freeze-fractured, indicating that formation of myelin figures was not dependent on glutaraldehyde fixation and glycerol infiltration of the tissue. Our findings show that excess fatty acids in adipose tissue can be visualized as myelin figures if the tissue is exposed to pH 8.1-9.0 and maintained at or above pH 7.4, or as smooth-surfaced droplets if the tissue is processed at pH 7.0 or 4.5. We conclude that myelin figures formed under these conditions are composed primarily of partially ionized fatty acids (acid-soaps), and that the smooth-surfaced droplets in the extracellular space are composed of un-ionized (protonated) fatty acids.

Combined lipase deficiency (cld/cld) in mice. Demonstration that an inactive form of lipoprotein lipase is synthesized.

Combined lipase deficiency, cld, is a recessive mutation within the T/t complex of mouse chromosome 17. Mice homozygous for this defect display severe functional deficiencies of lipoprotein lipase and the related hepatic lipase. They develop massive hyperchylomicronemia and die within 3 days when allowed to suckle. Heart, diaphragm muscle, and brown adipose tissue of 1-day-old cld/cld and unaffected mice incorporated in vivo [35S]methionine into a protein that could be immunoprecipitated by antilipoprotein lipase serum. The immunoprecipitated protein in all tissues had the same Mr as bovine lipoprotein lipase as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The proportion of radioactivity in the lipoprotein lipase band to that in total protein was 0.02% in tissues of cld/cld mice and 0.01% in tissues of unaffected mice. There was 2-6 times more lipoprotein lipase-like protein (determined by immunoassay) in tissues of defective mice than in those of unaffected mice. These findings indicate that the cld mutation did not cause deletion of the structural gene for lipoprotein lipase. Lipoprotein lipase activity in heart, diaphragm muscle, brown adipose tissue, and lung of cld/cld mice was less than 5% of that in tissues of unaffected mice. This low activity could be inhibited more than 85% by antilipoprotein lipase serum, but not by nonimmune serum. It is concluded that tissues in cld/cld mice synthesize a lipoprotein lipase-like protein which has subnormal catalytic activity.

Clinical disorders associated with autoantibodies to the insulin receptor. Simulation by passive transfer of immunoglobulins to rats.

Patients with autoantibodies to the insulin receptor (Anti-R) may exhibit either fasting hypoglycemia or hyperglycemia and extreme insulin resistance. Occasionally, both these phenomena are observed in the same patient at different times in the clinical course. In an effort to understand what determines the patient's response to Anti-R, we developed an animal model of these clinical disorders by passive transfer of Anti-R IgG to rats. IgG fractions from the plasma of Anti-R patients and control subjects were prepared by affinity chromatography with staphylococcal protein A-Sepharose. Anti-R IgG, injected into fasting rats, induced severe and persistent hypoglycemia (plasma glucose 30-60 mg/dl). Rats injected with control IgG maintained a plasma glucose within the range of 75 (fasting) to 165 mg/dl (feeding). In comparison with the effects of insulin, the hypoglycemic response to Anti-R IgG had a slower onset (2-4 h) and lasted longer (8-24 h). Similar, dose-dependent hypoglycemic responses were observed in rats whether the Anti-R IgG was derived from an insulin-resistant or hypoglycemic patient. When Anti-R IgG was administered in sufficiently high doses for several days to fed rats, persistent hyperglycemia (plasma glucose 200-400 mg/dl) developed. Based on these in vivo and previous in vitro studies, we attribute the hypoglycemic response to an insulin-like effect of Anti-R, and the hyperglycemic response to a desensitization of host tissues to the effects of insulin, with more prolonged exposure to higher levels of Anti-R.

Influence of glycogen on liver density: computed tomography from a metabolic perspective.

The liver is a metabolically active organ with a radiographic density that can be modified by its glycogen and fat content. In rhesus monkeys an increase in liver glycogen induced by glucose loading was accompanied by an increase in attenuation values on computed tomography and a decrease in total liver fat. Conversely, fasting depleted glycogen, increased fat, and decreased liver attenuation. Acute glycogen depletion without significant change in fat was induced by administration of glucagon and accompanied by a decrease in attenuation. These results along with in vitro measurements of glycogen solutions suggest that an increase of approximately 3 Hounsfield units can be expected for each percent increase in liver glycogen content.

Lipoprotein lipase and uptake of triacylglycerol, cholesterol and phosphatidylcholine from chylomicrons by mammary and adipose tissue of lactating rats in vivo.

The relationship between lipoprotein lipase activity and uptake of triacylglycerol, cholesterol and phosphatidylcholine from chylomicrons was studied in mammary gland and adipose tissue of rats lactating 6--7 days. 60% of triacylglycerol [14C]oleic acid, 13% of [3H]cholesterol and 8% of [32P]phosphatidylcholine in chylomicrons injected intravenously were taken up within 11 min by mammary gland whereas negligible amounts were taken up by adipose tissue. Non-suckling for 44 h decreased markedly uptake of all lipids by mammary gland and retarded clearance of chylomicrons from blood, while it increased significantly uptake of triacylglycerol fatty acids and cholesterol by adipose tissue. Non-suckling also decreased lipoprotein lipase activity in mammary gland from 7.7 to 0.4 units/g, while it increased activity in adipose tissue from 0.1 to 2.7 units/g. These findings indicate that lipoprotein lipase is involved in uptake of chylomicron triacyglycerol and cholesterol by mammary gland and adipose tissue, and also in uptake of chylomicron phosphatidylcholine by mammary gland. They also show that reciprocal changes in lipoprotein lipase activity in mammary gland and adipose tissue, as occur during lactation, result in diversion of chylomicron lipids from one tissue to the other.

Lipoprotein lipase and uptake of chylomicron triglyceride by skeletal muscle of rats.

Uptake of chylomicron triglyceride and lipoprotein lipase was studied in red and white skeletal muscles, heart, and adipose tissue of rats. Retention of triglyceride fatty acids 10 min after injection was 1.6%/g in heart and adipose tissue, 0.2-0.4%/g in red (soleus and diaphragm) muscles, and 0.1%/g in white (psoas minor) muscles of fed rats. Fasting (24 h) increased retention two- to fourfold in red skeletal muscles and heart, had no effect in white muscles, and decreased retention greater than 75% in adipose tissue. Lipoprotein lipase activity in fed rats was lowest in white muscles and in certain red (posterior belly of digastric and medial head of triceps brachii) musclws, intermediate in soleus and diaphragm muscles and adipose tissue, and highest in heart. Fasting doubled lipoprotein lipase activity in all red skeletal muscles and heart, had no effect in white muscles, and decreased activity 60% in adipose tissue. The findings indicate that triglyceride uptake is related to lipoprotein lipase activity in skeletal muscle and the changes in enzyme activity during fasting divert blood triglyceride to red skeletal muscles.