Studies on norepinephrine-induced efflux of free fatty acid from hamster brown-adipose-tissue cells.

Cells were isolated from brown adipose tissue of warm-adapted hamsters and the fate of free fatty acids released during norepinephrine-induced lipolysis was investigated. The isolated resting cells contain between 100-400 nmoles cell-associated free fatty acids per 10(6) cells; most preparations contained about 200 nmoles/10(6) cells. During norepinephrine-stimulated lipolysis, the level of cell-associated free fatty acids remains constant or decreases gradually, but does not increase, while the concentration of extracellular fatty acids increases linearly. The rate of norepinephrine-stimulated efflux of free fatty acids was 40 +/- 20 nmol X min-1 X 10(6) cells-1 (n = 11) at 37 degrees C. The data strongly indicate that brown adipose tissue can supply free fatty acids to the circulatory system in hamster.     

Mitochondrial and peroxisomal fatty acid oxidation in liver homogenates and isolated hepatocytes from control and clofibrate-treated rats.

Mitochondrial and peroxisomal fatty acid oxidation were compared in whole liver homogenates. Oxidation of 0.2 mM palmitoyl-CoA or oleate by mitochondria increased rapidly with increasing molar substrate:albumin ratios and became saturated at ratios below 3, while peroxisomal oxidation increased more slowly and continued to rise to reach maximal activity in the absence of albumin. Under the latter condition mitochondrial oxidation was severely depressed. In homogenates from normal liver peroxisomal oxidation was lower than mitochondrial oxidation at all ratios tested except when albumin was absent. In contrast with mitochondrial oxidation, peroxisomal oxidation did not produce ketones, was cyanide-insensitive, was not dependent on carnitine, and was not inhibited by (+)-octanoylcarnitine, malonyl-CoA and 4-pentenoate. Mitochondrial oxidation was inhibited by CoASH concentrations that were optimal for peroxisomal oxidation. In the presence of albumin, peroxisomal oxidation was stimulated by Triton X-100 but unaffected by freeze-thawing; both treatments suppressed mitochondrial oxidation. Clofibrate treatment increased mitochondrial and peroxisomal oxidation 2- and 6- to 8-fold, respectively. Peroxisomal oxidation remained unchanged in starvation and diabetes. Fatty acid oxidation was severely depressed by cyanide and (+)-octanoylcarnitine in hepatocytes from normal rats. Hepatocytes from clofibrate-treated rats, which displayed a 3- to 4-fold increase in fatty acid oxidation, were less inhibited by (+)-octanoylcarnitine. Hydrogen peroxide production was severalfold higher in hepatocytes from treated animals oxidizing fatty acids than in control hepatocytes. Assuming that all H2O2 produced during fatty acid oxidation was due to peroxisomal oxidation, it was calculated that the contribution of the peroxisomes to fatty acid oxidation was less than 10% both in cells from control and clofibrate-treated animals.     

Total and peroxisomal fatty acid oxidation by liver homogenates from autopsied Reye's and control subjects

To determine whether the accumulation of liver triglyceride in Reye's syndrome could be due to a block in beta-oxidation of the fatty acids, the ability of Reye's and control liver homogenates from samples obtained at autopsy to oxidize fatty acids was examined. Total fatty acid oxidation as measured by oxidation of [1-14C]oleoyl CoA, which mostly represents mitochondrial activity, was comparable between the groups. Peroxisomal fatty acid oxidation was, likewise, similar despite the reported increase in the numbers and sizes of these organelles. This disparity could not be explained by an artifactual dilution of product by accumulated endogenous substrate. Inference is made that active peroxisomal beta-oxidation may contribute to the increased short chain fatty CoA content of liver which was reported earlier.     

Lipogenesis in the liver and adipose tissue of the cardiomyopathic hamster.

The activities of fatty acid synthetase, citrate cleavage enzyme, glucose-6-phosphate dehydrogenase and malic enzyme were measured in the liver and adipose tissue of cardiomyopathic and normal hamsters at age 33, 68 and 108 days. There was no difference in the activity of hepatic fatty acid synthetase between the diseased animals and the controls at any stage in their development. The activity of glucose-6-phosphate dehydrogenase was not different until age 108 days where it was significantly elevated in the BIO 82.62 strain. Citrate cleavage enzyme in the liver was depressed at all stages in the diseased animals as was malic enzyme. In adipose tissue, all enzyme activities were significantly depressed in the cardiomyopathic animals at the three stages. These data suggest that lipogenesis was depressed in the cardiomyopathic hamster.     

Intermediates in fatty acid oxidation

1. Aqueous extracts of acetone-dried liver and kidney mitochondria, supplemented with NAD⁺, CoA and phenazine methosulphate, efficiently convert fatty-acyl-CoA compounds into acetyl-CoA; the process was followed with an O₂ electrode. 2. Label from [1-¹⁴C]octanoyl-CoA appears in acetyl-CoA more rapidly than that from [8-¹⁴C]octanoyl-CoA. 3. Oxidation of [8-¹⁴C]octanoyl-CoA was terminated by addition of neutral ethanolic hydroxylamine and the resulting hydroxamates were separated chromatographically. Hydroxamate derivatives of 3-hydroxyoctanoyl-, hexanoyl-, butyryl- and acetyl-CoA were obtained. 4. These and other observations suggest that oxidation of octanoyl-CoA by extracts involves participation of free intermediates rather than uninterrupted complete degradation of individual molecules to acetyl-CoA by a multienzyme complex. 5. Intact liver mitochondria studied by the hydroxamate technique were also shown to form intermediates during oxidation of labelled octanoates. In addition to octanoylhydroxamate, [8-¹⁴C]octanoate gave rise to small amounts of hexanoyl-, butyryl- and 3-hydroxyoctanoyl-hydroxamate. In contrast with extracts, however, where the quantity of intermediates found was a significant fraction of the precursors, mitochondria oxidizing octanoate contained much larger quantities of octanoyl-CoA than of any other intermediate.     

Unsaturated fatty acid-dependent oxidation of epinephrine in homogenates of the gorgonian, Pseudoplexaura porosa

A novel epinephrine oxidation system in homogenates of the gorgonian Pseudoplexaura porosa was discovered. The enzymatic reaction required an unsaturated fatty acid and molecular oxygen or hydrogen peroxide. Diphenylisobenzofuran was also oxidized by Ps. porosa homogenates in the presence of an unsaturated fatty acid. Hydroxyl radical and superoxide anion did not appear to be involved in either of these oxidative reactions. The production of lipid hydroperoxides was not necessary for epinephrine oxidation and, with the exception of arachidonic acid, lipid hydroperoxide production did not occur. Evidence is presented for the involvement of singlet oxygen or a similar activated oxygen intermediate in the reactions, and a possible mechanism was proposed. The use of arachidonate-dependent epinephrine oxidation as a measure of prostaglandin synthetase activity is criticized.     

Calcium and myocardial cell injury. An appraisal in the cardiomyopathic hamster

The heart muscle is very compliant within a wide range of physiologic impulses. The adaptive energy of the myocardium depends, however, upon adequate oxygen supply and the functional state of the plasmalemma. These limitations have been well demonstrated in a number of experimental models with emphasis on the essential role of Ca2+ transmembrane movements for maintenance of heart functions and its viability. This postulate appeared quite important when we found that Ca2+ slow channel blockers could prevent necrotic changes in hamster hereditary cardiomyopathy. However, the effectiveness of beta-adrenoagonists when given in low doses seems more difficult to interpret since these agonists can only promote Ca2+ transmembrane movements. We can only surmise that Ca2+ accumulation in cardiomyopathic hearts does not derive from a primary defect of the plasmalemma but rather from an exhausted hypokinetic state that favours Ca2+ accumulation with progressive deterioration of the structural proteins. It is thus inferred that Ca2+ mediates rather than initiates the degradation process which characterizes this inherited cardiomyopathy.