THE EFFECT OF HIBERNATION ON THE LIPIDS OF BRAIN MYELIN AND MICROSOMES IN THE SYRIAN HAMSTER

Abstract— Microsomal and myelin membrane fractions were prepared from the brains of warm-adapted (room temperature) and hibernating Syrian hamsters ( Mesocricetus auratus ). Lipid extracts of these preparations were assayed for phospholipid and galactosphingolipid composition, and for cholesterol levels. In both myelin and microsomes, plasmenlethanolamine levels decreased while total ethanol-amineglycerophospholipid levels remained constant with hibernation. Cerebroside levels changed slightly, increasing in microsomes while decreasing in myelin. No changes in cholesterol levels were detectable. Fatty acid analyses of microsomal ethanolamineglycerophospholipids and phosphatidylserine showed predominantly increases in 18:1 and 20:4 (n-6), and decreases in 18:0 and 22:6 (n-3), in both lipid classes with hibernation. Myelin ethanolamineglycerophospholipids exhibited a decrease in 20:1 and an increase in 20:4 (n-6). Aldehyde analyses of plasmenylethanolamines revealed a decrease in 16:0 and an increase in 18:1 in microsomes, and an increase in 18:O in myelin. The hydroxylated fatty acids of myelin cerebrosides showed no discernible changes in composition with hibernation. It is proposed that these lipid changes aid in the maintenance of the structure and function of brain membranes at the reduced temperatures encountered during hibernation.     

Role of the microsomal ethanol-oxidizing system in regulating linoleoyl CoA desaturase activity in long-term ethanol loading

Long-term ethanol load resulted in a decrease of the rat liver linoleyl desaturase activity and the activation of MEOS accompanied by an increase in the activity of NADPH-dependent chain and the initial steps of NADH-dependent chain of microsomal electron transport, indicating electron transfer from NADH to cytochrome P-450. It is suggested that, when the main potential of NADH- and NADPH-dependent chains is transferred to microsomal ethanol oxidation, insufficient electron supply for linoleyl-CoA desaturase decreases the activity of this process.     

STUDIES ON THE INHIBITION OF BRAIN PHOSPHO-FRUCTOKINASE BY OLEATE AND THE DETERMINATION OF FATTY ACIDS IN NORMAL AND HYPOXIC BRAIN

Abstract— Oleate inhibited phosphofructokinase activity in the brain in a way which was similar to known surface-active protein denaturants. Experimental hypoxia produced an increase in the level of fatty acids in the microsomal, but not in the cytosol fraction of the brain. It is suggested that under hypoxic conditions the influence of fatty acids on the activity of phosphofructokinase (if any) is of non-specific character.     

Stearyl coenzyme A desaturase activity in mouse liver microsomes of varying lipid composition

Liver microsomes derived from mice fed fat-free diets contained tenfold more stearyl coenzyme A desaturase activity than microsomes derived from mice fed a safflower oil supplemented diet. Removal of the native lipid from each of the microsomal desaturase proteins was performed and the native lipid was replaced by a mixture of phosphatidylcholine and oleic acid. Desaturase activity could only be restored to the level present in the original microsomes in both instances and it was concluded that, although the lipid composition of the two kinds of microsomes was markedly different, this was not directly responsible for the difference in enzyme activity. Microsomal electron transport chain intermediates remained unchanged during the feeding time tested, however, the rate of oxidation of cytochrome b₅could be stimulated sevenfold by stearyl coenzyme A only in microsomes that contained a high desaturase activity. This demonstrates that a blockage in the electron transport chain exists in microsomes from mice fed safflower oil supplemented diets and that this correlates with a markedly reduced desaturase activity in these microsomes.     

STEARYL COENZYME A DESATURASE ACTIVITIES IN RAT BRAIN MICROSOMES

—A quantitative assay for the rat brain microsomal stearyl CoA desaturase is described. The method was used to determine the developmental pattern and regional distribution of the desaturase in rat brain. Even though the specific activity of the enzyme decreased to one-third from 8 to 60 days of age, the total activity per brain remained the same. The regional distribution of the activity in adult brain was of the order midbrain > medulla oblongata > cerebral hemispheres > cerebellum, with midbrain activity being about twice as that of the cerebellum.     

Effect of clofibrate on fatty acid desaturation of rats treated with ethanol

The effect of clofibrate and ethanol in the rat was studied on the following aspects of lipid composition and metabolism: liver delta 5, delta 6 and delta 9 fatty acid desaturases, fatty acid synthetase and fatty acid desaturase microsomal electron transport chain activity and serum cholesterol, triacylglycerols and high (HDL), low (LDL) and very low density lipoprotein (VLDL) levels. Clofibrate administered for 9 days (0.3% W/W) did not modify the relative composition of liver phospholipids and cholesterol, but did diminish triacylglycerol levels increased by ethanol. This effect could be explained by the possible beta-adrenergic blocking properties of clofibrate or by an increased activity of peroxisomal beta-oxidation. Clofibrate also promoted a decrease in serum cholesterol and triacylglycerol levels, delta 6 desaturase activity and a suppression of the electron transport chain as measured by NADH cytochrome b5 reductase and NADH cytochrome c reductase. The drug increased delta 9 desaturase activity and fatty acid synthetase, while no effect could be found in delta 5 desaturase activity. The hypocholesterolenic effect of clofibrate can not be explained through the delta 6 desaturase inhibition, or the fatty acid synthetase enhancement. Ethanol increased the HDL and VLDL and lowered LDL serum concentrations, while clofibrate reversed these results. Considering that clofibrate could have antiatherosclerotic effect in the rat, it is difficult to explain it through these changes in lipoprotein levels, since according to Miller and Miller low HDL levels are predictive of coronary heart disease.     

Regulation of the rate of respiration and oxidative phosphorylation in liver mitochondria from hibernating ground squirrels, Citellus undulatus

1. The rates of oxidation of various substrates (beta-hydroxybutyrate, succinate, ascorbate + TMPD) and the rate of ATP synthesis in liver mitochondria from active and hibernating ground squirrels were measured. 2. It was shown that the rate of mitochondrial respiration is significantly lower in hibernating animals than in active animals. 3. The degree of inhibition of mitochondrial respiration in hibernating ground squirrels was found to correlate with the length of the respiratory chain fragment involved in the oxidation of a given substrate. 4. The inhibition of mitochondrial respiration in hibernating animals was accompanied by a decrease in the rate of ATP synthesis. 5. The activity of phospholipase A2 in liver mitochondria from hibernating ground squirrels was found to be decreased. The activation of phospholipase A2 by Ca2+ ions eliminated the inhibition of respiration almost completely. 6. It was assumed that the inhibition of mitochondrial respiration during hibernation is (a) related to the suppression of phospholipase A2 activity and (b) caused by the reduced rates of electron transport through the respiratory chain and/or of substrate transport across the mitochondrial membrane.     

Synthesis of chain elongation-desaturation products of linoleic acid by liver and brain microsomes during development of the pig.

Microsomes isolated from liver and brain tissue were assayed to examine transitions in metabolic capability to synthesize chain elongation-desaturation products of C18:2(9,12) during the perinatal development of the pig. Microsomal synthesis of trienes, tetraenes and pentaenes was compared for fetal, neonatal and postnatal piglets. Rates of synthesis of tetraenes and pentaenes by chain elongation-desaturation of C18:2(9,12) were greatest in liver. During the later half of gestation, the capability to synthesize tetraenes increased 2-3-fold on a per mg of microsomal protein basis. Increase in the capacity to synthesize tetraenes suggests a significant transition in the activity of delta 5 desaturase during the last half of gestation. For brain, synthesis of C22:5(4,7,10,13,16) from C18:2(9,12) was greatest at term. These observations indicate that in liver and brain the capability to chain elongate-desaturate C18:2(9,12) to longer chain homologues increases significantly during early development. It is suggested that during gestation the activity of the delta 5 desaturase limits synthesis of C20 and C22 homologues of C18:2(9,12). The metabolic conversion of C20 and C22 fatty acids by chain elongation of C20:4(5,8,11,14) does not appear to limit the synthesis of very long chain homologues of linoleic acid in fetal liver or brain.     

Mineralocorticoids modify rat liver delta 6 desaturase activity and other parameters of lipid metabolism

The changes in linoleyl-CoA desaturase activity of rat liver microsomes were studied after a single intraperitoneal injection of 11-deoxycorticosterone or aldosterone at physiological doses. Fatty acid of plasma and different liver fractions, and physical properties of microsomal membranes were also investigated. It was found that the specific activity of delta 6 desaturase decreased 4-fold 24 hr after the injection of aldosterone or deoxycorticosterone. Pretreatment of the rats with aldosterone led to a significant decrease in the percent distribution of palmitic, arachidonic, docosapentaenoic and docosahexenoic acids, with a concomitant increase in palmitoleic, oleic and linoleic acids in plasma and liver homogenates, microsomes and cytosol fractions. A similar pattern was observed after deoxycorticosterone administration. The changes resulted in a decreased unsaturation index of all fractions studied and were well-correlated with the increase observed in fluorescence depolarization of the hydrophobic probe 1,6-diphenylhexatriene in liver microsomal membranes. The interlipid and lipid/protein ratios in microsomes remained constant after hormonal treatment. These results are consistent with the idea that the inhibition of delta 6 desaturase activity and the alterations in fatty acid composition induced by mineralocorticoids, are solely responsible for the measured decrease in liver microsomal membrane fluidity.     

The acyl-CoA desaturases of microsomes from rat liver and the Morris 7777 hepatoma.

We have investigated the role of the microsomal oxidative desaturase in defining the aberrant phosphoglyceride fatty acid composition of hepatomas. The microsomal delta 9-stearoyl-CoA, delta 6-oleoyl(linolenoyl)-CoA, and delta 5-eicosatrienoyl-CA desaturase activities were studied in control and host liver and in the poorly differentiated Morris 7777 hepatoma. The delta 9-stearoyl-CoA desaturase of the hepatoma was significantly decreased (42%) relative to control liver, yet the hepatoma specific activity was twice that of host liver. Additionally, the specific activity of the delta 9-stearoyl-CoA desaturase of the tumor was found to decrease with increasing tumor weight. Also this desaturase was inactivated by freezing and thawing. The delta 6-oleoyl(linolenoyl)-CoA and delta 5-eicosatrienoyl-CoA desaturases of the hepatoma were 39% and 4% of control, respectively. The electron transport components involved in the desaturase system were reduced, although this did not appear to be rate-limiting. In addition, two competing metabolic reactions which could lower the observed desaturase activities, hydrolysis of the thioester and incorporation of substrate acyl-CoA molecules into glycerides, did not appear to be responsible for the lowered desaturase activities of the tumor. Thus, it appears that reduced levels of the desaturases themselves may be responsible for the observed activities. These results indicate that the capacity of the hepatoma to biosynthesize polyunsaturated fatty acids is greatly reduced and this is consistent with the decreased polyene content observed in many neoplasms.     

Dietary control of stearyl CoA and alkylacylglycerophosphorylethanolamine desaturases in tumor

The responses of stearyl CoA desaturase and alkylacylglycerophosphorylethanolamine desaturase were compared in Fischer R-3259 tumors of rats maintained on normal and fat-free diets. The stearyl CoA desaturase activity significantly increased in control livers, host livers, and tumors in rats maintained on the fat-free diet over that in the same tissues from animals maintained on laboratory chow; however, no increase of alkylacylglycerophosphorylethanolamine desaturase was observed in tumors of rats maintained on the fat-free diet. These findings suggest that the two desaturase systems are not identical and that they are controlled by different components of the microsomal electron transport system. Stearyl CoA desaturase activity was lower in the livers of tumor-bearing animals than in those of control animals. This finding supports the concept of others that indicates host livers tend to acquire the enzymic composition of immature livers.     

THE PENETRATION OF THE MEMBRANE OF BRAIN MITOCHONDRIA BY ANIONS

The permeability of the membrane of rat brain non-synaptosomal mitochondria, towards inorganic and substrate anions, was assessed by measuring the rate of swelling that occurred when mitochondria were suspended in an iso-osmotic solution of a permeant anion, in the presence of a permeant cation such as NH⁺₄ or K⁺ in the presence or absence of valinomycin. In NH⁺₄-phosphate swelling was higher than it was in KCI or K⁺-phosphate, which showed the prevalence of the mechanism of phosphate transport previously demonstrated in liver mitochondria. The entry of succinate and L-malate seemed to require the presence in the inner mitochondrial membrane of specific carriers. as previously postulated for liver mitochondria, but the rate of swelling of brain mitochondria was lower than that of liver organelles. In K⁺-succinate, in the presence of antimycin, added ATP induced swelling and this was attributable to the simultaneous permeation both of the anion and the cation. Fumarate did not penetrate into brain mitochondria. Practically no swelling was recorded in NH⁺₄ or K⁺-citrate, which indicated that this anion penetrated poorly into the isolated brain mitochondria even in the presence of malate. Swelling occurred in NH⁺₄-L-glutamate in the presence of rotenone, and the entry of this anion seemed to follow a gradient of concentration although the presence of a specific translocator in the inner mitochondrial membrane might be concerned. The entry of glutamate was independent of that of phosphate and N-ethylmaleimide appeared to be a specific inhibitor of this entry. Swelling in K⁺-L-glutamate, in the presence of rotenone, was enhanced by the addition of valinomycin or ATP but in the latter case when osmotic equilibrium was reached swelling was not reversed by oligomycin. In conclusion, the lesser extent of swelling of isolated brain mitochondria compared with liver mitochondria could be attributed to the heterogeneity of the populations of these organelles, each population possessing its own characteristics of membrane permeability. Observations of electron micrographs of brain mitochondria incubated in iso-osmotic substrate anions confirmed the heterogeneous rate of swelling of these particles.     

POLYAMINE METABOLISM IN THE BRAIN AND LIVER OF THE DEVELOPING MONKEY

Abstract— The concentrations of putrescine and the polyamines, spermidine and spermine, along with the specific activities of the enzymes involved in their biosynthesis, ornithine decarboxylase, S -adenosylmethionine decarboxylase and spermidine synthase have been measured in brain and liver of the developing Rhesus monkey from mid-gestation, through birth and neonatal life to maturity. The results suggest that it is an increased concentration of putrescine and an increased specific activity of ornithine decarboxylase which are associated with the rapid growth of fetal brain during the middle of gestation. By the end of two-thirds of gestation, both of these parameters have attained values similar to those found in mature brain. The concentration of spermidine in brain and the specific activities of S -adenosylmethionine decarboxylase and spermidine synthase are lower in fetal brain than adult brain and increase slowly after birth to reach values similar to those of the adult only after several months. These results provide additional evidence that in the mature brain spermidine serves some function other than one associated with rapid growth.
Fetal liver at mid-gestation was characterized by increased concentrations of both putrescine and spermidine and increased specific activities of the enzymes which synthesize them. By two-thirds of gestation, values similar to those found in adult liver had been attained. Liver has thus reached maturity with regard to polyamine metabolism by this time.     

DISTRIBUTION OF ENZYMES CLEAVING PYRIDINE NUCLEOTIDES IN ANIMAL TISSUES

1. The distribution of DPN and DPNH pyrophosphatases and DPNase in centrifugally prepared fractions of organs of several species of animals is reported. 2. A DPNH pyrophosphatase was found in the soluble fraction of pigeon and of rabbit liver. This enzyme did not split DPN but accounted for over 50 per cent of the DPNH pyrophosphatase activity of the whole homogenates. 3. All the organs tested, including the pigeon liver and rabbit liver, contained a microsomal pyrophosphatase that attacked both DPNH and DPN. This microsomal enzyme split DPNH faster than DPN in all cases. 4. DPN pyrophosphatase and DPNase activity were generally concentrated in the microsomal fraction of liver, of kidney, and of brain. 5. The DPNase of hamster liver was virtually inactive at pH 7.5 but was optimally active at pH 5.5. Considerable difference was found with respect to pH on the activity of DPNase from organs of different animals. 6. The inhibition of mitochondrial and microsomal DPNH oxidation by nicotinamide was noted during the course of these experiments. 7. The significance of some of the distribution patterns is discussed.     

The effects of halothane on hepatic microsomal electron transfer.

1. The effects of halothane (CF3CHBrCl), a volatile anaesthetic agent, on electron transfer in isolated rat liver microsomal preparations were examined. 2. At halothane concentrations achieved in tissues during clinical anaesthesia (1-2mM), halothane shifts the redox equilibrium of microsomal cytochrome b5 in the presence of NADPH towards the oxidized form. Halothane accelerates stoicheiometric consumption of NADPH and O2, increases the rate of reoxidation of NADH-reduced microsomal ferrocytochrom b5, but does not affect NADPH- or NADH-cytochrome c reductase activity. The enhanced microsomal electron flow seen in the presence of halothane is not diminished by CO nor is it increased by pretreatment of the animals with phenobarbital. 3. The effects of halothane are maximum in microsomal preparations isolated from animals fed on a high-carbohydrate diet to induce stearate desaturase activity. Changes in microsomal electron transfer caused by halothane are in all cases abolished by low concentrations (1-2mM) of cyanide. Microsomal stearate desaturase activity is unaffected by halothane. 4. The first-order rate constant for oxidation of membrane-bound ferrocytochrome b5 in the absence of added substrate (k1 equals 1.5 times 10(-3)A-1) is similar to that for autoxidation of purified ferrocytochrome b5(k1 equals 7 times 10(-3)S-1) the rate of autoxidation of soluble ferrocytochrome b5 is unaffected by halothane. 5. It is concluded that the effects of halothane on microsomal electron transfer are not related to cytochrome P-450 linked metabolism but rather arise from the interaction of halothane with the cyanide-sensitive factor of the stearate desaturase pathway.     

STUDIES ON THE CDP-ETHANOLAMINE-1,2-DIGLYCERIDE ETHANOLAMINEPHOSPHOTRANSFERASE OF RAT BRAIN

Abstract— The ethanolaminephosphotransferase (EC 2.7.8.1) of rat brain is found largely in the microsomal fraction and is active towards both diacyl glycerol and alkenyl acyl glycerol. Manganese ions were found to be more effective activators of the enzyme than magnesium ions at low concentrations. The K_m for CDP-ethanolamine was found to be about 2.5 × 10⁻⁴ M in the presence of either lipid acceptor and the K _m for the two lipid acceptors about 1.6 × 10⁻³ M. Under the most favourable conditions rates of 270 nmol phosphatidylethanolamine and 70 nmol ethanolamine plasmalogen/mg microsomal protein/h at 39°C were obtained. The effect of temperature on the reaction rate depended on whether diacyl glycerol or alkenyl acyl glycerol was the lipid acceptor. Although diacyl glycerol inhibited the formation of ethanolamine plasmalogen the inhibition was not a simple competitive one. In terms of microsomal protein the activity was maximal during the period of active myelination but at3 days and 150 days of ageitwasat least 50 percent of this maximal activity.     

ENDOGENOUS MICROSOMAL PHOSPHOLIPID PEROXIDATION IN MOUSE BRAIN

Abstract— Release of malondialdehyde from microsomal phospholipids during incubation in vitro was studied in the brain cytoplasm and in the microsomes fortified by deproteinized cytosole.
Linearity between the log of specific activity of peroxidation (malondialdehyde release) and the negative log of protein concentration was demonstrated. The boiling of microsomes significantly quenched the ability to produce malondialdehyde, while preincubation with phospholipase A completely abolished this ability.
In general, aromatic and not aliphatic compounds inhibited the reaction. 1,1,1-Trichloro-2,2-bis ( p -chlorophenyl) ethane (DDT) was found to be a selective inhibitor of membrane peroxidative activity. The maximal inhibition is invariable. The data obtained revealed that brain and liver microsomal phospholipid peroxidation differ in some respects and the differences are of both quantitative and qualitative nature.     

DISTRIBUTION AND PROPERTIES OF ANGIOTENSIN CONVERTING ENZYME OF RAT BRAIN

Abstract— Angiotensin converting enzyme of rat brain was studied using Hip-His-Leu as substrate. The highest specific activity of the enzyme was associated with the microsomal fraction. The specific activity of the microsomal enzyme in several regions of the rat brain varied significantly. For example, the specific activities of the striatal and pituitary enzymes were about 10-fold greater than that of the cerebral cortical enzyme. The enzyme required chloride ion; moreover, activity was inhibited in the presence of disodium EDTA or O-phenanthroline, effects suggesting that the converting enzyme of brain is a metalloprotein. SQ-20881, a nonapeptide that inhibits converting enzyme in peripheral tissue, was a potent inhibitor of the enzyme of brain. In addition to Hip-His-Leu, the microsomal fraction was capable of liberating C terminal dipeptides from angiotensin I, Hip-Gly-Gly and Z-Gly- Gly-Val. The broad substrate specificity of the enzyme suggests that, in addition to the possible contribution of the enzyme to the brain renin-angiotensin system, other naturally occurring peptides might also be substrates for the enzyme.     

THE ISOLATION OF CELL NUCLEI FROM RAT BRAIN

A method for preparing highly pure cell nuclei from adult rat brain, using both differential and isopycnic centrifugation in sucrose media, is described. The morphology of these preparations was examined by both phase contrast and electron microscopy. The isolated nuclei retained many aspects of their in situ morphology; in particular, the nuclear envelope was double layered and interrupted by pore-like discontinuities, and the nucleoli consisted of irregular masses of densely packed granules. Analyses of these nuclear preparations for cytochrome oxidase and cholinesterase activity, as well as RNA/DNA ratio, indicated minimal contamination with mitochondria and microsomes. Problems involving the homogenization technique, choice of ionic conditions in the homogenization medium, and choice of optimal density of the sucrose solution used for the final purification of nuclei are discussed. Results of application of the technique to isolation of adult rat liver nuclei are also reported.     

EFFECT OF PYRIDOXINE DEFICIENCY ON AROMATIC l-AMINO ACID DECARBOXYLASE IN THE DEVELOPING RAT LIVER AND BRAIN

—Maternal pyridoxine deficiency begun 2 weeks before mating and continued throughout pregnancy and the nursing period resulted in diminished wt. gains in the brain, the liver and the body in the first 16 days of life, as well as lowered levels of the aromatic l -amino acid decarboxylase in both brain and liver tissue. The fetus was protected from the effect of vitamin B₆ deficiency during pregnancy, since at birth the body wt., organ weights, and decarboxylase levels in these tissues were comparable to those of control litters. The brain was affected less than the liver, both in rate of wt. increase and decarboxylase activity. The cerebellum normally developed measurable decarboxylase activity only during the second week of life. The cortex normally slowly increased its low decarboxylase activity during the first week postnatally, with a more rapid increase during the second week. This rapid increase was primarily in the holoenzyme moiety. The rest of the brain, which had well developed levels of decarboxylase activity at birth, normally showed a sharp increase during the second week of life which was also largely in the holoenzyme portion. When the increasing weights of these tissues were considered, it became obvious that the total amount of apoenzyme as well as the amount of holoenzyme were increasing in the normally developing rat, although the greatest amount of the change was in the holoenzyme form. The liver normally showed a much more rapid increase in decarboxylase activity than did the brain, and showed the increase much earlier. The holoenzyme normally increased rapidly after the first 4 days, whereas the apoenzyme concentration levelled off at this time. The effect of the pyridoxine deficiency on decarboxylase activity was almost entirely on the holoenzyme form of the decarboxylase, since the apoenzyme form generally remained the same in the control and the deficient pups during development. There appeared to be no decarboxylase inhibitor present in pyridoxine deficient tissues, nor any evidence in control tissues for an enzyme required for the activation of the decarboxylase by cofactor.