Studies on the protein-synthesizing activity of the ribosomes of rat liver. The activity of free polysomes

1. The activities of microsome fractions from the liver of adult and 5-day-old rats for the incorporation of [(14)C]phenylalanine into protein were similar in the presence and absence of polyuridylic acid. 2. The activity of a light-microsome fraction from adult liver was greater than that of a heavy-microsome fraction, and the light-microsome fraction was also more markedly stimulated by the presence of polyuridylic acid. 3. The light-microsome fraction, when analysed by density-gradient centrifugation, contained a higher ratio of free ribosomes to bound ribosomes, whereas the reverse was true for the heavy-microsome fraction. Similar results were obtained for liver from adult and 5-day-old rats. 4. When the light-microsome fraction was incubated under conditions in which amino acid was incorporated into protein there was only a small increase in the ratio of free to bound ribosomes. When such a fraction was incubated with [(14)C]leucine and was then subjected to density-gradient centrifugation the fraction with the highest specific activity based on RNA had a density between that of the bound and free ribosomes. Treatment of the incubated fraction with ribonuclease shifted the radioactivity towards the free ribosome peak. These properties are consistent with the presence of active free polysomes. Such a component appeared also to be present when the heavy-microsome fraction was incubated under similar conditions. 5. The effect of the presence of polyuridylic acid on the incorporation of [(14)C]phenylalanine by the light-microsome fractions from liver of adult and 5-day-old rats was greatest in the region of the free ribosomes, but it is probable that some small polysomes containing polyuridylic acid are formed. 6. Polyuridylic acid also stimulated the bound ribosomes to a small extent when the heavy-microsome fraction from the liver of young rats was incubated with [(14)C]phenylalanine. 7. The results are discussed in terms of the various morphological constituents in liver now known to play a role in the synthesis of protein for export and for the internal activity of the cell.     

Effect of sex and bezafibrate on incorporation of blood borne palmitate into lipids of rat liver nuclei

The aim of the present study was to investigate whether lipid metabolism in the nuclei is affected by changes in the metabolism of free fatty acids in the liver. The experiments were carried out on 3 groups of rats: 1 - control-male, 2 - female, and 3 - male, treated with bezafibrate (a peroxisome proliferator). The rats received 14C-palmitic acid intravenously. Thirty min later liver samples and blood from the abdominal aorta were taken. The liver nuclei were isolated in sucrose gradient. Lipids were extracted from the nuclei and the liver homogenate and subsequently separated into the following fractions: phospholipids, mono, di- and triacylglycerols, free fatty acids, cholesterol and cholesterol esters. The radioactivity of each fraction was counted. Furthermore, the content of free fatty acids and the fatty acid binding proteins was measured. It was found that radioactivity was present in each lipid fraction obtained from the liver homogenate and from the nuclei. In the female group, the total radioactivity of lipids in the liver homogenate was lower, whereas in the nuclei it was higher in comparison to the male group. The reduction in the radioactivity in the liver was mostly accounted for by decreased radioactivity in the fraction oftriacylglycerols and phospholipids. In the nuclei, the radioactivity of the fraction of phospholipids, free fatty acids and diacylglycerols was elevated. Bezafibrate did not affect the total radioactivity of lipids in the liver and reduced it in the nuclei. In the liver, the drug increased radioactivity mostly in the fraction of phospholipids and reduced it mainly in the fraction of triacylglycerols. In the nuclei, the radioactivity of each lipid fraction examined was reduced. The content of the fraction of free fatty acids in the liver and in the nuclei in the female and in the bezafibrate-treated groups did not differ from the respective value in the control group. The content of fatty acid binding proteins in the nuclei of the female and bezafibrate-treated groups increased in parallel to the elevation in their content in the cytosol. It is concluded that the female sex hormones and bezafibrate influence the transport of selected lipids into the nuclei. The effects seem to be a consequence of the action of these factors directly on the nucleus.     

Effect of sex and bezafibrate on incorporation of blood borne palmitate into lipids of rat liver nuclei

The aim of the present study was to investigate whether lipid metabolism in the nuclei is affected by changes in the metabolism of free fatty acids in the liver. The experiments were carried out on 3 groups of rats: 1 - control-male, 2 - female, and 3 - male, treated with bezafibrate (a peroxisome proliferator). The rats received ¹⁴C-palmitic acid intravenously. Thirty min later liver samples and blood from the abdominal aorta were taken. The liver nuclei were isolated in sucrose gradient. Lipids were extracted from the nuclei and the liver homogenate and subsequently separated into the following fractions: phospholipids, mono-, di- and triacylglycerols, free fatty acids, cholesterol and cholesterol esters. The radioactivity of each fraction was counted. Furthermore, the content of free fatty acids and the fatty acid binding proteins was measured. It was found that radioactivity was present in each lipid fraction obtained from the liver homogenate and from the nuclei. In the female group, the total radioactivity of lipids in the liver homogenate was lower, whereas in the nuclei it was higher in comparison to the male group. The reduction in the radioactivity in the liver was mostly accounted for by decreased radioactivity in the fraction of triacylglycerols and phospholipids. In the nuclei, the radioactivity of the fraction of phospholipids, free fatty acids and diacylglycerols was elevated. Bezafibrate did not affect the total radioactivity of lipids in the liver and reduced it in the nuclei. In the liver, the drug increased radioactivity mostly in the fraction of phospholipids and reduced it mainly in the fraction of triacylglycerols. In the nuclei, the radioactivity of each lipid fraction examined was reduced. The content of the fraction of free fatty acids in the liver and in the nuclei in the female and in the bezafibrate-treated groups did not differ from the respective value in the control group. The content of fatty acid binding proteins in the nuclei of the female and bezafibrate-treated groups increased in parallel to the elevation in their content in the cytosol. It is concluded that the female sex hormones and bezafibrate influence the transport of selected lipids into the nuclei. The effects seem to be a consequence of the action of these factors directly on the nucleus.     

Studies on the site of biosynthesis of acidic glycoproteins of guinea-pig serum

1. Studies were carried out to determine the cellular and subcellular site of biosynthesis of components of fraction I, an alpha-globulin fraction containing acidic glycoproteins isolated from guinea-pig serum. l-[U-(14)C]Leucine or -valine and d-[1-(14)C]glucosamine were used as precursors. 2. A lag of about 10min. occurred before appreciable label appeared in fraction I of serum after injection of leucine or glucosamine. Label in fraction I after 60min. labelling with glucosamine was present almost entirely in hexosamine and sialic acid. 3. Site of synthesis was investigated by studies in vivo up to 17min. after injection of precursor. Particulate subcellular fractions isolated from liver, spleen and kidney or homogenates of the latter two tissues were extracted with Lubrol. Extracts were allowed to react by double diffusion with antisera to fraction I or to subfractions isolated from it, and gels were subsequently subjected to radioautography. With either amino acid or glucosamine as precursor, only extracts of the microsome fraction of liver formed precipitin lines that were appreciably radioactive. 4. The role of the microsome fraction of liver in the synthesis of these glycoproteins was confirmed by immunological studies after incubation of liver slices with leucine or glucosamine. Incorporation of leucine was also investigated in a cell-free microsome system. 5. Material was also precipitated from certain Lubrol extracts of liver microsomes by direct addition of antiserum and its radioactivity measured. Degradation of material thus precipitated and use of heterologous immune systems showed that labelling of precipitin lines represented biosynthesis. 6. A study of extraction procedures suggested that the substances present in the microsome fraction of liver that react with specific antisera are associated with membranous structures. 7. Most or all precipitin lines formed by Lubrol extracts of liver microsomes interacted with precipitin lines given by guinea-pig serum or fraction I, immunological identity being apparent with some lines. The microsome-bound substances thus represent serum glycoproteins or precursors of them. 8. The distribution of label in various tissues and in the protein of subcellular fractions of liver after administration of [(14)C]glucosamine to the guinea pig was also studied. Some variation in results obtained with liver was found depending on the fractionation medium used.     

Fraction from human and rat liver which is inhibitory for proliferation of liver cells

A comparative study was undertaken with human and rat liver of a fraction reported to have growth inhibitory activity when prepared from rat liver. Fractions which were soluble in 70% ethanol and insoluble in 87% ethanol were prepared from liver cytosols. Electrophoretic analysis under denaturing conditions indicated that there were several quantitative or qualitative differences in the fractions from the two species. Fractions from both human and rat liver were found to be inhibitory for the incorporation of 3H-thymidine into DNA of foetal chick hepatocytes. Under conditions in which the rat fraction inhibited precursor incorporation into DNA of rat liver epithelial cells there was not a significant inhibitory effect with the fraction from human liver. DNA synthesis in a rat hepatoma cell line was not significantly inhibited by preparations from either species. The data suggested that corresponding fractions from both rat and human liver could have inhibitory effects on precursor incorporation into DNA but the magnitude of the effects and target cell specificity may differ.     

Fractionation of Soluble Copper- and Zinc-Binding Proteins From Cattle Liver

The distribution of copper and zinc among soluble proteins in liver from normal slaughter cattle was examined after gel filtration of the proteins. Gopper- and zinc-binding proteins were mainly separated into three fractions. Varying amounts of zinc were eluted in a fourth fraction of molecular weight less than 2,000. A clear relationship was noted between the amount of copper bound to the low molecular weight fraction (m.w. ~ 10,000) and the total liver zinc concentration. The high molecular weight protein fraction (m.w. > 65,000) dominated in liver with zinc concentrations below 40 µg/g wet weight and total copper concentrations from 16 to 240 µg/g, while in liver with zinc concentrations above 40 µg/g and copper concentrations ranging from 20 to 107 µg/g, the low molecular weight metallothionein-like fraction dominated.     

Cytoplasmic origin of the so-called nuclear neutral histone protease.

1. We have investigated the origin of proteolytic activity which causes degradation of histones in chromatin isolated from Xenopus liver and the rat liver at neutral pH. Polyacrylamide disc gel electrophoresis was used for detection of proteolytic products of histones. 2. No proteolytic degradation of histones occurs in chromatin isolated from Xenopus erythrocytes and rat liver according to our procedure even after prolonged incubation at pH 8.0 and pH 5.0. However with chromatin isolated from Xenopus liver a high level of histone degradation is observed under similar conditions. 3. Mixing isolated nuclei from Xenopus erythrocytes with a crude cytoplasmic fraction from Xenopus liver causes histone proteolysis in isolated chromatin at pH 8.0. In similar experiments with corresponding fractions from rat liver histone proteolysis can be introduced only after repeated freezing and thawing of the cytoplasmic fraction. 4. A purified lysosomal preparation from rat liver causes a similar type of histone degradation upon incubation with chromatin from Xenopus erythrocytes and rat liver. 5. The neutral proteolytic activity that can be introduced in isolated chromatin by a crude cytoplasmic fraction and by a purified lysosomal erythrocytes and rat liver. 5. The neutral proteolytic activity that can be introduced in isolated chromatin by a crude cytoplasmic fraction and by a purified lysosomal fraction from rat liver is inhibited by sodium bisulphite. 6. We conclude that the neutral proteolytic activity which causes degradation of histones in isolated chromatin is due to a contamination with neutral protease(s) originating from cytoplasmic organelles.     

Subcellular distribution of total poly (A) -containing RNA and ferritin-mRNA in the cytoplasm of rat liver.

Poly(A)-containing RNA was isolated from rat liver microsomes and from the post-microsomal supernatant fraction. Approximately 15% of total rat liver poly(A)-containing RNA was found to be present in the post-microsomal supernatant. The relative capacity for apoferritin synthesis of each poly(A)-containing RNA preparation was measured in a cell-free system derived from wheat germ. The post-microsomal supernatant fraction was found to be highly enriched with ferritin mRNA and accounted for 40–50% of the total ferritin-mRNA present in the cytoplasm of rat liver.     

Subcellular distribution of cytochrome c in rat liver. Methods for its extraction and purification

1. A method for the extraction and purification of cytochrome c from rat liver is described. The method depends on multiple chromatography on Amberlite IRC-50 with elution with ammonium phosphate buffers of differing ionic composition and pH, interspersed with gel filtration with Sephadex G-25. Conditions leading to denaturation are avoided and the product is chromatographically pure. 2. The method may be used for the quantitative analysis of cytochrome c either in unfractionated liver or in subcellular fractions. 3. Two pools of cytochrome c were detected, one extractable at pH4.0 with distilled water and the other extracted from the residues of the first extraction with 0.15m-sodium chloride. 4. For subcellular distribution studies the liver was homogenized in 0.3m-sucrose and a nuclear fraction (washed thoroughly to remove trapped mitochondria), a mitochondrial fraction, a heavy microsomal fraction, a standard microsomal fraction and the cell sap were isolated. The mitochondrial fraction was subfractionated further by density-gradient centrifugation. Each fraction was analysed for protein, RNA, DNA, succinate-neotetrazolium oxidoreductase and glucose 6-phosphatase. 5. A total of 123mug. of cytochrome c was obtained/g. wet wt. of rat liver. 6. Values for the percentage subcellular distribution of cytochrome c are: nuclear fraction, 24.4; mitochondrial fraction, 57.2; heavy microsomal fraction, 5.2; standard microsomal fraction, 10.6; cell sap, 2.7. 7. Three out of the eight mitochondrial subfractions separated by gradient centrifugation contained 76% of the cytochrome c and 85% of the succinate-neotetrazolium oxidoreductase present in the mitochondrial fraction. 8. In unfractionated liver 94% of the cytochrome c was extracted at pH4.0 with water whereas in most of the subcellular fractions the corresponding value was approx. 75-80%.     

Identification of the membrane form of phenylalanine hydroxylase from the human liver and characteristics of its subunit composition

Phenylalanine hydroxylase was detected among human liver bioptats and autoptats extracted with 0.4% Triton X-100 from the 105,000 g homogenate fraction. In contrast to the membrane form of the rat liver enzyme, human liver phenylalanine hydroxylase is detected both by its enzymatic activity and immunochemically under non-denaturating conditions. The enzymatic activity of phenylalanine hydroxylase makes 5-15% of that of the cytoplasmic fraction and 20-30% of the amount of antigen in the cytoplasmic fraction and 20-30% of the amount of antigen in the cytoplasmic fraction as can be evidenced from rocket immunoelectrophoresis data. Immunoblotting of proteins performed after denaturating electrophoresis of the membrane and cytoplasmic fractions revealed an antigen band with a similar electrophoretic mobility. The subunit composition of the enzyme in both fractions was characterized by two-dimensional electrophoresis with subsequent immunoblotting. It was found that the membrane fraction of the enzyme is represented only by the L-subunit with Mr of 55 kD, whereas the cytoplasmic fraction, besides the predominant L-subunit, also contains 2H-subunits of the enzyme with Mr = 57 kD. These 2H-subunits differ between themselves as well as from the L-subunit by the pI value.     

Effect of triiodothyronine on the content of phospholipids in the rat liver nuclei.

The aim of the present study was to examine the effect of triiodothyronine (T3) on the content of phospholipids and on the incorporation of blood-borne palmitic acid into the phospholipid moieties in the nuclei of the rat liver. T3 was administered daily for 7 days, 10 microg x 100 g(-1). The control rats were treated with saline. Each rat received 14C-palmitic acid, intravenously suspended in serum. 30 min after administration of the label, samples of the liver were taken. The nuclei were isolated in sucrose gradient. Phospholipids were extracted from the nuclei fraction and from the liver homogenate. They were separated into the following fractions: sphingomyelin, phosphatidylcholine, phosphatidylserine, phosphatidylinositol, phosphatidylethanolamine and cardiolipin. The content and radioactivity of each fraction was measured. It was found that treatment with T3 reduced the content of phosphatidylinositol and increased the content of cardiolipin in the nuclear fraction. In the liver homogenate, the content of phosphatidylinositol decreased and the content of phosphatidylethanolamine and cardiolipin increased after treatment with T3. The total content of phospholipids after treatment with T3 remained unchanged, both in the nuclear fraction and in the liver homogenate. T3 reduced the specific activity of phosphatidylcholine, phosphatidylserine, phosphatidylethanolamine and cardiolipin and had no effect on the specific activity of sphingomyelin and phosphatidylinositol both in the fraction of the nuclei and the liver homogenate. It is concluded that excess of triiodothyronine affects the content of phospholipids in the nuclei. The changes in the content of phospholipids in the nuclei largely reflect changes in their content in the liver.     

Kinase activator protein mediates longer-term effects of starvation on activity of pyruvate dehydrogenase kinase in rat liver mitochondria.

Starvation of rats for 48 h increased the activity of PDH (pyruvate dehydrogenase) kinase 2.2-fold in extracts of liver mitochondria, 2.9-fold in PDH complex partially purified therefrom by fractional precipitation, and 5-fold in PDH complex partially purified by gel filtration on Sephacryl S-300. A protein fraction was separated from PDH complex in extracts of rat liver mitochondria by gel filtration or fractional precipitation, which increased the activity of PDH kinase in rat liver and pig heart PDH complexes. The activity of this protein fraction was increased approx. 2.5-fold by 48 h starvation of rats. With highly purified pig heart PDH complex it was shown that the protein fraction increased the Vmax. of the PDH kinase reaction 35-fold (fraction from fed rats) or 82-fold (fraction from starved rats); starvation had no effect on the concentration of protein fraction required to give 0.5 Vmax. Evidence is given that the increase in PDH kinase activity effected in extracts of liver mitochondria by starvation is due to increased activity of kinase activator protein, which is tightly bound by rat liver PDH complex and not removed by a single gel filtration. With pig heart PDH complex, increased PDH kinase activity was retained after gel filtration of an admixture with kinase activator protein from starved rats, but was restored to the control value by a second gel filtration; the alterations in PDH kinase activity were associated with obvious changes in protein bands in SDS gels.     

Increased activity of cyclic AMP phosphodiesterase from frozen-thawed rat liver. A role of lysosomal protease in enzyme activation.

The activity of cyclic AMP phosphodiesterase (3':5'-cyclic-nucleotide 5'-nucleotidohydrolase, EC 3.1.4.17) in 105 000 X g supernatant fraction from frozen-thawed rat liver was 2.5 times higher than the corresponding preparation from fresh liver. This increased activity of frozen liver enzyme was accompanied by a decreased sensitivity of the enzyme to known activators such as alpha-tocopheryl phosphate and trypsin. Neither membrane-bound cyclic AMP phosphodiesterase, nor supernatant cyclic GMP phosphodiesterase increased in frozen liver preparation. It is unlikely that the activator protein of phosphodiesterase participated in the observed change of enzyme activity. Among rat tissues so far tested, the increased level of cyclic AMP phosphodiesterase was noted only in tissues rich in lysosome content. In the recombination experiment where phosphodiesterase from fresh liver was incubated with lysosomal fraction, stimulation of the enzyme activity was observed with a concomitant loss of sensitivity to above-mentioned activators. Since the stimulation by lysosomal fraction was effectively inhibited by cathepsin B1 inhibitors, leupeptin and antipain, it was deduced cathepsin-B1 (EC 3.4.12.3) type protease(s) was the main causative of activating the cyclic AMP phosphodiesterase. The freezing-thawing process of rat liver made the lysosomal membrane more permeable, and hence lysosomal proteases were released into soluble fraction during phosphodiesterase preparation. These results provide a warning not to use frozen liver for phosphodiesterase preparation, otherwise altered properties of the enzymes will be seen.     

Re-evaluation of protein-bound glutathione in rat liver

The extent of intracellular glutathione binding to proteins through a disulfide linkage in rat liver was examined quantitatively. The content of glutathione associated with the acid-precipitable fraction and releasable on borohydride treatment was 0.024 +/- 0.016 mumol/g liver, which accounted for less than one per cent of the total glutathione (6-7 mumol/g liver) in the liver of fed rats. Most of the thiol (2-4 mumol/g liver) liberated from liver proteins into the acid-soluble fraction on borohydride reduction in the presence of guanidine hydrochloride was not glutathione but was proteinaceous in nature. The amounts of thiols liberated per g of liver were similar in fed, fasted, and dibutyryl-3',5'-cyclic AMP-treated rats.     

Effect of bile anionic polypeptidic fraction on the fate of cholesterol carried by liposomes in the rat

[14C]Cholesterol associated with liposomes with or without anionic polypeptidic fraction was administered intravenously to the rat. The cholesterol originated from liposomes including anionic polypeptidic fraction is secreted in bile much later, is stored in liver in higher quantity, and is metabolized into bile salts in lesser quantity during the 4 hr of experimentation than the cholesterol issued from liposomes exempt of anionic polypeptidic fraction. From these results it can be postulated that the cholesterol associated with liposomes containing anionic polypeptidic fraction might be directed in a particular liver pathway.     

Origin of glutamate dehydrogenase from the mucosa of the sheep rumen

Glutamate dehydrogenase [GDH] from the mucosa of sheep rumen was partly purified and characterized. In chromatography on DEAE cellulose, GDH activity separated into two fractions. Fraction I, isolated at a low NaCl gradient concentration, was not affected by Zn2+ or by the purine nucleotides GTP and AMP. The chromatographic behaviour of fraction II was the same as the parallel fraction isolated from the liver by the same technique. The activity of fraction II and the liver fraction was strongly inhibited by Zn2+ in 10(-6) to 3.10(-5) mol/1 concentration and by GTP in 10(-5) to 2.10(-5) mol/1 concentration. It was activated by AMP in 5.10(-6) to 6.10(-5) mol/1 concentration and by leucine in 3.10(-3) to 10(-2) mol/1 concentration. The coenzyme specificity of fraction I was greater for NADPH than for NADH. In the case of fraction II, like the fraction isolated from sleep liver, it was greater for NADH than for NADPH. It is concluded from the different effect of Zn2+ and of purine nucleotides on the enzyme activity of the fractions isolated from rumen mucosa that the mucosa of the sheep rumen contains two enzymes with GDH activity, one of which [probably adsorbed] is of bacterial origin and the other is a constitutive tissue enzyme of the rumen wall.     

Amino acid incorporation by nuclear membrane fraction of rat liver.

Nuclear membrane fraction of rat liver is able to incorporate ¹⁴C-leucine into its proteins $\text{in vitro}$. The incorporation of ¹⁴C-leucine into the nuclear membrane fraction was almost completely inhibited by chloramphenicol, but the inhibition by cycloheximide and puromycin was not so remarkable. RNase and DNase were not effective. The incorporation was also inhibited by several reagents known to interfere with energy metabolism. These characteristics of the incorporation of ¹⁴C-leucine by the nuclear membrane fraction are quite similar to those of the incorporation by nuclei isolated from rat liver and mitochondrial fraction, but seem to be different from those of the ordinary protein synthetic system in microsomal fraction. ¹⁴C-Leucine was preferentially incorporated into intrapolypeptide or C-terminal residues but not into N-terminal residues. Acrylamide gel electrophoresis showed that three protein species were mainly labelled. The incorporating activity of the nuclear membrane fraction obtained from regenerating liver 17 h after partial hepatectomy showed 220 % of the control. The possibility that the contaminated mitochondrial fraction might be responsible for the incorporation of ¹⁴C-leucine by the nuclear membrane fraction was ruled out.     

On the non-ferritin depot iron fraction in the rat liver

Liver depot iron can be divided into two fractions: ferritin iron and non-ferritin depot iron. Three methods intended to measure the non-ferritin depot iron in the rat liver were compared using livers of normal rats and livers of rats loaded with iron by transfusion of erythrocytes. Liver depot iron varied between 75 and 850 μg Fe/g liver. Non-ferritin depot iron, measured as the iron fraction sedimentable at 10 000 × g, was in the range 4–22 μg Fe/g liver. This fraction did contain ferritin. When measured as the difference between total liver depot iron and heat-stable iron (ferritin iron), the range was 10–270 μg Fe/g liver but this fraction also includes some ferritin iron.The values derived with both methods were linearly proportional to the total liver depot iron values.Non-ferritin depot iron, when measured as the difference between total liver depot iron and total ferritin iron, ranged from 0 to 190 μg Fe/g liver. In this last method no ferritin iron is included. This method provides the best estimate of the non-ferritin depot iron fraction. The concentrations obtained with this method were not always linearly proportional to the total liver depot iron concentration. Intravenous injection of rat liver ferritin resulted in a rapid accumulation of ferritin iron in the liver, together with an increase of the non-ferritin depot iron fraction from 18 μg Fe/g liver to 55 μg Ge/g liver. This confirms a relationship between ferritin catabolism and the non-ferritin depot iron fraction.     

Studies on the stearic acid dehydrogenase in the liver and brain of rats of various ages (author's transl)]

Tissue slices from the liver and brain of 7-day-old rats incubated with [1-14C]stearic acid desaturate the stearate to oleate. The activities of the two tissues are different but of the same order of magnitude. With increasing age, the activity in the liver increases markedly, while the brain activity decreases. The postmitochondrial supernatant from adult (3-month-old) liver contains 2 to 3 orders of magnitude more stearoyl-CoA dehydrogenase activity than the brain postmitochondrial fraction. The washed microsomal fraction from liver had about the same activity as the postmitochondrial supernatant, but no dehydrogenase activity could be detected in the washed microsomal fraction from the brain. The acyl-CoA synthetase and the palmitoyl-CoA hydrolase activities measured in the washed microsomes from adult brain were both lower than in liver microsomes. The concentration of stearoyl-CoA (the substrate for the stearoyl-CoA dehydrogenase) resulting from the ratio of these activities was too high, however, for the lack of desaturase activity to have been simulated by lack of substrate.     

Isolation of rat liver lysosomes by isopycnic centrifugation in a metrizamide gradient

A preparation, similar to the light mitochondrial fraction of rat liver (L fraction of de Duve et al, (1955, Biochem. J. 60: 604-617), was subfractionated by isopycnic centrifugation in a metrizamide gradient and the distribution of several marker enzymes was established. The granules were layered at the top or bottom of the gradient. In both cases, as ascertained by the enzyme distributions, the lysosomes are well separated from the peroxisomes. A good separation from mitochondria is obtained only when the L fraction if set down underneath the gradient. Taking into account the analytical centrifugation results, a procedure was devised to purify lysosomes from several grams of liver by centrifugation of an L fraction in a discontinuous metrizamide gradient. By this method, a fraction containing 10--12% of the whole liver lysosomes can be prepared. As inferred from the relative specific activity of marker enzymes, it can be estimated that lysosomes are purified between 66 and 80 times in this fraction. As ascertained by plasma membrane marker enzyme activity, the main contaminant could be the plasma membrane components. However, cytochemical tests for 5'AMPase and for acid phosphatase suggest that a large part of the plasma membrane marker enzyme activity present in the purified lysosome preparation could be associated with the lysosomal membrane. The procedure for the isolation of rat liver lysosomes described in this paper is compared with the already existing methods.