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.

Identification of HE1 as the second gene of Niemann-Pick C disease.

Niemann-Pick type C2 disease (NP-C2) is a fatal hereditary disorder of unknown etiology characterized by defective egress of cholesterol from lysosomes. Here we show that the disease is caused by a deficiency in HE1, a ubiquitously expressed lysosomal protein identified previously as a cholesterol-binding protein. HE1 was undetectable in fibroblasts from NP-C2 patients but present in fibroblasts from unaffected controls and NP-C1 patients. Mutations in the HE1 gene, which maps to chromosome 14q24.3, were found in NP-C2 patients but not in controls. Treatment of NP-C2 fibroblasts with exogenous recombinant HE1 protein ameliorated lysosomal accumulation of low density lipoprotein-derived cholesterol.

Deleterious effects of xanthine oxidase on rat liver endothelial cells after ischemia/reperfusion.

Previous studies have demonstrated that reactive oxygen species are involved in ischemic injury. The present work was undertaken to determine in vivo the role of xanthine oxidase in the oxygen free radical production during rat liver ischemia and to examine the activity of antioxidant enzymes (superoxide dismutase, catalase and glutathione peroxidase) during the same period. Our results indicate a 4-fold increase in xanthine oxidase activity between 2 and 3 hours of normothermic ischemia, in parallel with a decrease in cell viability. Moderate hypothermia delays both events. Under the same conditions, the activity of oxygen radical scavenging enzymes remains unchanged. Moreover, we have compared in vitro the susceptibility of isolated liver cells to an oxidative stress induced by O2.-, H2O2 and .OH. Our results reveal that endothelial cells are much more susceptible to reactive oxygen species than hepatocytes, probably because they lack H2O2-detoxifying enzymes. These findings suggest that xanthine oxidase might play a major role in the ischemic injury mainly at the level of the sinusoidal space where most endothelial cells are located.

Lateral phase separations and structural integrity of the inner membrane of rat-liver mitochondria. Effect of compression. Implications in the centrifugation of these organelles.

When maintained in the vicinity of the lower transition temperature of their membrane lipids, rat-liver mitochondria undergo lysis as shown by the release of malate dehydrogenase, (an enzyme located within the mitochondrial matrix), in the surrounding medium. Structural changes take place in the membranes of mitochondria subjected to increasing pressure at 0 degrees C, when the pressure reaches 750 kg/cm2. Freeze-fracture electron microscopy shows the appearance of smooth areas devoid of particles in fracture faces of mitochondrial membranes, together with zones, where aggregated particles can be seen. Concurrently, a suppression of the malate dehydrogenase structure-linked latency is observed. These structural changes can be prevented by increasing the temperature at which compression is performed. The freeze-etching observations suggest that lateral phase separations occur in mitochondrial membranes subjected to high pressure. This can be explained by supposing that pressure promotes the gel-phase appearance in a lipid system and raises the transition temperature since the transition liquid crystal lead to gel is accompanied by a decrease in volume. The deterioration of mitochondria subjected to high pressure is interpreted as a result of the lateral phase separation induced by compression in the membranes. These results are discussed with respect to our interpretation of the damaging effects that hydrostatic pressure, generated by centrifugation, exerts on rat-liver mitochondria.

Uptake of tyramine by rat hepatocytes.

Observations on the uptake of tyramine by hepatocytes indicate that the amine is taken up by simple diffusion and a transporter mediated system, with a Km of 39 microM and a Vmax of 270 pmol/min/10(5) cells. The carrier-mediated process is pH- and temperature-dependent and requires an activation energy of 12.9 kcal/mol. An overshoot uptake is achieved a few minutes after adding this amine to the cell suspension, suggesting that active transport is involved. This is supported by the finding that partial inhibition of the uptake can be induced by oligomycin, azide, cyanide and dinitrophenol. NO3-, SCN- and SO4(2-), which change the membrane potential significantly, and depress the transporter mediated uptake further, suggesting that the membrane potential is the driving force for the entry of this amine across hepatic membrane. Cysteine is essential for the normal carrier function; whereas, histidine, tryptophan, arginine and lysine do not directly deal with the activity of the carrier. Many substances, but not amino acids, H, M, and N receptor agonists, can inhibit the uptake of tyramine. It is possible that other amines can enter hepatocytes by using this transporter.

Imipramine and lipid phase transition in inner mitochondrial membrane.

As ascertained by freeze-fracture electron microscopy, imipramine prevents lateral phase separation from taking place in inner mitochondrial membranes at sub-zero temperatures. Electron spin resonance (ESR) measurements performed on mitochondrial membranes labeled with the N-oxyl-4',4'-dimethyloxazolidine derivative of 16-ketostearic acid, show that the spin probe motion is markedly inhibited below 0 degree C and that 5 mM imipramine attenuates the temperature effect. These results are explained by supposing that imipramine is able to decrease the transition temperature of the inner mitochondrial membrane lipids as it does for simple lipid systems.

Cytotoxicity and effect of glycyl-D-phenylalanine-2-naphthylamide on lysosomes.

Glycyl-D-phenylalanine-2-naphthylamide (Gly-D-Phe-2-NNap) is a cytotoxic agent as exemplified by its effect on Vero cells in culture. This effect is inhibited to some extent by nigericin. On the other hand, Gly-D-Phe-2-NNap induces an increase of free activity of N-acetylglucosaminidase when incubated with a mitochondrial fraction of rat liver at pH 7.5. The phenomenon is inhibited by chloroquine, NH4Cl and nigericin, substances that are known to increase the intralysosomal pH. The latency of enzymes located in other subcellular structures - mitochondria, peroxisomes and endoplasmic reticulum - is not affected by Gly-D-Phe-2-NNap. Moreover, that compound does not cause a release of FITC-Dextran present in endosomes. Apparently Gly-D-Phe-2-NNap is a specific lytic agent for lysosomes. It is proposed that the molecule behaves like a lysosomotropic substance that is able to attack the lysosomal membrane from the interior of the organelle. Its cytotoxic properties could be explained by its effect on lysosomes.

Uptake of tyramine cellobiose by rat liver.

The uptake of 125I-tyramine cellobiose (TC) by isolated rat hepatocytes and by total rat liver is markedly higher than that of 14C-sucrose and 125I-PVP, suggesting that TC does not enter the cells by fluid phase endocytosis. The distribution of radioactivity after differential centrifugation shows that the compound is shared out amongst sedimentable structures and unsedimentable fraction. Analysis by isopycnic centrifugation indicates that quickly after its penetration into the cells, most of sedimentable 125I-TC is associated with lysosomes. Such an intracellular localization is confirmed by the distributions observed after free flow electrophoresis and by the fact that radioactivity and cathepsin C, a lysosomal hydrolase, are simultaneously released from a mitochondrial fraction treated with glycyl-L-phenylalanine-2-naphthylamide. Pretreatment of the rats with chloroquine, an acidotropic drug that accumulates in lysosomes, prevents to some extent the entry of 125I-TC into these organelles. Experiments performed with purified lysosomes show that 14C-sucrose does not cross the lysosomal membrane when 125I-TC accumulates linearly with time in the fractions. These results are explained by supposing that the linkage of tyramine to cellobiose allow the disaccharide to diffuse through the plasma and the lysosome membranes, and that the accumulation of the molecule in these organelles results from its weak basic properties. 125I-TC could be an interesting molecule with which to study acidotropism in the whole animal and in isolated and cultured cells.

Permeability of mitochondria to sucrose induced by hydrostatic pressure.

When subjected to increasing pressure at 0 degree C, rat liver mitochondria become permeable to sucrose, causing them to swell and their outer membrane to rupture. Afterwards they are lysed and their matrix content is released into the medium. This permeation to sucrose may be prevented to some extent by increasing the temperature at which compression is carried out. 0.75 mM imipramine protects mitochondria against lysis caused by hydrostatic pressure, but does not oppose their permeation to sucrose nor the swelling resulting from the compression. At this concentration, the drug does not exhibit a significant effect on the lateral phase separations which take place in the inner mitochondrial membrane under pressure. The mitochondria of rat fetal liver (21 days), kidney and Morris hepatoma 16 become permeable to sucrose when they are subjected to compression; under these conditions, lateral phase separations occur in their inner membrane. Contrary to liver mitochondria, the former do not undergo lysis. Taking into account both present and previous results, events leading to mitochondrial membrane deterioration by hydrostatic pressure may be summarized in the following way. Pressure first leads to a phase transition of the membrane lipids, thus causing a permeation to sucrose; as a result the mitochondria swell because they have absorbed osmotic water. The membrane lipids freeze increasingly as the pressure increases; the inner membrane becomes fragile and finally, in the case of the adult liver organelles, can no longer resist the swelling. All these events can be avoided by increasing the temperature; imipramine only prevents inner membrane lysis.

Biochemical characterization of subcellular particles in fetal and neonatal rats.

By a variety of methods, such as ultracentrifugation in different media, hypoosmotic activation and hydrostatic compression, subcellular particles were characterized at different perinatal ages and compared to the adult rats. Fetal mitochondria elicited a higher density, an increased osmotic space and a greater resistance to compression. The size of these particles was larger than in the adults. Mitochondria in the 1-day-old animals were freely permeable to sucrose and their external membrane was more resistant to hypoosmotic activation. Lysosomes were shown to decrease their sucrose permeability and their resistance to hypoosmotic activation with development. Moreover, the size of the lysosomes increased with development.

Presence of a transglutaminase activity in rat liver lysosomes.

The intracellular distribution of rat liver transglutaminase has been investigated by centrifugation methods. When measured in presence of Ca++ the enzyme is mainly present in the unsedimentable fraction of the homogenate. When assayed in absence of Ca++, the enzymatic activity exhibits a distribution pattern like that of lysosomal markers, both after differential and isopycnic centrifugation. The enzyme shows the phenomenom of structure linked latency and can be unmasked parallel with acid phosphatase by freezing and thawing. The origin of this transglutaminase is discussed; it is proposed that it is a genuine constituent of lysosomes.

Endosomes, lysosomes: their implication in gene transfer.

Plasmid DNA, naked or bound to a non-viral vector, is taken up by endocytosis. As a result, it has to travel through the intracellular endocytic pathway involving endosomes and lysosomes. However, some DNA molecules must escape these organelles to reach the nucleus where transcription takes place. In this paper, we consider different factors that could affect the trafficking of plasmid DNA and influence transfection efficiency.

Cationic lipids destabilize lysosomal membrane in vitro.

Addition of cationic lipids to plasmid DNA considerably increases the efficiency of transfection. The mechanism has not yet been elucidated. A possibility is that these compounds destabilize biological membranes (plasma, endosomal, lysosomal), facilitating the transfer of nucleic molecules through these membranes. We have investigated the problem by determining if a cationic lipid N-(1-(2,3-dioleoxy)propyl)-N,N,N,-trimethylammonium methyl-sulfate (DOTAP, Boehringer, Mannheim, Germany) affects the integrity of rat liver lysosomal membrane. We have measured the latency of beta-galactosidase, a lysosomal enzyme, and found that incubation of lysosomes with low concentrations of DOTAP causes a striking increase in free activity of the hydrolase and even a release of the enzyme into the medium. This indicates that lysosomal membrane is deeply destabilized by the lipid. The phenomenon depends on pH, it is less pronounced at pH 5 than at pH 7.4. Anionic compounds, particularly anionic amphipathic lipids, can to some extent prevent this phenomenon. It can be observed with various cationic lipids. A possible explanation is that cationic liposomes interact with anionic lipids of lysosomal membrane, allowing a fusion between the lipid bilayers which results in a destabilization of the organelle membrane.

Uptake by rat liver and intracellular fate of plasmid DNA complexed with poly-L-lysine or poly-D-lysine.

Efficiency of transfection is probably dependent on the rate of intracellular degradation of plasmid DNA. When a non-viral vector is used, it is not known to what extent the plasmid DNA catabolism is subordinated to the catabolism of the vector. In the work reported here, the problem was approached by following the intracellular fate in rat liver, of plasmid [35S]DNA complexed with a cationic peptide poly-L-lysine that can be hydrolyzed by cellular peptidases or with its stereoisomer, poly-D-lysine, that cannot be split by these enzymes. Complexes of DNA with poly-L-lysine and poly-D-lysine are taken up to the same extent by the liver, mainly by Kupffer cells, but the intracellular degradation of nucleic acid molecules is markedly quicker when poly-L-lysine is injected. The association of DNA with the polycations inhibits DNA hydrolysis in vitro by purified lysosomes but similarly for poly-L-lysine and poly-D-lysine. The intracellular journey followed by [35S]DNA complexed with poly-L- or poly-D-lysine was investigated using differential and isopycnic centrifugation. Results indicate that [35S]DNA is transferred more slowly to lysosomes, the main site of intracellular degradation of endocytosed macromolecules, when it is given as a complex with poly-D-lysine than with poly-L-lysine. They suggest that the digestion of the vector in a prelysosomal compartment is required to allow endocytosed plasmid DNA to rapidly reach lysosomes. Such a phenomenon could explain why injected plasmid DNA is more stable in vivo when it is associated with poly-D-lysine.

Effect of various flavonoids on lysosomes subjected to an oxidative or an osmotic stress.

When a light mitochondrial fraction (L fraction) of rat liver is incubated in the presence of an oxygen free radical generating system (xanthine-xanthine oxidase), the free activity of N-acetylglucosaminidase (NAGase) increases as a result of the deterioration of the lysosomal membrane. Various flavonoids are able to prevent this phenomenon, others are ineffective. Comparative activity studies suggest the importance of the presence of two OH groups in orthosubstitution in the B ring and of an OH in the 3 position. Flavan-type flavonoids behave like their related flavonoids; d-catechin also opposes lysosome disruption. Kaempferol, quercetin, 7,8-dihydroxyflavone and d-catechin inhibit lipoperoxidation occurring in an L fraction incubated with the xanthine oxidase system as ascertained by malondialdehyde (MDA) production. For kaempferol and quercetin, such an inhibition parallels the prevention of NAGase release; this is not the case for the two other compounds where inhibition of NAGase release takes place at a flavonoid concentration lower than that required to oppose MDA production. Morphological observations performed on purified lysosomes confirm the biochemical results. Some flavonoids are also able to prevent release of NAGase caused by the incubation of an L fraction in isoosmotic glucose. Only flavone and hydroxyflavones are effective. It is proposed that the protective effect of flavonoids on lysosomes subjected to oxygen free radicals does not only originate from their scavenger and antilipoperoxidant properties; a more direct action on lysosomal membrane making it more resistant to oxidative aggression has to be considered. The prevention by some flavonoids of lysosome osmotic disruption in isoosmotic glucose could be the result of an inhibition of glucose translocation through the lysosomal membrane.