In vitro response of hepatic lysosomes to endogenous and exogenous cationic compounds

An investigation of the effect of four cationic compounds on rat liver lysosomes was carried out. Lysosomes from homogenized rat liver were isolated by differential centrifugation at 0-5 degrees C in 0.3 M sucrose. These lysosomes were then incubated for 1 hr at 37 degrees C in 0.25 M glycine solution containing widely varied concentrations of the test agent. The lysosomes were resedimented and the N-acetyl-beta-glucosaminidase (NAG) activity was measured in the supernatant and in the remaining pellet after disruption. Spermine, ferric ion, mepacrine, and gentamicin all produced dose-dependent effects on these lysosomes. Low concentrations of these compounds inhibited the release of NAG into the supernatant while high concentrations enhanced the release of NAG. This effect of these cationic compounds on the lysosomal membrane may be a mechanism by which they produce cellular toxicity with the organ or tissue selectivity being related to the distribution of the cation.     

Studies on the utilization of ferritin iron in the ferrochelatase reaction of isolated rat liver mitochondria.

The utilization of ferritin as a source of iron for the ferrochelatase reaction has been studied in isolated rat liver mitochondria. 1. It was found that isolated rat liver mitochondria utilized ferritin as a source of iron for the ferrochelatase reaction in the presence of succinate plus FMN (or FAD). 2. Under optimal experimental conditions, i.e., approx. 50 micromol/1 FMN, 37 degrees C, pH 7.4 and 0.5 mmol/l Fe(III) (as ferritin iron), the release process, as shown by the formation of deuteroheme, amounted to approx. 0.5 nmol iron/min per mg protein. 3. The release process could not be elicited by ultrasonically treated mitochondria, lysosomes, microsomes or cytosol, i.e., the release of iron from ferritin was due to mitochondria and was a function of the in situ orientation of the mitochondrial inner membrane. 4. The release of iron from ferritin by the mitochrondria might be of relevance not only for the in situ synthesis of heme in the hepatocyte, but also with respect to the mechanism(s) by means of which iron is mobilized for transport to the erythroid tissue.     

The degradation of intravenously injected chondroitin 4-sulphate in the rat

The degradation of chondroitin 4-[(35)S]sulphate isolated from chick-embryo cartilage was studied in the rat by experiments on free-range animals, on wholly anaesthetized animals with ureter cannulae, by perfusion of isolated liver, by whole-body radioautography and by isolation of liver lysosomes. After injection into rats 68% of the radioactivity was recovered in the urine after 24h, approximately one-half of this being in the form of low-molecular-weight material, chiefly inorganic sulphate. Cannulation experiments demonstrated that the proportion of low-molecular-weight components excreted in the urine increased with time until, after 12h, virtually all was inorganic sulphate. Whole-body radioautography identified the liver as the major site of radioisotope accumulation after injection of labelled polysaccharide. Perfusion through isolated liver indicated that this organ has the ability to metabolize the polymer with the release of low-molecular-weight products, principally inorganic sulphate. Incubation of a lysosomal fraction prepared from rat liver after injection of chondroitin 4-[(35)S]sulphate gave rise to degradation products of low molecular weight, and experiments in vitro with rat liver lysosomes confirmed that these organelles are capable of the entire degradative process from chondroitin sulphate to free inorganic sulphate.     

Isolation of two lysosomal populations from iron-overloaded rat liver with different iron concentration and proteolytic activity

Iron overload results in an accumulation of electron-dense iron-containing particles (IPs) such as ferritin and hemosiderin within the lysosomes of rat liver cells. In order to evaluate the effect or iron overload on lysosomal function, efforts were made to isolate lysosomes with different iron contents by means of ultracentrifugation in Percoll and Metrizamide gradients. Lysosomes isolated on the Percoll gradient were characterized ultrastructurally by a uniform matrix consisting mainly of IPs and these lysosomes contained a high iron concentration and showed a very low proteolytic activity. They may, therefore, constitute, or be equated, with a special type of residual bodies. They were also fragile, as judged by their significant release of enzymes during incubation in vitro. Lysosomes isolated in the Metrizamide gradient contained remnants of sequestered organelles and some IPs. These organelles displayed a somewhat impeded proteolytic activity compared with control lysosomes, as well as preserved membrane stability during incubation in vitro. We suggest that these may be precursors of the heavily iron-laden lysosomes recovered in the Percoll gradient. Our findings demonstrate that different populations of lysosomes exist in iron-overloaded rat liver cells, which show specific characteristics with regard to ultrastructural appearance, iron content and proteolytic activity. Differing iron contents is the most likely reason for their diverging densities and membrane integrities, whereas the difference in proteolytic activity could be a result of varying amounts of degradable substrate.     

Passive diffusion of non-electrolytes across the lysosome membrane.

An osmotic-protection method has been used to study the permeability of rat liver lysosomes to 43 organic non-electrolytes of formula weights ranging from 62 to 1000. A lysosome-rich centrifugal fraction of rat liver homogenate was resuspended in an unbuffered 0.25 M solution of test solute, pH 7.0, and incubated at 25 degrees C for 60 min. The free and total activities of 4-methylumbelliferyl N-acetyl-beta-D-glucosaminidase were measured after incubation for 0, 30 and 60 min. Three patterns of results were seen. In pattern A the percentage free activity remained low throughout the 60 min incubation, indicating little or no solute entry into the lysosomes. In pattern B, the percentage free activity was initially low, but rose substantially during the incubation, indicating solute entry. In pattern C there was not even initial osmotic protection, indicating very rapid solute entry. The rapidity of solute entry into the lysosomes showed no correlation with the formula weight, but a perfect inverse correlation with the hydrogen-bonding capacity of the solutes. The results, which can be used to predict the ability of further compounds to cross the lysosome membrane by unassisted diffusion, are discussed in the context of metabolite and drug release from lysosomes in vivo.     

Expression of rat liver Na+/L-alanine co-transport in Xenopus laevis oocytes. Effect of glucagon in vivo.

Poly(A)+ RNA (mRNA) isolated from rat liver was injected into Xenopus laevis oocytes, and expression of Na+/L-alanine transport was assayed by measuring Na(+)-dependent uptake of L-[3H]alanine. Expression of Na+/L-alanine transport was detected 3-7 days after mRNA injection, and was due to an increment of the Na(+)-dependent component. After injection of 40 ng of total mRNA, Na(+)-dependent uptake of L-alanine was 2.5-fold higher than in water-injected oocytes. In contrast with Na+/L-alanine transport by water-injected oocytes, expressed Na+/L-alanine transport was inhibited by N-methylaminoisobutyric acid, was inhibited by an extracellular pH of 6.5 and was saturated at approx. 1 mM-L-alanine. After sucrose-density-gradient fractionation, highest expression of Na+/L-alanine uptake was observed with mRNA of 1.9-2.5 kb in length. Compared with mRNA isolated from control rats, mRNA isolated from glucagon-treated rats showed a approx. 2-fold higher expression of Na+/L-alanine transport. The results demonstrate that both liver Na+/L-alanine transport systems (A and ASC) can be expressed in X. laevis oocytes. Furthermore, the data obtained with mRNA isolated from glucagon-treated rats suggest that glucagon regulates liver Na+/L-alanine transport (at least in part) via the availability of the corresponding mRNA.     

Polyamines stimulate lysosomal cystine transport

Lysosomal cystine transport is a carrier-dependent process that, in isolated lysosomes, is stimulated by proton gradients, membrane potential, and millimolar concentrations of divalent cations. The importance of these regulatory factors in vivo is not well established. Polyamines were found to stimulate cystine transport in Percoll gradient purified rat liver lysosomes with spermidine greater than putrescine = cadaverine greater than spermine in order of effectiveness. Maximal stimulation was achieved with 500 microM spermidine. The effects of optimal concentrations of polyamines and divalent cations on cystine transport were not additive. Spermidine stimulated cystine efflux from lysosomes of cultured human diploid fibroblasts, but had no effect on lysosomes of cystinotic fibroblasts which have defective cystine transport. Spermidine did not accumulate within lysosomes in exchange for cystine, had no effect on lysosomal pH, had only slight effects on the lysosomal membrane potential, and had little effect on either methionine or tyrosine efflux. Polyamines are cellular cytoplasmic components that, in physiologic concentrations, stimulate lysosomal cystine transport.     

Active alanine transport in isolated brush border membranes.

Uptake of L-alanine against a concentration gradient has been shown to occur with isolated brush border membranes from rat small intestine. An alanine transport system, displaying the following characteristics, was shown: (a) L-alanine was taken up and released faster than D-alanine; (b) Na+ as well as Li+ stimulated the uptake of both stereoisomers; (c) the uptake of L- and D-alanine showed saturation kinetics; (d) countertransport of L-alanine was shown; (e) other neutral amino acids inhibited L-alanine but not D-alanine entry when an electrochemical Na+ gradient across the membrane was present initially during incubation. No inhibition occurred in the absence of a Na+ gradient. The electrogenicity of L-alanine transport was established by three types of experiments: (a) Gradients of Na+ salts across the vesicle membrane (medium concentration greater than intravesicular concentration) supported a transient uptake of L-alanine above equilibrium level, and the lipophilic anion SCN- was the most effective counterion. (b) A gradient of K= across the membrane (vesicle greater than medium) likewise supported active transport of L-alanine into the vesicles provided the K= conductance of the membrane was increased with valinomycin. (c) Similarly, a proton gradient (vesicle greater than medium) in the presence of carbonyl cyanide p-trifluoromethoxyphenylhydrazone, an agent known to increase the proton conductance of membranes, produced an overshooting L-alanine uptake. A consideration of the possible forces, existing under the experimental conditions, suggests that the gradients of SCN-, K+ in the presence of valinomycin, and H+ in the presence of carbonyl cyanide p-trifluoromethoxyphenylhydrazone contribute to the driving force for L-alanine transport by creating a diffusion potential. Since the presence of Na+ was required in all experiments with active L-alanine transport these results support the existence of a transport system in the brush border membrane which catalyzes the co-transport of Na+ and L-alanine across this membrane.     

Effects of ten steroids on acridine orange uptake and beta-N-acetylglucosaminidase levels in rat liver lysosomes.

Ten steroids have been compared for their ability to modify the rate of uptake of acridine orange by rat liver and by rat liver lysosomes in vivo. The short-term effects of the ten steroids on the specific activity of a lysosomal enzyme, beta-N-acetylglucosaminidase, were also compared. Five of the ten steroids were administered as tritium-labelled compounds and the concentration of steroids or metabolites was measured in rat liver and liver lysosomes at 2.5h and 3.75h after administration. Cortisone acetate, etiocholanolone (5-beta-androstan-3-alpha-01-17-one) and testosterone accelerate and increase the uptake of acridine orange by rat liver lysosomes. Deoxycorticosterone, corticosterone, triamcinolone (9-alpha-fluoro-11-beta, 17, 21-trihydroxy-16-alpha-methyl-pregna-1, 4-diene-3, 20-dione), estradiol-17-beta and progesterone appear to inhibit the uptake of acridine orange by rat liver lysosomes at 2.5 hours. Cortisol and dexamethasone (9-alpha-fluoro-11-beta, 17, 21-trihydroxy-16-alpha-methyl-pregna-1, 4-diene-3, 20-dione) had little effect. All steroids with the exception of etiocholanolone and deoxycorticosterone increase with the specific activity of beta-N-acetylglucosaminidase in the lysosomal fraction at 2.5h. None of the effects at 2.5h are due to lowered protein levels. Lysosomal concentrations of radioactivity following the administration of tritiated steroids were greated for the glucocorticoids, corticosterone and cortisol. Estradiol-17-beta, progesterone and testosterone showed much lower concentrations of radioactivity in isolated lysosomes. Most of the lysosomal radioactivity (73-96%) was associated with the soluble fraction of the disrupted lysosomes.     

Stabilization of rat liver lysosomes by new anti-inflammatory steroids in vitro

Steroid acid esters, synthesized by modifying the 17-ketol side chain of prednisolone, were tested for their in vitro ability to stabilize heavy mitochondrial lysosomes prepared from rat liver. Membrane stabilization was determined by assessing capability of steroids to decrease extrusion of the marker enzymes (acid phosphatase, beta-glucuronidase and aryl sulfatase) from lysosomes incubated in hypo-osmotic sucrose-Tris acetate buffer. Results indicated that prednisolone (1) significantly inhibited the lysosomal release of acid phosphatase as did the new anti-inflammatory steroid, methyl 20-dihydroprednisolonate. Methyl prednisolonate exhibited weak membrane stabilization capacities and 20-dihydroprednisolonic acid, a metabolic product of methyl 20-dihydroprednisolonate, showed virtually no membrane stabilization.     

Fate of N-(2-hydroxypropyl)methacrylamide copolymers with pendent galactosamine residues after intravenous administration to rats

N-(2-Hydroxypropyl)methacrylamide (HPMA) copolymers bearing galactosamine residues accumulate in the liver after intravenous administration to rats (Duncan, R., Kopec̆ek, J., Rejmanová, P. and Lloyd, J.B. (1983) Biochim. Biophys. Acta 755, 518–521). In this study HPMA copolymers bearing pendent galactosamine residues (1.0–11.6 mol%) were injected intravenously intor rats and their rates of blood clearance and liver accumulation were measured. A level of substitution of 4 mol% was found to be sufficient to cause substantial deposition in the liver 30 min after administration. The most highly substituted polymer (11.6 mol%) was directed rapidly to the liver, 80–90% being recovered there less than 10 min after administration. Separation of liver into hepatocytes and non-parenchymal cells indicated that polymer was largely associated with the hepatocytes, and density-gradient subcellular fractionation of liver at various times after administration confirmed that polymer was internalized by liver cells and transported, with time, into the secondary lysosomes. Experiments using isolated rat hepatocytes indicated that HPMA copolymers with high galactosamine content have higher affinity for the hepatocyte plasma membrane. HPMA copolymers containing galactosamine and in addition glycylglycyltyrosianmide side-chains were used to demonstrate release of a drug analogue across the lysosomal membrane. These polymers were radioiodinated and, following intravenous administration to rats, the liver lysosomes were isolated and incubated at 37°C in 0.25 M sucrose. Radioactivity was released from the lysosomes faster than the lysosomal enzyme arylsulphatase, an observation that indicates intralysosomal hydrolysis of the copolymer side-chain with subsequent passage of low molecular weight degradation product across the lysosomal membrane.     

Subcellular distribution of rat liver porin

The subcellular distribution of rat liver porin was investigated using the immunoblotting technique and monospecific antisera against the protein isolated from the outer membrane of rat liver mitochondria. Subfractionation of mitochondria into inner membranes, outer membranes and matrix fractions revealed the presence of porin only in the outer membranes. Porin was also not detected in highly purified subcellular fractions, including plasma membranes, nuclear membranes, Golgi I and Golgi II, microsomes and lysosomes. Thus, liver porin is located exclusively in the outer mitochondrial membrane.     

Transport of acid phosphatase to lysosomes does not involve passage through the cell surface

In foregoing studies, we reported that LGP107, a major lysosomal membrane glycoprotein in the rat liver, distributes in and circulates continuously throughout the endocytic membrane system (endosomes, lysosomes and plasma membrane), in hepatocytes (1,2). In the present study we examined whether acid phosphatase (APase), an enzyme that is transported to lysosomes as a transmembrane protein, passes through the cell surface during intracellular transport, because transport of newly synthesized APase to lysosomes involves the passage of endosomes containing a ligand which is internalized via receptors on the cell surface and is finally dispatched to lysosomes for degradation (3). When localization of APase in rat hepatocytes was investigated by immunoelectron microscopy, APase was found to be localized in lysosomes and endosomes, but not in coated pits on the cell surface, which are positive for LGP107, and from which antibodies for LGP107 are internalized. Further, unlike LGP107, newly synthesized APase was not detected in plasma membranes isolated from livers of rats given [35S]methionine, and when cultured hepatocytes were exposed to 125I-labeled anti APase IgG at 37 degrees C, there was no transfer of the antibody to lysosomes even after 24 h incubation. Therefore, these results indicate that intracellular movement of APase does not involve cell surface passage in rat hepatocytes, and clearly differs from the recent report that human APase is transported to lysosomes via the cell surface in BHK cells transfected with its cDNA (4).     

Isolation of an anorexigenic protein from membranes

Satiety means an internal state that leads to termination of eating. We have isolated an anorexigenic glycoprotein (MW 50,000 dalton) from human and rat erythrocyte membrane and from rat liver plasma membrane. The substance isolated from all these membrane sources has almost same onset and offset anorectic effect in rats deprived of food for 96 h as well as in normally fed rats without any rebound. Similar properties of membrane anorectic substance and plasma satietin indicated that it has membrane origin. The results also suggest that the loss of appetite in chronic diseases involving damage or turn-over of cell membranes could be due to release of a glycopeptide from cellular membranes into the circulation.     

Temporal relationship of free radical-induced lipid peroxidation and loss of latent enzyme activity in highly enriched hepatic lysosomes

Loss of latency due to membrane lipid peroxidation induced in vitro was studied in highly purified rat liver lysosomes. Enriched fractions of lysosomes were isolated by free flow electrophoresis. Lipid peroxidation of lysosomes, assayed as malondialdehyde formation, was catalyzed by a radical generating system consisting of dihydroxyfumaric acid and Fe3+-ADP. The peroxidation reaction occurred readily at 37 degrees C and reached a plateau at 10 min; however, the loss of lysosomal latency, determined as increased percentage free beta-N-acetylglucosaminidase activity, occurred more gradually and reached a maximum after 30 min. Scavengers of superoxide, hydrogen peroxide, singlet oxygen, and hydroxyl radicals did not inhibit the peroxidation reaction nor prevent the loss of lysosomal latency. However, preincubation of the lysosomes with alpha-tocopherol effectively blocked the induction of peroxidation and substantially reduced the loss of lysosomal latency. These results indicate that the lysosomal membrane is susceptible to free radical-induced lipid peroxidation; further, this process may be the immediate cause of the subsequent disintegration of the lysosome. The nature of the protective effect of alpha-tocopherol is unclear but may be due to its interaction with the unsaturated membrane lipids and the subsequent interruption of the chain-reaction initiated by free radicals.     

Excess generation of endogenous heme inhibits L-alanine:4,5-dioxovalerate transaminase in rat liver mitochondria

In the present study, we examined the possibility that the excess heme generation within mitochondria may provide a local concentration, sufficient to inhibit the activity of L-alanine:4,5-dioxovalerate transaminase, the enzyme proposed for an alternate route of delta-aminolevulinic acid biosynthesis in mammalian system. This was accomplished by assaying together L-alanine:4,5-dioxovalerate transaminase and heme synthetase activities in intact mitochondria isolated from rat liver. Endogenous heme in intact mitochondria has been generated in excess, by increasing the concentration of the substrate of heme synthetase. Our studies showed that the activity of L-alanine:4,5-dioxovalerate transaminase decreased as the rate of heme formation increased. In intact mitochondria, almost 50% inhibition of alanine:4,5-dioxovalerate transaminase was obtained with 4.0 mumole of heme generation. We conclude that end product inhibition of L-alanine:4,5-dioxovalerate transaminase by hemin, which was proposed in earlier report by us (FEBS Letter (1985), 189, 129), is an important physiological mechanism for the regulation of hepatic heme biosynthesis.     

Effect of the permeability of lysosomal and mitochondrial membranes on the ability of their cryoextracts to inhibit the protein-synthesizing activity of cell-free systems

Changes in permeability of lysosomal and mitochondrial membranes were studied under different temperatures at which cryoextracts from organelles inhibit most distinctly the protein synthesizing activity of the cell-free system from the rat liver. It is found that mitochondria are more sensitive to the effect of low temperature effect than lysosomes. Overcooling of the mitochondria suspension to the temperature of the free water crystallization is shown to cause no release of the protein synthesis inhibitor. The inhibitor release from organelles occurs from the moment of crystallization and reaches its maximum at the eutectic temperatures of the freezing medium which is due to the injury effect of the complex of physicochemical factors on the membrane structures, occurring during the phase transition of the solvent.     

Characteristics of hepatic alanine-glyoxylate aminotransferase in different mammalian species.

Mitochondrial extracts of dog, cat, rat and mouse liver contain two forms of alanine-glyoxylate aminotransferase (EC 2.6.1.44): one, designated isoenzyme 1, has mol.wt. approx. 80 000 and predominates in dog and cat liver; the other, designated isoenzyme 2, has mol.wt. approx. 175 000 and predominates in rat and mouse liver. In rat and mouse liver, isoenzyme 1 activity was increased by the injection in vivo of glucagon, but not isoenzyme 2 activity. Isoenzyme 1 was purified and characterized from liver mitochondrial extracts of the four species. Both rat and mouse enzyme preparations catalysed transamination between a number of L-amino acids and glyoxylate, and with L-alanine as amino donor the effective amino acceptors were glyoxylate, phenylpyruvate and hydroxypyruvate. In contrast, both dog and cat enzyme preparations were specific for L-alanine and L-serine with glyoxylate, and used glyoxylate and hydroxypyruvate as effective amino acceptors with L-alanine. Evidence that isoenzyme 1 is identical with serine-pyruvate aminotransferase (EC 2.6.1.51) was obtained. Isoenzyme 2 was partially purified from mitochondrial extracts of rat and mouse liver. Both enzyme preparations were specific for L-alanine and glyoxylate. On the basis of physical properties and substrate specificity, it was concluded that isoenzyme 2 is a separate enzyme. Some other properties of isoenzymes 1 and 2 are described.     

The membrane-stabilizing action of zinc carnosine (Z-103) in stress-induced gastric ulceration in rats

Zinc compounds have been shown to antagonize various types of gastric ulceration in rats. Zinc carnosine (Z-103), a newly developed agent was, therefore, examined for its antiulcer effect in stress-induced ulceration and also its membrane stabilizing action in rat stomachs. Cold-restraint (restrained at 4 degrees C for 2 h) stress induced severe hemorrhagic lesions together with increased mast cell degranulation and beta-glucuronidase release in the gastric glandular mucosa. Z-103 pretreatment with a single oral dose (3, 10 or 30 mg/kg) reversed these actions in a dose-dependent manner. When the compound was incubated in concentrations of 10(-7, 10(-6), 10(-5) or 10(-4) M, with isolated hepatic lysosomes, it significantly reduced the spontaneous release of beta-glucuronidase in the medium. The present study not only demonstrates the antiulcer effect of Z-103 but also indicates that the protective action is likely to be mediated by its membrane-stabilizing action on mast cells and lysosomes in the gastric glandular mucosa.     

Structural and physical changes in lysosomes from isolated rat hepatocytes treated with methylamine

Incubation of isolated rat hepatocytes with 10 mM methylamine resulted in an inhibition of endogenous protein degradation and a microscopically visible enlargement of the lysosomes. Lysosomes from methylamine-treated cells exhibited increased buoyancy in metrizamide gradients and increased fragility as measured by the release of acid phosphatase activity in vitro, despite the fact that no methylamine remained in the gradient-isolated organelles. When methylamine was extracted from intact cells, the inhibition of protein degradation was immediately relieved, whereas the lysosomal enlargement (and to a certain extent also the increased fragility) persisted for some time. The methylamine-induced osmotic swelling of the lysosomes would thus seem to involve not merely a passive stretching of the lysosomal membrane, but rather some structural change (e.g., an increased amount of membrane material) which is relatively slowly reversible, but without effect on lysosomal function.