Large-scale preparation of highly purified lysosomes from normal rat liver

Lysosomes from rabbit type II cells catabolize surfactant lipids

The role of a lysosome fraction from rabbit type II cells in surfactant dipalmitoylphosphatidylcholine (DPPC) catabolism was investigated in vivo using radiolabeled DPPC and dihexadecylphosphatidylcholine (1, 2-dihexadecyl-sn-glycero-3-phosphocholine; DEPC), a phospholipase A(1)- and A(2)-resistant analog of DPPC. Freshly isolated type II cells were gently disrupted by shearing, and lysosomes were isolated with Percoll density gradients (density range 1.0591-1.1457 g/ml). The lysosome fractions were relatively free of contaminating organelles as determined by electron microscopy and organelle marker enzymes. After intratracheal injection of rabbits with [(3)H]DPPC and [(14)C]DEPC associated with a trace amount of natural rabbit surfactant, the degradation-resistant DEPC accumulated 16-fold compared with DPPC in lysosome fractions at 15 h. Lysosomes can be isolated from freshly isolated type II cells, and lysosomes from type II cells are the primary catabolic organelle for alveolar surfactant DPPC following reuptake by type II cells in vivo.

Human acetyl-coenzyme A:alpha-glucosaminide N-acetyltransferase. Kinetic characterization and mechanistic interpretation

Acetyl-CoA: alpha-glucosaminide N-acetyltransferase (N-acetyltransferase) is an integral lysosomal membrane protein which catalyses the transfer of acetyl groups from acetyl-CoA on to the terminal glucosamine in heparin and heparan sulphate chains within the lysosome. In vitro, the enzyme is capable of acetylating a number of mono- and oligo-saccharides derived from heparin, provided that a non-reducing terminal glucosamine is present. We have prepared highly enriched lysosomal membrane fractions from human placenta by a combination of differential centrifugation and density-gradient centrifugation in Percoll. This preparation was used to investigate the kinetics of the enzyme with three acetyl-acceptor substrates, i.e. glucosamine and a disaccharide and a tetrasaccharide derived from heparin, each containing a terminal glucosamine residue. The enzyme showed a pH optimum at 6.5, extending to 8.0 for the mono- and di-saccharide substrates but falling off sharply above pH 6.5 for the tetrasaccharide substrate. We identified two distinct Km values for the glucosamine substrate at both pH 7.0 and pH 5.0, whereas the tetrasaccharide substrate displayed only a single Km value at each pH. The Km values were found to be highly pH-dependent, and at pH 5.0 the values for the acetyl-acceptor substrates showed a decreasing trend as the size of the substrate increased, suggesting that the enzyme recognizes an extended region of the non-reducing terminus of the heparin or heparan sulphate polysaccharides. Double-reciprocal analysis, isotope exchange between N-acetylglucosamine and glucosamine, and inhibition studies with desulpho-CoA indicate that the enzyme operates by a random-order ternary-complex mechanism. Product inhibition studies display a complex pattern of dead-end inhibition. Taken in context with what is known about lysosomal utilization and physiological levels of acetyl-CoA, these results suggest that in vivo the enzyme operates via a random-order ternary-complex mechanism which involves the utilization of cytosolic acetyl-CoA to transfer acetyl groups on to the terminal glucosamine residues of heparin within the lysosome.

Isolation of highly purified rat liver lysosomal membranes using two Percoll gradients

Normal rat liver lysosomal membranes in the form of membrane vesicles have been purified using Percoll density gradient centrifugation. Lysosomes (density = 1.111) were purified approximately 63 +/- 12-fold (mean +/- standard deviation, n = 5) using a gradient of Percoll made isotonic with sucrose and buffered to pH 7.0. These lysosomes were then exposed to 10 mM methionine methyl ester, pH 7.0, the uptake of which resulted in swelling and breakage of the lysosomes with subsequent vesicle formation. These vesicles (density = 1.056) were further separated from residual mitochondrial and plasma membrane enzyme activities using a second Percoll density gradient. Marker enzyme analysis and electron microscopy indicated that the lysosomal membranes were essentially free of both beta-hexosaminidase, a soluble lysosomal enzyme, and contaminating organelles. The specific activity of lysosomal ATPase in the lysosomal membranes was fourfold greater than in the intact lysosomes.

Lysosomes of the renal cortex: heterogeneity and role in protein handling

Rate sedimentation of the kidney cortical mitochondrial/lysosomal (ML) fraction yields two distinct classes of lysosomes: the large lysosomes or protein droplets and a heterogeneous broad band of smaller lysosomes. The protein droplets which are recovered as a well defined zone of high purity also sediment as a homogeneous band after equilibrium banding at a density of 1.235 g/ml in sucrose. The small lysosomes co-sediment with other subcellular organelles as a broad band, indicated by the distribution of various acid hydrolases, which exhibit subtle heterogeneity among these small lysosomes. The distribution of renin containing granules indicates that in size they represent a distinct subpopulation of small lysosomes. Further fractionation of small lysosomes by equilibrium banding separates two distinct populations at densities 1.20 (small light) and 1.235 g/ml (small dense). Comparison of lysosomal populations fractionated in these studies with the distribution of lysosomal acid hydrolases along the different segments of the nephron suggests that large and small dense lysosomes probably originate from the proximal tubule while the small light lysosomes may contain lysosomes from the distal tubule. Very small, lysosome-like organelles subfractionated from the 'microsomes' may constitute a mixture of small light lysosomes, lysosomal fragments and endocytic vesicles from a variety of cell types. Time course studies with 3H labelled Cd-thionein, following intravenous administration, suggests that uptake in the kidney cortex is very rapid and that catabolism takes place in two distinct phases: rapid breakdown starting in the endosome compartment and slower breakdown in lysosomes. From the association of labelled lysozyme (125I) and Cd-thionein (109Cd) it appears that all the different lysosomal populations identified are at some stage involved with uptake and catabolism of these two proteins.

Mechanism of unbalanced growth-induced cell damage. I. A probable role for hydrolytic enzymes synthesis

This study examines the relationship between cell progress into the state of unbalanced growth, hydrolytic enzyme activities and cell survival during the exposure of L5178Y cells to hydroxyurea (HU), excess thymidine (dThR), hydroxyurea with excess of four deoxyribonucleosides (dNR) or excess dTHR with deoxycytidine (dCR). Cell progress into the state of unbalanced growth was measured as cell size, protein/DNA ratio and protein content per cell. Activities of two lysosomal (acid phosphatase, beta-N-acetylglucosaminidase) and one cytoplasmic non-lysosomal (LDH) enzymes were determined. It has been found that in cells arrested by HU or excess dThR, a progressive cell volume increase with protein/DNA imbalance is correlated with a progressive increase in lysosomal and non-lysosomal hydrolase activities in the cells and in the medium and with a marked lethal effect. Cell volume increase, enhancement of enzyme activities and cell killing could be prevented in HU-arrested cells by concomitant addition of excess dNR (deoxyadenosine, deoxyguanosine, thymidine, deoxycytidine) leading to equal inhibition of DNA and protein synthesis. Control-like values of all parameters were achieved also in cells in which the dThR-inhibiting effect was reversed by dCR addition. It is suggested that a common pathway in the mode of action of the chemotherapeutic agents inducing cell killing through the state of unbalanced growth can be the over-production, abnormal accumulation and progressive leakage of numerous hydrolytic enzymes through the cell membranes, leading in consequence to 'lytic' cell death.

Isolation of pig thyroid lysosomes. Biochemical and morphological characterization

Open thyroid follicles were prepared by mechanical disruption of pig thyroid fragments through a metal sieve. This procedure allowed preparation of thyroid-cell material depleted of colloid thyroglobulin. Open thyroid follicles were used to prepared a crude particulate fraction, which contained lysosomes, mitochondria and endoplasmic reticulum. These organelles were subfractionated by isopycnic centrifugation on iso-osmotic Percoll gradients. A lysosomal peak was identified by its content of acid hydrolases: acid phosphatase, cathepsin D, beta-galactosidase and beta-glucuronidase. The lysosomal peak was well separated from mitochondria and endoplasmic reticulum. The lysosomal peak, from which Percoll was removed by centrifugation, was taken as the purified lysosome fraction (L). Lysosomes of fraction L were purified 45-55-fold (as compared with the homogenate) and contained about 5% of the total thyroid acid hydrolase activities. Electron microscopy showed that fraction L was composed of an approx. 90% pure population of lysosomes, with an average diameter of 220 nm. Acid hydrolase activities were almost completely (80-90%) released by an osmotic-pressure-dependent lysis. Thyroglobulin was identified by polyacrylamide-gel electrophoresis as a soluble component of the lysosome fraction. In conclusion, a 50-fold purification of pig thyroid lysosomes was achieved by using a new tissue-disruption procedure and isopycnic centrifugation on Percoll gradient. The presence of thyroglobulin indicates that the lysosome population is probably composed of primary and secondary lysosomes. Isolated thyroid lysosomes should serve as an interesting model to study the reactions whereby thyroid hormones are generated from thyroglobulin and released into the thyroid cells.

The effects of aspirin and dimethyl sulphoxide on the latency of lysosomes in a cell-free system

Lysosomal preparations were exposed to various concentrations of dimethylsulphoxide (DMSO) and aspirin singularly and in combination. Acid phosphatase and beta-glucuronidase activities were measured and utilized as an indication of lysosomal membrane stability under experimental conditions in the presence and absence of these drugs. Extremely low concentrations of each drug were employed in an attempt to mimic the levels which might be feasible in vivo. There was a significant decrease of enzyme activity (increased structure-linked latency) in the presence of DMSO. Aspirin had no significant effect on the latency of the lysosomes. There was no indication of synergism between DMSO and aspirin. It was concluded that some of the therapeutic advantages attributed to DMSO in the treatment of arthritis and other musculoskeletal diseases may come from the stabilization of lysosomes in cells that contribute to the pathological condition. Aspirin did not seem to exert a therapeutic effect through this mechanism.

Improved recovery of rat liver fractions enriched in lysosomes by specific alteration of the sedimentation properties of mitochondria

A method for the preparation of lysosomes from rat liver is presented. The procedure requires only standard equipment and is completed within less than 3 h. Homogenization and differential centrifugation were performed at pH 7.4 in isotonic potassium phosphate-buffered sucrose medium. The addition of potassium phosphate, at the concentration used (10 mM), accelerated the sedimentation rate of mitochondria without altering that of lysosomes resulting in the decrease in the mitochondrial contamination of the final pellet. Further purification was achieved by isopycnic centrifugation in 45% isotonic Percoll performed in an angle rotor. Lysosomal fractions representing 51.5% of the original population were recovered over a density range of 1.09 to 1.15 g/ml. The most purified fraction (37-fold purified) contained 25.3% of lysosomal beta-N-acetylglucosaminidase, and only 0.9% of mitochondrial monoamine oxidase and 0.6% of peroxisomal urate oxidase original activities. It was practically devoid to endoplasmic reticulum contamination.

Sugar transport in rat liver lysosomes. Direct demonstration by using labelled sugars

Purified rat liver lysosomes ('tritosomes') were prepared from rats injected with Triton WR-1339. 2. The water space of tritosomes, measured by using [3H]water and [14C]sucrose, was 2.15 +/- 0.72 microliter/mg of protein (mean +/- S.E.M., n = 12). 3. Tritosomes, when compared with a crude preparation of normal lysosomes by an indirect method of study, showed sugar specificity but decreased stereospecificity of sugar uptake. 4. At 125 mM the relative rates of net uptake of D-[14C]ribose, D-[14C]- or D-[3H]glucose and 2-deoxy-D-[3H]glucose were the same as that inferred from the indirect study. 5. The entry of D-[3H]glucose into tritosomes showed concentration-dependence suggestive of saturation, with a Km of 48 +/- 18 mM (4). 6. D- and L-glucose, D-ribose, 2-deoxy-D-glucose and D-mannose competed with D-[14C]glucose or D-[14C]ribose for uptake. 7. Cytochalasin B inhibited D-[3H]glucose uptake. 8. Uptake of 1 mM-L-[14C]glucose was slower than for 1 mM-D-[14C]glucose. 9. It is concluded that a facilitated-diffusion transport system is present in purified rat liver lysosomes.