Isopycnic density values for lysosomes and mitochondria in rat adrenal cortex

Adrenocortical tissues of male adult Wistar rats were fractionated by isopycnic density gradient centrifugation. Fractions were analyzed for density, protein and marker enzymes for lysosomes and mitochondria with rat liver being used as a reference tissue for subcellular enzyme distribution. Both lysosomes and mitochondria of adrenal cortex showed unimodal distribution profiles of marker enzymes with their modal isopycnic density values at 1.165. This value was significantly lower than the corresponding ones for lysosomes and mitochondria in rat liver but was very close to those in porcine adrenal cortex. Modal isopycnic density as well as distribution profiles of marker enzymes for lysosomes and mitochondria remained unchanged 24 hr after 0.1 or 10 units of ACTH (Cortrosyn Z) administration. As in porcine adrenal cortex, lysosomes in rat adrenal cortex were characterized by a higher content of cathepsin D than those in rat liver.     

A centrifugation study of rat-liver mitochondria, lysosomes and peroxisomes during the perinatal period.

We have investigated the intracellular distribution of several enzymes on homogenates of late foetal, early postnatal and adult rat livers. Homogenates were subjected to differential centrifugations in 0.25 M sucrose and four fractions were isolated which corresponded to the N (nuclear) ML (total mitochondrial) P (microsomal) and S (soluble) fractions of de Duve et al. (1955). In general the age of the animal did not significantly affect the distribution pattern. Reference enzymes of mitochondria, lysosomes and peroxisomes were mainly recovered in the total mitochondrial fraction (ML). Glucose-6-phosphatase and esterase, both located in the endoplasmic reticulum, were chiefly associated with the microsomal fraction P together with galactosyltransferase (a reference enzyme of the Golgi apparatus). 5'-Nucleotidase, (a plasma membrane enzyme) exhibits a bimodal distribution and is mainly recovered in the N and the P fractions. Such results indicate that the membrane composition of the fractions isolated by the fractionation scheme was used, does not appreciably differ for the late foetal, early postnatal and adult rat livers. An analytical fractionation of the mitochondrial (ML) fraction of livers at different stages of development was performed by isopycnic centrifugation in sucrose gradients and in glycogen gradients using sucrose solutions of various concentrations as the solvents. The distribution of mitochondria, lysosomes and peroxisomes were assessed by establishing the distribution of their reference enzymes. Some physical characteristics of the particles were deduced from the manner in which the distributions were influenced by the sucrose concentration of the centrifugation medium. The distribution of liver mitochondrial enzymes one day prenatal differs strikingly from that of enzymes one day postnatal; foetal mitochondria seem characterized by a high osmotic space and a high hydrated matrix density; neonatal mitochondria seem devoid of an osmotic space and the density of their hydrated matrix is markedly lower than that of the foetal mitochondria. As ascertained by the distribution of mitochondrial enzymes in a sucrose 2H2O gradient, the high density of a foetal mitochondria matrix does not mainly originate from a lower amount of hydration water. The behavior of lysosomal enzymes in media with increasing concentrations of sucrose suggests that lysosomes originating from late foetal rat liver are endowed with a very small osmotic space. As for the peroxisomes, our results do not display significant behavior differences in centrifugations that would indicate physicochemical changes of these particles during the perinatal period.     

A simple procedure for the isolation of highly purified lysosomes from normal rat liver

A procedure for the isolation of highly purified lysosomes from normal rat liver is described. The method depends on the swelling of mitochondria when the postnuclear supernatant fraction is incubated with 1 mM Ca2+. The lysosomes can then be separated from the swollen mitochondria by Percoll density gradient centrifugation. The lysosomal fraction obtained by our method was enriched more than 120-fold in terms of the marker enzymes with a yield of 25%. The electron microscopic examination and the measurement of the activities of marker enzymes for various subcellular organelles indicated that our lysosomal preparation was essentially free from contamination by other organelles.     

Characterization of porcine adrenocortical lysosomes

Porcine adrenocortical lysosomes were characterized by differential centrifugation, acid hydrolase contents, latency of cathepsin D, release of bound acid hydrolases in soluble form, and isopycnic density gradient centrifugation. Cathepsins D and B, beta-N-acetylglucosaminidase, beta-galactosidase and arylsulphatase were found exclusively in the lysosomes, while alpha-mannosidase and beta-glucuronidase were in both the lysosomal and microsomal fractions. The activity of cathepsin D was remarkably high, amounting to more than 6 times that in porcine liver and to more than 10 times that in liver of Sprague-Dawley rats in terms of units per g wet tissue. Porcine adrenocortical lysosomes showed a modal isopycnic density value of 1.155, but mitochondria a value of 1.145. The validity of these values was studied by investigating the possibilities of agglutination of organelles, damage to lysosomal membranes, disruption of mitochondria due to the hydrostatic pressure and by applying the same procedures of isopycnic centrifugation to hog and rat livers. After these validity tests, porcine adrenocortical lysosomes were concluded to be unique in their strikingly high content of cathepsin D as well as in their low modal isopycnic density which is very close to that of porcine adrenocortical mitochondria.     

Density gradient separation of two populations of lysosomes from rat parotid acinar cells

Exocrine acinar cells possess two cytochemically distinct populations of secondary lysosomes. One population is Golgi associated and has demonstrable acid phosphatase (AcPase) activity, whereas the second is basally located and lacks AcPase activity but has trimetaphosphatase (TMPase) activity. The basal lysosomes are tubular in shape and rapidly label with horseradish peroxidase (HRP) after intravenous injection. In the present study using isolated rat parotid acinar cells, the two lysosomal populations were separated by cell fractionation on Percoll density gradients and were analyzed biochemically and by EM cytochemistry. On 35% Percoll gradients, two peaks of AcPase and beta-hexosaminidase, both lysosomal marker enzymes, and succinic dehydrogenase, an enzyme marker for mitochondria, could be resolved. The major peaks of beta-hexosaminidase and succinic dehydrogenase and the minor peak of AcPase corresponded with the dense lysosome fraction. The major peak of AcPase and the minor peaks for beta-hexosaminidase and succinic dehydrogenase coincided with the light membrane fraction. Galactosyl transferase (a marker enzyme for Golgi saccules) and 5'-nucleotidase (a plasma membrane marker) were also associated with this fraction. By electron microscopy, the light membrane fraction was seen to contain tubular elements, multivesicular bodies (MVB), Golgi saccules, GERL, immature secretory granules, and some mitochondria. Electron microscopic cytochemical examination showed that these tubular structures were lysosomes. The dense lysosome fraction contained lysosomes positive for both AcPase and TMPase. After continuous incubation of isolated acinar cells with HRP, reaction product was rapidly localized to the light membrane fraction (greater than 2 min), where it was found in vesicles and tubular lysosomes. By 10 min it was present in MVB and tubular lysosomes, but by 60 min no HRP reaction product had appeared in the dense lysosomes. These results demonstrate that the tubular lysosomes are separable from dense lysosomes, typical secondary lysosomes, and are involved in the initial stages of endocytosis.     

Receptors for gonadotropins and prostaglandins in lysosomes of bovine corpora lutea.

The total mitochondrial fraction of bovine corpus luteum specifically bound [³H]prostaglandin (PG) E₁, [³H] PGF_2α, and ¹²⁵I-labeled human lutropin (hLH) despite very little 5′-nucleotidase activity, a marker for plasma membranes. Since the total mitochondrial fraction isolated by conventional centrifugation techniques contains both mitochondria and lysosomes, it was subfractionated into mitochondria and lysosomes to ascertain the relative contribution of these fractions to the binding. Subfractionation resulted in an enrichment of cytochrome c oxidase (a marker for mitochondria) in mitochondria and of acid phosphatase (a marker for lysosomes) in lysosomes. The lysosomes exhibited little or no contamination with Golgi vesicles, rough endoplasmic reticulum, or peroxisomes as assessed by their appropriate marker enzymes. Subfractionation also re ulted in [³H] PGE₁, [³H] PGF_2α, and ¹²⁵I-labeled hLH binding enrichment with respect to homogenate in lysosomes but not in mitochondria. The lysosomal binding enrichment and recovery were, however, lower than in plasma membranes. The ratios of marker enzyme to binding, an index of organelle contamination, revealed that plasma membrane and lysosomal receptors were intrinsic to these organelles. Freezing and thawing had markedly increased lysosomal binding but had no effect on plasma membrane binding. Exposure to 0.05% Triton X-100 resulted in a greater loss of plasma membrane compared to lysosomal binding. In summary, the above results suggest that lysosomes, but not mitochondria, in addition to plasma membranes, intrinsically contain receptors for PGs and gonadotropins. Furthermore, lysosomes overall contain a greater number of PGs and gonadotropin receptors compared to plasma membranes and these receptors are associated with the membrane but not the contents of lysosomes.     

Effects of methylcyclodextrin on lysosomes.

The cholesterol complexing agent methyl-cyclodextrin (MCD) provides an efficient mean for the removal of cholesterol from biological membranes. In order to study the effects of this agent on the lysosomal membrane in situ, we treated HepG2 cells with MCD and studied the effects of this treatment on lysosomes in isolated fractions. We found that lysosomes prepared from treated cells are more sensitive to various membrane perturbing treatments such as: incubation of lysosomes in isotonic glucose, in hypotonic sucrose or in the presence of the lytic agent glycyl-L-phenylalanine 2-naphthylamide. The lysosomal membrane is also less resistant to increased hydrostatic pressure. Centrifugation methods were used to analyse the effect of MCD on lysosomes. Isopycnic centrifugation in sucrose density gradients demonstrates that the drug induces a reversible density increase of the lysosomes. Our study indicates that extracellularly added MCD can modify the properties of the lysosomal membrane in living cells. It suggests that MCD could be an effective tool to modulate the physical properties of lysosomes within intact cells and to monitor the cellular responses to such modifications.     

A histochemical study of the effect of phenol on the mitochondria and lysosomes of cultured cells

Synopsis This study was undertaken to assess the effect of a known cytotoxic substance on the permeability of the organelle membranes of cultured cells. BHK-21 (C-13) cells were grown as monolayers on glass cover-slips and exposed for 1 h to 1 mg/ml and 2mg/ml phenol. The cover slips were recovered and incubated for the demonstration of acid phosphatase and succinate dehydrogenase, marker enzymes for lysosomes and mitochondria respectively. The density of final reaction product after various incubation times was measured using a scanning integrating microdensitometer. At a concentration of 1 mg/ml, phenol causes labilization of the lysosomes and consequent loss of enzyme, which is further enhanced at 2 mg/ml. The mitochondrial membranes also showed a marked increase in permeability after exposure to 1 mg/ml phenol, but to a lesser extent than that of lysosomes. The results are discussed in the context of cell damage and DNA synthesis. Address after 1 April 1978: Department of Operative Dentistry, Dental Hospital, 196 Goderich Street, Perth, Western Australia 6000.     

A novel method of imaging lysosomes in living human mammary epithelial cells

Cancer cells invade by secreting degradative enzymes which, under normal conditions, are sequestered in lysosomal vesicles. The ability to noninvasively label lysosomes and track lysosomal trafficking would be extremely useful to understand the mechanisms by which degradative enzymes are secreted in the presence of pathophysiological environments, such as hypoxia and acidic extracellular pH, which are frequently encountered in solid tumors. In this study, a novel method of introducing a fluorescent label into lysosomes of human mammary epithelial cells (HMECs) was evaluated. Highly glycosylated lysosomal membrane proteins were labeled with a newly synthesized compound, 5-dimethylamino-naphthalene-1-sulfonic acid 5-amino-3,4,6-trihydroxy-tetrahydro-pyran-2-ylmethyl ester (6-O-dansyl-GlcNH2). The ability to optically image lysosomes using this new probe was validated by determining the colocalization of the fluorescence from the dansyl group with immunofluorescent staining of two well-established lysosomal marker proteins, LAMP-1 and LAMP-2. The location of the dansyl group in lysosomes was also verified by using an anti-dansyl antibody in Western blots of lysosomes isolated using isopycnic density gradient centrifugation. This novel method of labeling lysosomes biosynthetically was used to image lysosomes in living HMECs perfused in a microscopy-compatible cell perfusion system.     

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.     

Evidence for NAD nucleosidase in rabbit-liver lysosomes.

A method is described for the isolation of secondary lysosomes from homogenates of rabbit liver; The uptake of Triton WR-1339 by rabbit-liver lysosomes when administered by intraperitoneal injection was used to decrease the density of secondary lysosomes. Lysosomal fractions prepared by this method contain an NAD nucleosidase (NAD glycohydrolase, EC 3;2.25), an enzyme which has previously been considered to be associated with other subcellular fractions. The enzyme has maximum activity at pH 6 and cleaves both NAD and NADP. It is inhibited by nicotinamide (Ki equals 4.5 mM) and by HgCl2. Both nucleosidase and 2'-nucleotidase show in-vitro latency typical of lysosomal acid hydrolases. Rabbit-liver plasma-membrane fractions were isolated which contained most 5'-nucleotidase but relatively little nucleosidase, whereas rabbit liver lysosomes contain both 5'-nucleotidase and nucleosidase enzymes but little adenyl cyclase.     

Identification of two subpopulations of thyroid lysosomes: relation to the thyroglobulin proteolytic pathway.

Using a combination of differential centrifugation and isopycnic centrifugation in Percoll gradients, we obtained a highly purified preparation of thyroid lysosomes [Alquier, Guenin, Munari-Silem, Audebet & Rousset (1985) Biochem. J. 232, 529-537] in which we identified thyroglobulin. From this observation, we postulated that the isolated lysosome population could be composed of primary lysosomes and of secondary lysosomes resulting from the fusion of lysosomes with thyroglobulin-containing vesicles. In the present study, we have tried to characterize these lysosome populations by (a) subfractionation of purified lysosomes using iterative centrifugation on Percoll gradients and (b) by functional studies on cultured thyroid cells. Thyroglobulin analysed by soluble phase radioimmunoassay, Western blotting or immunoprecipitation was used as a marker of secondary lysosomes. The total lysosome population separated from other cell organelles on a first gradient was centrifuged on a second Percoll gradient. Resedimented lysosomes were recovered as a slightly asymmetrical peak under which the distribution patterns of acid hydrolase activities and immunoreactive thyroglobulin did not superimpose. This lysosomal material (L) was separated into two fractions: a light (thyroglobulin-enriched) fraction (L2) and a dense fraction (L1). L1 and L2 subfractions centrifuged on a third series of Percoll gradients were recovered as symmetrical peaks at buoyant densities of 1.12-1.13 and 1.08 g/ml, respectively. In each case, protein and acid hydrolase activities were superimposable. The specific activity of acid phosphatase was slightly lower in L2 than in L1. In contrast, the immunoassayable thyroglobulin content of L2 was about 4-fold higher than that of L1. The overall polypeptide composition of L, L1 and L2 analysed by polyacrylamide-gel electrophoresis was very similar, except for thyroglobulin which was more abundant in L2 than in either L or L1. The functional relationship between L1 and L2 lysosome subpopulations has been studied in cultured thyroid cells reassociated into follicles. Thyroid cells, prelabelled with 125I-iodide to generate 125I-thyroglobulin, were incubated in the absence of in the presence of inhibitors of intralysosomal proteolysis. The fate of 125I-thyroglobulin, and especially its appearance in the lysosomal compartment, was studied by Percoll gradient fractionation and immunoprecipitation. Treatment of prelabelled thyroid cells with chloroquine and leupeptin induced the accumulation of immunoprecipitable 125I-thyroglobulin into a lysosome fraction corresponding to the L2 subpopulation. In control cells, in which intralysosomal proteolysis was n     

A rapid procedure for the isolation of lysosomes from kidney cortex by Percoll density gradient centrifugation

Highly pure lysosomes were isolated from buffalo(Bubalus bubalis) kidney cortex by a procedure involving differential and isopycnic Percoll density gradient centrifugations. Arylsulphatase, N-acetyl-Β-glucosamindase and cathepsin D in the lysosomal preparation were 26–45-fold enriched over the homogenate. The purified lysosomes contained less than 0·06% of mitochondrial, microsomal and peroxisomal marker enzymes. In the electron micrographs the particles appeared as large dense granules of size 0·3-1·9 μm with no apparent structural features belonging to mitochondria or microsomes. The isolation procedure was also found to be suitable to obtain highly pure lysosome particles from renal cortex of other sources such as rat, lamb and beef. No ultracentrifugation steps were involved in the procedure     

Inhibition of the discharge of endocytosed protein from phagosomes into lysosomes in hepatoma cells exposed to dimerized ribonuclease A.

The mechanism of the cytostatic action of dimerized ribonuclease A toward cultured hepatoma cells was investigated. A decrease in mitotic index, modifications of adsorptive properties of the pericellular membrane and inhibition of the degradation of two different proteins taken up by endocytosis are the first cell functions to be affected by the dimer. This effect on protein digestion is not due to an inhibition of proteolytic enzymes. The intracellular localization of exogenous protein and of ribonuclease dimer was studied by cell fractionation. When proteins (horseradish peroxidase or rabbit immunoglobulin G) are taken up by control hepatoma cells, they are first associated with phagosomes equilibrating at a lower density than lysosomes; their density distribution gradually becomes similar to that of lysosomes. When cells are pre-exposed to ribonuclease dimer, this modification of the density distribution as a function of time no longer occurs, although these proteins are still intracellular, as indicated by fractionation by differential centrifugation. During the first hour after addition of ribonuclease dimer, kinetic studies show an increased fixation of peroxidase to the cell membrane. Protein release into the culture medium is also increased. These results can be explained either by an absence of fusion between phagosomes and lysosomes, or by an inhibition of the discharge of peroxidase adsorbed to the phagosomal membrane after fusion.     

Isolation of rat liver lysosomes by a single two-phase partition on dextran/polyethylene glycol.

Crude mitochondria from liver rats were added to a two-phase system containing dextran and polyethylene glycol. The polymer and ionic concentration values of the two-phase system were changed in order to separate lysosomes from mitochondria. The best separation of lysosomes and mitochondria was obtained at 6.6-6.6% (w/w) dextran-polyethylene glycol and 5 mmol/kg ammonium chloride as shown by enzyme assays. This procedure showed good reproducibility, and lysosomes were never contaminated with more than 16% mitochondria, as determined by succinate dehydrogenase activity, and beta-D-galactosidase and acid phosphatase activities were enriched five- to sixfold. The lipid composition profile of lysosomes was quite similar to that obtained by means of free carrier electrophoresis, considered a reference method.     

Characterization of rabbit lung lysosomes and their role in surfactant dipalmitoylphosphatidylcholine catabolism

Although alveolar surfactant is rapidly catabolized in adult rabbit lungs, the pathways have not been characterized. Pathways of surfactant secretion and recycling involve lamellar bodies and multivesicular bodies, organelles shown to be related to lysosomes by cytochemistry and autoradiography. Since lysosomes are central to intracellular catabolic events, it is possible that lysosomes are involved in intrapulmonary surfactant catabolism. Lysosomes relatively free of contaminating organelles (as determined morphologically and by marker enzymes for mitochondria, endoplasmic reticulum, peroxisomes, and plasma membranes) were obtained from post-lavage lung homogenates of 1-kg rabbits by differential centrifugation in buffered sucrose and gradient separation in percoll (density, 1.075-1.165). The role of lung lysosomes in catabolism of dipalmitoylphosphatidylcholine (DPC) was then studied in rabbits killed 4, 12, and 24 h following intratracheal injection of [3H]DPC and [14C] dihexadecyl phosphatidylcholine (DPC-ether). While equal amounts of label were in the lamellar body containing fractions at 4 h, nearly 6-fold more DPC-ether label than DPC label was recovered in the lysosomal fractions. By 24 h, there was 15-fold more DPC-ether in the lysosomes. This is the first report of successful isolation of lysosomes relatively free of other organelles from rabbit lungs. The tracer studies indicate DPC and DPC-ether follow similar intracellular processing after alveolar uptake. The subsequent accumulation of the ether analog in the lysosomal fractions supports a role for these organelles in surfactant DPC catabolism.     

Purification and characterization of lysosomes from Chinese hamster ovary cells

Lysosomes were isolated from Chinese hamster ovary cells by fractionation of a postnuclear supernatant in consecutive density gradients. By marker enzyme analysis, the preparation was 63-fold enriched for lysosomes compared to the homogenate and contained at most trace amounts of marker activities for plasma membrane, Golgi, endoplasmic reticulum, peroxisomes, cytosol, and mitochondria. The lysosomes were intact as indicated by greater than 95% latency of beta-hexosaminidase activity, and the yield was about 12% relative to the homogenate. By electron microscopy, the lysosomal preparation contained very few mitochondrial profiles. By cytochemistry, greater than 80% of the organelle profiles were positive for the native lysosomal marker, acid phosphatase, and profiles were positive for long-term internalized horseradish peroxidase, an endocytic marker for lysosomes. By sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the lysosomal preparation displayed a unique pattern of polypeptides and was devoid of mitochondrial contamination. Lysosomes were fractionated into membrane and lumenal compartments by Na2CO3 treatment. Each compartment contained 20-30 distinct electrophoretic species ranging from 18 to 200 kDa. Each polypeptide could be assigned to either the membrane or lumenal compartment. A comparison of silver-stained polypeptides with those metabolically labeled with [35S]methionine indicated that, with the possible exception of an 18-kDa species, all of the major lysosomal polypeptides in both compartments were derived by endogenous synthesis in these exponentially growing fibroblasts.     

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.     

Effect on lysosomes of invertase endocytosed by rat-liver

The intracellular localization of invertase endocytosed by rat liver was investigated by analytical centrifugation in sucrose and Percoll gradients of mitochondrial fractions originating from rats killed 15 h after injection. After isopycnic centrifugation in a sucrose gradient, invertase is located in higher density zones than acid hydrolases. The difference between the distribution of invertase and that of acid hydrolases increases with the amount of invertase injected. When the invertase dose is sufficiently high, a change of lysosomal enzyme distribution is clearly visible. It consists in the shift of a proportion of these enzymes to higher density regions where invertase is located. The proportion of hydrolase activity affected by invertase is different for each enzyme measured; it is the least pronounced for acid phosphatase, and most for acid deoxyribonuclease and arylsulfatase. A pretreatment of the rat with Triton WR 1339 considerably decreases the equilibrium density of structures bearing invertase. Nevertheless invertase distribution is quite distinct from that of the bulk of lysosomal enzymes that are recovered in lower density zones of the gradient; on the other hand the invertase injection to rats treated with Triton WR 1339 causes a spreading of the acid hydrolase distribution towards higher density zones. The distribution of acid hydrolases and invertase in a Percoll gradient depends on the sucrose concentration of the solvent. It is shifted towards higher densities when the sucrose concentration increases. The phenomenon is more important for invertase. These results are best explained by supposing that invertase accumulates in a distinct population of lysosomes that can be individualized as a result of the density increase they are subjected to by the invertase they accumulate. It is proposed that these lysosomes mainly originate from non-parenchymal cells of the liver.     

Structural changes in lysosomes from cultured human fibroblasts in Duchenne's muscular dystrophy

We have previously reported a decreased activity of the lysosomal enzyme dipeptidyl aminopeptidase-I (DAP-I) in cultured fibroblasts from patients with Duchenne's muscular dystrophy (DMD). Here we report that electron microscope examination of these cells reveals the presence of abundant lamellar bodies, a morphologic abnormalities commonly associated with impaired lysosomal function. Morphometric analysis of these cytoplasmic figures in dystrophic cells shows a sevenfold increase relative to normal controls (P less than 0.01). Analysis of lysosomal density profiles by density gradient centrifugation reveals similar patterns in normal and DMD cells. Treatment of lysosomes wit the nonionic detergent Triton X-100 causes an activation of DAP-I. This activation, attributable to structure-linked latency, is markedly diminished in DMD cells which show an optimal activation of only 180% compared to 255% for control fibroblasts (P less than 0.01). These data suggest an alteration in the properties of the lysosomal membrane in DMD fibroblasts. This suggestion is also supported by studies on the release of DAP-I from lysosomes by osmotic shock which show it to be a membrane-associated enzyme with membrane-binding characteristics intermediate between those of tightly bound beta-glucosidase and those of unbound N-acetylgalactosaminidase. The latency characteristics of these other lysosomal enzymes are not altered in the DMD cells, indicating that the effect is specific for DAP-I.