The isolation of purified neurosecretory vesicles from bovine neurohypophysis using isoosmolar density gradients

Two different density gradients are described for the isolation of highly purified fractions of neurosecretory vesicles in isoosmotic solutions (300 mosm/kg) from bovine neurohypophyses. The techniques involve differential centrifugation of neural lobe homogenates followed by density gradient centrifugation on metrizamide-sucrose or Percoll-sucrose gradients. The purified fraction contained 44 and 65 μg vasopressin/mg protein, respectively. Neurosecretory vesicles thus isolated were only slightly contaminated with other subcellular organelles, e.g., mitochondria and lysosomes. These vesicles were highly stable in isotonic sucrose solutions (pH 7.5 and 5.5) even at 37°C for at least 2 h, retaining more than 90% of their hormonal content.     

Receptor-mediated endocytosis of polymeric IgA and galactosylated serum albumin in rat liver. Evidence for intracellular ligand sorting and identification of distinct endosomal compartments

Rat polymeric IgA (pIgA) and galactosylated bovine serum albumin (GalBSA), once injected to rats, are avidly taken up by hepatocytes via receptor-mediated endocytosis. Of injected pIgA, 64% was transferred undigested into bile within 3 h, with a peak at 30-45 min. GalBSA was essentially digested in lysosomes. By electron microscopy using ligand-peroxidase conjugates, both ligands were internalized through coated pits/coated vesicles into similar electron-lucent vesicles and tubules. Subsequently, pIgA remained mostly associated with small vesicles clustering around and fusing with bile canaliculi, while GalBSA was predominantly found in large, heterogeneous endocytic structures and in lysosomes. By subcellular fractionation, they were associated at 3 min after injection with structures that similarly sedimented in the P fraction (250 000 - 3 X 10(6) X g X min) and equilibrated at densities of about 1.13 g/ml in sucrose gradients. At 10 min and 20 min, pIgA distribution remained mostly in the P fraction at the same equilibrium density. A minor component of the pIgA distribution was found at the density of lysosomes, but contrary to lysosomal enzymes, its distribution was not affected by Triton WR 1339. In contrast to pIgA, GalBSA was progressively recovered in the L fraction (33 000 - 250 000 X g X min) with organelles equilibrating around 1.11 g/ml, and, by 20-45 min, was found in the ML fraction (10 000 - 250 000 X g X min), around 1.20 g/ml, i.e. in lysosomes. Chloroquine did not reduce the efficiency but delayed the secretion of pIgA into bile. Similarly, it did not affect the uptake of GalBSA but apparently delayed GalBSA transfer along successive populations of host organelles. The low density, GalBSA-containing structures were devoid of proteolytic activity. Anti-secretory components IgG and F(ab')2 were selectively excreted into bile, partially or totally as compounds of lower molecular mass. These antibody fragments probably result from a disulfide reduction activity along the pIgA pathway. In conclusion, our data (a) strongly suggest that pIgA and GalBSA are sorted between 3 min and 10 min after injection in non-lysosomal acidic organelles, (b) identify two successive and physically distinct endosomal populations containing GalBSA, and (c) provide the first evidence for a disulfide reduction activity along the transcytotic pathway of rat hepatocytes.     

Studies on the isolation and properties of renin granules from the rat kidney cortex.

The present study was undertaken to isolate and investigate some physicochemical properties of renin granules from the rat kidney cortex. Two preparations of subcellular organelles were used: a primary-granule fraction, which allowed the properties of lysosomes to be compared simultaneously with those of renin granules, and a semi-purified preparation of the latter. The specific activity of renin in the primary-granule preparations was about 4-fold higher than in the original homogenate; that of the semi-purified renin-granule preparation was about 18-fold higher than in the homogenate, and consisted mainly of electron-dense granules but some mitochondria were also observed. Renin and acid phosphatase release from the primary-granule preparation was increased by lowering osmolality, by a low-molecular-weight solute (glucose) and by Triton X-100 or digitonin. Enzyme release was decreased by lowering the incubation temperature (4 degrees C) or the presence of CaCl2. Renin release from the partially purified granule preparation was not affected by cyclic AMP, cyclic GMP and ATP.     

Characterisation of gut hormones storage granules from normal human jejunum using metrizamide density gradients

Analytical subcellular fractionation techniques using metrizamide density gradients have been used to investigate the properties of the gut hormone storage granules and the principal organelles from homogenates of normal human jejunal mucoosa obtained by peroral mucosal biopsy. The individual hormones, detected by radioimmunoassay, each showed single discrete peaks in the density gradient experiments indicating localisation to single granules each with characteristic modal densities. Thus motilin showed a modal density of 1.15, gastrin 1.16, gastric inhibitory polypeptide (GIP) 1.17, enteroglucagon 1.18 and somatostatin and vasoactive intestinal peptide (VIP) 1.10 g/ml. The following organelles, characterised by their marker enzymes were located in the density gradients; plasma membrane (5′-nucleotidase) brush border (α-glucosidase, pH 6.0) mitochondria (particulate malate dehydrogenase), peroxisomes (catalase), lysosomes ($\text{N-}\text{acetyl-β-glucosaminidase}$), endoplasmic reticulum (α-glucosidase, pH 8.0), cytosol (lactate dehydrogenase). These studies provide biochemical evidence of the distinct nature of the individual gut hormone storage granules and provide a basis for studying dynamic changes in the granules in response to physiological stimuli and pathological processes.     

Receptor-mediated endocytosis in rat liver: purification and enzymic characterization of low density organelles involved in uptake of galactose-exposing proteins

Rat liver organelles involved in receptor-mediated endocytosis were labeled with a conjugate of galactosylated BSA to horseradish peroxidase [( 3H]galBSA-HRP), injected 10 min before sacrifice. These organelles were recovered at low density (1.11-1.13 g/ml) in sucrose gradients (Quintart, J., P. J. Courtoy, J. N. Limet, and P. Baudhuin, 1983, Eur. J. Biochem., 131:105-112). Upon incubation of such low density fractions in 3,3'-diaminobenzidine (DAB) and H2O2 and equilibration in a second sucrose gradient, galBSA-HRP-containing particles selectively shifted towards heavier densities (Courtoy, P. J., J. Quintart, and P. Baudhuin, 1984, J. Cell Biol., 98:870-876, companion paper), resulting in up to 250-to 300-fold purification with respect to the homogenate. The most purified preparations, wherein DAB- stained structures represented approximately 85% of the total volume of particles, contained only trace activities of enzymes usually regarded as markers for other subcellular entities. These minor activities could reflect either contamination or true enzyme association to the ligand- containing structures. Considering the latter hypothesis, at most 1.0% of alkaline phosphodiesterase I and 2.6% of 5'-nucleotidase (markers for plasma membrane), 3.6% of N-acetyl-beta-glucosaminidase (lysosomes), and 6.0% of galactosyltransferase (Golgi complex) from the homogenate would be associated with the whole population of ligand- containing organelles. After DAB cytochemistry on liver fixed 10 min after galBSA-HRP injection, ligand-containing structures accounted for 0.78-0.89% of the fractional volume of the hepatocytes and displayed a membrane area of 2,100 cm2/cm3, compared with 6,700 cm2/cm3 for the pericellular membrane. Altogether, our data support the hypothesis that these ligand-containing organelles are structurally distinct from plasma membrane, lysosomes, and Golgi complex.     

Isolation of the major subcellular organelles from mouse liver using Nycodenz gradients without the use of an ultracentrifuge

Commonly, subcellular organelles such as nuclei, mitochondria, lysosomes, and Golgi membranes are isolated first by differential centrifugation in low-speed or high-speed centrifuges and then purified by gradient centrifugation in ultracentrifuges. We have prepared these organelles using a new high-speed centrifuge (28,000 rpm max) which allows the generation of higher radial centrifugal forces (rcfs) than are available in standard machines. We have shown that most subcellular organelles can be purified by using low-viscosity Nycodenz gradients at rcfs lower than those normally used in ultracentrifuges, without increasing the time of centrifugation. Use of Nycodenz also allows rapid harvesting of material from gradients and we have adapted a number of enzyme assays to facilitate gradient analysis.     

Renin substrate in granules from rat kidney cortex.

1. Subcellular fractions of rat kidney cortex generated angiotensin I continuously over 2h when incubated at 37degreesC with rat renin, indicating the presence of renin substrate within cells in the renal cortex. 2. Renin substrate was located in highest specific concentration in particulate fractions. The particles containing renin substrate had a sedimentation velocity slightly lower than mitochondria and renin granules but greater than the microsomal fraction. 3. Isopycnic gradient centrifugation indicated a density of 1.190g/ml for the particles containing renin substrate, compared with 1.201 for renin granules, 1.177 for mitochondria, and 1.170 and 1.230 for lysosomes in the heavy-granule fraction. 4. In the liver, renin substrate was also found in particles, but these had a lower sedimentation rate than those from the kidney. 5. The molecular weights of renin substrate in kidney and liver granules and rat plasma were similar, namely 61000-62000. 6. On the basis of these biochemical findings, a mechanism for the intrarenal production of angiotensin, incorporating a subcellular reaction scheme, is proposed.     

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     

Isolation and characterization of organelles from soybean suspension cultures

Whole homogenates from cells of Glycine max grown in suspension culture were centrifuged on linear sucrose gradients. Assays for marker enzymes showed that distinct peaks enriched in particular organelles were separated as follows: endoplasmic reticulum (density 1.10 g/cm³, NADH-cytochrome-c reductase), Golgi membranes (density 1.12 g/cm³, inosine diphosphatase), mitochondria (density 1.18—1.19 g/cm³, fumarase, cytochrome oxidase) and microbodies (density 1.21—1.23 g/cm³, catalase). In cells which had ceased to grow (stationary phase) only a single symmetrical catalase peak at density 1.23 g/cm³ was observed on the sucrose gradient. During the phase of cell division and expansion a minor particulate catalase component of lighter density was present; its possible significance is discussed.     

The Preparation of Subcellular Organelles from Mouse Liver in Self-Generated Gradients of Iodixanol

This paper reports the use of a new density gradient compound, Iodixanol, for the resolution of the major organelles from mouse liver. A major advantage of Iodixanol over other iodinated density gradient media is its ready ability to form self-generated gradients. Gradient-forming conditions have been modulated to provide optimal recoveries of Golgi membranes, lysosomes, mitochondria, and peroxisomes. The organelles were isolated in high yield (80-90% of gradient input) and high purity. Nycodenz and Iodixanol were compared using preformed gradients. Iodixanol provided resolution superior to that of Nycodenz, notably of peroxisomes and mitochondria and the separation of lysosomes from endoplasmic reticulum. Because Iodixanol does not interfere significantly with marker enzyme activities, gradient fractions can be analyzed without removal of the gradient medium.     

Developing Dictyostelium cells contain the lysosomal enzyme alpha- mannosidase in a secretory granule

The prespore vesicle (PSV) is an organelle which secretes spore coat proteins and gal/galNAc polysaccharides from prespore cells of Dictyostelium. By combining the techniques of protein A-gold immunocytochemistry and ricin-gold affinity cytochemistry we have demonstrated colocalization of the lysosomal enzyme alpha-mannosidase with gal/galNAc polysaccharides in prespore vesicles and the spore coat. To determine the origin of prespore vesicles a series of pulse- chase experiments were performed. Cells were labeled with [35S]methionine or [35S]sulfate at different times during development and allowed to differentiate in the presence of unlabeled methionine or sulfate for various periods of time. The cells were homogenized and intracellular organelles were separated using Percoll density gradient centrifugation. The distribution of [35S]methionine-labeled alpha- mannosidase and [35S]sulfate-labeled glycoproteins in the Percoll gradients was determined. It was found that prespore vesicles contained protein which was previously found in lysosomes. Newly labeled protein also entered these vesicles. The data suggest that developing Dictyostelium cells either restructure preexisting lysosomes into prespore vesicles or transport protein between these two organelles. We propose that secretory granules and lysosomes may have a common biosynthetic origin and may be evolutionarily related.     

Development and fate of the secretory granules of juxtaglomerular epithelioid cells

Summary The development and fate of the secretory granules in murine, rat and human juxtaglomerular epithelioid cells were examined using ultrastructural and immunocytochemical methods. The formation of mature renin granules occurs by fusion of rhomboid protogranules followed by coalescence of their paracrystalline contents, and by the fusion of roundish juvenile granules having an amorphous internum. Protogranules with paracrystalline contents are prominent in animals with stimulated renin synthesis, indicating an overcharge in processing and/or packaging of the secretory product, renin, under these conditions. Various similarities between lysosomes/multivesicular bodies (MVBs) and juvenile renin granules have been observed. With the exception of small MVBs, no renin-negative organelles that could be regarded as lysosomes were found in epithelioid cells of mice and rats. Therefore, we suggest that renin granules are modified lysosomes. Immunocytochemical findings indicate that juvenile secretory granules of epithelioid cells represent the converting and activating compartment for prorenin. Endocytosed foreign tracers such as HRP or cationized ferritin are preferentially internalized by juvenile renin granules, which hence appear to be outstanding by their fusogeneity. Consequently, juvenile granules are probably responsible for the secretion of prorenin, and mature granules for that of active renin.These studies were supported by the German Research Foundation within the Forschergruppe Niere/Heidelberg     

Analytical subcellular fractionation of needle-biopsy specimens from human liver.

1. Fragments (2-20 mg wet wt.) of closed needle-biopsy specimens from human liver were disrupted in iso-osmotic sucrose and subjected to low-speed centrifugation. The supernatant was layered on a linear sucrose-density gradient in the Beaufay small-volume automatic zonal rotor. The following organelles, with equilibrium densities (g/ml) and principal marker enzyme shown in parentheses, were resolved: plasma membrane (1.12-1.14; 5'-nucleotidase); lysosomes (1.15-1.20; N-acetyl-beta-glucosaminidase); mitochondria (1.20; malate dehydrogenase); endoplasmic reticulum (1.17-1.21; neutral alpha-glucosidase); peroxisomes (1.22-1.24; catalase). 2. The distribution of particulate alkaline phosphatase and, to a lesser degree, leucine 2-naphthylamidase followed that of 5'-nucleotidase. gamma-Glutamyltransferase was associated with membranes of significantly higher equilibrium density than was 5'-nucleotidase. 3. The distribution of 12 acid hydrolases was determined in the density-gradient fractions. beta-Glucosidase had a predominantly cytosolic localization, but the other enzymes showed a broad distribution of activity throughout the gradient. Evidence was presented for two populations of lysosomes with equilibrium densities of 1.15 and 1.20 g/ml, but containing differing amounts of each enzyme. Further evidence of lysosomal heterogeneity was demonstrated by studying the distribution of isoenzymes of hexosaminidase and of acid phosphatase. 4. The resolving power of the centrifugation procedure can be further enhanced with membrane perturbants. Digitonin (0.12 mM) selectively disrupted lysosomes, markedly increased the equilibrium density of plasma-membrane components and lowered the density of the endoplasmic reticulum, but did not affect the mitochondria or peroxisomes. Pyrophosphate (15 mM) selectively lowered the equilibrium density of the endoplasmic reticulum.     

Identification and subcellular localization of catalase activity in bovine adrenal medulla and cortex

Catalase activity was detected in homogenates of bovine adrenal cortex and medulla. Analysis by equilibrium density centrifugation in isoosmotic metrizamide-sucrose gradients revealed that 70% of the medullary catalase activity was soluble while most of the remainder was found in a particulate form with a density of 1.175 g/ml. This was distinct from the densities of lysosomes, mitochondria, and chromaffin granules. Catalase activity in adrenal cortex was primarily (90%) soluble with only 6% being particulate, with a density of 1.185 g/ml. d-Amino acid, uric acid, and α-hydroxyacid oxidase activities, often associated with peroxisomes in other tissues, were absent from homogenates and catalase-containing gradient fractions from either cortex or medulla. There was an indication that some catalase activity was associated with chromaffin granules on the basis of density gradient analysis of both medullary homogenates and crude granule preparations. When granule fractions were subjected to osmotic shock, catalase activity distributed between soluble and sedimentable fractions differently from epinephrine and dopamine β-hydroxylase activity. The sedimentable catalase activity remained associated with chromaffin granule membranes upon isopycnic centrifugation. We concluded that catalase activity in both adrenal cortex and medulla was largely cytoplasmic, but that both tissues contained at least some catalase in dense organelles. Catalase activity which may be associated with chromaffin granules represents a small fraction of the total activity in the medulla.     

Lysosome lipid storage disorder in NCTR-BALB/c mice: spleen and lung lysosomes store unesterified cholesterol but differ in their phospholipid composition

A strain derived from a colony of BALB/c mice at the National Center for Toxicological Research, Jefferson, AR, USA (NCTR-BALB/c) suffers from an autosomal recessive disorder characterized by proliferation of secondary lysosomes with accumulation ofunesterified cholesterol in several tissues. The unesterified cholesterol content of spleens and lungs from the affected mice were elevated 8- and 3-fold respectively over age- and sex-matched controls. Postnuclear supernatants of tissue homogenates were fractionated by sucrose density gradient centrifugation and the fractions were analyzed for unesterified cholesterol, protein and marker enzyme activities for lysosomes (N-acetyl-beta-D-glucosaminidase, beta-D-glucuronidase), plasma membrane (alkaline phosphodiesterase I), endoplasmic reticulum (glucose-6-phosphatase) and mitochondria (cytochrome oxidase). The enzyme distribution profile showed that lysosomes of affected tissues floated at low density regions (density 1.05-1.08) of the gradient and contained substantial amount of tissue unesterified cholesterol. These low density lysosomes were purified about 17-fold (58% yield) from spleen and about 6-fold (32% yield) from lungs with minimal contamination by other organelles They were mostly intact as judged by high latency for N-acetyl-beta-D-glucosaminidase activity (70-100%). Lysosomes of control tissues were not found at the low density regions. The distribution profiles for other organelles were similar between affected and control tissues. Phospholipid composition of low density lysosomes were distinctly different from their respective tissue homogenates. Spleen and lung lysosomes were enriched in sphingomyelin and phosphatidylcholine respectively. The results suggest that these lysosomes acquire their low densities due to accumulation of unesterified cholesterol, the retention of which may be aided by sphingomyelin and phosphatidylcholine content of the lysosomes.     

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.     

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.     

Separation of cell organelles in density gradients based on their permeability characteristics

The buoyant density of intracellular organelles is dependent in part on the nature of the buffer composition of the density gradient and the permeability characteristics of the organelle membrane to the constituents of this buffer. Therefore, knowledge of the transport properties of different organelles allows the design of density gradients useful for their purification. We have used this approach to significantly decrease mitochondrial contamination of pancreatic zymogen granules in a one-step purification procedure on a 40% Percoll density gradient. These gradients, prepared with isoosmotic sucrose, yield a narrow band of zymogen granules and mitochondria. However, by substitution of sucrose with salts to which mitochondria but not zymogen granules are permeable, the densities of mitochondria are altered to give a significant separation. For example, the incorporation of 100 mM sodium succinate in the Percoll gradient can produce a 70% reduction in mitochondrial contamination. The increased ionic strength has an additional beneficial effect on zymogen granule yield by 5-10%. The recognition and utilization of transport pathways in organelle membranes is the principal feature of this technique and should prove to be widely applicable to other isolation procedures.     

Lysosome lipid storage disorder in NCTR-BALB/c mice: Spleen and lung lysosomes store unesterified cholesterol but differ in their phospholipid composition

A strain derived from a colony of BALB/c mice at the National Center for Toxicological Research, Jefferson, AR, USA (NCTR-BALB/c) suffers from an autosomal recessive disorder characterized by proliferation of secondary lysosomes with accumulation of unesterified cholesterol in several tissues. The unesterified cholesterol content of spleens and lungs from the affected mice were elevated 8- and 3-fold respectively over age- and sex-matched controls. Postnuclear supernatants of tissue homogenates were fractionated by sucrose density gradient centrifugation and the fractions were analyzed for unesterified cholesterol, protein and marker enzyme activities for lysosomes (N-acetyl-b-D-glucosaminidase, -D-glucuronidase), plasma membrane (alkaline phosphodiesterase I), endoplasmic reticulum (glucose-6-phosphatase) and mitochondria (cytochrome oxidase). The enzyme distribution profile showed that lysosomes of affected tissues floated at low density regions (density 1.05-1.08) of the gradient and contained substantial amount of tissue unesterified cholesterol. These low density lysosomes were purified about 17-fold (58% yield) from spleen and about 6-fold (32% yield) from lungs with minimal contamination by other organelles They were mostly intact as judged by high latency for N-acetyl--D-glucosaminidase activity (70-100%). Lysosomes of control tissues were not found at the low density regions. The distribution profiles for other organelles were similar between affected and control tissues. Phospholipid composition of low density lysosomes were distinctly different from their respective tissue homogenates. Spleen and lung lysosomes were enriched in sphingomyelin and phosphatidylcholine respectively. The results suggest that these lysosomes acquire their low densities due to accumulation of unesterified cholesterol, the retention of which may be aided by sphingomyelin and phosphatidylcholine content of the lysosomes.     

The influence of Cortisone on the hepatic uptake of Triton WR-1339 in adrenalectomized rats.

The effect of cortisone acetate on the hepatic uptake of Triton WR-1339 was studied in adrenalectomized rats. The hormone was found to retard the uptake of Triton in the liver, and at the same time reduce the plasma clearance of this compound. The inhibitory effect of the hormone on endocytosis was seen in purified preparations of both Kupffer cells and parenchymal cells. Triton renders the liver lysosomes progressively lighter. The change in equilibrium density (in sucrose gradients) was found to occur more rapidly in hormone-treated animals. The possibility that cortisone reduces the number and increases the size of the lysosomes is discussed. Our data indicate that the uptake of Triton in non-parenchymal (Kupffer) cells represents about 20% of the total hepatic uptake.