Simultaneous labeling of lipoprotein intracellular trafficking in pigeon monocyte-derived macrophages.

Macrophage foam cell formation resulting from the accumulation of cholesterol and cholesterol esters derived from plasma lipoproteins is important for progression of atherosclerosis. Hypothetically, intracellular processing of lipoproteins that stimulate foam cell formation differs from processing of lipoproteins that do not. To test this, we examined simultaneous subcellular trafficking of lipoproteins in pigeon monocyte-derived macrophages. Pigeon beta-very-low-density lipoprotein (beta-VLDL), low-density lipoprotein (LDL), and acetylated low-density lipoprotein (Ac-LDL), differentially labeled with colloidal gold, were added in pairs to cells at 4 degrees C for 2 hours before uptake at 18 degrees C, 22 degrees C, or 37 degrees C for either 30 minutes or 2 hours. The colloidal gold distribution and percent co-labeling as observed by transmission electron microscopy were determined for organelles of the endocytic pathway. Incubations at 18 degrees C and 22 degrees C blocked lipoprotein trafficking to lysosomes. Incubation at 18 degrees C increased the percent distribution of lipoproteins in the endocytic pathway up to the early cisternal endosomes. Incubations at 22 degrees C resulted in a greater distribution of lipoproteins in the spherical late endosomes and late endosomal-prelysosomal tubular reticular compartment. The distribution in the endocytic pathway was a factor of time and temperature rather than lipoprotein type. The percentage of co-labeling of organelles for the three pairs of lipoproteins examined, Ac-LDL plus beta-VLDL, LDL plus beta-VLDL, and LDL plus Ac-LDL, was similar. Fewer noncoated and clathrin-coated pits and vesicles were co-labeled (average of 6%, maximum of 17%) than the rest of the endocytic pathway, early cisternal endosomes, spherical late endosomes, late endosomal-prelysosomal tubuloreticular compartment, and spherical lysosomes (average of 36%, maximum of 47%). The 36% of co-labeled later endocytic organelles contained an average of 58% of the labeled lipoproteins. This study suggests differential sorting does not occur for high-affinity uptake of lipoproteins.     

Modified LDLs induce and bind to membrane ruffles on macrophages

Macrophage foam cell formation in vitro requires uptake of modified low density lipoproteins (LDL) such as acetylated LDL (AcLDL) and moderately oxidized LDL (OxLDL), or beta‐migrating very low density lipoprotein (βVLDL), a naturally occurring lipoprotein. Incubation of macrophages with AcLDL and OxLDL resulted in stimulation of membrane ruffle formation, while βVLDL primarily resulted in increased numbers of microvilli. Time‐lapse Allen video enhanced contrast differential interference contrast (AVEC‐DIC) light microscopy and correlative whole mount intermediate‐voltage transmission electron microscopy (IVEM) was used to examine the dynamics of AcLDL stimulated membrane ruffling and membrane ruffle ultrastructure. Stereo 3D surface replicas confirmed that AcLDL bound to these AcLDL‐induced membrane ruffles. Quantification of the plasma membrane surface area after incubation with AcLDL, βVLDL or LDL confirmed that AcLDL stimulated membrane ruffling, while βVLDL and LDL stimulated microvilli formation. These studies suggest that modified LDLs induce circular membrane ruffles and modified LDLs bind to these ligand‐induced membrane ruffles. Anat Rec 255:44–56, 1999. © 1999 Wiley‐Liss, Inc.     

Beta very low density lipoprotein and clathrin-coated vesicles co-localize to microvilli in pigeon monocyte-derived macrophages.

Macrophages derived from blood monocytes are key in the development of atherosclerosis, as monocyte migration into the intima and accumulation of cholesterol leads to foam cell formation. To investigate the relationship between lipoprotein binding and the distribution of clathrin-coated endocytic vesicles, monocyte-derived macrophages were exposed in vitro to beta very low density lipoprotein (beta VLDL), conjugated to colloidal gold, and later were processed for immuno-electron microscopy to localize clathrin-coated vesicles. The immunolocalization was done in conjunction with either cryosectioning or whole mount intermediate voltage electron microscopy. Preferential binding of beta VLDL on small membrane ruffles and microvilli was quantitatively verified. Clathrin-coated vesicles were distributed throughout the cell; however, clusters of microvilli were associated with both a high concentration of coated vesicles and lipoprotein. Small membrane ruffles were not associated with clathrin-coated vesicles. These data support our hypothesis that endocytosis of beta VLDL near microvilli involves coated vesicles, whereas endocytosis of beta VLDL near ruffles is not mediated by coated endocytic vesicles. Furthermore, the association of coated vesicles with microvilli but not membrane ruffles may be important in understanding ligand trafficking within the cell. Given the distribution of coated vesicles within the cell, it is possible that the site of lipoprotein binding may determine the mechanism of entry into the cell and the metabolic effects of the internalized ligand.     

The LDL receptor and LRP are receptors for βVLDL on pigeon monocyte-derived macrophages

Receptors for the lipoprotein, beta very low density lipoprotein (VLDL), have been identified through the binding of VLDL-gold conjugates on two ligand-induced regions of pigeon monocyte-derived macrophages. These regions were microvilli/retraction fibers and membrane ruffles. The present study investigated the location and identity of VLDL receptors using an antiserum directed against the epidermal growth factor (EGF) precursor region of the human low density lipoprotein (LDL) receptor. The anti-receptor serum recognized two membrane proteins from pigeon monocyte-derived macrophages, a 116 kDa (LDL receptor) protein and a 600 kDa (low density lipoprotein receptor-related protein; LRP) protein. Ligand blot analysis demonstrated that pigeon VLDL bound to both the LDL receptor and LRP. Immuno-gold electron microscopy using the anti-receptor serum resulted in immunoglobulin localization on the same two ligand-induced regions, microvilli/retraction fibers and membrane ruffles, to which the ligand had bound. Furthermore, simultaneous immunogold localization of the lipoprotein receptor antigens and VLDL-gold (ligand) binding substantiated co-localization of the receptor antigens and VLDL on the ligand-induced regions. Cross-competition studies with the anti-receptor serum and VLDL-gold conjugates documented that increasing concentration of the anti-receptor serum resulted in 70% inhibition of VLDL-gold conjugate binding. These data suggest that pigeon monocyte-derived macrophages utilize both the LDL receptor and LRP as receptors for pigeon VLDL.Supported by grants National Institutes of Health Grants HL-41990, RR-02722 (National Resource for IVEM), HL-14164 (SCOR in Atherosclerosis), and American Heart Association Grant-In-Aid 93006580     

Morphological characterization of beta-VLDL and acetylated-LDL binding and internalization by cultured pigeon monocytes

The ultrastructure of binding, internalization, and translocation of beta-migrating very low density lipoprotein (beta-VLDL) and acetylated low density lipoprotein (Ac-LDL) by cultured pigeon monocytes was examined using lipoprotein-gold conjugates. Through morphometry, differences in the binding and uptake of beta-VLDL-gold and Ac-LDL-gold were documented. Cells exposed to either beta-VLDL-gold or Ac-LDL-gold for 2 hr at 4 degrees C had the label over noncoated regions of the plasma membrane. Upon warming the cells to 37 degrees C for 2 min, 35% of the surface-bound beta-VLDL-gold was within coated pits on the cell surface. Although coated pits occupied less than 2% of the surface, binding of beta-VLDL-gold was 53 times more concentrated in coated pits as compared to noncoated membrane regions. In contrast, Ac-LDL-gold neither bound to coated pits nor relocated into coated regions of the membrane upon warming to 37 degrees C. Both the beta-VLDL-gold and the Ac-LDL-gold were internalized when the cells were rewarmed at 37 degrees C. Most of the internalized gold particles for both lipoproteins were located in electron-lucent vesicles; however, 9% of the intracellular beta-VLDL-gold was observed within coated vesicles at early times. Upon prolonged rewarming (30-90 min), both lipoprotein-gold conjugates were within acid phosphatase-positive lysosomes. Ultimately 83% of the Ac-LDL-gold and 90% of the beta-VLDL-gold were within electron-dense and electron-lucent lysosomes. These results suggested that the receptor-mediated binding and internalization of beta-VLDL and Ac-LDL by pigeon monocyte macrophages proceeded by separate, distinct routes; beta-VLDL by both coated and noncoated pathways while Ac-LDL was internalized exclusively by noncoated mechanisms. Regardless of these internalization differences, both lipoproteins were delivered to lysosomes for degradation.     

Xanthoma tissue-extracted LDL density substances are the main inducer of myelin-like bodies and ceroid granules in foam cells

Characteristic intracellular organelles of the foam cells in xanthoma are composed of membrane-bound lipid vacuoles, membrane-free lipid vacuoles, cholesterol crystals, multivesicular or multilocular lipid bodies, myelin-like bodies, and ceroid granules. We aimed to clarify the formation of myelin-like bodies and ceroid granules in the foam cells of xanthoma. We ultrastructurally examined mouse peritoneal macrophages incubated with human low-density lipoprotein (LDL) modified by incubation with xanthoma tissue, with xanthoma tissue-extracted LDL density substances, and with homogenized xanthoma tissue-derived crude material. A large number of membrane-bound and membrane-free lipid vacuoles were observed in macrophages incubated with xanthoma tissue-modified LDL. The macrophages incubated with the xanthoma tissue-extracted LDL density substances contained a large number of myelin-like bodies and ceroid granules. The macrophages incubated with the homogenized xanthoma tissue-derived crude material accumulated many vacuoles containing vesicular structures and a small number of myelin bodies and ceroid granules. Membrane-bound lipid vacuoles are derived from lysosomes that accumulate mostly extravasated modified LDL in xanthoma tissue. On the other hand, myelin-like bodies and ceroid granules are mostly derived from LDL density substances derived from xanthoma tissue homogenate.     

Multifunctional roles of macrophages in the development and progression of atherosclerosis in humans and experimental animals

In atherosclerosis, macrophages are important for intracellular lipid accumulation and foam cell formation. Monocytes respond to chemotactic factors, cytokines, and macrophage growth factors produced by vascular endothelial cells, smooth muscle cells, and infiltrated cells, by migrating from peripheral blood into the arterial intima and differentiating into macrophages in atherosclerotic lesions. Although various chemotactic factors are known to induce monocyte migration, monocyte chemoattractant protein-1 is the most important and powerful inducer of migration into atherosclerotic lesions. Macrophage colony-stimulating factor is crucial for monocyte/macrophage differentiation and proliferation, and for the survival of macrophages in these lesions. A minor population of macrophages can proliferate in the atherosclerotic lesions themselves, particularly in the early stage. The macrophages express a variety of receptors, particularly scavenger receptors, and take up modified lipoproteins, including oxidized low-density lipoprotein, beta-very-low-density lipoprotein, and/or enzymatically degraded low-density lipoprotein. These cells accumulate cholesterol esters in the cytoplasm, which leads to foam cell formation in lesion development. Among various scavenger receptors, class A type I and type II macrophage scavenger receptors (MSR-A I,II) play the most important role in the uptake of oxidized low-density lipoprotein by macrophages. In addition, macrophages and macrophage-derived foam cells produce ceroid and advanced glycation end-products (AGEs) and accumulate these substances in their cytoplasm. Extracellularly generated AGEs are taken up by macrophages via receptors for AGEs, including MSR-AI,II. Most foam cells die in loco because of apoptosis, and some foam cells escape from the lesions into peripheral blood. Macrophages also play multifaceted roles in inducing plaque rupture, blood coagulation, and fibrinolysis via the production of various enzymes, activators, inhibitors, and bioactive mediators. During the development of atherosclerosis, macrophages interact with vascular endothelial cells, medial smooth muscle cells, and infiltrated inflammatory cells, particularly T cells and dendritic cells. This review, based on data accumulated in studies of atherosclerosis in humans and experimental animals, focuses on the multifunctional roles of macrophages in the pathogenesis and progression of atherosclerosis.     

Early atherogenesis in White Carneau pigeons. II. Ultrastructural and cytochemical observations.

The addition of cholesterol (0.5%) to the diet of White Carneau pigeons induces site specific, temporally predictable, atherosclerotic lesions. The earliest lesions, which occurred after 3 weeks, were small (less than 2500 sq mu in surface area) and were composed primarily of macrophage foam cells (94% of lesion volume). With a prolonged time on the diet the lesions expanded due to increases in the number and size of foam cells, increases in the amount of extracellular space, and influx of smooth muscle cells. Macrophage foam cells in advanced lesions composed 61% of the lesion volume, smooth muscle cells 25%, and extracellular space 14%. Concurrent with the alteration in the constituency of the lesion, redistribution of lipid within foam cells was noted. Lipid in small lesions was primarily cytoplasmic (88%), with the remaining 12% in acid-phosphatase-positive secondary lysosomes. In more advanced lesions, 34% of the lipid was cytoplastic and 66% was lysosomal. The changes in large lesions appeared to be a function of lesion age, because at the growing edge of large lesions both composition and lipid distribution resembled those of small early lesions.     

Response of human hepatocyte lysosomes to postmortem anoxia

We studied the ultrastructure and degradative activity of lysosomes in human livers after somatic death due to cerebral necrosis secondary to shock and/or head trauma. The livers were obtained at autopsy after varying postmortem intervals. Liver ultrastructure was studied in intact liver, in hepatocyte suspension obtained by collagenase perfusion of the liver, and in cultured hepatocytes. Lysosomal protein degradation was measured in a case 24 hours after hepatocyte isolation. By standard ultrastructural criteria, all the livers demonstrated typical reversible manifestations of cell injury. Most hepatocytes demonstrated varying degrees of irreversible cell injury. The ultrastructural alterations were less severe in the isolated hepatocytes in suspensions, and further improvement in morphologic appearance occurred in the cultured monolayers. The most striking alteration in the liver lysosomes was the increase in the numbers of lipofuscin granules (a type of residual body) compared with control liver. The hepatocyte lysosomes constituted an average 3.1% of cytoplasmic volume. There was no correlation between the volume density of lysosomes and either the duration of postmortem anoxia, clinical course, or patient's age. There was no increase in the number of autophagic vacuoles or of secondary lysosomes in postmortem liver. Autophagic vacuoles were more frequently seen in isolated and cultured hepatocytes. Cultured hepatocytes isolated within one hour of clinical death and tested 24 hours later degraded cell proteins at a rate of 1.7% per hour. Protein degradation was stimulated by a physiologic signal (Dibutyryl cAMP, 1 mmol/L) and was inhibited by microtubule poison (vinblastine). We conclude that (1) viable hepatocytes can be isolated even after prolonged postmortem intervals (range, 30 minutes to seven hours), (2) trauma and shock cause an expansion of hepatocyte lysosomes due to accumulation of lipofuscin, and (3) autophagy is blocked by postmortem anoxia and resumes in the recovery phase from anoxic injury in hepatocyte suspensions and in culture.     

Proteases involved in the metabolic degradation of human interleukin-1beta by rat kidney lysosomes.

The in vitro metabolic degradation of human interleukin (IL)-1beta was studied using lysates of rat kidney lysosomes, and proteases involved in the degradation were identified. In the study of IL-1beta degradation, fluorescein isothiocyanate (FITC)-labeled IL-1beta was used as a substrate. The maximal degradation of IL-1beta occurred at pH 3.0, and the reaction was proportional to the lysosomal protein concentration and time of incubation. The degradation was stimulated by the addition of L-cysteine. The reaction was not inhibited by phenylmethanesulfonyl fluoride or EDTA, indicating that serine proteases or metalloproteases do not play a major role in the degradation process. N-Ethylmaleimide, leupeptin and E-64, inhibitors of thiol protease, inhibited the degradation of IL-1beta, by 59%-70%. Pepstatin A, an inhibitor of carboxyl protease, inhibited the degradation by 58%. Combinations of thiol and carboxyl protease inhibitors nearly completely inhibited the degradation. Bio-Gel P-10 gel filtration chromatography of in vitro reactants confirmed the ability of lysosomal proteases to degrade IL-1beta and revealed four to five peaks of degradation products. Taken together, these results indicate that thiol protease and carboxyl protease play an important role in the IL-1beta degradation process by kidney lysosomes. Leupeptin and E-64 dose dependently inhibited both cathepsin B and cathepsin L activities, and pepstatin A strongly inhibited cathepsin D activity in rat kidney lysosomes. The present results suggest that cathepsin B, cathepsin L, and cathepsin D in kidney lysosomes are involved in the metabolic degradation of human IL-1beta.     

Coenzyme A protects very-low-density lipoproteins against peroxidation and increases plasma triacylglycerol metabolism.

CoA (coenzyme A) has an antiperoxidative action and protects erythrocytes against oxygen free radicals. The peroxidation favours the uptake of the modified LDL (low-density lipoprotein) by macrophages and has a role in the development of foam cells. A possible relation between the antiperoxidative action of CoA and its normalizing activity on plasma lipids in type IIb and type IV hyperlipoproteinaemias, was investigated in order to see whether CoA protects VLDL (very -low-density lipoproteins) against peroxidation and produces a quicker removal of VLDL from circulation when administered intravenously to rats. The addition of 5 mM CoA to rat hepatocytes in culture was found to produce a significant decrease in VLDL secretion. The plasma clearance was significantly more rapid and the removal of triacylglycerols was significantly enhanced in CoA-treated rats as compared to untreated ones. Furthermore CoA reduced the formation of material reacting with thiobarbituric acid (TBA) in human VLDL peroxidized by exposure to Cu2+. Our study shows that CoA protects VLDL from peroxidation in a significant and concentration-dependent manner and increases plasma triacylglycerol metabolism.     

The fine structure of dense lysosomes isolated from rat spleen.

A dense fraction from rat spleen was shown to consist of membrane bound organelles of varying shape and size which were packed with electron dense particles with the appearance of ferritin. Electron microscope microanalysis confirmed that iron was present in the organelles and the amount correlated with the density as noted in transmission electron microscopy. The organelles also stained, positively for acid phosphatase and, therefore, confirmed the biochemical findings that dense lysosomes (L30) had been isolated. The role lysosomes play in the degradation of red blood cells, and as possible sites of iron storage, are briefly discussed.     

The crucial impact of lysosomes in aging and longevity

Lysosomes are the main catabolic organelles of a cell and play a pivotal role in a plethora of cellular processes, including responses to nutrient availability and composition, stress resistance, programmed cell death, plasma membrane repair, development, and cell differentiation. In line with this pleiotropic importance for cellular and organismal life and death, lysosomal dysfunction is associated with many age-related pathologies like Parkinson’s and Alzheimer’s disease, as well as with a decline in lifespan. Conversely, targeting lysosomal functional capacity is emerging as a means to promote longevity. Here, we analyze the current knowledge on the prominent influence of lysosomes on aging-related processes, such as their executory and regulatory roles during general and selective macroautophagy, or their storage capacity for amino acids and ions. In addition, we review and discuss the roles of lysosomes as active players in the mechanisms underlying known lifespan-extending interventions like, for example, spermidine or rapamycin administration. In conclusion, this review aims at critically examining the nature and pliability of the different layers, in which lysosomes are involved as a control hub for aging and longevity.     

Macrophage uptake of low-density lipoprotein modified by 4-hydroxynonenal. An ultrastructural study

We have documented the ultrastructural characteristics of the uptake and processing by mouse peritoneal macrophages (MPM) of low-density lipoprotein (LDL) modified with 4-hydroxynonenal (HNE), an intermediate of lipid peroxidation. This was performed as part of a larger biochemical study assessing the role of LDL oxidation in lipid loading of macrophages during atherogenesis. Gold-labeled LDL that was modified with HNE leading to particle aggregation represented the morphologic probe used. When incubated with MPM, the probe became associated with short segments of cell membrane, probably derived from blebs or from lysed cells. At 37 degrees C there was a time-dependent increase in uptake by MPM, and at 4 hours the increase paralleled the degradation by MPM of 125I-labeled HNE-LDL-cAu. Clathrin-coated pits on the cell surface were consistently associated with probe. Uptake of probe appeared to occur via phagocytosis, because pseudopods frequently surrounded probe, and cytochalasin D quantitatively prevented probe uptake. A time-dependent increase was found in the number of gold particles per unit area within vacuoles, some of which were secondary lysosomes, based on acid phosphatase-positive staining. Thus, HNE-induced aggregation of LDL during oxidation, binding of aggregates to clathrin-coated pits on MPM, and subsequent phagocytosis may represent one of the ways lipid-laden foam cells are formed in vivo.     

Endocytic activity of Sertoli cells grown in bicameral culture chambers

Immature rat Sertoli cells were cultured for 7 to 14 days on Millipore filters impregnated with a reconstituted basement membrane extract in dual-environment (bicameral) culture chambers. Electron microscopy of the cultured cells revealed the presence of rod-shaped mitochondria, Golgi apparatus, rough endoplasmic reticulum, and Sertoli-Sertoli tight junctions, typical of these cells in vivo. The endocytic activity of both the apical and basal surfaces of the Sertoli cells was examined by either adding alpha 2-macroglobulin (alpha 2-M) conjugated to 20 nm gold particles to the apical chamber or by adding 125I labeled alpha 2-M to the basal chamber. During endocytosis from the apical surface of Sertoli cells, the alpha 2-M-gold particles were bound initially to coated pits and then internalized into coated vesicles within 5 minutes. After 10 minutes, the alpha 2-M-gold was found in multi-vesicular bodies (MVBs) and by 30 minutes it was present in the lysosomes. The proportion of alpha 2-M-gold found within endocytic cell organelles after 1 hour of uptake was used to estimate the approximate time that this ligand spent in each type of organelle. The alpha 2-M-gold was present in coated pits, coated vesicles, multivesicular bodies, and lysosomes for approximately 3, 11, 22, and 24 minutes, respectively. This indicates that the initial stages of endocytosis are rapid, whereas MVBs and lysosomes are relatively long-lived.(ABSTRACT TRUNCATED AT 250 WORDS)     

Uptake--microautophagy--and degradation of exogenous proteins by isolated rat liver lysosomes. Effects of pH, ATP, and inhibitors of proteolysis

Isolated rat liver lysosomes were incubated with [14C]methemoglobin under various conditions. Optimal pH for the in vitro proteolysis was found to be 4-5. To evaluate whether or not degradation of added proteins could be due to enzyme leakage the integrity of the lysosomes was measured. Isolated lysosomes were found to be stable for up to 10 min of incubation at pH 5.5 and for 30 min at pH 7. The degradation of three different proteins (methemoglobin, ovalbumin, and lysozyme) was analyzed. No correlation was detected between rate of breakdown and physical properties of the proteins. Leupeptin, chloroquine, and propylamine inhibited proteolysis of added proteins by 45-65% in both neutral and acid milieu. Possible energy requirement was tested by the addition of Mg2+ and ATP to the incubation medium. A dose-dependent increase in proteolytic rate was found when ATP was added to the lysosomal suspension, a finding most likely due to acidification of the lysosomes and ensuing increased degradation. GTP and ITP were somewhat less effective. The noncleavable ATP analogue 5'-adenylylimidodiphosphate gave no stimulation. The ATP-driven proteolysis was inhibited by ethylmaleimide. Isolated lysosomes were also incubated with ferritin in order to visualize a possible uptake process of a protein in the electron microscope. Following incubation, ferritin particles were seen inside intralysosomal vesicles which appeared to be formed by invagination of the lysosomal membrane, a process designated microautophagy. The results thus support the notion that isolated lysosomes may micropinocytose and degrade exogenously added proteins and that this process is ATP dependent.     

Expression of very low density lipoprotein receptor in the vascular wall. Analysis of human tissues by in situ hybridization and immunohistochemistry.

The recently cloned very low density lipoprotein (VLDL) receptor binds triglyceride-rich, apolipoprotein-E-containing lipoproteins with high affinity. The observation that VLDL receptor mRNA is abundantly expressed in extracts of tissues such as skeletal muscle and heart, but not liver, has led to the hypothesis that this receptor may facilitate the peripheral uptake of triglyceride-rich lipoproteins. However, little information is available concerning the types of cells that express this receptor in vivo. As expression of the VLDL receptor in the vascular wall might have important implications for the uptake and transport of triglyceride-rich lipoproteins, and perhaps facilitate the development of atherosclerosis in hypertriglyceridemic individuals, we used in situ hybridization and immunohistochemistry to determine whether VLDL receptor mRNA and protein was expressed in human vascular tissue. We observed expression of the receptor by both endothelial and smooth muscle cells within normal arteries and veins, as well as within atherosclerotic plaques. In the latter, the VLDL receptor was also expressed by macrophage-derived foam cells. The widespread distribution of the VLDL receptor in vascular tissue suggests a potentially important role for this receptor in normal and pathophysiological vascular processes.     

Involvement of lysosomes in the uptake of macromolecular material by bloodstream forms of Trypanosoma brucei

To investigate whether the lysosomes of Trypanosoma brucei are capable of uptake of macromolecules after internalization by the cell, we used Triton WR-1339, a non-digestible macromolecular compound, which is known to cause a marked decrease in the density of hepatic lysosomes due to massive intralysosomal storage. Intraperitoneal administration of 0.4 g/kg Triton WR-1339 to rats infected with T. brucei led to the development of a large vacuole in the trypanosomes between nucleus and kinetoplast within 22 h. Higher doses (2 g/kg) led to the disappearance of the trypanosomes from the blood and resulted in permanent cures (greater than 100 days). Lysosomes isolated from the trypanosomes of animals treated with a sub-curative dose showed a decrease in equilibrium density of 0.03 g/cm3 in sucrose gradients. These lysosomes were partly damaged as evidenced by a reduction in latency and an increase in the non-sedimentable part of lysosomal enzymes. We conclude that acid proteinase and alpha-mannosidase-containing organelles of T. brucei take up exogenous macromolecules and must therefore be considered as true lysosomes and that Triton WR-1339 acts in T. brucei as a true lysosomotropic drug. Its trypanocidal action probably results from an interference with lysosomal function.     

Effects of ATP on lysosomes: protection against hyperosmolar KCl

After incubation at 37 degrees C in isosmolar (200 mM) KCl, rat liver lysosomes are susceptible to damage caused by brief exposure to hyperosmolar (greater than 200 mM) KCl. Lysosomes that are exposed to hyperosmolar KCl do not undergo significant lysis as long as they are maintained at hyperosmolar conditions; however, they will lyse on being returned to lower osmolarities. If the hyperosmolar KCl-treated lysosomes are intermittently transferred into equally hyperosmolar sucrose, they no longer undergo lysis on subsequent exposure to lower osmolarities; this confirms the reversible nature of the hyperosmolar KCl-induced damage. Thus the hypothesis that the hyperosmolar KCl damage involves an isosmotic permeating of the lysosome by KCl appears reasonable. The increase caused by the hyperosmolar KCl in free activity of beta-N-acetyl-D-glucosaminidase is reduced by about 50% by ATP but not by ATP analogues. ATP protects provided that it is added either before, or simultaneously with, exposure of the lysosomes to hyperosmolar KCl. However, if the ATP is not added until the lysosomes are already in the presence of the hyperosmolar KCl, it does not reverse the damaging effects of the KCl even though actual lysis has not yet occurred at the time of the ATP addition. The protective effect is established very rapidly, because ATP added simultaneously with the addition of the hyperosmolar KCl protects to the same extent as does ATP added any time prior to the KCl addition. The protective effect requires Mg2+ and is not supported by Ca2+. Maximal protection is provided by 5 X 10(-4) M ATP. It is postulated that ATP protects lysosomes by reducing an increase in intralysosomal concentration of KCl, which occurs when incubated lysosomes are exposed to hyperosmolar KCl.     

Angulate lysosomes

Under many circumstances, macrophages accumulate lipids (possibly in combination with other materials) in the form of micelles that by their rigidity and size impart an irregular, angulate shape to the lysosomes in which they are stored. When macrophages contain large numbers of these angulate lysosomes, they have a characteristic light microscopic appearance and are often designated Gaucher cells or Gaucher-like cells. In most instances, however, the angulate lysosomes are small in number or size and are not easily recognized by light microscopy. A search of the literature and our own files revealed angulate lysosomes in a considerable number of conditions in which they have not previously been observed or recognized. In most conditions, the evidence indicates that the material stored is derived from phagocytosed cells that are incompletely digested, either because they are simply too numerous to be handled by the macrophage or due to a primary metabolic deficiency, or both. In contrast to what has been assumed, angulate lysosomes not only arise in situations in which blood cells are phagocytosed, but also when various types of degenerating tumor cells, remnants of myelin sheaths, or bacteria accumulate inside macrophages. In yet other conditions, the origin of the lysosomal contents remains to be elucidated.