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.     

Heterogeneity of lysosomes in human fibroblasts

Summary Lysosomes are defined traditionally with the marker enzyme acid phosphatase. We showed recently that lysosomes from human fibroblasts can be separated into a light and dense fraction as well as prelysosomal population. We now provide evidence that although acid phosphatase is enriched in all three fractions, the marker enzyme in the prelysosomal compartment is qualitatively distinct from that of the lysosomes. Ultrastructural analysis showed that the acid phosphatase in the prelysosomal vesicles deposited an extremely electron-dense reaction product, entirely obliterating the lumen of the vesicle, in contrast to that of the light and dense lysosomes which deposited a fine and diffuse product scattered throughout the luminal space. Biochemical analysis showed that only 51% of the acid phosphatase in the prelysosomes was inhibited by tartrate, while 80% of that in the lysosomes was tartrate-inhibitable. Immunoprecipitation with antibodies specific for various isozymes of acid phosphatase showed that 39% of the acid phosphatase in the prelysosomes was of the lysosomal type whereas over 5007o of the acid phosphatase in the lysosomes was of this type. These results showed that acid phosphatase in the prelysosomes of human cultured fibroblasts can be distinguished from that of the lysosomes cytochemically, biochemically, and immunologically and that lysosomes, as marked by acid phosphatase, are a heterogeneous organelle.     

Lysosomes from rabbit type II cells catabolize surfactant lipids

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

Peroxisome development in the metanephric kidney of mouse.

The relationship of enzymatic activity to organelle development and organelle number during differentiation of the metanephric kidney in the mouse was approached from several experimental directions. Biochemical analyses of marker enzymes for peroxisomes (catalase and D-amino acid oxidase), mitochondria (cytochrome oxidase) and lysosomes (acid phosphatase) were performed on kidneys at ages from 17 days prenatal to adult. These data were correlated with a morphometric analysis of populations of peroxisomes and mitochondria in differentiating cells of the proximal tubule. Postnatal development of the metanephric kidney was found to be accompanied by a rapid increase in both the specific activity of catalase and the number of peroxisomes per 100 mu2 in the proximal tubule during the first 4 weeks of postnatal growth. Elaboration of the endoplasmic reticulum (ER) was seen to parallel the increase in number of peroxisomes to which segments of ER were often in close apposition. Extensive interactions between segments of ER and peroxisomes were readily visible in 0.5-mu sections viewed in the high voltage electron microscope. In contrast to peroxisomes, neither mitochondria nor lysosomes followed a similar pattern of net organelle increase, suggesting that a defined population density of mitochondria and lysosomes may exist in the proximal tubule at birth, prior to complete development of the kidney.     

Isolation of a storage and secretory organelle containing Von Willebrand protein from cultured human endothelial cells

Von Willebrand protein was synthesized and secreted by human endothelial cells in culture. Ca²⁺ ionophore A23187 and phorbol myristate acetate stimulated the release of Von Willebrand protein from the cultured cells. Stimulated release was accompanied by the disappearance of rod-like structures from the cultured endothelial cells immunostained for Von Willebrand protein, suggesting the existence of a storage organelle for Von Willebrand protein in these cells (Loesberg, C., Gonsalves, M.D., Zandbergen, J., Willems, C., Van Aken, W.G., Stel, H.V., Van Mourik, J.A. and De Groot, P.G. (1983) Biochim. Biophys. Acta 763, 160–168). Cultured human endothelial cells were fractionated on a density gradient of colloidal silica. Von Willebrand protein was found in two organelle populations: a buoyant one sedimenting with a variety of cell organelle marker enzymes, including those of the Golgi apparatus, mitochondria, lysosomes, peroxisomes, endoplasmic reticulum and plasma membrane fragments (peak density of this fraction: 1.08 g·ml^?1), and a dense one with a peak density of 1.12 g·ml^?1. The dense organelles containing Von Willebrand protein were apparently free of other organelles. Stimulating Von Willebrand protein release with phorbol myristate acetate or Ca²⁺ ionophore A23187 resulted in a decrease or even complete disappearance of Von Willebrand protein from the high-density organelle fraction, implying a role of this organelle in the stimulus-induced release of Von Willebrand protein. The Von Willebrand protein content of the buoyant fraction was lowered to some extent or did not change upon incubation of the cells with ionophore A23187 and phorbol myristate acetate. Restoration of Von Willebrand protein content of the dense organelle fraction after stimulation occurred within 2 days; this was accompanied by recurrence of immunostaining of rod-shaped structures in cells and an increase in cellular Von Willebrand protein. The excretion of restored Von Willebrand protein could be stimulated again.     

Autophagic-lysosomal and mitochondrial sequestration of [14C]sucrose. Density gradient distribution of sequestered radioactivity

[14C]Sucrose, introduced into the cytosol of isolated rat hepatocytes by means of electropermeabilization, was sequestered by sedimentable subcellular particles during incubation of the cells at 37 degrees C. The sedimentation characteristics of particle-associated [14C]sucrose were different from the lysosomal marker enzyme acid phosphatase, suggesting an involvement of organelles of greater size than the average lysosome. Isopycnic banding in isotonic metrizamide/sucrose density gradients resolved two major peaks of radioactivity: a light peak (1.08-1.10 g/ml) coinciding with lysosomal marker enzymes, and a dense peak (1.15 g/ml), coinciding with a mitochondrial marker enzyme. The dense peak was preferentially associated with large-size particles having the sedimentation properties of mitochondria, and it was resistant to the detergent digitonin at a concentration which extracted all of the radioactivity in the light peak. Similarly the autophagy inhibitor 3-methyladenine prevented accumulation of [14C]sucrose in the light peak, while the radioactivity in the dense peak was unaffected. We therefore tentatively conclude that the light peak represents autophagic sequestration of [14C]sucrose into lysosomes (and probably autophagosomes) while the dense peak represents a mitochondrial uptake unrelated to autophagy.     

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.     

The lytic granules of natural killer cells are dual-function organelles combining secretory and pre-lysosomal compartments

Cytolytic lymphocytes contain specialized lytic granules whose secretion during cell-mediated cytolysis results in target cell death. Using serial section EM of RNK-16, a natural killer cell line, we show that there are structurally distinct types of granules. Each type is composed of varying proportions of a dense core domain and a multivesicular cortical domain. The dense core domains contain secretory proteins thought to play a role in cytolysis, including cytolysin and chondroitin sulfate proteoglycan. In contrast, the multivesicular domains contain lysosomal proteins, including acid phosphatase, alpha-glucosidase, cathepsin D, and LGP-120. In addition to their protein content, the lytic granules have other properties in common with lysosomes. The multivesicular regions of the granules have an acidic pH, comparable to that of endosomes and lysosomes. The granules take up exogenous cationized ferritin with lysosome-like kinetics, and this uptake is blocked by weak bases and low temperature. The multivesicular domains of the granules are rich in the 270-kD mannose-6-phosphate receptor, a marker which is absent from mature lysosomes but present in earlier endocytic compartments. Thus, the natural killer granules represent an unusual dual-function organelle, where a regulated secretory compartment, the dense core, is contained within a pre-lysosomal compartment, the multivesicular domain.     

Secondary lysosomes as an integral part of the cytoskeleton: a morphological study in rat Kupffer cells

Rat Kupffer cells contain the three major cytoskeletal components: microfilaments (MF), microtubules (MT), and intermediate filaments (IF) of the vimentin type. Previous cytomagnetometric data obtained from alveolar macrophages and rat Kupffer cells in culture provided evidence that actin filaments contribute to the movements of lysosomes. The lysosomal transport in living cells was affected, when the MFs were selectively disturbed, whereas the depolymerization of the MTs had no effect on the lysosomal movement measured by cytomagnetometric means. Immunofluorescence and ultrastructural studies of isolated and cultured rat Kupffer cells, presented in this paper, will investigate the relationship between lysosomes and the cytoskeleton. The principal filamentous structure in the peripheral cytoplasm of Kupffer cells in a dense meshwork of actin filaments. The dimension of the meshes combined with the dimensions of lysosomes implies the necessity of either (i) disintegration of the actin filament cross-links, (ii) depolarymerization and redistribution of MF's, or (iii) a displacement of actin filaments by the lysosomes during the organelle transport. The presence of microtubules in cytoplasmic protrusions and their track from the periphery to the perinuclear region during interphase might play a role in the transport mechanism of lysosomes, the more so because microtubules could often be demonstrated in closest association with lysosomes even in the first phase of endocytosis. The distribution pattern of vimentin, found as a dense interconnected framework surrounding the lysosomes like a basket, could play a role in positioning the organelles. The dynamic functions of MF's and MT's and their multifunctionality led to an adaptive and flexible organization of these filaments which may both be involved in lysosomal motion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence for both prelysosomal and lysosomal intermediates in endocytic pathways

Horseradish peroxidase (HRP), an enzyme internalized by fluid phase pinocytosis, has been used to study the process by which pinosome contents are delivered to lysosomes in Chinese hamster ovary cells. Pinosome contents were labeled by allowing cells to internalize HRP for 3-5 min. Following various chase times, cells were either processed for HRP and acid phosphatase (AcPase) cytochemistry or homogenized and fractionated in Percoll gradients. In Percoll gradients, pinosomes labeled by a 3-5 min HRP pulse behaved as a vesicle population more dense than plasma membrane and less dense than lysosomes. In pulse- chase experiments, internalized HRP was chased rapidly (3-6 min chase) to a density position intermediate between the "initial" pinocytic vesicle population and lysosomes. With longer chase periods, a progressive accumulation of HRP in more dense vesicles was observed. Correspondence between the HRP distribution and lysosomal marker distribution was reached after a approximately 1-h chase. By electron microscope cytochemistry of intact cells, the predominant class of HRP- positive vesicles after pulse uptakes or a 3-min chase period was characterized by a peripheral rim of reaction product and was AcPase negative. After 10-120-min chase periods, the predominant class of HRP- positive vesicles was characterized by luminal deposits and HRP activity was frequently observed in multivesicular bodies. HRP-positive vesicles after a 10- or 30-min chase were AcPase-positive. No HRP activity was detected in Golgi apparatus. Together these observations indicate that progressive processing of vesicular components of the vacuolar apparatus occurs at both a prelysosomal and lysosomal stage.     

Composition of the von Willebrand factor storage organelle (Weibel- Palade body) isolated from cultured human umbilical vein endothelial cells

von Willebrand factor (VWF) is a large, adhesive glycoprotein that is biosynthesized and secreted by cultured endothelial cells (EC). Although these cells constitutively release VWF, they also contain a storage pool of this protein that can be rapidly mobilized. In this study, a dense organelle fraction was isolated from cultured umbilical vein endothelial cells by centrifugation on a self-generated Percoll gradient. Stimulation of EC by 4-phorbol 12-myristate 13-acetate (PMA) resulted in the disappearance of this organelle fraction and the synchronous loss of Weibel-Palade bodies as judged by immunoelectron microscopy. Electrophoretic and serologic analyses of biosynthetically labeled dense organelle fraction revealed that it is comprised almost exclusively of VWF and its cleaved pro sequence. These two polypeptides were similarly localized exclusively to Weibel-Palade bodies by ultrastructural immunocytochemistry. The identity of the dense organelle as the Weibel-Palade body was further established by direct morphological examination of the dense organelle fraction. The VWF derived from this organelle is distributed among unusually high molecular weight multimers composed of fully processed monomeric subunits and is rapidly and quantitatively secreted in unmodified form after PMA stimulation. These studies: establish that the Weibel-Palade body is the endothelial-specific storage organelle for regulated VWF secretion; demonstrate that in cultured EC, the VWF concentrated in secretory organelles is of unusually high molecular weight and that this material may be rapidly mobilized in unmodified form; imply that proteolytic processing of VWF involved in regulated secretion takes place after translocation to the secretory organelle; provide a basis for further studies of intracellular protein trafficking in EC.     

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     

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.     

An improved procedure for the simultaneous purification in high yield of peroxisomes,lysosomes, and mitochondria from rat liver

Summary Peroxisomes, lysosomes, and mitochondria have been purified from rat liver by sucrose density gradient centrifugation without prior treatment of the animals with Triton WR-1339 or other detergents which cause hyperlipidemia. A crude organelle fraction was first prepared by differential centrifugation of a rat liver homogenate, this fraction contained approximately 70% of the mitochondrial, 40% of the peroxisomal, and 30% of the lysosomal marker enzymes measured in the homogenate. The crude organelle fraction was applied to the top of a sucrose density gradient and centrifuged. A clear separation of the organelles was obtained only when dextran was present in the gradients. Success or failure of the method was found to depend on the particular preparation of dextran used in the gradients. A method for subfractionating dextran was developed which yields dextran fractions that make the separations completely reproducible. Starting with a crude organelle fraction derived from 12 g of liver, approximately 85% of the mitochondrial, 70% of the peroxisomal, and 50% of the lysosomal activities were obtained as pure fractions. The organelle separation takes less than five hours to complete, it represents a substantial improvement over previous methods.     

Pre-lysosomal divergence of alpha 2-macroglobulin and transferrin: a kinetic study using a monoclonal antibody against a lysosomal membrane glycoprotein (LAMP-1)

We have used electron microscopic immunocytochemistry to compare the distribution of LAMP-1, a marker for lysosomal membranes, with the intracellular localization of alpha 2-macroglobulin (alpha 2-M) and transferrin at various time points after their endocytosis into cultured NIH 3T3 cells. The purposes of this study were (a) to determine how soon endocytic ligands reach lysosomal organelles, (b) to examine whether the intermediate endocytic vesicles gained lysosomal markers gradually or in a precipitous, discrete event, and (c) to examine the relationship, if any, between the pathway of recycling ligands and lysosomes. At early time points (0-5 min) after initiation of endocytosis, most structures containing alpha 2-M labeled with colloidal gold (receptosomes) were not labeled by anti-LAMP-1 detected using ferritin bridge or peroxidase immunocytochemistry. At late time points (greater than or equal to 15 min), the structures containing alpha 2-M (lysosomes) were strongly labeled by anti-LAMP-1. In contrast, transferrin that was directly labeled with ferritin was mostly located in LAMP-1-negative structures at all time points studied. The proportion of alpha 2-M-gold containing vesicles strongly labeled for LAMP-1 roughly paralleled the proportion of alpha 2-M-gold-containing structures positive for cytochemically detectable acid phosphatase. Our data indicate that ligands such as transferrin that are internalized through coated pits and receptosomes, but not delivered to lysosomes, do not traverse a lysosomal organelle compartment as marked by LAMP-1 content. Ligands such as alpha 2-M that are destined for lysosomal delivery reach a LAMP-1-positive organelle compartment only after they traverse LAMP-1-negative, non-lysosomal vesicles previously described as receptosomes.     

TassC结合过氧化物酶体对早期受染巨噬细胞内的鼠伤寒沙门菌的影响

探讨鼠伤寒沙门菌在感染鼠巨噬细胞早期与细胞器的相互作用。用pTassC-GFP质粒转染鼠巨噬细胞RAW264.7,结合多抗的溶酶体标志物溶酶体相关膜蛋白-1用键合了Alexa594的羊抗鼠二抗显色,以观察标记了绿色荧光蛋白的TassC与溶酶体的关系;用pTassC-GFP和pDsRed2-Perxi质粒共转染RAW264.7细胞,以观察TassC-GFP与过氧化物酶体的关系;用SYTO42标记鼠伤寒沙门菌,感染用pTassC-GFP和pDsRed2-Perxi质粒共转染的RAW264.7细胞,以观察细菌与TassC和过氧化物酶体的关系。免疫荧光显示TassC-GFP不与鼠巨噬细胞RAW264.7中的溶酶体结合,但与标记了红色荧光的过氧化物酶体共定位;感染1 h的RAW264.7胞内SYTO42标记的鼠伤寒沙门菌吞噬泡可招募TassC-GFP和过氧化物酶体。这些发现提示在鼠伤寒沙门菌感染早期过氧化物酶体携带杀菌成分通过TassC介导可参与发挥一定的杀菌作用。     

Fusion of Lysosomes with Late Endosomes Produces a Hybrid Organelle of Intermediate Density and Is NSF Dependent

Using a cell-free content mixing assay containing rat liver endosomes and lysosomes in the presence of pig brain cytosol, we demonstrated that after incubation at 37°C, late endosome–lysosome hybrid organelles were formed, which could be isolated by density gradient centrifugation. ImmunoEM showed that the hybrids contained both an endocytosed marker and a lysosomal enzyme. Formation of the hybrid organelles appeared not to require vesicular transport between late endosomes and lysosomes but occurred as a result of direct fusion. Hybrid organelles with similar properties were isolated directly from rat liver homogenates and thus were not an artifact of cell-free incubations. Direct fusion between late endosomes and lysosomes was an N-ethylmaleimide–sensitive factor– dependent event and was inhibited by GDP-dissociation inhibitor, indicating a requirement for a rab protein. We suggest that in cells, delivery of endocytosed ligands to an organelle where proteolytic digestion occurs is mediated by direct fusion of late endosomes with lysosomes. The consequences of this fusion to the maintenance and function of lysosomes are discussed.     

High- and low-uptake forms of β-hexosaminidase in human platelets Selective retention of the high-uptake form during stimulation with thrombin

Human platelets are rich in β-hexosaminidase and other acid hydrolases contained in organelles (lysosomes) distinct from α-granules and dense granules. Incubation of platelets with bovine or human thrombin (100 U/ml for 5 min at 37°C) induces the secretion of 100% of the contents of α- and dense granules, but only 40–60% of total β-hexosaminidase from lysosomes. Both isozymes Hex A and Hex B are secreted in the same proportion as found intracellulary. There is no selective recapture or plasma membrane binding by platelets of secreted β-hexosaminidase. The secreted enzyme is of the low-uptake type, i.e., it is poorly recognized by the phosphomannosyl receptor-mediated uptake mechanism of fibroblasts, while the retained enzyme is a 3-fold higher uptake form. Preincubation of platelets with NH₄Cl (10 mM, 2 h), followed by thrombin stimulation, results in secretion of all β-hexosaminidase as a low-uptake form. The data support the hypothesis that there are secretory and nonsecretory forms of lysosomes. The secretory lysosomes would contain low-uptake forms of hydrolases in addition to acid phosphatase, while the nonsecretory lysosomes would contain high-uptake hydrolases and be acid phosphatase-deficient. Conditions where the contents of both lysosomal populations were released together, i.e., amine treatment followed by thrombin induction, or extraction of unstimulated cells, would result in the exposure of high-uptake phosphomannosylated hydrolases released from one population of lysosomes to acid phosphatase released from the second population of lysosomes with their subsequent conversion to low-uptake forms.     

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     

Actin cytoskeleton controls movement of intracellular organelles in pancreatic duct epithelial cells

In most eukaryotic cells, microtubules and filamentous actin (F-actin) provide tracks on which intracellular organelles move using molecular motors. Here we report that cytoplasmic movement of both mitochondria and lysosomes is slowed by F-actin meshwork formation in pancreatic duct epithelial cells (PDEC). Mitochondria and lysosomes were labeled with fluorescent Mitotracker Red CMXRos and Lysotracker Red DND-99, respectively, and their movements were monitored using epi-fluorescence and confocal microscopy. Mitochondria and lysosomes moving actively at rest stopped rapidly within several seconds after an intracellular Ca(2+) rise induced by activation of P2Y(2) purinergic receptors. The 'freezing' of the organelles was inhibited by blocking the Ca(2+) rise or by pretreatment with latrunculin B, an inhibitor of F-actin formation. Indeed, this freezing effect on the organelles was accompanied by the formation of F-actin in the whole cytoplasm as stained with Alexa 488-phalloidin in fixed PDEC. For real-time monitoring of F-actin formation in live cells, we expressed sGFP-fimbrin actin binding domain2 (fABD2) in PDEC. Rapid recruitment of the fluorescent probe near the nucleus and lysosomes suggested dense F-actin formation around intracellular structures. The development of F-actin paralleled that of organelle freezing. We conclude that rapid Ca(2+)-dependent F-actin formation physically restrains intracellular organelles and reduces their mobility non-selectively in PDEC.