Occurrence of an anomalous endocytic compartment in fibroblasts from Sandhoff disease patients

Sandhoff disease (SD) is a lysosomal storage disorder due to mutations in the gene encoding for the β-subunit of β-hexosaminidase, that result in β-hexosaminidase A (αβ) and β-hexosaminidase B (ββ) deficiency. This leads to the storage of GM2 ganglioside in endosomes and lysosomes, which ends in a progressive neurodegeneration. Currently, very little is known about the biochemical pathways leading from GM2 ganglioside accumulation to pathogenesis. Defects in transport and sorting by the endosomal–lysosomal system have been described for several lysosomal storage disorders. Here, we have investigated the endosomal–lysosomal compartment in fibroblasts from SD patients and observed that both late endosomes and lysosomes, but not early endosomes, have a higher density in comparison with normal fibroblasts. Moreover, Sandhoff fibroblasts have an intracellular distribution of terminal endocytic organelles that differs from the characteristic perinuclear punctate pattern observed in normal fibroblasts and endocytic vesicles also appear larger. These findings reveal the occurrence of an alteration in the terminal endocytic organelles of Sandhoff fibroblasts, suggesting an involvement of this compartment in the disruption of cell metabolic and signalling pathways and in the onset of the pathological state.     

The biogenesis of lysosomes: Is it a kiss and run,continuous fusion and fission process?

Molecules are transferred to lysosomes, the major, acid pH, digestive compartment in eukaryotic cells, by a complex series of pathways that converge at a late endosome/prelysosomal compartment. Here, we discuss the relationship between this compartment and the lysosome. We propose that lysosomes are maintained within cells by a repeated series of kiss and run, transient fusion and fission processes with the late endosome/prelysosome compartment. Directionality to these processes may be conferred by pH gradients and retrieval mechanisms. The future challenge in testing this and any other proposed hypothesis for lysosomal biogenesis will be the establishment of molecular mechanisms.     

Lysosomal membrane proteins: life between acid and neutral conditions

Whereas we have a profound understanding about the function and biogenesis of the protein constituents in the lumen of the lysosomal compartment, much less is known about the functions of proteins of the lysosomal membrane. Proteomic analyses of the lysosomal membrane suggest that, apart from the well-known lysosomal membrane proteins, additional and less abundant membrane proteins are present. The identification of disease-causing genes and the in-depth analysis of knockout mice leading to mutated or absent membrane proteins of the lysosomal membrane have demonstrated the essential role of these proteins in lysosomal acidification, transport of metabolites resulting from hydrolytic degradation and interaction and fusion with other cellular membrane systems. In addition, trafficking pathways of lysosomal membrane proteins are closely linked to the biogenesis of this compartment. This is exemplified by the recent finding that LIMP-2 (lysosomal integral membrane protein type-2) is responsible for the mannose 6-phosphate receptor-independent delivery of newly synthesized β-glucocerebrosidase to the lysosome. Similar to LIMP-2, which could also be linked to vesicular transport processes in certain polarized cell types, the major constituents of the lysosomal membrane, the glycoproteins LAMP (lysosome-associated membrane protein)-1 and LAMP-2 are essential for regulation of lysosomal motility and participating in control of membrane fusion events between autophagosomes or phagosomes with late endosomes/lysosomes. Our recent investigations into the role of these proteins have not only increased our understanding of the endolysosomal system, but also supported their major role in cell physiology and the development of different diseases.     

Characterization of mechanisms involved in secretion of active heparanase

Heparanase is an endo-beta-D-glucuronidase involved in extracellular matrix remodeling and degradation and implicated in tumor metastasis, angiogenesis, inflammation, and autoimmunity. The enzyme is synthesized as a latent 65-kDa protein and is processed in the lysosomal compartment to an active 58-kDa heterodimer, where it is stored in a stable form. In contrast, its heparan sulfate substrate is localized extracellularly, suggesting the existence of mechanisms that trigger heparanase secretion. Here we show that secretion of the active enzyme is mediated by the protein kinase A and C pathways. Moreover, secretion of active heparanase was observed upon cell stimulation with physiological concentrations of adenosine, ADP, and ATP, as well as by the noncleavable ATP analogue adenosine 5'-O-(thiotriphosphate). Indeed, heparanase secretion was noted upon cell stimulation with a specific P2Y1 receptor agonist and was inhibited by P2Y receptor antagonists. The kinetics of heparanase secretion resembled the secretion of cathepsin D, a lysosomal enzyme, indicating that the secreted heparanase is of lysosomal origin. We suggest that secretion of active heparanase is initiated by extracellular cues activating the protein kinase A and C signaling pathways. The secreted enzyme(s) then facilitate cell invasion associated with cancer metastasis, angiogenesis, and inflammation.     

Autophagy: many paths to the same end

Different mechanisms lead to the degradation of intracellular proteins in the lysosomal compartment. Activation of one autophagic pathway or another, under specific cellular conditions, plays an important role in the ability of the cell to adapt to environmental changes. Each form of autophagy has its own individual characteristics, but it also shares common steps and components with the others. This interdependence of the autophagic pathways confers to the lysosomal system, both specificity and flexibility on substrate degradation. We describe in this review some of the recent findings on the molecular basis and regulation for each of the different autophagic pathways. We also discuss the cellular consequences of their interdependent function. Malfunctioning of the autophagic systems has dramatic consequences, especially in non-dividing differentiated cells. Using the heart as an example of such cells, we analyze the relevance of autophagy in aging and cell death, as well as in different pathological conditions.     

Vesicular trafficking in osteoclasts

Bone-resorbing osteoclasts are highly dependent on vesicular trafficking pathways that are regulated by Rab GTPases. In particular, polarised transport of acidic vesicles of the endocytic/lysosomal pathway is required for formation of the ruffled border, the resorptive organelle of the osteoclast. The breakdown products of resorption are then transported through the osteoclast by transcytosis, enabling their excretion. In this review, we summarise these trafficking routes, highlight the emerging evidence that the bone disease osteopetrosis results from defects in vesicular trafficking in osteoclasts, and outline the similarities between the endocytic/lysosomal compartment in osteoclasts and secretory lysosomes in other cell types.     

Lysosomal–mitochondrial cross-talk during cell death

Lysosomes are membrane-bound organelles, which contain an arsenal of different hydrolases, enabling them to act as the terminal degradative compartment of the endocytotic, phagocytic and autophagic pathways. During the last decade, it was convincingly shown that destabilization of lysosomal membrane and release of lysosomal content into the cytosol can initiate the lysosomal apoptotic pathway, which is dependent on mitochondria destabilization. The cleavage of BID to t-BID and degradation of anti-apoptotic BCL-2 proteins by lysosomal cysteine cathepsins were identified as links to the mitochondrial cytochrome c release, which eventually leads to caspase activation. There have also been reports about the involvement of lysosome destabilization and lysosomal proteases in the extrinsic apoptotic pathway, although the molecular mechanism is still under debate. In the present article, we discuss the cross-talk between lysosomes and mitochondria during apoptosis and its consequences for the fate of the cell.     

Connecting Hsp70, sphingolipid metabolism and lysosomal stability

Heat shock protein 70 (Hsp70) is an evolutionary highly conserved molecular chaperone. Upon cancer-associated translocation to the lysosomal compartment, it promotes cell survival by inhibiting lysosomal membrane permeabilization, a hallmark of stress-induced death. We have recently shown that Hsp70 stabilizes lysosomes by binding to the endo-lysosomal lipid bis(monoacylglycero)phosphate (BMP), an essential co-factor for lysosomal sphingolipid catabolism. The Hsp70–BMP interaction enhances the activity of acid sphingomyelinase, an important enzyme that hydrolyzes sphingomyelin. Importantly, treatment with recombinant Hsp70 effectively reverts the dramatic increase in lysosomal volume and decrease in lysosomal stability in cells from patients with Niemann-Pick disease, a genetic disorder associated with reduced acid sphingomyelinase activity. These findings give new insight into the mechanisms controlling lysosomal stability and integrity, and open new exciting possibilities for the treatment of cancer as well as Niemann-Pick disease.     

Chinese hamster ovary cell lysosomes retain pinocytized horseradish peroxidase and in situ-radioiodinated proteins.

We used Chinese hamster ovary cells, a cell line of fibroblastic origin, to investigate whether lysosomes are an exocytic compartment. To label lysosomal contents, Chinese hamster ovary cells were incubated with the solute marker horseradish peroxidase. After an 18-h uptake period, horseradish peroxidase was found in lysosomes by cell fractionation in Percoll gradients and by electron microscope cytochemistry. Over a 24-h period, lysosomal horseradish peroxidase was quantitatively retained by Chinese hamster ovary cells and inactivated with a t 1/2 of 6 to 8 h. Lysosomes were radioiodinated in situ by soluble lactoperoxidase internalized over an 18-h uptake period. About 70% of the radioiodine incorporation was pelleted at 100,000 X g under conditions in which greater than 80% of the lysosomal marker enzyme beta-hexosaminidase was released into the supernatant. By one-dimensional electrophoresis, about 18 protein species were present in the lysosomal membrane fraction, with radioiodine incorporation being most pronounced into species of 70,000 to 75,000 daltons. After a 30-min or 2-h chase at 37 degrees C, radioiodine that was incorporated into lysosomal membranes and contents was retained in lysosomes. These observations indicate that lysosomes labeled by fluid-phase pinocytosis are a terminal component of endocytic pathways in fibroblasts.     

Artesunate activates mitochondrial apoptosis in breast cancer cells via iron-catalyzed lysosomal reactive oxygen species production

The antimalarial agent artesunate (ART) activates programmed cell death (PCD) in cancer cells in a manner dependent on the presence of iron and the generation of reactive oxygen species. In malaria parasites, ART cytotoxicity originates from interactions with heme-derived iron within the food vacuole. The analogous digestive compartment of mammalian cells, the lysosome, similarly contains high levels of redox-active iron and in response to specific stimuli can initiate mitochondrial apoptosis. We thus investigated the role of lysosomes in ART-induced PCD and determined that in MCF-7 breast cancer cells ART activates lysosome-dependent mitochondrial outer membrane permeabilization. ART impacted endolysosomal and autophagosomal compartments, inhibiting autophagosome turnover and causing perinuclear clustering of autophagosomes, early and late endosomes, and lysosomes. Lysosomal iron chelation blocked all measured parameters of ART-induced PCD, whereas lysosomal iron loading enhanced death, thus identifying lysosomal iron as the lethal source of reactive oxygen species upstream of mitochondrial outer membrane permeabilization. Moreover, lysosomal inhibitors chloroquine and bafilomycin A1 reduced ART-activated PCD, evidencing a requirement for lysosomal function during PCD signaling. ART killing did not involve activation of the BH3-only protein, Bid, yet ART enhanced TNF-mediated Bid cleavage. We additionally demonstrated the lysosomal PCD pathway in T47D and MDA-MB-231 breast cancer cells. Importantly, non-tumorigenic MCF-10A cells resisted ART-induced PCD. Together, our data suggest that ART triggers PCD via engagement of distinct, interconnected PCD pathways, with hierarchical signaling from lysosomes to mitochondria, suggesting a potential clinical use of ART for targeting lysosomes in cancer treatment.     

Multiple endocytic trafficking pathways of MHC class I molecules induced by a Herpesvirus protein

The K3 protein of a human tumor-inducing herpesvirus, Kaposi's sarcoma-associated herpesvirus (KSHV), down-regulates major histocompatibility complex (MHC) class I surface expression by increasing the rate of endocytosis. In this report, we demonstrate that the internalization of MHC class I by the K3 protein is the result of multiple, consecutive trafficking pathways that accelerate the endocytosis of class I molecules, redirect them to the trans-Golgi network (TGN), and target MHC class I to the lysosomal compartment. Remarkably, these actions of K3 are functionally and genetically separable; the N-terminal zinc finger motif and the central sorting motif are involved in triggering internalization of MHC class I molecules and redirecting them to the TGN. Subsequently, the C-terminal diacidic cluster region of K3 is engaged in targeting MHC class I molecules to the lysosomal compartment. These results demonstrate a novel trafficking mechanism of MHC class I molecules induced by KSHV K3, which ensures viral escape from host immune effector recognition.     

ErbB2-associated changes in the lysosomal proteome

Late endosomes and lysosomes (hereafter referred to as lysosomes) play an essential role in the turnover of cellular macromolecules and organelles. Their biochemical characterization has so far depended on purification methods based on either density gradient centrifugations or magnetic purification of iron-loaded organelles. Owing to dramatic changes in lysosomal density and stability associated with lysosomal diseases and cancer, these methods are not optimal for the comparison of normal and pathological lysosomes. Here, we introduce an efficient method for the purification of intact lysosomes by magnetic immunoprecipitation with antibodies against the vacuolar-type H(+) -ATPase. Quantitative MS-based proteomics analysis of the obtained lysosomal membranes identified 60 proteins, most of which have previously been associated with the lysosomal compartment. Interestingly, the lysosomal membrane proteome was significantly altered by the ectopic expression of an active form of the ErbB2 oncogene, which renders the cells highly metastatic. The furthermost ErbB2-associated changes included increased levels of CD63, S100A11 and ferritin heavy chain. Overall, our data introduce the antibody-based purification of lysosomes as a suitable method for the characterization of lysosomes from a variety of pathological conditions with altered lysosomal density and stability.     

Autophagy: Many paths to the same end

Different mechanisms lead to the degradation of intracellular proteins in the lysosomal compartment. Activation of one autophagic pathway or another, under specific cellular conditions, plays an important role in the ability of the cell to adapt to environmental changes. Each form of autophagy has its own individual characteristics, but it also shares common steps and components with the others. This interdependence of the autophagic pathways confers to the lysosomal system, both specificity and flexibility on substrate degradation. We describe in this review some of the recent findings on the molecular basis and regulation for each of the different autophagic pathways. We also discuss the cellular consequences of their interdependent function. Malfunctioning of the autophagic systems has dramatic consequences, especially in non-dividing differentiated cells. Using the heart as an example of such cells, we analyze the relevance of autophagy in aging and cell death, as well as in different pathological conditions. (Mol Cell Biochem 263: 55–72, 2004)     

Core signaling pathways of survival/death in autophagy-related cancer networks

Autophagy (macroautophagy), an evolutionarily conserved lysosomal degradation process, is implicated in a wide variety of pathological processes including cancer. Autophagy plays the Janus role in regulating several survival or death signaling pathways that may decide the fate of cancer cell. Accumulating evidence has revealed the core molecular machinery of autophagy in tumor initiation and progression; however, the intricate relationships between autophagy and cancer are still in its infancy. In this review, we summarize several key survival/death pathways such as mTOR subnetwork, Beclin 1 interactome, and p53 signaling that may play the crucial roles for the regulation of the autophagy-related cancer networks. Therefore, a better understanding of the relationships between autophagy and cancer may ultimately allow cancer biologists and clinicians to harness core autophagic pathways for the discovery of potential novel drug targets.     

Quantitative and time-resolved monitoring of organelle and protein delivery to the lysosome with a tandem fluorescent Halo-GFP reporter

Lysosomal degradative compartments hydrolyze macromolecules to generate basic building blocks that fuel metabolic pathways in our cells. They also remove misfolded proteins and control size, function, and number of cytoplasmic organelles via constitutive and regulated autophagy. These catabolic processes attract interest because their defective functioning is linked to human disease and their molecular components are promising pharmacologic targets. The capacity to quantitatively assess them is highly sought-after. Here we present a tandem-fluorescent reporter consisting of a HaloTag-GFP chimera appended at the C- or at the N-terminus of select polypeptides to monitor protein and organelle delivery to the lysosomal compartment. The Halo-GFP changes color on fluorescent pulse with cell-permeable HaloTag ligands and, again, on delivery to acidic, degradative lysosomal compartments, where the fluorescent ligand-associated HaloTag is relatively stable, whereas the GFP portion is not, as testified by loss of the green fluorescence and generation of a protease-resistant, fluorescent HaloTag fragment. The Halo-GFP tandem fluorescent reporter presented in our study allows quantitative and, crucially, time-resolved analyses of protein and organelle transport to the lysosomal compartment by high resolution confocal laser scanning microscopy, antibody-free electrophoretic techniques and flow cytometry.     

Internalized proteins directed into accumulative compartments of mosquito oocytes by the specific ligand, vitellogenin

We have investigated the internalization pathways for a specific protein, vitellogenin, and a non-specific protein, horseradish peroxidase, in the mosquito oocyte in vivo. The internalized proteins were localized by electron microscopical immunocytochemistry or autoradiography; the relationship of their destination compartments with lysosomes was monitored by visualization of acid phosphatase. Proteins internalized by the oocyte follow either a specific accumulative route or a lysosomal degradative route. Via coated vesicles, both proteins enter the same compartment, the endosome, where they dissociate from membrane-binding sites. The route to their final destination depends on the presence of the specific ligand. In its absence, the degradative route is followed, and the endosome with non-specific protein fuses with lysosomes. In the presence of the specific ligand, the accumulative route is followed, and both specific and non-specific proteins are delivered into an accumulative compartment, the transitional yolk body. During the transformation of the transitional yolk body into the final storage compartment, a mature yolk body, vitellogenin undergoes crystallization, whereas the non-specific protein is concentrated in small vesicular extensions of the compartmental membrane. These vesicles are separated from the yolk bodies and apparently deliver the non-specific protein into the lysosomal system. We concluded that any protein bound to the membrane would be internalized by the oocyte, but only binding of the specific ligand to its receptor serves as a transmembrane signal stimulating the formation of accumulative compartments.     

The role of ceroid lipofuscinosis neuronal protein 5 (CLN5) in endosomal sorting

Mutations in the gene encoding CLN5 are the cause of Finnish variant late infantile Neuronal Ceroid Lipofuscinosis (NCL), and the gene encoding CLN5 is 1 of 10 genes (encoding CLN1 to CLN9 and cathepsin D) whose germ line mutations result in a group of recessive disorders of childhood. Although CLN5 localizes to the lysosomal compartment, its function remains unknown. We have uncovered an interaction between CLN5 and sortilin, the lysosomal sorting receptor. However, CLN5, unlike prosaposin, does not require sortilin to localize to the lysosomal compartment. We demonstrate that in CLN5-depleted HeLa cells, the lysosomal sorting receptors sortilin and cation-independent mannose 6-phosphate receptor (CI-MPR) are degraded in lysosomes due to a defect in recruitment of the retromer (an endosome-to-Golgi compartment trafficking component). In addition, we show that the retromer recruitment machinery is also affected by CLN5 depletion, as we found less loaded Rab7, which is required to recruit retromer. Taken together, our results support a role for CLN5 in controlling the itinerary of the lysosomal sorting receptors by regulating retromer recruitment at the endosome.     

Ubiquitin trafficking to the lysosome: keeping the house tidy and getting rid of unwanted guests

Bacterial killing by autophagic delivery to the lysosomal compartment has been shown for Mycobacteria, Streptococcus, Shigella, Legionella and Salmonella, indicating an important role for this conserved trafficking pathway for the control of intracellular bacterial pathogens.(1-5) In a recent study we found that solubilized lysosomes isolated from bone marrow-derived macrophages had potent antibacterial properties against M. tuberculosis and M. smegmatis that were associated with ubiquitin and ubiquitin-derived peptides. We propose that ubiquitinated proteins are delivered to the lysosomal compartment, where degradation by lysosomal proteinases generates ubiquitin-derived peptides with antimycobacterial properties. This surprising finding provokes a number of questions regarding the nature and trafficking of ubiquitin and ubiquitin-modified proteins in mammalian cells. We discuss the possible role(s) that the multivesicular body (MVB), the late endosome and the autophagosome may play in trafficking of ubiquitinated proteins to the lysosome.     

Macrophages Create an Acidic Extracellular Hydrolytic Compartment to Digest Aggregated Lipoproteins

A critical event in atherogenesis is the interaction of macrophages with subendothelial lipoproteins. Although most studies model this interaction by incubating macrophages with monomeric lipoproteins, macrophages in vivo encounter lipoproteins that are aggregated. The physical features of the lipoproteins require distinctive mechanisms for their uptake. We show that macrophages create an extracellular, acidic, hydrolytic compartment to carry out digestion of aggregated low-density lipoproteins. We demonstrate delivery of lysosomal contents to these specialized compartments and their acidification by vacuolar ATPase, enabling aggregate catabolism by lysosomal acid hydrolases. We observe transient sealing of portions of the compartments, allowing formation of an “extracellular” proton gradient. An increase in free cholesterol is observed in aggregates contained in these compartments. Thus, cholesteryl ester hydrolysis can occur extracellularly in a specialized compartment, a lysosomal synapse, during the interaction of macrophages with aggregated low-density lipoprotein. A detailed understanding of these processes is essential for developing strategies to prevent atherosclerosis.     

An unusual lysosome compartment involved in vitellogenin endocytosis by Xenopus oocytes

We have investigated the lysosomal compartment of Xenopus oocytes to determine the possible role of this organelle in the endocytic pathway of the yolk protein precursor, vitellogenin. Oocytes have lysosome-like organelles of unusual enzymatic composition at all stages of their development, and the amount of hydrolase activity increases steadily throughout oogenesis. These unusual lysosomes appear to be located primarily in a peripheral zone of oocyte cytoplasm. At least two distinct populations of lysosomal organelles can be identified after sucrose density gradient fractionation of vitellogenic oocytes. Most enzyme activity resides in a compartment of large size and high density that appears to be a subpopulation of yolk platelets that are less dense than most platelets within the cell. The appearance of this high density peak of lysosomal enzyme activity coincides with the time of onset of vitellogenin endocytosis during oocyte development. The data suggest that endocytic vesicles that contain vitellogenin fuse with modified lysosomes shortly after their internalization by the oocyte. Pulse-chase experiments with radiolabeled vitellogenin suggest that the ligand passes through the low density platelet compartment en route to the heavy platelets. The accumulation of yolk proteins apparently results from a failure of these molecules to undergo complete digestion after their entry into an unusual lysosomal compartment. The yolk platelets that these proteins finally enter for prolonged storage appear to be a postlysosomal organelle.