Intracellular localization of beta-glucuronidase in fibroblasts after direct transfer from macrophages

Time-course study of the early lysosomal responses to pollutants in mussel digestive cells using acid phosphatase as lysosomal marker enzyme

Lysosomal biomarkers are early warning signals of the biological effects caused by environmental pollutants but the promptness of lysosomal responses to pollutants has not been investigated yet. This work is aimed to determine the response-time of digestive cell lysosomes in mussels exposed to metals and hydrocarbons. Mussels, Mytilus galloprovincialis, were exposed, under laboratory conditions to Cd and to the water-accommodated fraction of a lubricant oil. One mussel per experimental group was sacrificed and processed every hour from 0 h to 30 h. Changes in AcP activity, immunoreactivity and LMS test based on AcP histochemistry, discriminates significantly control and exposed mussels within 5 h exposure. The present results suggested that after 15-20 h exposure digestive cell loss might be accompanied by increased AcP activity (extralysosomal) without a parallel increase in the levels of immunoreactive AcP protein, especially after Cd-exposure. The reduced labilisation period of lysosomal membrane constitute a cost effective early warning signal that, however, is not necessarily correlated with the exposure time. The routine application of immunochemical techniques deserves more research efforts before its implementation although, these techniques are very valuable to understand and interpret correctly lysosomal responses to pollutants.

Early onset of lysosomal storage disease in a murine model of mucopolysaccharidosis type VII: undegraded substrate accumulates in many tissues in the fetus and very young MPS VII mouse

Lysosomal storage diseases (LSDs), due to deficiency of a lysosomal enzyme, are inherited, progressive disorders that are often fatal during childhood. The mucopolysaccharidoses (MPS) are LSDs caused by deficiency of a lysosomal enzyme needed for the stepwise degradation of glycosaminoglycans. A murine model of MPS VII shares many clinical, biochemical, and pathologic features with human MPS and has proved valuable for the study of the pathophysiology of MPS and for evaluation of therapies for LSDs. Early therapy of MPS VII mice, initiated in the first weeks of life, is much more effective in decreasing clinical and morphologic evidence of disease than treatment begun in mature animals. Whether such early therapy decreases existing storage or prevents its accumulation is incompletely investigated. We performed an analysis of storage in very young MPS VII mice to define the extent of disease at and before the time of initiation of early treatments. MPS VII pups from 12 days postcoitus (dpc) to 31 days postnatal (dpn) were studied. Storage accumulated in fixed tissue macrophages in the liver and cartilage as soon as 12 dpc and was present in central nervous system glia, leptomeninges, and perivascular cells by 15 dpc. Osteoblast and primitive neocortical cell storage was apparent at 18 to 19 dpc. At 2 dpn, lysosomal distention appeared in circulating leukocytes. Abundant lysosomal storage was present in many sites by 14 dpn. Secondary accumulation of beta-hexosaminidase paralleled increasing glycosaminoglycan storage. These results confirm the presence of widespread storage even in utero and in the very young MPS VII mouse and highlight the importance of early treatment to prevent storage accumulation.

Uptake of oxidized LDL by macrophages differs from that of acetyl LDL and leads to expansion of an acidic endolysosomal compartment

Accumulation of cholesterol by macrophage foam cells in atherosclerotic lesions is thought to involve the uptake of modified low density lipoproteins (LDLs). Previous studies have shown that there is impaired degradation of oxidized LDL in macrophages. The present study was done to determine whether the differences in intracellular metabolism of oxidized LDL and acetyl LDL were associated with delivery to different intracellular compartments. Mouse peritoneal macrophages were incubated with 1,1'-dioctadecyl-3, 3,3',3'-tetramethylindocarbocyanine perchlo- rate-labeled oxidized LDL or 3,3'-dioctadecyloxacarbocyanine perchlorate-labeled acetyl LDL and examined by fluorescence microscopy. Deconvolution image analysis showed <10% colocalization of the 2 lipoproteins at incubation times ranging from 30 minutes to 6 hours. Subcellular fractionation of macrophages after incubation with (99m)Tc-labeled oxidized LDL revealed accumulation of the tracer in a compartment with a d=1.042 g/mL, consistent with endosomes. Surprisingly, there was a concurrent dramatic shift of the density of lysosomal marker enzymes from d=1.1 g/mL to the same fractions that contained (99m)Tc, indicating that this compartment was formed after fusion with primary lysosomes. Parallel experiments in J774 cells, a murine macrophage-like cell line, did not show a similar density shift, perhaps because of the slower rate of accumulation of oxidized LDL by these cells. Fluorescence microscopy of macrophages labeled with a lysosomotropic dye revealed a marked expansion of the acidic compartment after exposure of cells to oxidized LDL. We conclude that oxidized LDL and acetyl LDL are internalized by morphologically distinct pathways. Furthermore, because of its impaired lysosomal degradation, oxidized LDL causes expansion of and a decrease in the density of the lysosomal compartment in macrophages.

Alternative mechanisms for trafficking of lysosomal enzymes in mannose 6-phosphate receptor-deficient mice are cell type-specific

Viable mice nullizygous in genes encoding the 300 kDa and the 46 kDa mannose 6-phosphate receptors (MPR 300 and MPR 46) and the insulin like growth factor II (IGF II) were generated to study the trafficking of lysosomal enzymes in the absence of MPRs. The mice have an I-cell disease-like phenotype, with increase of lysosomal enzymes in serum and normal activities in tissues. Surprisingly, the ability of MPR-deficient cells to transport newly synthesized lysosomal enzymes to lysosomes and the underlying mechanisms were found to depend on the cell type. MPR-deficient thymocytes target newly synthesized cathepsin D to lysosomes via an intracellular route. In contrast, hepatocytes and fibroblasts secrete newly synthesized cathepsin D. In fibroblasts recapture of secreted lysosomal enzymes, including that of cathepsin D, is limited and results in lysosomal storage, both in vivo and in vitro, whereas recapture by hepatocytes is remarkably effective in vivo and can result in lysosomal enzyme levels even above normal.

Lysosomal storage diseases: mechanisms of enzyme replacement therapy

Lysosomal diseases result from deficiency of one of the many enzymes involved in the normal, step-wise breakdown of macromolecules. Studies in vitro have shown that cells from enzyme-deficient patients can be corrected by an exogenous supply of the missing enzyme. This occurs by receptor-mediated endocytosis of normal enzyme added to tissue culture medium and also by direct transfer from normal leukocytes during cell-to-cell contact. Immunohistochemical analysis has revealed that these processes have similar pathways of intracellular transport of the acquired enzymes, which ultimately reach mature lysosomes in the recipient cells. Moreover, recent studies suggest that both mechanisms are important in the therapy of lysosomal storage diseases by bone marrow transplantation. Advances in gene technology are likely to improve the successful treatment of these disorders, by facilitating the large scale production of clinically effective proteins and also by enabling the stable and safe introduction of normal lysosomal genes into cells of affected patients.

An N-terminal peptide from link protein is rapidly degraded by chondrocytes, monocytes and B cells

A peptide cleaved from the link-protein component of human and pig proteoglycan aggregates by trypsin and stromelysin was taken up and degraded further by human monocytes, B cells, chondrocytes and by mouse peritoneal macrophages. Monocytes were able to process the peptide twice as rapidly as peritoneal macrophages and some 16 times more rapidly than articular chondrocytes. The B cell line Priess, which unlike the monocytes and macrophages could not take up or degrade whole proteoglycan aggregates, was able to degrade the peptide at a rapid rate. Synthetic, unglycosylated peptides consisting of the first 16 and 13 N-terminal amino acids of human link protein, corresponding to its stromelysin-cleavage and trypsin-cleavage products, were also taken up and degraded in a similar manner to the natural products and, in addition, were able to block uptake of the 125I-labelled natural peptides. The isoelectric points of the re-secreted breakdown fragment from both the synthetic and natural peptides were identical and each peptide was processed by the cells to produce a single radiolabelled fragment. Each of these fragments was eluted with the same retention time during HPLC, indicating that the natural peptides were derived from the N-terminal region of the link. Since a proportion of the link protein extracted from human and pig cartilage has already undergone proteolysis to remove peptides from its N-terminal region, these peptides may be produced in articular cartilage during the normal process of turnover and ageing. Although a physiological function for this protein has not been established, it may have a homeostatic role in the regulation of proteoglycan synthesis.

A proteolytic fragment from human link protein is taken up and processed by monocytes and B cells

Mild digestion of 125I-labelled human proteoglycan aggregates with trypsin or stromelysin produced specific peptides that were taken up rapidly by THP-1 monocytes. SDS/PAGE of undigested aggregate showed that the three components of molecular mass 48, 44 and 41 kDa, corresponding to isoforms of link protein originally present, had been converted into a single component of 41 kDa by trypsin treatment, and that fragments of 6-12 kDa were present in fractions containing the high-uptake peptide. Separate proteolysis of isolated proteoglycan monomer and link protein confirmed that the specific high-uptake fragment was derived from link protein. Uptake of the link fragment was rapid, reaching a maximum after 5 min, and specific, since it was blocked by metabolic or serine proteinase inhibitors and at 4 degrees C. After uptake the cleaved fragment was processed further, with 50% of the radiolabel being released as degraded peptides within 5 min. In contrast, accumulation of whole aggregate reached a maximum after 45 min and only 50% had been released after 2 h. Uptake of aggregate was less affected by inhibitors or at low temperature, suggesting that a separate mechanism existed for its turnover. The aggregate was transported to lysosomes after uptake, although the link fragment did not sediment with either lysosomes or plasma membranes, suggesting that it was present in the cytoplasm or in very labile vesicles. However, the mode of handling of the peptide by the cells remains unclear. The link fragment was taken up by several different monocytic and B cell lines, but not by mouse fibroblasts or peritoneal macrophages. These data suggest that a surface serine proteinase on monocytes and B cells enables them to process and take up a fragment of link protein derived by extracellular proteolysis.

Contact formation and transfer of mannose BSA gold from macrophages to cocultured fibroblasts

When macrophages were cocultured with fibroblasts many of the cells formed firm contacts. In some of these contacts both cell types were closely apposed and in others they were more clearly separated with numerous pseudopodia extending from macrophages toward the fibroblasts. Many small vesicles similar in structure to caveoli were observed immediately beneath the plasma membrane of some fibroblasts in regions immediately adjacent to areas of contact with macrophages. The membrane integrity of both cell types was always maintained and no connecting cytoplasmic strands were observed between contacting cells. Junctions were freely permeable to ruthenium red and less permeable to the larger cationized ferritin. Gold conjugated to mannose BSA was taken up readily by macrophages but not by fibroblasts. When fibroblasts were cocultured with macrophages that had been labeled with endocytosed gold, increasing amounts were transferred to them. Gold was observed within gaps formed between cocultured cells and within recipient fibroblasts in vesicles anatomically similar to lysosomes. These points of contact thus appear to provide a series of specialized protected clefts into which directed exocytosis of ligands from donor cells can take place and from which endocytosis into recipient cells is facilitated.

Intercellular transport of lysosomal acid lipase mediates lipoprotein cholesteryl ester metabolism in a human vascular endothelial cell-fibroblast coculture system

We present results from studies of human cell culture models to support the premise that the extracellular transport of lysosomal acid lipase has a function in lipoprotein cholesteryl ester metabolism in vascular tissue. Vascular endothelial cells secreted a higher fraction of cellular acid lipase than did smooth muscle cells and fibroblasts. Acid lipase and lysosomal beta-hexosaminidase were secreted at approximately the same rate from the apical and basolateral surface of an endothelial cell monolayer. Stimulation of secretion with NH4Cl did not affect the polarity. We tested for the ability of secreted endothelial lipase to interact with connective tissue cells and influence lipoprotein cholesterol metabolism in a coculture system in which endothelial cells on a micropore filter were suspended above a monolayer of acid lipase-deficient (Wolman disease) fibroblasts. After 5-7 d, acid lipase activity in the fibroblasts reached 10%-20% of the level in normal cells; cholesteryl esters that had accumulated from growth in serum were cleared. Addition of mannose 6-phosphate to the coculture medium blocked acid lipase uptake and cholesterol clearance, indicating that lipase released from endothelial cells was packaged into fibroblast lysosomes by a phosphomannosyl receptor-mediated pathway. Supplementation of the coculture medium with serum was not required for lipase uptake and cholesteryl ester hydrolysis by the fibroblasts, but was necessary for cholesterol clearance. Results from our coculture model suggest that acid lipase may be transported from intact endothelium to cells in the lumen or the wall of a blood vessel. We postulate that delivery of acid hydrolases and lipoproteins to a common endocytic compartment may occur and have an impact on cellular lipoprotein processing.