N-acetylneuraminic acid accumulation in a buoyant lysosomal fraction of cultured fibroblasts from patients with infantile generalized N-acetylneuraminic acid storage disease

Cultured fibroblasts from control individuals and two patients affected with the infantile variant of generalized N-acetylneuraminic acid (NeuAc) storage disease were disrupted by nitrogen cavitation, and the post-nuclear supernatant fractions were subjected to subcellular fractionation on Percoll gradients. Accumulating NeuAc in affected fibroblasts (approx. 150 nmol/mg protein) co-localized with the lysosomal marker N-acetyl-beta-hexosaminidase (Hex), in a fraction with a mean density of 1.035 g/ml. In contrast, more than 70% of the Hex activity of control cells sedimented in comparable gradients with a density of more than 1.07 g/ml. The lysosomal localization of NeuAc accumulation in affected fibroblasts was confirmed by treatment of post-nuclear supernatant fractions with 0.5 mM Gly-Phe-beta-naphthylamide (20 min, 37 degrees C) prior to centrifugation, which resulted in the simultaneous loss of latency of Hex and free NeuAc, and their association with the soluble fraction on Percoll gradients. The results provide direct evidence for the accumulation of free NeuAc in a unique buoyant lysosomal fraction of affected fibroblasts.     

Inhibition of early but not late proteolytic processing events leads to the missorting and oversecretion of precursor forms of lysosomal enzymes in Dictyostelium discoideum

Lysosomal enzymes are initially synthesized as precursor polypeptides which are proteolytically cleaved to generate mature forms of the enzymatically active protein. The identification of the proteinases involved in this process and their intracellular location will be important initial steps in determining the role of proteolysis in the function and targeting of lysosomal enzymes. Toward this end, axenically growing Dictyostelium discoideum cells were pulse radiolabeled with [35S]methionine and chased in fresh growth medium containing inhibitors of aspartic, metallo, serine, or cysteine proteinases. Cells exposed to the serine/cysteine proteinase inhibitors leupeptin and antipain and the cysteine proteinase inhibitor benzyloxycarbonyl-L-phenylalanyl-L-alanine-diazomethyl ketone (Z-Phe- AlaCHN2) were unable to complete proteolytic processing of the newly synthesized lysosomal enzymes, alpha-mannosidase and beta-glucosidase. Antipain and leupeptin treatment resulted in both a dramatic decrease in the efficiency of proteolytic processing, as well as a sevenfold increase in the secretion of alpha-mannosidase and beta-glucosidase precursors. However, leupeptin and antipain did not stimulate secretion of lysosomally localized mature forms of the enzymes suggesting that these inhibitors prevent the normal sorting of lysosomal enzyme precursors to lysosomes. In contrast to the results observed for cells treated with leupeptin or antipain, Z-Phe-AlaCHN2 did not prevent the cleavage of precursor polypeptides to intermediate forms of the enzymes, but greatly inhibited the production of the mature enzymes. The accumulated intermediate forms of the enzymes, however, were localized to lysosomes. Finally, fractionation of cell extracts on Percoll gradients indicated that the processing of radiolabeled precursor forms of alpha-mannosidase and beta-glucosidase to intermediate products began in cellular compartments intermediate in density between the Golgi complex and mature lysosomes. The generation of the mature forms, in contrast, was completed immediately upon or soon after arrival in lysosomes. Together these results suggest that different proteinases residing in separate intracellular compartments may be involved in generating intermediate and mature forms of lysosomal enzymes in Dictyostelium discoideum, and that the initial cleavage of the precursors may be critical for the proper localization of lysosomal enzymes.     

Sulfated N-linked oligosaccharides affect secretion but are not essential for the transport, proteolytic processing, and sorting of lysosomal enzymes in Dictyostelium discoideum

Although previous studies have indicated that N-linked oligosaccharides on lysosomal enzymes in Dictyostelium discoideum are extensively phosphorylated and sulfated, the role of these modifications in the sorting and function of these enzymes remains to be determined. We have used radiolabel pulse-chase, subcellular fractionation, and immunofluorescence microscopy to analyze the transport, processing, secretion, and sorting of two lysosomal enzymes in a mutant, HL244, which is almost completely defective in sulfation. [3H]Mannose-labeled N-linked oligosaccharides were released from immunoprecipitated alpha-mannosidase and beta-glucosidase of HL244 by digestion with peptide: N-glycosidase. The size, Man9-10GlcNAc2, and processing of the neutral species were similar to that found in the wild type, but the anionic oligosaccharides were less charged than those from the wild-type enzymes. All of the negative charges on the oligosaccharides for HL244 were due to the presence of 1, 2, or 3 phosphodiesters and not to sulfate esters. The rate of proteolytic processing of precursor forms of alpha-mannosidase and beta-glucosidase to mature forms in HL244 was identical to wild type. The precursor polypeptides in the mutant and the wild type were membrane associated until being processed to mature forms; therefore, sulfated sugars are not essential for this association. Furthermore, the rate of transport of alpha-mannosidase and beta-glucosidase from the endoplasmic reticulum to the Golgi complex was normal in the mutant as determined by the rate at which the newly synthesized proteins became resistant to the enzyme, endo-beta-N-acetylglucosaminidase H. There was no increase in the percentage of newly synthesized mutant precursors which escaped sorting and were secreted, and the intracellularly retained lysosomal enzymes were properly localized to lysosomes as determined by fractionation of cell organelles on Percoll gradients and immunofluorescence microscopy. However, the mutant secreted lysosomally localized mature forms of the enzymes at 2-fold lower rates than wild-type cells during both growth and during starvation conditions that stimulate secretion. Furthermore, the mutant was more resistant to the effects of chloroquine treatment which results in the missorting and oversecretion of lysosomal enzymes. Together, these results suggest that sulfation of N-linked oligosaccharides is not essential for the transport, processing, or sorting of lysosomal enzymes in D. discoideum, but these modified oligosaccharides may function in the secretion of mature forms of the enzymes from lysosomes.     

Intracellular transport of acid alpha-glucosidase in human fibroblasts: evidence for involvement of phosphomannosyl receptor-independent system

Intracellular transport of two lysosomal enzymes, acid alpha-glucosidase and beta-hexosaminidase, was analyzed in human fibroblasts. The precursors of beta-hexosaminidase in normal fibroblasts were released from the membrane fraction by treatment with mannose 6-phosphate, but the precursor of alpha-glucosidase was not. Percoll density gradient centrifugation revealed a normal amount of acid alpha-glucosidase activity in heavy lysosomes in I-cell disease fibroblasts despite impaired maturation and defective phosphorylation, and beta-hexosaminidase activity was markedly reduced in lysosomes. It was concluded that the membrane-bound precursor of acid alpha-glucosidase is transported to lysosomes by a phosphomannosyl receptor-independent system although the enzyme lacks the recognition marker for the phosphomannosyl receptor and processing of an intermediate form to mature forms does not occur in this disease.     

Endolysosomal transport of newly-synthesized cathepsin D in a sucrose model of lysosomal storage

Newly-synthesized soluble lysosomal enzymes are transported from the trans-Golgi network to lysosomes by a mannose 6-phosphate receptor-mediated pathway. Lysosomal storage of indigestible material has been reported to perturb the biosynthesis and the fate of lysosomal hydrolases. In this study, we have focused our attention on the last steps in the transport of newly-synthesized cathepsin D to lysosomes in sucrose-treated WI-38 fibroblasts. Pulse-chase experiments indicate that, in sucrose-treated cells, cathepsin D maturation is delayed by 2 to 4 h. By subcellular fractionation, we show that newly-synthesized cathepsin D precursors transit through organelles endowed with a high sedimentation coefficient. These organelles are recovered in the dense region of a self-forming Percoll density gradient while the bulk of hydrolytic activities is redistributed to the low density region. Only later, are the precursors delivered to organelles containing the bulk of active hydrolases. There, procathepsin D is proteolytically processed into its 31 kDa-mature form. Our results suggest that when sucrose is present, the delayed maturation of procathepsin D is related to the delivery of the polypeptides into an organelle behaving in centrifugation like lysosomes but which is poorly efficient in proteolytic processing of procathepsin D. This low proteolytic activity of this organelle could be due to its poor ability to interact with hydrolase-containing structures.     

Role of acidic intracellular compartments in the biosynthesis of Dictyostelium lysosomal enzymes. The weak bases ammonium chloride and chloroquine differentially affect proteolytic processing and sorting

Radiolabel pulse-chase and subcellular fractionation procedures were used to analyze the transport, proteolytic processing, and sorting of two lysosomal enzymes in Dictyostelium discoideum cells treated with the weak bases ammonium chloride and chloroquine. Dictyostelium lacks detectable cation-independent mannose-6-phosphate receptors and represents an excellent system to investigate alternative mechanisms for lysosomal enzyme targeting. Exposure of growing cells to ammonium chloride, which increased the pH in intracellular vacuoles from 5.4 to 5.8-6.1, slowed but did not prevent the proteolytic processing and correct localization of pulse-radiolabeled precursors to the lysosomal enzymes alpha-mannosidase and beta-glucosidase. Additionally, ammonium chloride did not affect transport of the enzymes to the Golgi complex, as they acquired resistance to the enzyme endoglycosidase H at the same rate as in control cells. When the pH of lysosomal and endosomal organelles was raised to 6.4 with higher concentrations of ammonium chloride, the percentage of secreted (apparently mis-sorted) precursor polypeptides increased slightly, but proteolytic processing of intermediate forms of lysosomal enzymes to mature forms was greatly reduced. The intermediate and mature forms of alpha-mannosidase and beta-glucosidase did, however, accumulate intracellularly in vesicles similar in density to lysosomes. In contrast, in cells exposed to low concentrations of chloroquine the intravacuolar pH increased only slightly (to 5.7); however, enzymes were inefficiently processed and, instead, rapidly secreted as precursor molecules. Experiments involving the addition of chloroquine at various times during the chase of pulse-radiolabeled cells demonstrated that this weak base acted on a distal Golgi or prelysosomal compartment to prevent the normal sorting of lysosomal enzymes. These results suggest that although acidic endosomal/lysosomal compartments may be important for the complete proteolytic processing of lysosomal enzymes in Dictyostelium, low pH is not essential for the proper targeting of precursor polypeptides. Furthermore, certain amines may induce mis-sorting of these enzymes by pH-independent mechanisms.     

Effect of swainsonine on the processing and turnover of lysosomal beta-galactosidase and beta-glucuronidase from mouse peritoneal macrophages

The effect of swainsonine, an inhibitor of Golgi alpha-mannosidase II and lysosomal alpha-mannosidase, on the synthesis, processing, and turnover of two glycoproteins, lysosomal beta-galactosidase and lysosomal beta-glucuronidase, has been studied in cultured mouse peritoneal macrophages. No effect of the inhibitor on the relative rates of synthesis of the precursor form of either enzyme was observed. On the other hand, carbohydrate processing of beta-galactosidase and beta-glucuronidase was markedly altered by swainsonine, consistent with a blockage by the inhibitor of the removal of the alpha-1,3- and alpha-1,6-linked mannose residues which occurs in normal processing. In homogenates of both normal and swainsonine-treated cells, the precursor forms of the enzymes were found exclusively in the light membrane fraction on Percoll gradients and the mature forms exclusively in the lysosomal fractions indicating that translocation from Golgi to lysosomes and proteolytic processing in the lysosome were not impaired by the presence of abnormal oligosaccharide side chains. There was no detectable effect of swainsonine during a 4-day chase period on the total cellular turnover of these enzymes which involves two processes, secretion and degradation. In the absence of swainsonine, secretion represented about 40% of the total turnover of beta-galactosidase and about 50% with beta-glucuronidase. The presence of swainsonine increased these proportions to about 60 and 70%, respectively.     

Processing of human cathepsin D in lysosomes in vitro

The proteolytic maturation of cathepsin D polypeptides was studied in lysosomes isolated from metabolically labeled fibroblasts. In lysosomes isolated from fibroblasts labeled with [35S]methionine, 70-95% of labeled cathepsin D polypeptides were represented by a Mr = 47,000 polypeptide after a 20-min pulse and 75-min chase. When these lysosomes were incubated in vitro, up to 70% of the Mr = 47,000 polypeptide was processed to mature cathepsin D polypeptides. The processing was dependent on the integrity of the lysosomes, had an optimum between pH 6 and 7, and could be stimulated by dithiothreitol and ATP. The noncleavable ATP analogue, adenosine 5'-(beta, gamma-imido)triphosphate, and GTP, CTP, and UTP could not substitute for ATP. The ATP-dependent stimulation was associated with an acidification of lysosomes. It was inhibited by agents that dissipate the lysosomal pH gradient (carbonyl cyanide p-trifluoromethoxyphenylhydrazone, N,N'-dicyclohexylcarbodiimide, nigericin, NH4Cl). A stimulatory effect of ATP was observed also at pH 5.5. The stimulation at pH 5.5 was not associated with acidification of lysosomes and was resistant to protonophores. Inhibitors of lysosomal cysteine proteinases and N-ethylmaleimide inhibited the processing. In the presence of ATP the processing activity was partially protected from inhibition by N-ethylmaleimide. In conclusion, the maturation of cathepsin D in lysosomes depends on cysteine proteinases and is stimulated by the ATP-driven acidification of lysosomes. In addition, ATP stimulates maturation at pH 5.5 by a mechanism not involving the proton pump.     

Accumulation of sialic acid in endocytic compartments interferes with the formation of mature lysosomes. Impaired proteolytic processing of cathepsin B in fibroblasts of patients with lysosomal sialic acid storage disease.

The impact of an altered endocytic environment on the biogenesis of lysosomes was studied in fibroblasts of patients suffering from sialic acid storage disease (SASD). This inherited disorder is characterized by the accumulation of acidic monosaccharides in lysosomal compartments and a concomitant decrease of their buoyant density. We demonstrate that C-terminal trimming of the lysosomal cysteine proteinase cathepsin B is inhibited in SASD fibroblasts. This late event in the biosynthesis of cathepsin B normally takes place in mature lysosomes, suggesting an impaired biogenesis of these organelles in SASD cells. When normal fibroblasts are loaded with sucrose, which inhibits transport from late endosomes to lysosomes, C-terminal cathepsin B processing is prevented to the same extent. Further characterization of the terminal endocytic compartments of SASD cells revealed properties usually associated with late endosomes/prelysosomes. In addition to a decreased buoyant density, SASD "lysosomes" show a reduced acidification capacity and appear smaller than their normal counterparts. We conclude that the accumulation of small non-diffusible compounds within endocytic compartments interferes with the formation of mature lysosomes and that the acidic environment of the latter organelles is a prerequisite for C-terminal processing of lysosomal hydrolases.     

Lysosomal accumulation of phospholipids in mucolipidosis IV cultured fibroblasts

Pulse-chase studies were performed to investigate the metabolism of phosphatidylethanolamine (PEA) in cultured fibroblasts from patients with mucolipidosis type IV (MLIV) and normal controls. When cultured cells were incubated with 3H-ethanolamine, 80-90% of the intracellular radioactivity was associated with PEA. Compared to the metabolism of 3H-PEA in normal cells, the phospholipid was retained in greater amounts and degraded more slowly in the MLIV fibroblasts. The 3H-PEA concentration in lysosomal preparations isolated by Percoll gradients was more than 3-fold greater in MLIV than in normal cells after 10 days chase. These studies indicate that PEA catabolism is deranged in MLIV and suggest that the primary metabolic defect causes abnormal phospholipid catabolism in the lysosomes of affected individuals.     

Biosynthesis,glycosylation, and enzymatic processing in vivo of human tripeptidyl-peptidase I

Human tripeptidyl-peptidase I (TPP I, CLN2 protein) is a lysosomal serine protease that removes tripeptides from the free N termini of small polypeptides and also shows a minor endoprotease activity. Due to various naturally occurring mutations, an inherited deficiency of TPP I activity causes a fatal lysosomal storage disorder, classic late infantile neuronal ceroid lipofuscinosis (CLN2). In the present study, we analyzed biosynthesis, glycosylation, transport, and proteolytic processing of this enzyme in stably transfected Chinese hamster ovary cells as well as maturation of the endocytosed proenzyme in CLN2 lymphoblasts, fibroblasts, and N2a cells. Human TPP I was initially identified as a single precursor polypeptide of approximately 68 kDa, which, within a few hours, was converted to the mature enzyme of approximately 48 kDa. Compounds affecting the pH of intracellular acidic compartments, those interfering with the intracellular vesicular transport as well as inhibition of the fusion between late endosomes and lysosomes by temperature block or 3-methyladenine, hampered the conversion of TPP I proenzyme into the mature form, suggesting that this process takes place in lysosomal compartments. Digestion of immunoprecipitated TPP I proenzyme with both N-glycosidase F and endoglycosidase H as well as treatment of the cells with tunicamycin reduced the molecular mass of TPP I proenzyme by approximately 10 kDa, which indicates that all five potential N-glycosylation sites in TPP I are utilized. Mature TPP I was found to be partially resistant to endo H treatment; thus, some of its N-linked oligosaccharides are of the complex/hybrid type. Analysis of the effect of various classes of protease inhibitors and mutation of the active site Ser(475) on human TPP I maturation in cultured cells demonstrated that although TPP I zymogen is capable of autoactivation in vitro, a serine protease that is sensitive to AEBSF participates in processing of the proenzyme to the mature, active form in vivo.     

Presence of a lysosomal enzyme, arylsulfatase-A, in the prelysosome-endosome compartments of human cultured fibroblasts

Although endosomes and lysosomes are associated with different subcellular functions, we present evidence that a lysosomal enzyme, arylsulfatase-A, is present in prelysosomal vesicles which constitute part of the endosomal compartment. When human cultured fibroblasts were subfractionated with Percoll gradients, arylsulfatase-A activity was enriched in three subcellular fractions: dense lysosomes, light lysosomes, and light membranous vesicles. Pulsing the cells for 1 to 10 min with the fluid-phase endocytic marker, horseradish peroxidase, showed that endosomes enriched with the marker were distributed partly in the light lysosome fraction but mainly in the light membranous fraction. By pulsing the fibroblasts for 10 min with horseradish peroxidase conjugated to colloidal gold and then staining the light membranous and light lysosomal fractions for arylsulfatase-A activity with a specific cytochemical technique, the endocytic marker was detected under the electron microscope in the same vesicles as the lysosomal enzyme. The origin of the lysosomal enzyme in this endosomal compartment was shown not to be acquired through mannose 6-phosphate receptor-mediated endocytosis of enzymes previously secreted from the cell. Together with our recent finding that the light membranous fraction contains prelysosomes distinct from bona fide lysosomes and was highly enriched with newly synthesized arylsulfatase-A molecules, these results demonstrate that prelysosomes also constitute part of the endosomal compartment to which intracellular lysosomal enzymes are targeted.     

Specific storage of subunit c of mitochondrial ATP synthase in lysosomes of neuronal ceroid lipofuscinosis (Batten's disease).

Immunochemical studies demonstrated the specific accumulation of subunit c of mitochondrial ATP synthase in the brain homogenates of late infantile and juvenile forms of Batten's disease. It is not stored in the infantile form. Storage of subunit alpha of mitochondrial ATP synthase and cytochrome c oxidase subunit IV, an inner membrane protein of mitochondria was not detected in the brains. There was also no difference in the levels of cathepsin B between the two forms of Batten's disease and controls. In cultured skin fibroblasts subunit c accumulates in the late infantile form, whereas it does not in other lysosomal storage diseases. Crude mitochondrial lysosomal preparations of control fibroblasts were separated into high-density fractions rich in a lysosomal marker and low-density fractions rich in a mitochondrial marker on Percoll density gradients. Subunit c was mostly recovered in low-density mitochondrial fractions, but in cells from the late infantile disease a part of subunit c was recovered in the high-density lysosomal fractions. Immunolocalization studies demonstrated a dot-like staining of storage materials for subunit c in the cells from late infantile patients and the staining pattern of subunit c is similar to that of a lysosomal membrane marker, lgp120. Immunostaining failed to detect subunit c in control cells. These results indicate a specific accumulation of subunit c in lysosomes, and suggest that the two forms of Batten's disease are caused by a specific failure in the degradation of subunit c.     

Biosynthesis and processing of lysosomal acid phosphatase in cultured human cells

The biosynthesis of lysosomal acid phosphatase was studied in a normal human embryonic lung cell line, WI-38. Cells were labeled with radioactive leucine under a variety of conditions, the enzyme was immunoprecipitated using a monospecific antiserum raised against human liver lysosomal acid phosphatase, and the products were separated by electrophoresis and were visualized by fluorography. Lysosomal acid phosphatase constitutes 60% of the total tartrate-inhibitable acid phosphatase in WI-38. It is initially synthesized as a high-molecular-weight precursor polypeptide of 69 kDa. The precursor polypeptide is rapidly glycosylated and processed to a mature enzyme of 53-45 kDa via intermediates of 65 and 60 kDa in WI-38 cells. The 69-kDa precursor polypeptide is also converted to larger precursor polypeptides of 74 and 80 kDa. The multiplicity of precursor polypeptides is due at least in part to differences in the glycosylation and phosphorylation of the polypeptides. Sensitivity of phosphorylated oligosaccharide chains from precursor, mature and small polypeptides to endo-beta-hexosaminidase H-catalyzed cleavage suggests the presence of high-mannose phosphorylated oligosaccharide chains similar to those present on many other lysosomal enzymes. The effects of tunicamycin and ammonium chloride were also studied. In contrast to the effect of ammonium chloride on arylsulfatase A secretion, the lysosomal acid phosphatase in WI-38 cells was not secreted in the presence of NH4Cl. This is consistent with the existence of an alternate route for the transfer of lysosomal acid phosphatase into lysosomes. This alternate route may be the reason that I-cell fibroblasts contain a normal level of lysosomal acid phosphatase.     

Defective lysosomal egress of free sialic acid (N-acetylneuraminic acid) in fibroblasts of patients with infantile free sialic acid storage disease

Egress of free NeuAc from normal lysosome-rich granular fractions was assessed at NeuAc concentrations of up to 221 pmol/hexosaminidase unit, achieved by exposure of growing fibroblasts to 40-125 nM N-acetylmannosamine for up to 7 days. The normal velocity of NeuAc egress increased with NeuAc loading and with temperature, exhibiting a Q10 of 2.4, characteristic of carrier-mediated transport. Fibroblasts cultured from five patients with infantile free sialic acid storage disease (ISSD) contained approximately 139 nmol of free NeuAc/mg of whole cell protein, or 100 times the normal level. Differential centrifugation, as well as density gradient analysis using 25% Percoll, showed that the stored NeuAc cosedimented with the lysosomal enzyme beta-hexosaminidase. The velocity of appearance of free NeuAc outside ISSD granular fractions was negligible, even at initial loading levels of up to 3500 pmol/hexosaminidase unit. The lack of egress from ISSD granular fractions was found for both endogenous and N-acetylmannosamine-derived NeuAc. Fibroblasts from ISSD parents did not accumulate excess free NeuAc and did not display a velocity of NeuAc egress significantly different from normal. The defect in ISSD, like that in Salla disease, appears to be an impairment of carrier-mediated transport of free NeuAc across the lysosomal membrane. Clinical and biochemical differences between Salla disease and ISSD may reflect differences in the amount of residual NeuAc transport capacity.     

A sequence in beta-hexosaminidase from Dictyostelium discoideum required for sorting of proteins to a compartment involved in developmentally induced secretion.

To study the sorting of proteins in Dictyostelium discoideum, we used vector constructs that contain cDNA coding for the entire beta-hexosaminidase protein to prepare transformants of a mutant that lacks this enzyme activity. These transformants overexpressed active, normally processed beta-hexosaminidase. The overexpressed enzyme colocalized with other acid hydrolases in the soluble fraction of vesicles in the lysosomal region of Percoll gradients. The sorting of other hydrolases was unaltered. We also prepared transformants with constructs that contain 22 (Hex 22-Inv), 70 (Hex 70-Inv), and 532 (Hex 532-Inv) amino-terminal amino acids from beta-hexosaminidase fused in frame with the coding sequence for the yeast SUC2 gene product, invertase. Fusion molecular masses were those expected for fully N-glycosylated proteins. Hex 22-Inv was rapidly (t1/2 less than 30 min) and quantitatively secreted. The others were slowly (t1/2 greater than 5 h) and partially secreted. Each expressed invertase activity. During growth, the invertase activity of Hex 70-Inv and Hex 532-Inv was retained to the same extent as that of endogenous lysosomal enzymes. Most of the Hex 70-Inv migrated in Percoll gradients with vesicles of intermediate density (d = 1.055), but a portion co-migrated with lysosomal enzymes at d = 1.08. Hex 70-Inv was sulfated, and its N-glycosides were resistant to endoglycosidase H, indicating Golgi processing. Hex 70-Inv and Hex 532-Inv, like endogenous lysosomal enzymes, were subject to developmentally induced secretion.     

Relations between plasma membrane and lysosomal membrane. 1. Fate of covalently labelled plasma membrane protein

To quantify the kinetics of the plasma membrane flow into lysosomes, we covalently labelled at 4 degrees C the pericellular membrane of rat fibroblasts and followed label redistribution to the lysosomal membrane using purified lysosomal preparations. The polypeptides were, either labelled with 125I by the lactoperoxidase procedure, or conjugated to [3H]peroxidase using bisdiazobenzidine as a bifunctional reagent. Both labels were initially bound to plasma membrane, as indicated by their equilibrium density in sucrose or Percoll gradients and their displacement by digitonin, as well as by electron microscopy. Upon cell incubation at 37 degrees C, both covalent labels were lost from cells with diphasic kinetics: a minor component (35% of cell-associated labels) was rapidly released (half-life less than 1 h), and most label (65%) was released slowly (half-life was 20 h for incorporated 125I and 27 h for 3H). Immediately after labelling up to 30 h after incubation at 37 degrees C, the patterns of 125I-polypeptides quantified by autoradiography after SDS-PAGE were indistinguishable, indicating no preferential turnover for the major plasma membrane polypeptides. The redistribution of both labels to lysosomes was next quantified by cell fractionation. At equilibrium (between 6 and 25 h of cell incubation) 2-4% of cell-associated 125I label was recovered with the purified lysosomal membranes. By contrast, when 3H-labelled cells were incubated for 16 h, most of the label codistributed with lysosomes. However, only 6% of cell-associated 3H was bound to lysosomal membrane. These results indicate that in cultured rat fibroblasts, a minor fraction of plasma membrane polypeptides becomes associated with the lysosomal membrane and is constantly equilibrated by membrane traffic.     

Cellular repressor of E1A-stimulated genes is a bona fide lysosomal protein which undergoes proteolytic maturation during its biosynthesis

Cellular repressor of E1A-stimulated genes (CREG) has been reported to be a secretory glycoprotein implicated in cellular growth and differentiation. We now show that CREG is predominantly localized within intracellular compartments. Intracellular CREG was found to lack an N-terminal peptide present in the secreted form of the protein. In contrast to normal cells, CREG is largely secreted by fibroblasts missing both mannose 6-phosphate receptors. This is not observed in cells lacking only one of them. Mass spectrometric analysis of recombinant CREG revealed that the protein contains phosphorylated oligosaccharides at either of its two N-glycosylation sites. Cellular CREG was found to cosediment with lysosomal markers upon subcellular fractionation by density-gradient centrifugation. In fibroblasts expressing a CREG-GFP fusion construct, the heterologous protein was detected in compartments containing lysosomal proteins. Immunolocalization of endogenous CREG confirmed that intracellular CREG is localized in lysosomes. Proteolytic processing of intracellular CREG involves the action of lysosomal cysteine proteinases. These results establish that CREG is a lysosomal protein that undergoes proteolytic maturation in the course of its biosynthesis, carries the mannose 6-phosphate recognition marker and depends on the interaction with mannose 6-phosphate receptors for efficient delivery to lysosomes.     

Biosynthesis of lysosomal proteinases in health and disease

Proteolytic maturation of lysosomal proteinases is initiated after receptor-mediated targeting to prelysosomal compartments, while terminal processing occurs upon delivery to lysosomes. These late processing events are impaired in patients suffering from inherited lysosomal disorders, such as sialic acid storage disease and mucolipidosis II (I-cell disease). Lysosomes in the affected cells display marked changes in their physiological and morphological properties, with features reminiscent of prelysosomal compartments. This indicates that the absence of mature lysosomes interferes with the final processing steps during the biosynthesis of lysosomal proteinases. Thus, impaired proteinase maturation reflects an incompetent lysosomal apparatus and as such can be seen as a hallmark of lysosomal storage diseases.     

Isolation and characterization of chicken liver lysosomes

The distribution patterns of chicken liver lysosomal enzymes were studied in iso-osmotic gradients of Percoll. The lysosomal enzymes separated by Percoll gradients showed three different types of distribution. In contrast with rat liver lysosomes, purified chicken liver lysosomes were very stable during storage at 4 degrees C.