Mannose 6-phosphate-independent targeting of cathepsin D to lysosomes in HepG2 cells.

We have studied the role of N-linked oligosaccharides and proteolytic processing on the targeting of cathepsin D to the lysosomes in the human hepatoma cell line HepG2. In the presence of tunicamycin cathepsin D was synthesized as an unglycosylated 43-kDa proenzyme which was proteolytically processed via a 39-kDa intermediate to a 28-kDa mature form. Only a small portion was secreted into the culture medium. During intracellular transport the 43-kDa procathepsin D transiently became membrane-associated independently of binding to the mannose 6-phosphate receptor. Subcellular fractionation showed that unglycosylated cathepsin D was efficiently targeted to the lysosomes via intermediate compartments similar to the enzyme in control cells. The results show that in HepG2 cells processing and transport of cathepsin D to the lysosomes is independent of mannose 6-phosphate residues. Inhibition of the proteolytic processing of 53-kDa procathepsin D by protease inhibitors caused this form to accumulate intracellularly. Subcellular fractionation revealed that the procathepsin D was transported to lysosomes, thereby losing its membrane association. Procathepsin D taken up by the mannose 6-phosphate receptor also transiently became membrane-associated, probably in the same compartment. We conclude that the mannose 6-phosphate-independent membrane-association is a transient and compartment-specific event in the transport of procathepsin D.     

Protein determinants impair recognition of procathepsin L phosphorylated oligosaccharides by the cation-independent mannose 6-phosphate receptor

Cathepsin L, a lysosomal cysteine protease, is the major excreted protein of transformed mouse NIH 3T3 cells. Previous studies have shown that asparagine-linked oligosaccharides associated with the secreted hydrolase contain mannose 6-phosphate (Man 6-P), the recognition marker for transport of newly synthesized acid hydrolases to lysosomes. To investigate the mechanism by which cathepsin L evades targeting to lysosomes, we determined the structure of the enzyme's oligosaccharides and analyzed its interaction with the cation-independent mannose 6-phosphate (Man 6-PCl) receptor. Oligosaccharides associated with procathepsin L isolated from the medium of [3H]mannose-labeled J774 cells were remarkably homogeneous; all of the radiolabeled structures were high mannose-type units that contained two phosphomonoesters and 7 mannose residues. Both the alpha 1,3- and alpha 1,6-branches of the oligosaccharides were phosphorylated. Oligosaccharides released by endoglycosidase H from [3H]mannose-labeled procathepsin L bound to a Man 6-PCl receptor affinity column. Despite the high affinity binding of these oligosaccharides, the intact glycoprotein was not a good ligand for the Man 6-PCl receptor. Procathepsin L was internalized poorly by Man 6-P receptor-mediated endocytosis and the purified acid protease interacted weakly with a Man 6-PCl affinity column. In contrast, pro-beta-glucuronidase (another acid hydrolase produced by J774 cells) was an excellent ligand for the Man 6-PCl receptor as judged by the endocytosis and affinity chromatographic assays. Phosphorylated oligosaccharides associated with the J774-secreted pro-beta-glucuronidase were heterogeneous and contained both mono- and diphosphorylated species. Tryptic glycopeptides generated from [3H]mannose-labeled procathepsin L, unlike the intact protein, were excellent ligands for the Man 6-PCl receptor. The results indicate that oligosaccharides associated with procathepsin L are processed uniformly to diphosphorylated species that bind with high affinity to the Man 6-PCl receptor. Protein determinants inherent within the intact acid hydrolase, however, inhibit the high affinity binding of these oligosaccharides and, as a result, impair the interaction of procathepsin L with the receptor.     

Identification of subcellular compartments involved in biosynthetic processing of cathepsin D.

We have assigned the biosynthetic processing steps of cathepsin D to intracellular compartments which are involved in its transport to lysosomes in HepG2 cells. Cathepsin D was synthesized as a 51-kDa proenzyme. After formation of 51-55-kDa intermediates due to processing of N-linked oligosaccharides, procathepsin D was proteolytically processed to an intermediate 44-kDa and the mature 31-kDa enzyme. The intersection of the biosynthetic pathway of cathepsin D with the endocytic pathway was labeled with horseradish peroxidase and monitored biochemically by 3,3'-diaminobenzidine cytochemistry. Horseradish peroxidase was used either as a fluid-phase marker to label the entire endocytic pathway or conjugated to transferrin (Tf) to label endosomes only. Directly after biosynthesis cathepsin D was accessible neither to horseradish peroxidase nor Tf-horseradish peroxidase. Newly synthesized 51-55-kDa species of cathepsin D present in the trans-Golgi reticulum were accessible to both horseradish peroxidase and Tf-horseradish peroxidase. The accessibility of trans-Golgi reticulum to both endocytosed horseradish peroxidase and Tf-horseradish peroxidase was monitored by colocalization with a secretory protein, alpha 1anti-trypsin. The proteolytic processing of 51-55-kDa to 44-kDa cathepsin D occurred in compartments which were fully accessible to fluid-phase horseradish peroxidase. Tf-horseradish peroxidase had access to only 20% of 44-kDa cathepsin D while it had no access to 31-kDa cathepsin D. In contrast, the 31-kDa species was completely accessible to fluid-phase horseradish peroxidase. We conclude that proteolytic processing of 51-55-kDa to 44-kDa cathepsin D occurs in endosomes, whereas the processing of 44-31-kDa cathepsin D takes place in lysosomes.     

Structural studies of rat cathepsin E: amino-terminal structure and carbohydrate units of mature enzyme

The amino-terminal structure of rat gastric cathepsin E was identified and compared with the corresponding regions of human procathepsin E and other aspartic proteinases. The alignment revealed that cathepsin E has the most extended amino-terminal structure in aspartic proteinases, thus suggesting that the activation peptide (propeptide) of the human enzyme is 39-residues long. Analysis of oligosaccharide units suggested that rat cathepsin E possesses one N-linked carbohydrate unit, probably of the high mannose type. No evidence was obtained for the presence of O-linked sugars in rat cathepsin E.     

The role of the cathepsin D propeptide in sorting to the lysosome.

The propeptides of lysosomal enzymes have been implicated in membrane association and mannose 6-phosphate-independent sorting to the lysosome (Rijnboutt, S., Aerts, H., Geuze, H. J., Tager, J. M., and Strous, G. J. (1991) J. Biol. Chem. 266, 4862-4868; McIntyre, G. F., and Erickson, A. H. (1991) J. Biol. Chem. 266, 15438-15445). In this report, the function of the propeptide of procathepsin D in sorting to the lysosome was directly assessed using a cathepsin D deletion mutant lacking the propeptide, and using a chimeric cDNA encoding the cathepsin D propeptide fused to the secretory protein alpha-lactalbumin. Proteins encoded by these cDNAs were expressed in mouse Ltk- cells and in human hepatoma Hep G2 cells, and then immunoprecipitated and analyzed by SDS-polyacrylamide gel electrophoresis. The deletion mutant was glycosylated but was rapidly degraded in a chloroquine-independent fashion and did not assume an active conformation. Thus the propeptide appeared to be necessary for correct folding. The chimeric protein was glycosylated and secreted. The coincidence of complex oligosaccharide modification and secretion of the chimeric protein suggested that it was slowly released from the endoplasmic reticulum and rapidly passed through the cell to the extracellular compartment. This was confirmed by immunofluorescent localization of the proteins. The data indicated that the propeptide appeared to be necessary for folding of cathepsin D but, unlike the yeast vacuolar propeptides, was not sufficient to direct a secretory protein to the lysosome in fibroblasts or in epithelial cells.     

Human and hamster procathepsin D, although equally tagged with mannose-6-phosphate, are differentially targeted to lysosomes in transfected BHK cells

BHK cells transfected with human cathepsin D (CD) cDNA normally segregate the autologous hamster cathepsin D while secreting a large proportion of the human proenzyme. In the present work, we have utilized these transfectants to examine to what extent the mannose-6-phosphate-dependent pathway for lysosomal enzyme segregation contributes to the differential sorting of human and hamster CD. We report that, in recipient control BHK cells, the rate of mannose-6-phosphate-dependent endocytosis of human procathepsin D secreted by transfected BHK cells is lower than that of hamster procathepsin D and much lower than that of human arylsulphatase A. The missorted human enzyme bears phosphorylated oligosaccharides and most of its phosphate residues are “uncovered”, like the autologous enzyme. Thus, despite both the Golgi-associated modifications of oligosaccharides, i.e. the phosphorylation of mannose and the uncovering of mannose-6-phosphate residues, which proceed on human and hamster procathepsin D with comparable efficiency, only the latter is accurately packaged into lysosomes. Ammonium chloride partially affects the lysosomal targeting of cathepsin D in control BHK cells, whereas in transfected cells, this drug strongly inhibits the maturation of human procathepsin D and slightly enhances its secretion. These data indicate that: (1) over-expression of a lysosomal protein does not saturate the Golgi-associated reactions leading to the synthesis of mannose-6-phosphate; (2) a portion of cathepsin D is targeted independently of mannose-6-phosphate receptors in the transfected BHK cells; and (3) whichever mechanism for lysosomal delivery of autologous procathepsin D is involved, this is not saturated by the high rate of expression of human cathepsin D.     

Cathepsin L1, the major protease involved in liver fluke (Fasciola hepatica) virulence: propetide cleavage sites and autoactivation of the zymogen secreted from gastrodermal cells

The secretion and activation of the major cathepsin L1 cysteine protease involved in the virulence of the helminth pathogen Fasciola hepatica was investigated. Only the fully processed and active mature enzyme can be detected in medium in which adult F. hepatica are cultured. However, immunocytochemical studies revealed that the inactive procathepsin L1 is packaged in secretory vesicles of epithelial cells that line the parasite gut. These observations suggest that processing and activation of procathepsin L1 occurs following secretion from these cells into the acidic gut lumen. Expression of the 37-kDa procathepsin L1 in Pichia pastoris showed that an intermolecular processing event within a conserved GXNXFXD motif in the propeptide generates an active 30-kDa intermediate form. Further activation of the enzyme was initiated by decreasing the pH to 5.0 and involved the progressive processing of the 37 and 30-kDa forms to other intermediates and finally to a fully mature 24.5 kDa cathepsin L with an additional 1 or 2 amino acids. An active site mutant procathepsin L, constructed by replacing the Cys(26) with Gly(26), failed to autoprocess. However, [Gly(26)]procathepsin L was processed by exogenous wild-type cathepsin L to a mature enzyme plus 10 amino acids attached to the N terminus. This exogenous processing occurred without the formation of a 30-kDa intermediate form. The results indicate that activation of procathepsin L1 by removal of the propeptide can occur by different pathways, and that this takes place within the parasite gut where the protease functions in food digestion and from where it is liberated as an active enzyme for additional extracorporeal roles.     

An alternate targeting pathway for procathepsin L in mouse fibroblasts

In transformed mouse fibroblasts, a significant proportion of the lysosomal cysteine protease cathepsin L remains in cells as an inactive precursor which associates with membranes by a mannose phosphate-independent interaction. When microsomes prepared from these cells were resolved on sucrose gradients, this procathepsin L was localized in dense vesicles distinct from those enriched for growth hormone, which is secreted constitutively when expressed in fibroblasts. Ultrastructural studies using antibodies directed against the propeptide to avoid detection of the mature enzyme in lysosomes revealed that the proenzyme was concentrated in dense cores within small vesicles and multivesicular endosomes which labeled with antibodies specific for CD63. Consistent with the resemblance of these cores to those of regulated secretory granules, secretion of procathepsin L from fibroblasts was modestly stimulated by phorbol, 12-myristate, 13-acetate. When protein synthesis was blocked with cycloheximide and lysosomal proteolysis inhibited with leupeptin, procathepsin L was found to gradually convert to the active single-chain protease. The data suggest that when synthesis levels are high, a portion of the procathepsin L is packaged in dense cores within multivesicular endosomes localized near the plasma membrane. Gradual activation of this proenzyme achieves targeting of the proenzyme to lysosomes by a mannose phosphate receptor-independent pathway.     

Procathepsin L self-association as a mechanism for selective secretion

The lysosomal cysteine pro-protease procathepsin L was enriched in dense vesicles detectable when microsomes prepared from wild-type or transformed mouse fibroblasts were resolved on sucrose gradients. These dense vesicles did not comigrate with proteins characteristic of the endoplasmic reticulum, Golgi, endosomes or lysosomes. When gradient fraction vesicles were lysed at acidic pH in the presence of excess mannose 6-phosphate to prevent binding to mannose phosphate receptors, the majority of the procathepsin L was associated with the membrane, not the soluble, fraction. Immunogold labeling of procathepsin L in thin sections of cells or gradient fractions, using antibodies directed against the propeptide to avoid detection of the mature enzyme in dense lysosomes, revealed that the proenzyme was concentrated in dense cores localized in small vesicles near the plasma membrane and in multivesicular bodies. Consistent with the density of the gradient fraction and the electron density of the cores, yeast two-hybrid assays indicated the proenzyme could bind itself but could not interact with the aspartic proprotease procathepsin D. The data suggest that in mouse fibroblasts procathepsin L may self-associate into aggregates, initiating the formation of dense vesicles that could mediate the selective secretion of procathepsin L independent of mannose phosphate receptors.     

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.     

A new Saccharomyces cerevisiae mnn mutant N-linked oligosaccharide structure

We find that the N-linked Man8GlcNAc2- core oligosaccharide of Saccharomyces cerevisiae mnn mutant mannoproteins is enlarged by the addition of the outer chain to the alpha 1----3-linked mannose in the side chain that is attached to the beta 1----4-linked mannose rather than by addition to the terminal alpha 1----6-linked mannose. This conclusion is derived from structural studies on a phosphorylated oligosaccharide fraction and from mass spectral fragment analysis of neutral core oligosaccharides.     

Activity and deletion analysis of recombinant human cathepsin L expressed in Escherichia coli

A cDNA clone encoding the human cysteine protease cathepsin L was expressed at high levels in Escherichia coli in a T7 expression system. The insoluble recombinant enzyme was solubilized in urea and refolded at alkaline pH. 38-kDa procathepsin L was purified by gel filtration at pH 8.0, and a 29-kDa form of the enzyme was purified by gel filtration after autoprocessing of the proenzyme at pH 6.5. The kinetic properties of the 29-kDa species of recombinant cathepsin L were similar to those published for the human liver enzyme (Mason, R. W., Green, G. D. J., and Barrett, A.J. (1985) Biochem. J. 226, 233-241), using benzyloxycarbonyl-Phe-Arg-7-(4-methyl)coumarylamide as substrate. However, the stability of the recombinant enzyme, and its pH optimum for this substrate was shifted to a higher pH. Structure-function studies of cathepsin L were performed by constructing mutations in either the propeptide portion or the carboxyl-terminal light chain portion of the protein. These constructions were expressed in the E. coli system, and enzymatic activities were assayed following solubilization, renaturation, and gel filtration chromatography of the mutated proteins. Deletions of increasing size in the propeptide resulted in large proportional losses of activity, indicating that the propeptide is essential for proper enzyme folding and/or processing in this renaturation system. Deletion of part of the light chain containing a disulfide-forming cysteine residue or a single amino acid substitution of alanine for this cysteine residue resulted in almost complete loss of activity. These data suggest that the disulfide bond joining the heavy and light chains of cathepsin L is essential for enzymatic activity.     

Role of N-linked oligosaccharide flexibility in mannose phosphorylation of lysosomal enzyme cathepsin L

Mannose phosphorylation of N-linked oligosaccharides by UDP-GlcNAc:lysosomal enzyme N-acetylglucosamine-1-phosphotransferase is a key step in the targeting of lysosomal enzymes in mammalian cells and tissues. The selectivity of this process is determined by lysine-based phosphorylation signals shared by lysosomal enzymes of diverse structure and function. By introducing new glycosylation sites at several locations on the surface of mouse procathepsin L and modeling oligosaccharide conformations for sites that are phosphorylated, it was shown that the inherent flexibility of N-linked oligosaccharides can account for the specificity of the transferase for oligosaccharides at different locations on the protein. By using this approach, the physical relationship between the lysine-based signal and the site of phosphorylation of mannose residues was determined. The analysis also revealed the existence of additional independent lysine-based phosphorylation signals on procathepsin L, which account for the low level of phosphorylation observed when the primary Lys-54/Lys-99 signal is ablated. Mutagenesis of residues that surround Lys-54 and Lys-99 and demonstration of mannose phosphorylation of a glycosylated derivative of green fluorescent protein provide strong evidence that the cathepsin L phosphorylation signal is a simple structure composed of as few as two well placed lysine residues.     

Biosynthesis of a lysosomal enzyme. Partial structure of two transient and functionally distinct NH2-terminal sequences in cathepsin D

Various biosynthetic forms of porcine spleen cathepsin D (Erickson, A. H. and Blobel, G. (1979) J. Biol. Chem. 254, 11771-11774), isolated by immunoprecipitation of in vivo- and in vitro-synthesized products, have been characterized by partial NH2-terminal sequence analysis. Two short lived and functionally distinct NH2-terminal sequence extensions, a "pre" sequence and a "pro" sequence, have been detected. Both sequence extensions are present in preprocathepsin D which is the primary translation product immunoprecipitated after translation of porcine spleen mRNA in a wheat germ cell-free system. Preprocathepsin D is not glycosylated and has an approximate Mr = 43,000. Its 20-residue pre sequence resembles the signal sequences of presecretory proteins in abundance of Leu residues (7 out of 20 residues). Addition of dog pancreatic microsomal vesicles to the translation system resulted in the cleavage of the pre sequence and yielded segregated and glycosylated procathepsin D (Mr = 46,000) that was indistinguishable from its in vivo-synthesized counterpart detected after pulse-labeling of cultured porcine kidney cells. Some of this in vivo-synthesized procathepsin D was secreted and persisted as such in the culture medium. The remainder was converted within a period of 15 min to 2 h to single chain cathepsin D (Mr = 44,000) by removal of a pro sequence which was estimated to be 44 residues. Its partial sequence showed considerable sequence homology to the 44-residue activation peptide of pepsinogen. It is possible, therefore, that the prosequence of procathepsin D serves as an activation peptide that keeps the enzyme inactive during intracellular transport to the lysosome. The enzymatically active single chain form of cathepsin D undergoes further cleavage into a light and a heavy chain (Mr = 15,000 and 30,000, respectively) over a period of 2-24 h after synthesis. The oligosaccharide moieties of procathepsin D and of the single chain and heavy chain forms of cathepsin D are cleaved by endoglycosidase H. Treatment of cells with tunicamycin arrests the biosynthetic pathway of cathepsin D at procathepsin D. The nonglycosylated procathepsin D is not proteolytically processed and its secretion is greatly inhibited.     

Glycosidase inhibitors: inhibitors of N-linked oligosaccharide processing.

The biosynthesis of the various types of N-linked oligosaccharide structures involves two series of reactions: 1) the formation of the lipid-linked saccharide precursor, Glc3Man9(GlcNAc)2-pyrophosphoryl-dolichol, by the stepwise addition of GlcNAc, mannose and glucose to dolichyl-P, and 2) the removal of glucose and mannose by membrane-bound glycosidases and the addition of GlcNAc, galactose, sialic acid, and fucose by Golgi-localized glycosyltransferases to produce different complex oligosaccharide structures. For most glycoproteins, the precise role of the carbohydrate is still not known, but specific N-linked oligosaccharide structures are key players in targeting of lysosomal hydrolases to the lysosomes, in the clearance of asialoglycoproteins from the serum, and in some cases of cell:cell adhesion. Furthermore, many glycoproteins have more than one N-linked oligosaccharide, and these oligosaccharides on the same protein frequently have different structures. Thus, one oligosaccharide may be of the high-mannose type whereas another may be a complex chain. One approach to determining the role of specific structures in glycoprotein function is to use inhibitors that block the modification reactions at different steps, causing the cell to produce glycoproteins with altered carbohydrate structures. The function of these glycoproteins can then be assessed. A number of alkaloid-like compounds have been identified that are specific inhibitors of the glucosidases and mannosidases involved in glycoprotein processing. These compounds cause the formation of glycoproteins with glucose-containing high mannose structures, or various high-mannose or hybrid chains, depending on the site of inhibition. These inhibitors have also been useful for studying the processing pathway and for comparing processing enzymes from different organisms.     

Structural studies on the carbohydrate moieties of rat liver cathepsins B and H

Cathepsins B and H from rat liver contain one asparagine-linked sugar chain in each molecule. The sugar chains were liberated from the polypeptide portions by hydrazinolysis followed by N-acetylation and NaB3H4 reduction. Paper electrophoresis of the radioactive oligosaccharide fractions revealed that they were mixtures of neutral oligosaccharides only. After fractionation by gel filtration the structure of each oligosaccharide was studied by sequential exoglycosidase digestion in combination with methylation analysis. The sugar chain of cathepsin H was a high mannose type oligosaccharide which varied in size from 5 to 9 mannose residues; on the other hand the major oligosaccharide of cathepsin B was a tetrasaccharide whose structure was Manalpha 1----6Manbeta 1----4GlcNAcbeta 1----4GlcNAc.     

Glycosaminoglycans facilitate procathepsin B activation through disruption of propeptide-mature enzyme interactions

Lysosomal cysteine cathepsin B participates in numerous diverse cellular processes. In acquiring its activity, the proregion, which blocks the substrate-binding site in the proenzyme, needs to be cleaved off. Here we demonstrate that polyanionic polysaccharides, glycosaminoglycans (GAGs), can accelerate the autocatalytic removal of the propeptide and subsequent activation of cathepsin B. We show that naturally occurring GAGs such as chondroitin sulfates and heparin, as well as the synthetic analog dextran sulfate, accelerate the processing in a concentration-dependent manner. Heparin oligosaccharides down to the size of tetrasaccharides were efficient in accelerating the procathepsin B processing, whereas disaccharides were without effect. Further, the ability of the GAGs to accelerate procathepsin B processing was sensitive to increasing NaCl concentrations, indicating that electrostatic interaction between the GAGs and procathepsin B are operative in the accelerating effect. Also the processing of the catalytic procathepsin B mutant by wild type cathepsin B was enhanced in the presence of GAGs, suggesting that GAGs induce a conformational change in procathepsin B, converting it into a better substrate. Site-directed mutagenesis showed that His(28), Lys(39), and Arg(40), located within the procathepsin B propeptide, have significant roles in the acceleration of procathepsin B activation induced by short GAGs. Because procathepsin B and GAGs often co-localize in vivo, we propose that GAGs may play a physiological role in the activation of procathepsin B.     

Folding competence of N-terminally truncated forms of human procathepsin B

Besides acting as an inhibitor, the propeptide of human cathepsin B exerts an important auxiliary function as a chaperone in promoting correct protein folding. To explore the ability of N-terminally truncated forms of procathepsin B to fold into enzymatically active proteins, we produced procathepsin B variants progressively lacking N-terminal structural elements in baculovirus-infected insect cells. N-terminal truncation of the propeptide by up to 22 amino acids did not impair the production of activable procathepsin B. Secreted forms lacking the first 20, 21, or 22 amino acids spontaneously generated mature cathepsin B through autocatalytic processing, demonstrating that the first alpha-helix (Asp11-Arg20) is necessary for efficient inhibition of the enzyme by its propeptide. In contrast, proenzymes lacking the N-terminal part including the first beta-sheet (Trp24-Ala26) of the propeptide or containing an amino acid mutation directly preceding this beta-sheet were no longer properly folded. This shows that interactions between Trp24 of the propeptide and Tyr183, Tyr188, and Phe180 of the mature enzyme are important for stabilization and essential for procathepsin B folding. Thus, proenzyme forms missing more than the N-terminal 22 amino acids of the propeptide (notably truncated cathepsin B produced by the mRNA splice variant lacking exons 2 and 3, resulting in a propeptide shortened by 34 amino acids) are devoid of proteolytic activity because they cannot fold correctly. Thus, any pathophysiological involvement of truncated cathepsin B must be ascribed to properties other than proteolysis.     

Human lysosomal protective protein. Glycosylation, intracellular transport, and association with beta-galactosidase in the endoplasmic reticulum.

In lysosomes beta-galactosidase and neuraminidase acquire a stable and active conformation through their association with the protective protein. The latter is homologous to serine carboxypeptidases and has cathepsin A-like activity which is distinct from its protective function towards the two glycosidases. To define signals in the human protective protein important for its intracellular transport, and to determine the site of its association with beta-galactosidase, we have generated a set of mutated protective protein cDNAs carrying targeted base substitutions. These mutants were either singly transfected into COS-1 cells or cotransfected together with wild type human beta-galactosidase. We show that all point mutations cause either a complete or partial retention of the protective protein precursor in the endoplasmic reticulum. This abnormal accumulation leads to degradation of the mutant proteins probably in this compartment. Only the oligosaccharide chain on the 32-kDa subunit acquires the mannose 6-phosphate recognition marker, the one on the 20-kDa subunit seems to be merely essential for the stability of the mature protein. In cotransfection experiments, wild type beta-galactosidase and protective protein appear to assemble already as precursors, soon after synthesis, in the endoplasmic reticulum. Mutated protective protein precursors that are retained in the endoplasmic reticulum or pre-Golgi complex interact with and withhold normal beta-galactosidase molecules in the same compartments, thereby preventing their normal routing.     

Oligosaccharides on cathepsin D from porcine spleen

Cathepsin D from porcine spleen contained mannose (3.3%), glucosamine (1.4%), and mannose 6-phosphate (0.08%). Essentially all of the oligosaccharides of cathepsin D could be released by endo-β-N-acetylglucosaminidase H, pointing to oligomajmoside types of structures. Three neutral oligosaccharide fractions, containing 5, 6, and 7 mannose residues, respectively, were isolated by gel permeation chromatography on Bio-Gel P-2. Studies using exoglycosidase digestions and 500-MHz ¹H NMR spectroscopy revealed that their structures are [Manα1 → 2]_{0 or 1}Manα1 → 6[Manα1 → 3]Manα1 → 6[(Manα1 → 2)_{0 or 1}Manα1 → 3]Manβ1 → 4GlcNAcβ1 → 4 GlcNAc. These structures are identical to what have recently been proposed by Takahashi et al. for the major oligosaccharide units of cathepsin D from the same source (T. Takahashi P.G. Schimidt, and J. Tang (1983)J. Biol. Chem.258, 2819–2930), except for the occurrence of two isomeric oligosaccharides containing six mannoses. Only a part (3.4%) of the oligosaccharides were acidic, containing phosphates in monoester linkage. The phosphorylated oligosaccharides also consisted of oligomannoside-type chains which were analogous to, but more heterogeneous in size than the neutral oligosaccharides. Cathepsin D was bound to a mannose- and N-acetylglucosamine-specific lectin (mannan-binding protein) isolated from rabbit liver with the K_i value of 5.4 × 10^?6m.