Basis for low affinity binding of a lysosomal cysteine protease to the cation-independent mannose 6-phosphate receptor

In cultured mouse fibroblasts, secretion of the lysosomal cysteine protease, MEP (major excreted protein) is regulated by growth factors and viral transformation. The ability of this protein to be regulated has been attributed to its intrinsic low affinity for the cation-independent mannose 6-phosphate (Man-6-P) receptor (Dong, J., Prence, E. M., and Sahagian, G. G. (1989) J. Biol. Chem. 264, 7377-7383). In this study, the basis for this low affinity was examined. Chromatography on a cation-independent Man-6-P receptor affinity matrix was used to assess relative affinities of Man-6-P-containing oligosaccharides and proteins, and the state of phosphorylation of the oligosaccharides was determined by ion exchange chromatography on QAE-Sephadex. MEP proteins synthesized by normal NIH 3T3 cells or NIH cells transformed with Kirsten sarcoma virus displayed a similar low affinity for the receptor and were found to possess oligosaccharide species with two phosphomonoester moieties. The affinity of these oligosaccharides for the receptor was the same as intact MEP protein and as great as phosphorylated oligosaccharides obtained from lysosomal proteins with the usual high affinity for the receptor. These results indicate that the polypeptide portion of MEP has no effect on binding of the protein to the receptor and that the difference in affinity of MEP and lysosomal proteins with high affinity cannot be attributed to differences in oligosaccharide structure. To investigate this further, we examined the binding characteristics of MEP made by CHO cells. In contrast to mouse MEP, CHO MEP bound to the receptor with high affinity. Partial endoglycosidase H treatment indicated that CHO MEP has two phosphorylated oligosaccharides, whereas the mouse protein has only one. Both oligosaccharides of the CHO cell protein contained two phosphomonoester moieties and displayed an affinity for the receptor that was indistinguishable from that of oligosaccharides of the mouse protein. Conversion of CHO MEP to a one-oligosaccharide species by partial endoglycosidase H treatment produced a protein that displayed low affinity binding similar to that of mouse MEP. A substantial portion of the pool of CHO cell lysosomal protein was also converted to a low affinity ligand by this treatment. Taken together, these results suggest that high affinity binding to the cation-independent receptor involves a divalent interaction with lysosomal proteins that contain two or more phosphorylated oligosaccharides, and that the low affinity of MEP results from an inability to form this multivalent interaction.     

Sequence and expression of the cDNA for MEP (major excreted protein), a transformation-regulated secreted cathepsin.

The major excreted protein (MEP) of malignantly transformed mouse fibroblasts is a secreted thiol proteinase. Sequencing of the MEP cDNA shows the coding region for the protein to be identical with the sequence for a mouse cysteine proteinase isolated from macrophages, but the MEP cDNA is polyadenylated at a different site in the 3' non-coding region. Strong homology of MEP with human cathepsin L suggests that MEP is the mouse analogue of cathepsin L. Amino acid sequencing of the N-terminus of the secreted form of MEP indicates that, during secretion, the polypeptide is cleaved between amino acids 17 and 18. We have placed the MEP cDNA in a eukaryotic expression vector and demonstrated the production of the 39 kDa polypeptide form of mouse MEP in monkey CV-1 cells.     

Modulation of the transport of a lysosomal enzyme by PDGF

The major excreted protein (MEP) of transformed mouse fibroblasts is the lysosomal protease, cathepsin L. MEP is also secreted by untransformed mouse cells in response to growth factors and tumor promoters, and is thought to play a role in cell growth and transformation. To determine the relationship between MEP synthesis and MEP secretion, we have examined these events in PDGF-treated NIH 3T3 cells. PDGF enhanced MEP synthesis and caused the diversion of MEP from the lysosomal delivery pathway to a secretory pathway. These two effects were found to be regulated independently at various times after growth factor addition. Short PDGF treatments (0.5 or 1 h) resulted in quantitative secretion of MEP although synthesis was near the control level. High levels of both synthesis and secretion occurred between 2 and 14 h of PDGF treatment. Between 18 and 30 h, the amount of secreted MEP returned to the low control level even though synthesis remained elevated. The secretion was specific for MEP; other lysosomal enzymes were not found in the media from PDGF-treated cells. PDGF-induced secretion of MEP was inhibited 84% by cycloheximide, suggesting that protein synthesis is required to elicit this effect. PDGF also caused a time-dependent increase in mannose 6-phosphate (Man-6-P) receptor-mediated endocytosis. These data support a model in which PDGF alters the distribution of Man-6-P receptors such that the Golgi concentration of receptors becomes limiting, thereby causing the selective secretion of the low affinity ligand, MEP.     

Use of a cloned multidrug resistance gene for coamplification and overproduction of major excreted protein, a transformation-regulated secreted acid protease.

Malignantly transformed mouse fibroblasts synthesize and secrete large amounts of major excreted protein (MEP), a 39,000-dalton precursor to an acid protease (cathepsin L). To evaluate the possible role of this protease in the transformed phenotype, we transfected cloned genes for mouse or human MEP into mouse NIH 3T3 cells with an expression vector for the dominant, selectable human multidrug resistance (MDR1) gene. The cotransfected MEP sequences were efficiently coamplified and transcribed during stepwise selection for multidrug resistance in colchicine. The transfected NIH 3T3 cell lines containing amplified MEP sequences synthesized as much MEP as did Kirsten sarcoma virus-transformed NIH 3T3 cells. The MEP synthesized by cells transfected with the cloned mouse and human MEP genes was also secreted. Elevated synthesis and secretion of MEP by NIH 3T3 cells did not change the nontransformed phenotype of these cells.     

Processing and lysosomal localization of a glycoprotein whose secretion is transformation stimulated

The major excreted protein (MEP) of transformed mouse fibroblasts is a mannose 6-phosphate-containing glycoprotein whose synthesis and secretion are increased in malignantly transformed 3T3 cells and whose synthesis is increased by treatment of 3T3 cells with tumor promoters or growth factors. When pulse-labeled extracts from Kirsten virus-transformed NIH 3T3 (KNIH) cells were immunoprecipitated using an antibody against secreted MEP, one cellular protein was immunoprecipitated that had the same molecular weight and tryptic peptide map as the secreted protein. Pulse-chase labeling experiments showed that 50-60% of this 39,000-mol-wt form was secreted in transformed cells. Of the 40-50% remaining, approximately 5% was processed into two lower molecular weight forms (29,000 and 20,000) which are sequestered within the cell. Similar processing of these proteins was observed in the nontransformed parent NIH 3T3 (NIH) cells. However, in NIH cells, much less of the synthesized MEP was secreted. Measurements of steady-state levels of these three forms of cellular MEP by Western blot immunolocalization revealed approximately fourfold more MEP in KNIH cells than in NIH cells as well as differences in the relative distribution of MEP forms in transformed and nontransformed cells. Subcellular fractionation of KNIH cells on a Percoll gradient demonstrated a distribution of total MEP similar to that of several lysosomal enzymes. The light lysosomal/Golgi peak from these gradients contained both the precursor 39,000-mol-wt form of MEP and the 20,000-mol-wt form, whereas the heavy lysosomal peak was enriched in the 20,000-mol-wt form. The distribution of MEP forms was found to be similar in NIH cells except that the 29,000-mol-wt form was also seen to be enriched in the heavy lysosomal peak. This biochemical localization of MEP was confirmed by immunolocalization with light and electron microscopy. These data support the hypothesis that MEP is a lysosomal protein that is secreted by transformed cells.     

Lipoprotein receptor binding, cellular uptake, and lysosomal delivery of fusions between the receptor-associated protein (RAP) and alpha-L-iduronidase or acid alpha-glucosidase

Enzyme replacement therapy for lysosomal storage disorders depends on efficient uptake of recombinant enzyme into the tissues of patients. This uptake is mediated by oligosaccharide receptors including the cation-independent mannose 6-phosphate receptor and the mannose receptor. We have sought to exploit alternative receptor systems that are independent of glycosylation but allow for efficient delivery to the lysosome. Fusions of the human lysosomal enzymes alpha-l-iduronidase or acid alpha-glucosidase with the receptor-associated protein were efficiently endocytosed by lysosomal storage disorder patient fibroblasts, rat C6 glioma cells, mouse C2C12 myoblasts, and recombinant Chinese hamster ovary cells expressing individual members of the low-density lipoprotein receptor family. Uptake of the fusions exceeded that of phosphorylated enzyme in all cases, often by an order of magnitude or greater. Uptake was specifically mediated by members of the low-density lipoprotein receptor protein family and was followed by delivery of the fusions to the lysosome. The advantages of the lipoprotein receptor system over oligosaccharide receptor systems include more efficient cellular delivery and the potential for transcytosis of ligands across tight endothelia, including the blood-brain barrier.     

Phosphorylation of Asn-linked oligosaccharides located at novel sites on the lysosomal enzyme cathepsin D.

We have examined the phosphorylation of Asn-linked oligosaccharides introduced at seven novel sites on human cathepsin D to determine whether the location of an oligosaccharide on a lysosomal enzyme affects its ability to serve as a substrate for UDP-GlcNAc:lysosomal enzyme N-acetylglucosamine-1-phosphotransferase (phosphotransferase), the enzyme that catalyzes the initial step in the biosynthesis of mannose 6-phosphate residues. The glycosylation sites were introduced into the cathepsin D cDNA by site-directed mutagenesis and were selected to be widely distributed over the surface of the molecule. When the constructs were expressed in Xenopus oocytes, the oligosaccharides at each glycosylation site were phosphorylated at levels considerably above background (19-70% phosphorylation versus < 0.4% for the secretory protein glycopepsinogen). However, oligosaccharides located closer to the essential components of the phosphotransferase recognition domain (lysine 203 and amino acids 265-292) were phosphorylated better than oligosaccharides located further away. Similar results were obtained for oligosaccharides at homologous sites on a pepsinogen/cathepsin D chimera containing only lysine 203 and residues 265-319 of cathepsin D, although the absolute levels of phosphorylation were lower. These results demonstrate that there is considerable flexibility in the placement of glycosylation sites on cathepsin D in terms of the ability of the oligosaccharides to serve as substrates for phosphotransferase, although oligosaccharides located closer to the phosphotransferase recognition determinant are preferentially phosphorylated.     

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.     

An acid protease secreted by transformed cells interferes with antigen processing

The major excreted protein of malignantly transformed mouse fibroblasts (MEP), which is the precursor to lysosomal cathepsin L, was used to study the effect of exogenous acid proteases on antigen processing. When MEP and native pigeon cytochrome c were added to Chinese hamster ovary (CHO) cells expressing transfected major histocompatability complex class II gene products, the antigen-specific T-cell hybridoma 2B4 did not respond to the antigen. MEP appears to destroy the antigen in an acid compartment of the presenting cell because: (a) MEP is only active as a protease under acid conditions; (b) mannose 6-phosphate inhibited the internalization of MEP and blocked its effect on antigen processing; (c) the destruction required the simultaneous entry of the antigen and MEP into the cells; and (d) cytochrome c fragment 66-104 which does not need to be processed stimulated 2B4 in the presence of MEP. These results support the hypothesis that antigen processing requires internalization of the antigen into an acidic compartment, and they provide a new model for the investigation of the contribution of acid proteases to the reduced immunocompetence of tumor-bearing animals.     

Biosynthesis and processing of lysosomal cathepsin L in primary cultures of rat hepatocytes

The biosynthesis and proteolytic processing of lysosomal cathepsin L was studied using in vitro translation system and in vivo pulse-chase analysis with [35S]methionine and [32P]phosphate in primary cultures of rat hepatocytes. Messenger RNA prepared from membrane-bound but not free polysomes directed the synthesis of a primary translation product of an immunoprecipitable 37.5-kDa cathepsin L in vitro. The 37.5-kDa form was converted to the 39-kDa form when translated in the presence of dog pancreas microsomes. During pulse-chase experiments with [35S]methionine in cultured rat hepatocytes, cathepsin L was first synthesized as a 39-kDa protein, presumably the proform, after a short time of labeling, and was subsequently processed into the mature forms of 30 and 25 kDa in the cell. On the other hand, considerable amounts of the proenzyme were found to be secreted into the culture medium without further proteolytic processing during the chase. The precursor and mature enzymes were N-glycosylated with high-mannose-type oligosaccharides, and the proenzyme molecule contained phosphorylated oligosaccharides. The effects of tunicamycin and chloroquine were also investigated. In the presence of tunicamycin, a 36-kDa unglycosylated polypeptide appeared in the cell and this protein was exclusively secreted from the cells without undergoing proteolytic processing. These results suggest that cathepsin L is initially synthesized on membrane-bound polysomes as a 37.5-kDa prepropeptide and that the cotranslational cleavage of the 1.5-kDa signal peptide and the core glycosylation convert the precursor to the 39-kDa proform, which is subsequently processed to the mature form during biosynthesis. Thus, the biosynthesis and secretion of lysosomal cathepsin L in rat hepatocytes seem to be analogous to those of the major excreted protein of transformed mouse fibroblasts [S. Gal, M. C. Willingham, and M. M. Gottesman (1985) J. Cell Biol. 100, 535-544] and the mouse cysteine proteinase of activated macrophages [D.A. Portnoy, A. H. Erickson, J. Kochan, J. V. Ravetch, and J. C. Unkeless (1986) J. Biol. Chem. 261, 14697-14703].     

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.     

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.     

Phosphorylation, glycosylation, and proteolytic activity of the 52-kD estrogen-induced protein secreted by MCF7 cells

We have studied the posttranslational modifications of the 52-kD protein, an estrogen-regulated autocrine mitogen secreted by several human breast cancer cells in culture (Westley, B., and H. Rochefort, 1980, Cell, 20:353-362). The secreted 52-kD protein was found to be phosphorylated mostly (94%) on high-mannose N-linked oligosaccharide chains, and mannose-6-phosphate signals were identified. The phosphate signal was totally removed by alkaline phosphatase hydrolysis. The secreted 52-kD protein was partly taken up by MCF7 cells via mannose-6-phosphate receptors and processed into 48- and 34-kD protein moieties as with lysosomal hydrolases. By electron microscopy, immunoperoxidase staining revealed most of the reactive proteins in lysosomes. After complete purification by immunoaffinity chromatography, we identified both the secreted 52-kD protein and its processed cellular forms as aspartic and acidic proteinases specifically inhibited by pepstatin. The 52-kD protease is secreted in breast cancer cells under its inactive proenzyme form, which can be autoactivated at acidic pH with a slight decrease of molecular mass. The enzyme of breast cancer cells, when compared with cathepsin D(s) of normal tissue, was found to be similar in molecular weight, enzymatic activities (inhibitors, substrates, specific activities), and immunoreactivity. However, the 52-kD protein and its cellular processed forms of breast cancer cells were totally sensitive to endo-beta-N-acetylglucosaminidase H (Endo H), whereas several cellular cathepsin D(s) of normal tissue were partially Endo H-resistant. This difference, in addition to others concerning tissue distribution, mitogenic activity and hormonal regulation, strongly suggests that the 52-kD cathepsin D-like enzyme of breast cancer cells is different from previously described cathepsin D(s). The 52-kD estrogen-induced lysosomal proteinase may have important functions in facilitating the mammary cancer cells to proliferate, migrate, and metastasize.     

An Active 32-kDa Cathepsin L Is Secreted Directly from HT 1080 Fibrosarcoma Cells and Not via Lysosomal Exocytosis

Cathepsin L [EC 3.4.22.15] is secreted via lysosomal exocytosis by several types of cancer cells, including prostate and breast cancer cells. We previously reported that human cultured fibrosarcoma (HT 1080) cells secrete cathepsin L into the medium; this secreted cathepsin is 10-times more active than intracellular cathepsin. This increased activity was attributed to the presence of a 32-kDa cathepsin L in the medium. The aim of this study was to examine how this active 32-kDa cathepsin L is secreted into the medium. To this end, we compared the secreted active 32-kDa cathepsin L with lysosomal cathepsin L by using a novel gelatin zymography technique that employs leupeptin. We also examined the glycosylation and phosphorylation status of the proteins by using the enzymes endoglycosidase H [EC 3.2.1.96] and alkaline phosphatase [EC 3.1.3.1]. Strong active bands corresponding to the 32-kDa and 34-kDa cathepsin L forms were detected in the medium and lysosomes, respectively. The cell extract exhibited strong active bands for both forms. Moreover, both forms were adsorbed onto a concanavalin A-agarose column. The core protein domain of both forms had the same molecular mass of 30 kDa. The 32-kDa cathepsin L was phosphorylated, while the 34-kDa lysosomal form was dephosphorylated, perhaps because of the lysosomal marker enzyme, acid phosphatase. These results suggest that the active 32-kDa form does not enter the lysosomes. In conclusion, our results indicate that the active 32-kDa cathepsin L is secreted directly from the HT 1080 cells and not via lysosomal exocytosis.     

Purification, cDNA cloning, and expression of a new human blood plasma glutamate carboxypeptidase homologous to N-acetyl-aspartyl-alpha-glutamate carboxypeptidase/prostate-specific membrane antigen

We describe the identification, cDNA cloning, and biochemical characterization of a new human blood plasma glutamate carboxypeptidase (PGCP). PGCP was co-purified from human placenta with lysosomal carboxypeptidase, cathepsin A, lysosomal endopeptidase, cathepsin D, and a gamma-interferon-inducible protein, IP-30, using an affinity chromatography on a Phe-Leu-agarose column. A PGCP cDNA was obtained as an expressed sequence tag clone and completed at 5'-end by rapid amplification of cDNA ends polymerase chain reaction. The cDNA contained a 1623-base pair open reading frame predicting a 541-amino acid protein, with five putative Asn glycosylation sites and a 21-residue signal peptide. PGCP showed significant amino acid sequence homology to several cocatalytic metallopeptidases including a glutamate carboxypeptidase II also known as N-acetyl-aspartyl-alpha-glutamate carboxypeptidase or as prostate-specific membrane antigen and expressed glutamate carboxypeptidase activity. Expression of the PGCP cDNA in COS-1 cells, followed by Western blotting and metabolic labeling showed that PGCP is synthesized as a 62-kDa precursor, which is processed to a 56-kDa mature form containing two Asn-linked oligosaccharide chains. The mature form of PGCP was secreted into the culture medium, which is consistent with its intracellular localization in secretion granules. In humans, PGCP is found principally in blood plasma, suggesting a potential role in the metabolism of secreted peptides.     

Mechanism for selective secretion of a lysosomal protease by transformed mouse fibroblasts

Studies in recent years have indicated that secretion of certain lysosomal hydrolases can be enhanced under various conditions. One such protein, the major excreted protein (MEP) of Kirsten virus-transformed NIH 3T3 (KNIH) fibroblasts, is a lysosomal cysteine protease whose synthesis and secretion are affected by viral transformation and growth factors. We have been studying the synthesis and transport of MEP in order to understand better the mechanisms responsible for regulation of lysosomal enzyme secretion. Synthesis of MEP in KNIH cells was found to be 25-fold greater than that in untransformed NIH cells, and 94% of the MEP made was secreted. This was in contrast to NIH cells which secreted only 11% of the newly synthesized MEP. The high level of secretion by the transformed cells was relatively specific in that most other lysosomal enzymes were retained. MEP isolated from both NIH and KNIH cells exhibited a low intrinsic affinity for the mannose-6-phosphate receptor which was at least 10-fold lower than that of other lysosomal enzymes. On the basis of these results, we suggest that both the high level of MEP synthesis and the intrinsic low affinity of MEP for the receptor are responsible for the specific increase in MEP secretion by transformed cells.     

Affinity labelling of enzymes with triazine dyes. Isolation of a peptide in the catalytic domain of horse-liver alcohol dehydrogenase using Procion blue MX-R as a structural probe

The incorporation of [3H]leucine and [32P]phosphate into three lysosomal enzymes, cathepsin D, beta-hexosaminidase and arylsulfatase A by fibroblasts from six patients affected with mucolipidosis III was determined. In the mutant cells the incorporation of 32P in the enzymes was reduced by 70-97% as compared to controls. The residual phosphorylation of lysosomal enzymes is definitely higher than in fibroblasts from patients with mucolipidosis II, where apparently non-phosphorylated enzymes are formed. In mucolipidosis III the major part of the newly formed enzymes accumulated extracellularly and the cellular enzymes were recovered mainly in their processed forms. In mucolipidosis III arylsulfatase A and the processed forms of cathepsin D exhibited a heterogeneity that was not observed in controls. beta-Hexosaminidase and cathepsin D secreted by mucolipidosis III fibroblasts contained only a small amount of phosphorylated oligosaccharides with either one or two phosphate groups per oligosaccharide. As in controls the major fraction of phosphate was present as acid-labile phosphodiester resistant to alkaline phosphatase. The residual phosphorylation of lysosomal enzymes may be related to the partial intracellular retention and processing of these enzymes in fibroblasts from patients with mucolipidosis III.     

Characterization and cloning of lgp110, a lysosomal membrane glycoprotein from mouse and rat cells

lgp110 is a heavily glycosylated intrinsic protein of lysosomal membranes. Initially defined by monoclonal antibodies against mouse liver lysosomes, it consists of a 45-kilodalton core polypeptide with O-linked and 17 asparagine-linked oligosaccharide side chains in mouse cells. Sialic acid residues make the mature protein extremely acidic, with an isoelectric point of between 2 and 4 in both normal tissues and most cultured cell lines. Partial sequencing of mouse lgp110 allowed oligonucleotide probes to be constructed for the screening of several mouse cDNA libraries. A partial cDNA clone for mouse lgp110 was found and used for additional library screening, generating a cDNA clone covering all of the coding sequence of mature rat lgp110 as well as genomic clones covering most of the mouse gene. These new clones bring to seven the number of lysosomal membrane proteins whose amino acid sequences can be deduced, and two distinct but highly similar groups (designated lgp-A and lgp-B) can now be defined. Sequence comparisons suggest that differences within each group reflect species variations of the same protein and that lgp-A and lgp-B probably diverged from a common ancestor prior to the evolup4f1ary divergence of birds and mammals. Individual cells and individual lysosomes possess both lgp-A and lgp-B, suggesting that these two proteins have different functions. Mouse lgp110 is encoded by at least seven exons; intron positions suggest that the two homologous ectodomains of each lgp arose through gene duplication.