The mannose-6-phosphate receptor for lysosomal enzymes is concentrated in cis Golgi cisternae

Mannose-6-phosphate (Man-6-P) receptors for lysosomal enzymes were localized by immunocytochemistry in several secretory and adsorptive cell types using monospecific antireceptor antibodies. By immunofluorescence, the receptors were found in the Golgi region of polarized cells. When localized by immunoperoxidase at the electron microscope level, they were detected in Golgi cisternae, coated vesicles, endosomes, and lysosomes of all cell types examined (hepatocytes, exocrine pancreatic and epididymal epithelia). Within the Golgi complex, immunoreactive receptors were restricted in their distribution to one or two cisternae on the cis side of the Golgi stacks. They were not detected in trans Golgi or GERL cisternae. Based on their high concentration of Man-6-P receptors, we propose that the cis Golgi cisternae represent the site where the secretory and lysosomal pathways diverge: lysosomal enzymes bearing the Man-6-P recognition marker bind to Man-6-P receptors in this location and are delivered to endosomes and lysosomes via coated vesicles.     

Endocytosis of mannose-6-phosphate binding sites by mouse T-lymphoma cells

The endocytosis and intracellular transport of mannose-6-phosphate conjugated to bovine serum albumin (Man-6-P:BSA) by mouse T-lymphoma cells were investigated in detail using several methods of analysis, both morphological and biochemical. Man-6-P:BSA was labeled with fluorescein or 125I and used to locate both surface and intracellular Man-6-P binding sites by light or electron microscopy, respectively. Incubation of cells with either fluorescent- or 125I-labeled Man-6-P:BSA at 0 degree C revealed a uniform distribution of the Man-6-P binding sites over the cell surface. Competition experiments indicate that the Man-6-P:BSA binding sites on the cell surface are the same receptors that can recognize lysosomal hydrolases. After as little as 1 min incubation at 37 degrees C, endocytosis of Man-6-P binding sites was clearly observed to occur through regions of the plasma membrane and via vesicles that also bound anticlathrin antibody. After a 5-15-min incubation of cells at 37 degrees C, the internalized ligand was detected first in the cis region of the Golgi apparatus and then in the Golgi stacks using both autoradiography and immunocytochemistry to visualize the ligand. The appearance of Man-6-P:BSA in the Golgi region after 15-30 min was confirmed by subcellular fractionation, which demonstrated an accumulation of Man-6-P:BSA in light membrane fractions that corresponded with the Golgi fractions. After a 30-min incubation at 37 degrees C, the internalized Man-6-P binding sites were localized primarily in lysosomal structures whose membrane but not lumen co-stained for acid phosphatase. These results demonstrate a temporal participation of clathrin-containing coated vesicles during the initial endocytosis of Man-6-P binding sites and that one step in the Man-6-P:BSA transport pathway between plasma membrane and the lysosomal structure can involve a transit through the Golgi stacks.     

The endosomal concentration of a mannose 6-phosphate receptor is unchanged in the absence of ligand synthesis

The cation-independent mannose-6-phosphate (Man-6-P) receptor is involved in the targeting of newly synthesized lysosomal hydrolases. To investigate the intracellular distribution of this receptor, a conjugate of lactoperoxidase coupled to asialoorosomucoid was used to catalyze its iodination within the endosomes of human hepatoma (HepG2) cells. The 215-kD, cation-independent Man-6-P receptor was iodinated by this procedure as shown by pentamannosyl-6-phosphate-Sepharose affinity chromatography and by immunoprecipitation of labeled cell extracts. The amount of this receptor detected in endosomes was found to be unchanged after inhibition of protein synthesis with cycloheximide. If the Man-6-P receptor accumulates in the Golgi apparatus in the absence of lysosomal hydrolase synthesis, it should have been correspondingly depleted from endosomes after a period of cycloheximide treatment, because these pools of receptor are in rapid equilibrium. Therefore, these data suggest that newly synthesized ligands are not required for the transport of the cation-independent Man-6-P receptor from the Golgi apparatus to endosomes.     

Localization of the carbohydrate recognition sites of the insulin-like growth factor II/mannose 6-phosphate receptor to domains 3 and 9 of the extracytoplasmic region

The insulin-like growth factor II/mannose 6-phosphate receptor is a multifunctional receptor that binds to a diverse array of mannose 6-phosphate (Man-6-P) modified proteins as well as nonglycosylated ligands. Previous studies have mapped its two Man-6-P binding sites to a minimum of three domains, 1-3 and 7-9, within its 15-domain extracytoplasmic region. Since the primary amino acid determinants of carbohydrate recognition by the insulin-like growth factor II/mannose 6-phosphate receptor are predicted by sequence alignment to the cation-dependent mannose 6-phosphate receptor to reside within domains 3 and 9, constructs encoding either domain 3 alone or domain 9 alone were expressed in a Pichia pastoris expression system and tested for their ability to bind several carbohydrate ligands, including Man-6-P, pentamannosyl phosphate, the lysosomal enzyme, beta-glucuronidase, and the carbohydrate modifications (mannose 6-sulfate and Man-6-P methyl ester) found on Dictyostelium discoideum lysosomal enzymes. Although both constructs were functional in ligand binding and dissociation, these studies demonstrate the ability of domain 9 alone to fold into a high affinity (K(d) = 0.3 +/- 0.1 nm) carbohydrate-recognition domain whereas the domain 3 alone construct is capable of only low affinity binding (K(d) approximately 500 nm) toward beta-glucuronidase, suggesting that residues in adjacent domains (domains 1 and/or 2) are important, either directly or indirectly, for optimal binding by domain 3.     

The cytoplasmic tail of the mannose 6-phosphate/insulin-like growth factor-II receptor has two signals for lysosomal enzyme sorting in the Golgi

The mannose 6-phosphate/insulin-like growth factor-II (Man-6-P/IGF-II) receptor is known to cycle between the Golgi, endosomes, and the plasma membrane. In the Golgi the receptor binds newly synthesized lysosomal enzymes and transports them directly to an endosomal (prelysosomal) compartment without traversing the plasma membrane. Deletion of the carboxyl-terminal Leu-Leu-His-Val residues of the 163 amino acid cytoplasmic tail of the bovine Man-6-P/IGF-II receptor partially impaired this function, resulting in the diversion of a portion of the receptor-ligand complexes to the cell surface, where they were endocytosed. The same phenotype was observed when 134 residues of the cytoplasmic tail were deleted from the carboxyl terminus. Disruption of the Tyr24-Lys-Tyr-Ser-Lys-Val29 plasma membrane internalization signal alone had little effect on Golgi sorting, but when combined with either deletion resulted in a complete loss of this function. The mutant receptors retained the ability to recycle to the Golgi and bind cathepsin D. These results indicate that the cytoplasmic tail of the Man-6-P/IGF-II receptor contains two signals that contribute to Golgi sorting, presumably by interacting with the Golgi clathrin-coated pit adaptor proteins. The Leu-Leu-containing sequence represents a novel motif for mediating interaction with Golgi adaptor proteins.     

Structural insights into the mechanism of pH-dependent ligand binding and release by the cation-dependent mannose 6-phosphate receptor

The cation-dependent mannose 6-phosphate receptor (CD-MPR) is a key component of the lysosomal enzyme targeting system that binds newly synthesized mannose 6-phosphate (Man-6-P)-containing acid hydrolases and transports them to endosomal compartments. The interaction between the MPRs and its ligands is pH-dependent; the homodimeric CD-MPR binds lysosomal enzymes optimally in the pH environment of the trans Golgi network (pH approximately 6.5) and releases its cargo in acidic endosomal compartments (相似文献   

The interaction of phosphorylated oligosaccharides and lysosomal enzymes with bovine liver cation-dependent mannose 6-phosphate receptor

We have analyzed the interaction of phosphorylated oligosaccharides and lysosomal enzymes with immobilized bovine liver cation-dependent mannose-6-P receptor. Oligosaccharides with phosphomonoesters were the only species that interacted with the receptor, and molecules with two phosphomonoesters showed the best binding. Lysosomal enzymes with several oligosaccharides containing only one phosphomonoester had a higher affinity for the receptor than did the isolated oligosaccharides, indicating the possible importance of multivalent interactions between weakly binding ligands and the receptor. The binding of a mixture of phosphorylated lysosomal enzymes to the cation-dependent Man-6-P receptor was markedly influenced by pH. At pH 6.3, almost all of the lysosomal enzymes bound to the receptor; whereas at pH 7.0-7.5, approximately one-third of the material passed through the column, one-third interacted weakly, and one-third bound tightly. The distribution of individual lysosomal enzyme activities was similar to that of the total material. The species of phosphorylated oligosaccharides present on the lysosomal enzymes which interacted poorly with the receptor were similar to those found on the tightly bound material and included species of oligosaccharides with two phosphomonoester groups. Isolated oligosaccharides of this type bound to the receptor over the entire pH range tested. These findings indicate that at neutral pH the phosphorylated oligosaccharides on some lysosomal enzyme molecules are oriented in a manner which makes them inaccessible to the binding site of the cation-dependent Man-6-P receptor. Since the same enzymes bind to the cation-independent Man-6-P receptor at neutral pH, at least a portion of the phosphomannosyl residues must be exposed. We conclude that small variations in the pH of the Golgi compartment where lysosomal enzymes bind to the receptors could potentially modulate the extent of binding to the two receptors.     

Renin, a secretory glycoprotein, acquires phosphomannosyl residues

Renin is an aspartyl protease which is highly homologous to the lysosomal aspartyl protease cathepsin D. During its biosynthesis, cathepsin D acquires phosphomannosyl residues that enable it to bind to the mannose 6-phosphate (Man-6-P) receptor and to be targeted to lysosomes. The phosphorylation of lysosomal enzymes by UDP- GlcNAc:lysosomal enzyme N-acetylglucosaminylphosphotransferase (phosphotransferase) occurs by recognition of a protein domain that is thought to be present only on lysosomal enzymes. In order to determine whether renin, being structurally similar to cathepsin D, also acquires phosphomannosyl residues, human renin was expressed from cloned DNA in Xenopus oocytes and a mouse L cell line and its biosynthesis and posttranslational modifications were characterized. In Xenopus oocytes, the majority of the renin remained intracellular and underwent a proteolytic cleavage which removed the propiece. Most of the renin synthesized by oocytes was able to bind to a Man-6-P receptor affinity column (53%, 57%, and 90%, in different experiments), indicating the presence of phosphomannosyl residues. In the L cells, the majority of the renin was secreted but 5-6% of the renin molecules contained phosphomannosyl residues as demonstrated by binding of [35S]methionine- labeled renin to the Man-6-P receptor as well as direct analysis of [2- 3H]mannose-labeled oligosaccharides. Although the level of renin phosphorylation differed greatly between the two cell types examined, these results demonstrate that renin is recognized by the phosphotransferase and suggest that renin contains at least part of the lysosomal protein recognition domain.     

Granzymes A and B are targeted to the lytic granules of lymphocytes by the mannose-6-phosphate receptor

To investigate the question of whether lytic granules share a common biogenesis with lysosomes, cloned cytolytic T cell lines were derived from a patient with I-cell disease. The targeting of two soluble lytic granule components, granzymes A and B, was studied in these cells which lack a functional mannose-6-phosphate (Man-6-P) receptor-mediated pathway to lysosomes. Using antibodies and enzymatic substrates to detect the lytic proteins, I-cells were found to constitutively secrete granzymes A and B in contrast to normal cells in which these proteins were stored for regulated secretion. These results suggest that granzymes A and B are normally targeted to the lytic granules of activated lymphocytes by the Man-6-P receptor. In normal cells, the granzymes bear Man-6-P residues, since the oligosaccharide side chains of granzymes A and B, as well as radioactive phosphate on granzyme A from labeled cells, were removed by endoglycosidase H (Endo H). However, in I-cells, granzymes cannot bear Man-6-P and granzyme B acquires complex glycans, becoming Endo H resistant. Although the levels of granzymes A and B in cytolytic I-cell lymphocytes are < 30% of the normal levels, immunolocalization and cell fractionation of granzyme A demonstrated that this reduced amount is correctly localized in the lytic granules. Therefore, a Man-6-P receptor-independent pathway to the lytic granules must also exist. Cathepsin B colocalizes with granzyme A in both normal and I-cells indicating that lysosomal proteins can also use the Man-6-P receptor-independent pathway in these cells. The complete overlap of these lysosomal and lytic markers implies that the lytic granules perform both lysosomal and secretory roles in cytolytic lymphocytes. The secretory role of lytic granules formed by the Man-6-P receptor-independent pathway is intact as assessed by the ability of I-cell lymphocytes to lyse target cells by regulated secretion.     

Expression of the yeast aspartyl protease, proteinase A. Phosphorylation and binding to the mannose 6-phosphate receptor are altered by addition of cathepsin D sequences

Proteinase A, a yeast aspartyl protease that is highly homologous to the mammalian lysosomal aspartyl protease, cathepsin D, was expressed in Xenopus oocytes and its biosynthesis and post-translational modifications were characterized. While 29-45% of the proteinase A was secreted from oocytes, approximately 37% of the cell-associated proteinase A underwent proteolytic cleavage, characteristic of delivery to a lysosomal organelle. Although proteinase A is not targeted to the yeast vacuole by a mannose 6-phosphate receptor-dependent pathway, 2-5% of the proteinase A molecules expressed in oocytes bound to a Man-6-P receptor column. However, analysis of its [2-3H]mannose-labeled oligosaccharides revealed that 14-23% of these units contain phosphomannosyl residues. A hybrid molecule (H6), in which the propiece and first 12 amino acids of proteinase A were changed to the cathepsin D sequence, was also expressed in oocytes. The binding of H6 to the Man-6-P receptor was approximately 12-fold greater than observed for proteinase A. This increased level of receptor binding could be accounted for by three factors: 1) a small increase in the total amount of phosphorylated oligosaccharides, 2) an increase in the number of oligosaccharides which acquire two phosphomonoesters, and 3) the presence of a greater percentage of oligosaccharides with one phosphomonoester which exhibit high affinity binding to the Man-6-P receptor. These results demonstrate that proteinase A is recognized by UDP-GlcNAc:lysosomal enzyme N-acetylglucosaminylphosphotransferase. However, this interaction is altered by the addition of cathepsin D sequences, resulting in the generation of a higher affinity ligand for binding to the Man-6-P receptor.     

Recognition of Dictyostelium discoideum lysosomal enzymes is conferred by the amino-terminal carbohydrate binding site of the insulin-like growth factor II/mannose 6-phosphate receptor

The insulin-like growth factor-II/mannose 6-phosphate receptor (IGF-II/MPR) is a type I glycoprotein that mediates both the intracellular sorting of lysosomal enzymes bearing mannose 6-phosphate (Man-6-P) residues to the lysosome and the bioavailability of IGF-II. The extracytoplasmic region of the IGF-II/MPR contains 15 repeating domains; the two carbohydrate recognition domains (CRDs) have been localized to domains 1-3 and 7-9, and the high-affinity IGF-II binding site maps to domain 11. To characterize the carbohydrate binding properties of the IGF-II/MPR, regions of the receptor encompassing the individual CRDs were produced in a baculovirus expression system. Characterization of the recombinant proteins revealed that the pH optimum for carbohydrate binding is significantly more acidic for the carboxyl-terminal CRD than for the amino-terminal CRD (i.e., pH 6.4-6.5 vs 6.9). Equilibrium binding studies demonstrated that the two CRDs exhibit a similar affinity for Man-6-P. Furthermore, substitution of the conserved arginine residue in domain 3 (R435) or in domain 9 (R1334) with alanine resulted in a similar >1000-fold decrease in the affinity for the lysosomal enzyme, beta-glucuronidase. In contrast, the two CRDs differ dramatically in their ability to recognize the distinctive modifications (i.e., mannose 6-sulfate and Man-6-P methyl ester) found on Dictyostelium discoideum lysosomal enzymes: the amino-terminal CRD binds mannose 6-sulfate and Man-6-P methyl ester with a 14-55-fold higher affinity than the carboxyl-terminal CRD. Taken together, these results demonstrate that the IGF-II/MPR contains two functionally distinct CRDs.     

Distinctive regulation of the functional linkage between the human cation-independent mannose 6-phosphate receptor and GTP-binding proteins by insulin-like growth factor II and mannose 6-phosphate

The rat insulin-like growth factor II (IGF-II) receptor develops transmembrane signaling functions by directly coupling to a guanine nucleotide-binding protein (G protein) having a 40-kDa alpha subunit, Gi-2, whereas recent studies have indicated that the IGF-II receptor is a molecule identical to the cation-independent mannose 6-phosphate receptor (CI-MPR), a receptor implicated in lysosomal enzyme sorting. In this study, by using vesicles reconstituted with the clonal human CI-MPR and G proteins, we indicated that the CI-MPR could stimulate guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) binding and GTPase activities of Gi proteins in response to IGF-II. The stimulatory effect of IGF-II on Gi-2 depended on the reconstituted amount of the CI-MPR; it could not be found in vesicles reconstituted with Gi-2 alone; and it was also observed on Gi-1 reconstituted with the CI-MPR in phospholipid vesicles. Of interest, such stimulatory effect was not reproduced by Man-6-P in CI-MPR vesicles reconstituted with either G protein. Furthermore, the affinity for Man-6-P-mediated beta-glucuronidase binding to several kinds of native cell membranes was not reduced by 100 microM GTP gamma S. Instead, however, Man-6-P dose-dependently inhibited IGF-II-induced Gi-2 activation with an IC50 of 6 microM in vesicles reconstituted with the CI-MPR and Gi-2. The action of 100 nM IGF-II was completely abolished by 1 mM Man-6-P. Such an inhibitory effect of Man-6-P was reproduced by 4000 times lower concentrations of beta-glucuronidase or similar concentrations of fructose 1-phosphate, but not by mannose or glucose 6-phosphate. These results indicate that the human CI-MPR has two distinct signaling functions that positively or negatively regulate the activity of Gi-2 in response to the binding of IGF-II or Man-6-P.     

Domain 5 of the cation-independent mannose 6-phosphate receptor preferentially binds phosphodiesters (mannose 6-phosphate N-acetylglucosamine ester)

The 300 kDa cation-independent mannose 6-phosphate receptor (CI-MPR) and the 46 kDa cation-dependent MPR (CD-MPR) are key components of the lysosomal enzyme targeting system that bind newly synthesized mannose 6-phosphate (Man-6-P)-containing acid hydrolases and divert them from the secretory pathway. Previous studies have mapped two high-affinity Man-6-P binding sites of the CI-MPR to domains 1-3 and 9 and one low-affinity site to domain 5 within its 15-domain extracytoplasmic region. A structure-based sequence alignment predicts that domain 5 contains the four conserved residues (Gln, Arg, Glu, Tyr) identified as essential for Man-6-P binding by the CD-MPR and domains 1-3 and 9 of the CI-MPR. Here we show by surface plasmon resonance (SPR) analyses of constructs containing single amino acid substitutions that these conserved residues (Gln-644, Arg-687, Glu-709, Tyr-714) are critical for carbohydrate recognition by domain 5. Furthermore, the N-glycosylation site at position 711 of domain 5, which is predicted to be located near the binding pocket, has no influence on the carbohydrate binding affinity. Endogenous ligands for the MPRs that contain solely phosphomonoesters (Man-6-P) or phosphodiesters (mannose 6-phosphate N-acetylglucosamine ester, Man-P-GlcNAc) were generated by treating the lysosomal enzyme acid alpha-glucosidase (GAA) with recombinant GlcNAc-phosphotransferase and uncovering enzyme (N-acetylglucosamine-1-phosphodiester alpha-N-acetylglucosaminidase). SPR analyses using these modified GAAs demonstrate that, unlike the CD-MPR or domain 9 of the CI-MPR, domain 5 exhibits a 14-18-fold higher affinity for Man-P-GlcNAc than Man-6-P, implicating this region of the receptor in targeting phosphodiester-containing lysosomal enzymes to the lysosome.     

Demonstration of lysosomal localization for the mammalian ependymin-related protein using classical approaches combined with a novel density shift method

Most newly synthesized soluble lysosomal proteins are delivered to the lysosome via the mannose 6-phosphate (Man-6-P)-targeting pathway. The presence of the Man-6-P post-translational modification allows these proteins to be affinity-purified on immobilized Man-6-P receptors. This approach has formed the basis for a number of proteomic studies that identified multiple as yet uncharacterized Man-6-P glycoproteins that may represent new lysosomal proteins. Although the presence of Man-6-P is suggestive of lysosomal function, the subcellular localization of such candidates requires experimental verification. Here, we have investigated one such candidate, ependymin-related protein (EPDR). EPDR is a protein of unknown function with some sequence similarity to ependymin, a fish protein thought to play a role in memory consolidation and learning. Using classical subcellular fractionation on rat brain, EPDR co-distributes with lysosomal proteins, but there is significant overlap between lysosomal and mitochondrial markers. For more definitive localization, we have developed a novel approach based upon a selective buoyant density shift of the brain lysosomes in a mutant mouse lacking NPC2, a lysosomal protein involved in lipid transport. EPDR, in parallel with lysosomal markers, shows this density shift in gradient centrifugation experiments comparing mutant and wild type mice. This approach, combined with morphological analyses, demonstrates that EPDR resides in the lysosome. In addition, the lipidosis-induced density shift approach represents a valuable tool for identification and validation of both luminal and membrane lysosomal proteins that should be applicable to high throughput proteomic studies.     

Estradiol down-regulates the mannose-6-phosphate/insulin-like growth factor-II receptor gene and induces cathepsin-D in breast cancer cells: a receptor saturation mechanism to increase the secretion of lysosomal proenzymes.

We have studied the regulation by estradiol of the mannose-6-phosphate (Man-6-P)/insulin-like growth factor-II (IGF-II) receptor concentration in different breast cancer cell lines. The mRNA level was assayed by Northern blot using the H5.1 cDNA probe. The protein level was assayed by Western ligand blot, by binding saturation with [125I]procathepsin-D on total membrane preparations, and by immunoprecipitation of 35S-labeled proteins. In three estrogen receptor-positive cell lines (MCF7, T47D, and ZR75-1), estradiol specifically decreased the steady state level of the Man-6-P/IGF-II receptor protein and mRNA. Moreover, in different cell lines and in primary culture of normal mammary cells, the secretion of procathepsin-D was inversely correlated with the level of Man-6-P/IGF-II receptor protein and mRNA. We conclude that estradiol down-regulates the Man-6-P/IGF-II receptor in breast cancer cells. Since two of its ligands, procathepsin-D and IGF-II, are induced by estrogen, we propose that the Man-6-P/IGF-II receptor becomes saturated after estrogen treatment. This model might explain the previously described estrogen-induced secretion of procathepsin-D and other lysosomal proenzymes routed by the same transport system.     

Expression of human cathepsin D in Xenopus oocytes: phosphorylation and intracellular targeting

We have obtained expression of a cDNA clone for human cathepsin D in Xenopus laevis oocytes. Biosynthetic studies with [35S]methionine labeling demonstrated that most of the cathepsin D remained intracellular and underwent proteolytic cleavage, converting a precursor of Mr 47,000 D to a mature form of Mr 39,000 D with processing intermediates of Mr 43,000-41,000 D. greater than 90% of the cathepsin D synthesized by oocytes bound to a mannose 6-phosphate (Man-6-P) receptor affinity column, indicating the presence of phosphomannosyl residues. An analysis of [2-3H]mannose-labeled oligosaccharides directly demonstrated phosphomannosyl residues on cathepsin D. Sucrose-gradient fractionation, performed to define the membranous compartments that cathepsin D traversed during its biosynthesis, demonstrated that cathepsin D is targeted to a subpopulation of yolk platelets, the oocyte equivalent of a lysosome. Xenopus oocytes were able to endocytose lysosomal enzymes from the medium and this uptake was inhibited by Man-6-P, thus demonstrating the presence of Man-6-P receptors in these cells. Therefore, the entire Man-6-P dependent pathway for targeting of lysosomal enzymes is present in the oocytes. Xenopus oocytes should be a useful system for examining signals responsible for the specific targeting of lysosomal enzymes to lysosomes.     

The insulin-like growth factor II/mannose-6-phosphate receptor

Recent evidence from molecular cloning, biochemical and immunological experiments has established that the cation-independent mannose-6-phosphate (Man-6-P) receptor and insulin-like growth factor-II (IGF-II) receptor are the same protein. Although the role of the IGF-II/Man-6-P receptor as a transporter of hydrolytic enzymes in the biogenesis of lysosomes is certain, elucidation of the receptor's structure has not yet provided major insights into the function of IGF-II binding. Mutually exclusive binding of IGF-II and naturally occurring phosphomannosyl ligands to distinct but proximal sites on the receptor suggests that the IGF-II/Man-6-P receptor cannot simultaneously fulfill the functional requirements of both IGF-II and lysosomal enzymes. Does the receptor transduce on intracellular signal in order to mediate the biological effects of IGF-II? If so, then the receptor must interact with an effector molecule, perhaps a G protein, in the mechanism of IGF-II action. Further information from ligand binding and especially mutagenesis experiments will be needed to elucidate the potentially multiple functions of the IGF-II/Man-6-P receptor.     

Identification of sites of mannose 6-phosphorylation on lysosomal proteins

Most newly synthesized soluble lysosomal proteins contain mannose 6-phosphate (Man-6-P), a specific carbohydrate modification that is recognized by Man-6-P receptors (MPRs) that direct targeting to the lysosome. A number of proteomic studies have focused on lysosomal proteins, exploiting the fact that Man-6-P-containing forms can be purified by affinity chromatography on immobilized MPRs. These studies have identified many known lysosomal proteins as well as many proteins not previously classified as lysosomal. The latter are of considerable biological interest with potential implications for lysosomal function and as candidates for lysosomal storage diseases of unknown etiology. However, a significant problem in interpreting the biological relevance of such proteins has been in distinguishing true Man-6-P glycoproteins from simple contaminants and from proteins associated with true Man-6-P glycoproteins (e.g. protease inhibitors and lectins). In this report, we describe a mass spectrometric approach to the verification of Man-6-phosphorylation based upon LC-MS of MPR-purified proteolytic glycopeptides. This provided a useful tool in validating novel MPR-purified proteins as true Man-6-P glycoproteins and also allowed identification of low abundance components not observed in the analysis of the total Man-6-P glycoprotein mixture. In addition, this approach allowed the global mapping of 99 Man-6-phosphorylation sites from 44 known lysosomal proteins purified from mouse and human brain. This information is likely to provide useful insights into protein determinants for this modification and may be of significant value in protein engineering approaches designed to optimize protein delivery to the lysosome in therapeutic applications such as gene and enzyme replacement therapies.     

Identification and validation of mannose 6-phosphate glycoproteins in human plasma reveal a wide range of lysosomal and non-lysosomal proteins

Acid hydrolase activities are normally confined within the cell to the lysosome, a membrane-delimited cytoplasmic organelle primarily responsible for the degradation of macromolecules. However, lysosomal proteins are also present in human plasma, and a proportion of these retain mannose 6-phosphate (Man-6-P), a modification on N-linked glycans that is recognized by Man-6-P receptors (MPRs) that normally direct the targeting of these proteins to the lysosome. In this study, we purified the Man-6-P glycoforms of proteins from human plasma by affinity chromatography on immobilized MPRs and characterized this subproteome by two-dimensional gel electrophoresis and by tandem mass spectrometry. As expected, we identified many known and potential candidate lysosomal proteins. In addition, we also identified a number of abundant classical plasma proteins that were retained even after two consecutive rounds of affinity purification. Given their abundance in plasma, we initially considered these proteins to be likely contaminants, but a mass spectrometric study of Man-6-phosphorylation sites using MPR-purified glycopeptides revealed that some proportion of these classical plasma proteins contained the Man-6-P modification. We propose that these glycoproteins are phosphorylated at low levels by the lysosomal enzyme phosphotransferase, but their high abundance results in detection of Man-6-P glycoforms in plasma. These results may provide useful insights into the molecular processes underlying Man-6-phosphorylation and highlight circumstances under which the presence of Man-6-P may not be indicative of lysosomal function. In addition, characterization of the plasma Man-6-P glycoproteome should facilitate development of mass spectrometry-based tools for the diagnosis of lysosomal storage diseases and for investigating the involvement of Man-6-P-containing glycoproteins in more widespread human diseases and their potential utility as biomarkers.     

Strategies for carbohydrate recognition by the mannose 6-phosphate receptors

The two members of the P-type lectin family, the 46 kDa cation-dependent mannose 6-phosphate receptor (CD-MPR) and the 300 kDa cation-independent mannose 6-phosphate receptor (CI-MPR), are ubiquitously expressed throughout the animal kingdom and are distinguished from all other lectins by their ability to recognize phosphorylated mannose residues. The best-characterized function of the MPRs is their ability to direct the delivery of approximately 60 different newly synthesized soluble lysosomal enzymes bearing mannose 6-phosphate (Man-6-P) on their N-linked oligosaccharides to the lysosome. In addition to its intracellular role in lysosome biogenesis, the CI-MPR, but not the CD-MPR, participates in a number of other biological processes by interacting with various molecules at the cell surface. The list of extracellular ligands recognized by this multifunctional receptor has grown to include a diverse spectrum of Man-6-P-containing proteins as well as several non-Man-6-P-containing ligands. Recent structural studies have given us a clearer view of how these two receptors use related, but yet distinct, approaches in the recognition of phosphomannosyl residues.