(Received for publication, August 20, 1996, and in revised form, October 15, 1996)
From the Georg-August-Universität Göttingen, Abteilung Biochemie II, Gosslerstrasse 12d, 37073 Göttingen, Germany
Mammalian cells contain two types of mannose 6-phosphate receptors (MPR), MPRs 46 and 300, that contribute with variable efficiency to the sorting of individual lysosomal proteins. To evaluate the role of phosphorylated oligosaccharides for the sorting efficiency by either of the two receptors, the structure of phosphorylated oligosaccharides on lysosomal proteins escaping sorting in cells lacking MPR 46 and/or MPR 300 was analyzed. Procathepsin D was chosen as a model because it is sorted efficiently via MPR 300 and poorly via MPR 46 and contains a distinct and highly heterogenous mixture of phosphorylated oligosaccharides at either of its two N-glycosylation sites. Both MPRs 46 and 300 were found to have a minor but distinct preference for forms of procathepsin D and other lysosomal proteins containing oligosaccharides with two phosphomonoesters. However, the phosphorylation of oligosaccharides in procathepsin D and other lysosomal proteins that escape sorting in control cells or in cells lacking MPR 46 and/or MPR 300 was strikingly similar, and oligosaccharides with two phosphomonoesters represented the major oligosaccharide species. We conclude from these results that the position of the position of the phosphate groups, the structure of the underlying oligosaccharide, and/or the polypeptide backbone of lysosomal proteins have major roles in determining the affinity to MPRs.
Mammalian cells express two different mannose 6-phosphate receptors (MPR)1 with apparent molecular masses of 46,000 Da (MPR 46) and 300,000 Da (MPR 300). The two receptors mediate the targeting of mannose 6-phosphate (Man-6-P)-containing lysosomal proteins to lysosomes (1, 2). A variable fraction, generally less than 20% of the newly synthesized lysosomal proteins, escapes targeting to lysosomes and is secreted. This is generally thought to reflect a failure of binding to MPRs in the secretory route, but there is also evidence that at least part of the secretion is mediated by MPR 46 (3). Loss of either MPR is associated with partial missorting of newly synthesized lysosomal proteins, which then are secreted (4, 5, 6, 7). In addition to sorting, MPR 300 mediates internalization of extracellular lysosomal proteins and of the non-phosphorylated insulin-like growth factor II. It is not clear why cells express two types of MPRs. One possibility is that the two receptors interact with different lysosomal proteins or different isoforms of a lysosomal protein. The analysis of the lysosomal proteins that escape sorting in cells lacking either MPR 46 or MPR 300 has indicated that most of the lysosomal proteins are partially missorted if either type of MPR is missing (8, 9). The extent of missorting, however, depends on the type of receptor, suggesting that the majority of lysosomal proteins interacts with both MPRs although with different affinities.
It has been suggested that structural differences in the
Man-6-P-containing oligosaccharides in lysosomal proteins contribute to
their different sorting efficiencies by MPRs (9). Indeed, phosphorylated oligosaccharides in lysosomal proteins are structurally a highly heterogenous population containing one or two phosphate groups. The phosphate groups may be present as diesters (interspaced between C1 of a covering N-acetylglucosamine and C6 of
mannose) or as monoesters. In monophosphorylated oligosaccharides, the phosphate group may be attached to 3 of the 5 mannose residues of the
-1,6 branch. In diphosphorylated oligosaccharides, the second
phosphate may be attached to 2 of the 3 mannose residues of the
-1,3
branch. Furthermore, the number and linkages of non-phosphorylated mannose residues can vary, and in monophosphorylated oligosaccharides, the
-1,3 branch may be replaced by a branch containing sialic acid
residues (for review, see Ref. 10). Both MPRs have the highest affinity
for oligosaccharides with two phosphomonoester groups (11, 12, 13).
In the present study, we analyzed the phosphorylated oligosaccharides of the lysosomal proteinase procathepsin D, accumulating in the secretions of mouse embryonic fibroblasts (MEF), that express physiological levels of either MPR 46 or MPR 300. The oligosaccharides were compared with those of procathepsin D secreted by MEF lacking or expressing both MPRs. Procathepsin was chosen because its sorting efficiency greatly depends on the type of receptor that is expressed. It is sorted poorly by cells expressing only MPR 46 and efficiently by cells expressing MPR 300 (8, 9). Secretions of MEF expressing MPR 300 and/or MPR 46 should be depleted in procathepsin D forms that are targeted by the receptors that are expressed. Analysis of the oligosaccharides should, therefore, reveal whether MPRs 46 and 300 interact with procathepsin D forms, which differ in their phosphorylation. Oligosaccharides from the two sites were analyzed separately since the bilobar procathepsin D contains in each of its two lobes one N-glycosylation site that might differ in its phosphorylation pattern.
The analysis of newly synthesized procathepsin D revealed that a heterogenous mixture of phosphorylated oligosaccharides is attached to either of the two N-glycosylation sites of procathepsin D and that the phosphorylated oligosaccharides at the two sites are clearly distinct. Unexpectedly, the pattern of phosphorylated oligosaccharides in procathepsin D secreted by MEF expressing MPR 46 and/or MPR 300, or neither MPR, was strikingly similar. This holds true also for the phosphorylated oligosaccharides of lysosomal proteins secreted by immortalized MEF overexpressing either MPR 46 or MPR 300. We conclude from these results that the presence of oligosaccharides with two phosphomonoesters is not sufficient for efficient sorting and that other factors, e.g. the polypeptide backbone of lysosomal proteins, determine the sorting efficiency via MPRs.
MEF expressing both MPRs, either MPR 46 or MPR 300, and no MPR were obtained as described previously (9). Immortalized mouse embryonic fibroblasts stably transfected with MPRs 46- and 300-cDNA, respectively, are described elsewhere (14). All cells were maintained in Dulbecco's minimal essential medium supplemented with Glutamax-I (Life Technologies, Inc.) and 10% fetal calf serum.
Purification of [2-3H]Mannose-labeled Procathepsin DMEF on 10-cm dishes were incubated in minimal essential medium containing 0.5 mM glucose and 5% dialyzed fetal calf serum for 1 h and then labeled for 16 h with D-[2-3H]mannose (Amersham Life Science, Inc., 666 GBq/mmol) in the same medium. Proteins of the conditioned media were concentrated by ammonium sulfate precipitation (50% w/v). Subsequent purification of labeled procathepsin D was performed according to Conner (15) with slight modifications. Briefly, the ammonium sulfate precipitate was dialyzed against buffer A (0.1% Triton X-100, 0.4 M NaCl in 0.1 M sodium formate, pH 3.5) and then applied to a 0.5-ml pepstatin A-agarose column (Sigma). The material was mixed by rotating end over end at 4 °C. The column was then washed with 4 volumes of buffer A, with 6 volumes of buffer A containing 6 M urea, and again with 4 volumes of buffer A. Finally, bound [2-3H]procathepsin D was eluted by 0.2% Triton X-100, 0.4 M NaCl in 20 mM Tris-HCl, pH 8.3. Purity of procathepsin D preparation was confirmed by SDS-PAGE and fluorography.
Reductive Carboxymethylation, Tryptic Digestion, and Separation of Tryptic PeptidesLabeled procathepsin D was mixed with 80 µg of mouse liver cathepsin D purified according to Claussen et al.2 and concentrated in ultra thimbles. The samples were adjusted to 6 M guanidinium hydrochloride, 10 mM EDTA, and 50 mM dithiothreitol in 400 mM Tris-HCl, pH 8.6. Reduction was carried out under an oxygen-free atmosphere for 1 h at 50 °C. For carboxymethylation, 2 M iodoacetic acid, adjusted to pH 8.6 with ammonium hydroxide, was added to a final concentration of 150 mM and incubated for 30 min at room temperature in darkness. To complete the reaction, a second cycle with 65 mM dithiothreitol and 122 mM iodoacetic acid (final concentration) followed (17). The samples then were desalted on an HPLC system (SMART; Pharmacia) using a Sephadex G-25 column (fast desalting PC 3.2/10; Pharmacia) equilibrated with 10% acetonitrile in 50 mM ammonium acetate, pH 8.6. The desalted material was digested with 2% (w/w) trypsin (Boehringer Mannheim) for 16 h at 37 °C. Tryptic peptides were separated by reverse phase-HPLC using a 220 × 2.1-mm C8 column (Aquapore RP300; BAI) equilibrated with 0.1% trifluoracetic acid in H2O and eluted with an increasing acetonitrile concentration (0.9% acetonitrile/min) and a flow rate of 0.3 ml/min. Fractionation was performed by automatic peak recognition (OD 210 nm), and the radioactivity was monitored by liquid scintillation counting. Glycopeptides I and II were identified by radiosequencing of 3H-labeled peptides after pooling of peak fractions.
Digestion with Endoglycosidase H and Separation of Released OligosaccharidesGlycopeptide I and II were lyophilized twice to remove any trace of acetonitrile and trifluoroacetic acid. Dried peptides were redissolved in 100 µl of 50 mM citrate-phosphate, pH 5.6, and digested with 3 milliunits of endo-H (Boehringer Mannheim) at 37 °C for 40 h under a toluene atmosphere with addition of the same amount of enzyme after 16 h (18). To separate free oligosaccharides from endo-H-resistant glycopeptides, samples were applied to C18-silica cartridges (Waters) equilibrated with 0.05% trifluoroacetic acid in H2O. The column was washed with this buffer and eluted with 0.05% trifluoroacetic acid in acetonitrile (18). The run-through material and wash fractions containing the 3H-labeled oligosaccharides were collected and desalted on a Sephadex G-25 column (NapTM 25 column, Pharmacia) in 7% 1-propanol in H20.
Analysis of Anionic Oligosaccharides on QAE-SephadexOligosaccharides were dissolved in 2 mM Tris-base, pH 9.5, and applied in 6-ml aliquots to a 1-ml column of QAE-Sephadex equilibrated in 2 mM Tris-base (19). The column was washed with 4 1-ml aliquots of 2 mM Tris-base and then eluted with a linear NaCl gradient (0-150 mM NaCl in 2 mM Tris-base). Fractions of 1-ml aliquots were collected and monitored for radioactivity. For further analysis, peak fractions were pooled, lyophilized, and desalted on a Sephadex G-25 column.
Oligosaccharide-samples that had been treated with HCl, alkaline phosphatase, or neuraminidase (see below) were eluted with a stepwise gradient of NaCl (20, 60, 90, and 140 mM) in 2 mM Tris-base.
Mild Acid HydrolysisLyophilized oligosaccharides were resuspended in 1 ml of 0.01 M HCl and heated at 100 °C for 30 min. The samples were immediately frozen, lyophilized, and resuspended in 6 ml of 2 mM Tris-base for subsequent QAE-Sephadex fractionation (19).
Enzyme Digestion of OligosaccharidesFor treatment of oligosaccharides with alkaline phosphatase, 2 units of Escherichia coli alkaline phosphatase (Sigma) were dialyzed against 50 mM Tris-HCl, pH 8.0. Oligosaccharides were resuspended therein and incubated at 37 °C for 16 h (19).
For digestion with Vibrio cholerae neuraminidase (Boehringer Mannheim), oligosaccharides were resuspended in 50 mM sodium acetate, 9 mM CaCl2, 150 mM NaCl, pH 5.5, and incubated for 16 h at 37 °C.
Metabolic Labeling of Cells and Immunoprecipitation of Cathepsin DMEF on 35 mm-dishes were incubated in methionine-free medium for 1 h and then labeled with [35S]methionine (Amersham Life Science, Inc.) in the same medium containing 5% dialyzed fetal calf serum. During the following chase for 6 h, the medium was supplemented with 0.25 mg/ml L-methionine. Immunoprecipitation from cells and media was carried out as described previously (20) with antisera specific for mouse cathepsin D (9). Densitometric quantification of cathepsin D was done using a Hewlett-Packard ScanJet 4c/T (Palo Alto, CA) and the program WinCam 2.2 (Microsoft).
Preparation of Oligosaccharides Derived from All Secreted Man-6-P-containing ProteinsFor the production of
Man-6-P-containing lysosomal proteins, immortalized mpr
MEF3 overexpressing MPR 46 or MPR 300 were
labeled as described above. The secretions were concentrated by
ammonium sulfate precipitation (50% w/v). To purify Man-6-P-containing
lysosomal proteins on MPR-columns, the precipitates were dialyzed
against binding buffer (50 mM imidazol-HCl, 5 mM Na-
-glycerophosphate, 150 mM NaCl, 2 mM EDTA, 10 mM MgCl2, 0.02%
NaN3, 0.05% Triton X-100, pH 6.5). Samples then were
repeatedly applied to MPRs 300 and 46 columns (9). After washing the
columns with binding buffer and 5 mM glucose 6-phosphate in
binding buffer, the material of interest was eluted with 5 mM Man-6-P in binding buffer. The Man-6-P eluates from the
MPR columns were combined, precipitated with cold acetone (
20 °C,
50% final concentration), and washed once with 50% acetone. The
material was solubilized by heating for 5 min at 95 °C in 1% SDS,
125 mM Tris-HCl, pH 6.8, and 20% glycerol.
Citrate-phosphate, pH 5.6, was added to a final concentration of 50 mM, and the samples were incubated with 3 milliunits of
endo-H at 37 °C for 40 h with addition of the same amount of
endo-H after 16 h. Separation of endo-H-released oligosaccharides
from peptides were performed as described above.
Cathepsin D contains in each of its two lobes one
N-glycosylation site, which corresponds in mouse cathepsin D
to Asp-134 (site I) and Asp-261 (site II). To analyze the pattern of
phosphorylated oligosaccharides in cathepsin D, we chose as a source
procathepsin D from secretions of immortalized mouse embryonic
fibroblasts that lack MPR 46 and MPR 300 (mpr MEF). These
cells secrete more than 90% of the newly synthesized cathepsin as
procathepsin D. The procathepsin D in these secretions is therefore
representative for newly synthesized cathepsin D, and the structure of
its oligosaccharides should reflect the biosynthetic pattern generated
in the Golgi cisternae unchanged by secondary modifications due to
lysosomal phosphatases and glycosidases. The oligosaccharide chains in
procathepsin D were metabolically labeled by incubation of
mpr
MEF with [2-3H]mannose. After
purification from the secretions, the 3H-labeled
procathepsin D (see inset of Fig. 1) was mixed with unlabeled cathepsin D purified from mouse liver, subjected to reductive
carboxymethylation, and digested with trypsin. Two major 3H-labeled glycopeptide fractions were obtained after
separation by reverse phase-HPLC (indicated by horizontal bars
in Fig. 1), which were identified by amino acid sequencing as the
glycopeptides carrying the N-glycosylation sites I and II,
respectively.
Digestion with endo-H released, from either of the two glycopeptides, more than 95% of the radioactivity as 3H-labeled oligosaccharides, which were separated from (glyco-) peptides by reverse phase chromatography. The oligosaccharides were then separated according to their charge at pH 9.5 by QAE-anion-exchange chromatography.
The oligosaccharides attached to site I separated into species lacking
a negative charge (I-0, 3%) or carrying 1 (I-1, 29%), 2 (I-2, 55%),
or 3 (I-3, 13%) negative charges (Fig. 2,
top). The percentages in the brackets refer to the
radioactivity recovered in these species. 97% of the oligosaccharides
attached to site II were anionic, carrying 1 (II-1, 1%), 2 (II-2,
24%), 3 (II-3, 15%), or 4 (II-4, 57%) negative charges (Fig. 2,
bottom).
The anionic oligosaccharides were further characterized by subjecting them to mild acid hydrolysis, treatment with alkaline phosphatase or neuraminidase, and followed by anion exchange chromatography. This allows us to differentiate whether a negative charge is due to the presence of a phosphomonoester group, a phosphodiester group, or a sialic acid residue. Mild acid hydrolysis increases the negative charge at alkaline pH by 1 if an acid-labile phosphodiester is converted into an acid-stable phosphomonoester or reduces the negative charge by 1 if an acid-labile sialic acid residue is cleaved. The negative charge at pH 9.5 is reduced by 2 for each phosphomonoester that is cleaved by alkaline phosphatase and by 1 for each sialic acid that is cleaved by neuraminidase.
Fig. 3 exemplifies the analysis for oligosaccharides in
fraction II-3 that carry, at pH 9.5, 3 negative charges (Fig.
3A). The negative charge of essentially all oligosaccharides
is reduced by 1 by mild acid hydrolysis (Fig. 3B). This
implies that all oligosaccharide species contain at least one sialic
acid residue. This is supported by the observation that the negative
charge of all oligosaccharides is reduced by 1 by treatment with
neuraminidase (Fig. 3D). Of the oligosaccharides, 30% were
resistant to alkaline phosphatase treatment, while 70% lost two
negative charges (Fig. 3C). The latter is due to the loss of
one phosphomonoester group. All oligosaccharides of fraction II-3 were
converted into neutral species when they were first subjected to mild
acid hydrolysis and then to digestion with alkaline phosphatase (not
shown). Taken together, these results indicate that 70% of the
oligosaccharides of fraction II-3 carry one phosphomonoester group and
one sialic acid residue. The remaining 30% contain one phosphodiester
group and two acid-labile negative charges, one of which is a
sialic acid residue. The other may represent a second sialic acid
residue resistant to V. cholerae neuraminidase or an unknown
acid-labile anionic group.
Table I summarizes the data on oligosaccharides released from sites I and II by endo-H. Of the oligosaccharides released from site I located within the amino-terminal lobe, 92% are phosphorylated. All phosphorylated oligosaccharides carry a single phosphate group that in 65% is present as a phosphomonoester and in 35% is present as a phosphodiester. About one-fifth of the phosphorylated oligosaccharides (21%) are of hybrid nature as indicated by the presence of sialic acid. Phosphodiesters were slightly more frequent (42%) in the fraction of hybrid oligosaccharides than in the fraction of high mannose oligosaccharides (33%).
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Of the oligosaccharides attached to site II located within the carboxyl lobe, 97% are phosphorylated. The major difference of the oligosaccharides attached to site I is the presence of oligosaccharides with two phosphomonoester groups, which represent the majority (57%) of the phosphorylated oligosaccharides. It should be noted that all phosphate groups in the diphosphorylated oligosaccharides are present as monoesters. Similar to site I, 65% of the monophosphorylated oligosaccharides at site II contain a phosphomonoester, and 35% contain a phosphodiester. Hybrid oligosaccharides represent about one-fifth of the phosphorylated oligosaccharides (23%). Compared with site I, this value is remarkably high since phosphorylated hybrid oligosaccharides can only be generated from monophosphorylated oligosaccharides (10). If referred to the latter, about 58% of the monophosphorylated oligosaccharides at site II are of hybrid nature. This frequency is almost 3 times as high than at site I (21%). Moreover, phosphodiesters were found exclusively in the group of hybrid oligosaccharides.
In summary, mouse cathepsin D is characterized by a glycosylation site-specific phosphorylation pattern. Oligosaccharides with two phosphomonoesters, which mediate high affinity binding to MPRs (11, 12, 13), are found only among those attached to the carboxyl lobe of cathepsin D.
Oligosaccharides in Procathepsin D Secreted by MEF Expressing MPR 46 and/or MPR 300As a source for procathepsin D secreted by
cells lacking either MPR 46 or MPR 300, we chose non-immortalized
primary MEF (9). Primary MEF with endogenous MPRs 46 and 300 are
targeting procathepsin D with high efficiency to lysosomes. Only 7 (3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20)% of the newly synthesized procathepsin D is secreted.
Deficiency of MPR 46 doubles the secreted fraction to 14 (7-30)%
while deficiency of MPR 300 increases the secreted fraction to 88 (86-94)%. Primary MEF lacking both receptors secrete 93 (91-96)% of
the 3H-labeled procathepsin D. The values given for the
secretions represent the mean and the range of four determinations, one
of which is shown in Fig. 4. In this figure, it is also
shown that the lowering of glucose to 0.5 mM as performed
during metabolic labeling with [2-3H]mannose does not
affect the sorting efficiency. The oligosaccharides in procathepsin D
secreted by MEF expressing MPR 46 and/or MPR 300 should reveal whether
MPR 46 and/or MPR 300 target subpopulations of procathepsin D to
lysosomes, which differ in their phosphorylation. Since the
oligosaccharides attached to the amino and carboxyl lobes have distinct
phosphorylation patterns, the oligosaccharides attached to sites I and
II were analyzed separately to also detect minor differences that would
be obscured if oligosaccharides from both sites would be mixed.
The oligosaccharides released by endo-H from the glycosylation sites I
and II were separated by QAE-Sephadex ion exchange chromatography. The
distribution of the radioactivity among oligosaccharide species with
0-4 negative charges is given in Table II. Further structural analysis (not shown) revealed that the composition of the
individual oligosaccharide fractions is comparable with that determined
for the respective fractions of procathepsin D secreted by immortalized
mpr MEF (see Table I).
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The charge pattern of oligosaccharides from glycosylation site I, which are only monophosphorylated, was independent of the type of MPR expressed by the MEF. For the charge pattern of oligosaccharides from glycosylation site II, which contain mostly two phosphomonoester groups, a slight but notable difference in the frequency of oligosaccharides with 4 negative charges (carrying two phosphomonoester groups) was noted. The relative frequency increased from 57% in control MEF, via 63% in MEF expressing only MPR 300, to 68% in MEF expressing only MPR 46. This increase is mainly at the expense of oligosaccharides with 2 negative charges (fraction II-2). The latter are monophosphorylated with a phosphomonoester to phosphodiester ratio of 2:1. Apparently the procathepsin D forms that escape sorting via MPR 46 or MPR 300 are enriched at site II in monophosphorylated and depleted in diphosphorylated oligosaccharides.
MEF deficient of MPR 46 secrete twice as much procathepsin D than do control MEF. Procathepsin D secreted by MPR 46-deficient MEF is therefore likely to represent a 1:1 mixture of procathepsin D that escapes sorting by either type of MPR and such that is normally sorted via MPR 46. Since the charge pattern of oligosaccharides in procathepsin D secreted by control MEF and MPR 46-deficient MEF is known, the charge pattern for oligosaccharides in the subpopulation of procathepsin D that is normally sorted via MPR 46 can be calculated. For site II, the predicted frequency of oligosaccharides with 2 and 4 negative charges is 14 and 69%, respectively. These values are very close to those (16 and 68%) observed in procathepsin D that escapes sorting in MPR 300-deficient MEF (see Table II) and normally would be sorted by this receptor.
In summary, these data show that the phosphorylation pattern of oligosaccharides released from sites I and II is strikingly similar for the forms of procathepsin D that normally are sorted via MPR 46 or MPR 300 and even for those that escape sorting by the two receptors.
Oligosaccharides in Man-6-P-containing Lysosomal Proteins Accumulating in Secretions of mpr- MEF Overexpressing MPR 46 or MPR 300The analysis of procathepsin D had shown that the
phosphorylation pattern of the secreted proenzyme was only marginally
dependent whether the cells express MPR 46 and/or MPR 300 or lack both
MPRs. To extend this analysis to other lysosomal proteins, the
secretions of immortalized MEF lacking both MPRs (mpr
MEF) or reexpressing MPR 46 (mpr
MEF/MPR 46) or MPR 300 (mpr
MEF/MPR 300) were used as sources for lysosomal
proteins. Reexpression of MPR 46 decreases the secretion of lysosomal
proteins to about 40% of that in mpr
MEF and
reexpression of MPR 300 to about 10% (14).
After metabolic labeling with [2-3H]mannose, the
Man-6-P-containing lysosomal proteins were isolated from the secretions
by an MPR 46/MPR 300 affinity chromatography. The oligosaccharides sensitive to endo-H were separated by anion exchange chromatography. The charge pattern of the anionic oligosaccharides was strikingly similar, irrespective of whether they were derived from MEF lacking both MPRs or overexpressing MPR 46 or MPR 300 (Fig. 5).
Of the oligosaccharides, 90-91% were negatively charged carrying
either 1 (2-3%), 2 (22-24%), 3 (6-9%), or 4 (56-60%) negative
charges.
The ratio of di- and monophosphorylated oligosaccharides (determined by ion exchange chromatography after mild acid hydrolysis) revealed minor differences between the three genotypes. The ratio was highest in MPR-deficient cells (56:32), intermediate in MPR 46-expressing cells (54:33), and lowest in MPR 300-expressing cells (51:35). This is consistent with the assumption that both MPRs 300 and 46 have a minor preference for oligosaccharides with two phosphomonoesters. These oligosaccharides are less abundant in secretions of MEF expressing MPR 300 than in MEF expressing MPR 46 since the former retain 90% and the latter only 60% of the newly synthesized lysosomal proteins.
In this study, the phosphorylated oligosaccharides of procathepsin D and other lysosomal proteins that escape sorting and are secreted by cells missing MPR 46 and/or MPR 300 were analyzed. The structure of these oligosaccharides should provide information whether, in vivo, the two MPRs prefer distinct sets of phosphorylated oligosaccharides.
Phosphorylation of Procathepsin DTo analyze the phosphorylation of cathepsin D at its two glycosylation sites, procathepsin D from secretions of MPR-deficient MEFs was utilized. This material represents more than 90% of newly synthesized procathepsin D, and its glycosyl moieties are not modified by lysosomal hydrolases.
Analysis of endo-H-releasable oligosaccharides (more than 90% at
either site) revealed an asymmetric phosphorylation pattern. More than
90% of the oligosaccharides at sites I and II were phosphorylated, but
oligosaccharides with two phosphate groups were restricted to site II.
About 60% of the procathepsin D polypeptides contain in their carboxyl
lobe an oligosaccharide with two phosphomonoester groups in combination
with monophosphorylated oligosaccharides in their amino lobe. The
remaining 40% of procathepsin D contain a monophosphorylated
oligosaccharide in either lobe. Phosphodiesters were recovered only in
monophosphorylated oligosaccharides, suggesting that presence of the
second phosphate group favors the interaction of the uncovering
-N-acetylglucosaminidase with phosphorylated oligosaccharides.
Preferred phosphorylation of specific N-glycosylation sites
has been observed earlier for the - and
-subunits of
-hexosaminidase (21, 22),
-glucuronidase (23, 24), and
arylsulfatase A (25). Human cathepsin D expressed in frog oocytes was
shown to be enriched at the carboxyl lobe in oligosaccharides with two phosphates and at the amino lobe in oligosaccharides with one phosphate
(18). This indicates that the mechanisms controlling the transfer of
either one or two N-acetylglucosamine 1-phosphate groups by
the phosphotransferase onto oligosaccharides at sites I and II of
procathepsin D are conserved between mouse and frog.
To answer the question of whether MPR 46 or MPR 300 interact with subpopulations of lysosomal proteins that differ in their phosphorylation, the oligosaccharides of procathepsin D in secretions from primary MEF that lack either MPR 46 or MPR 300 or both were analyzed. Primary MEF have the advantage of expressing physiological levels of the remaining MPR but have the disadvantage of being genetically not identical. These cell lines are derived from outbred mice with a C57 BL/6J and 129 SvJ background (9).
Analysis of the procathepsin D secreted by such cells indicated that loss of either MPR leads to a minor, but notable enrichment in the secretions of cathepsin D forms with two phosphomonoesters at glycosylation site II. In consideration of the different sorting efficiencies of MPRs 300 and 46 for procathepsin D, our results indicate that both receptors share the preference for procathepsin D forms with two phosphomonoesters at site II.
A similar analysis as for procathepsin D was performed for the bulk of lysosomal proteins. The latter were isolated from secretions of immortalized MPR-deficient MEF and such cells reexpressing either MPR 46 or MPR 300 (14). This had the advantage that lysosomal proteins were compared from cells with an identical genetic background except for the type of MPR. Moreover, the level of reexpression was deliberately chosen high to minimize the likeliness that sorting of lysosomal proteins was compromised by limiting receptor levels.
Also for the bulk of lysosomal proteins, a slight, but notable, preference for forms containing oligosaccharides with two phosphomonoesters was noted for both types of MPR. Again, the intermediate effect of MPR 46 expression on the frequency of oligosaccharides with two phosphomonoesters can be explained by its intermediate effect on the sorting efficiency for lysosomal proteins.
In a similarly designed study, Munier-Lehmann et al. (26) recently observed a preference of MPR 300 for the sorting of lysosomal proteins with oligosaccharides containing two phosphomonoesters. Different from the present study, a preferred interaction of MPR 46 with lysosomal proteins containing a single phosphomonoester was noted. At present, it is not possible to explain the variance between the two studies. The differences extend also to other parameters, such as the frequency of lysosomal proteins in the secretions of MEF and of oligosaccharides with two phosphomonoesters, for both of which significantly higher values were observed in this study.
Secretion of Lysosomal Proteins by MEF Expressing Physiological Levels of MPRs 46 and 300One of the unexpected observations made
in this study was the similarity of the phosphorylated oligosaccharides
in procathepsin D in the secretion of control MEF and MPR-deficient
MEF. The minor preference of the two MPRs for procathepsin D containing
oligosaccharides with two phosphomonoesters decreased the relative
frequency of these oligosaccharides at glycosylation site II from 68%,
in secretions that contain almost 90% of the newly synthesized
procathepsin D (MPR 300 MEF), to 57%, in secretions from
control MEF that contain less than 90% of the newly synthesized
procathepsin D due to MPR-dependent sorting. Thus, the
majority of procathepsin D, which escaped sorting via either MPR,
contains at site II oligosaccharides with two phosphomonoesters.
Furthermore, the oligosaccharide pattern at the glycosylation site I is
not affected by the MPR-dependent sorting of procathepsin
D. It appears unlikely, therefore, that the small fraction of
procathepsin D, which ends up in the secretions of control MEF, is
missorted due to a low affinity to MPR 46 and/or MPR 300. It is more
likely that most of this procathepsin D is secreted because it fails to
encounter a free receptor in the trans-Golgi network (TGN)
or is sorted via an MPR, but it is released from the receptor at a site
(e.g. early endosomes) from where it can exit to the
medium.
Previous studies have shown that both MPRs participate in general in the sorting of individual lysosomal proteins, albeit with variable efficiency (2, 9). Procathepsin D is an example of a lysosomal protein that is poorly sorted via the MPR 46 and efficiently sorted via the MPR 300. While until now it was assumed that preferential binding of a lysosomal protein to either MPR may be related to the structure of its Man-6-P recognition marker, this study demonstrates that structural differences of the recognition marker concerning the number of phosphate residues and their presence as a monoester- or diester-linkage cannot account for the MPR-dependent sorting efficiency.
The majority of procathepsin D forms that escape sorting by MPR 46 and/or MPR 300 contain, at site II, oligosaccharides with two phosphomonoester groups. Among the phosphorylated oligosaccharides, the latter have the highest affinity for MPRs 46 and 300. This makes it unlikely that the missorting of the procathepsin D, which is recovered in the secretions of the MEF expressing MPR 46 and/or MPR 300, is due to a low affinity of the phosphorylated oligosaccharides unless structural parameters not analyzed in this study are critical for the distinct affinity of diphosphorylated oligosaccharides in procathepsin D to MPRs. Such parameters are the structure of the underlying oligosaccharides and the position of the phosphorylated mannose residues within the oligosaccharides. An alternative possibility is that the polypeptide backbone of procathepsin D, rather than its phosphorylated oligosaccarides, determines its distinct affinities to the two MPRs. For procathepsin L, a negative modulation of the affinity of its phosphorylated oligosaccharides by protein determinants has been reported. Mouse procathepsin L contains a fairly homogenous population of phosphorylated oligosaccharides with two phosphomonoesters. While native or denatured procathepsin L interacts poorly with MPR 300, its oligosaccharides show high affinity binding to MPR 300 (16). The polypeptide backbone may modify the affinity by interacting with the phosphorylated oligosaccharides themselves or with the MPR. It remains, however, to be demonstrated that the polypeptide backbone of a lysosomal protein such as procathepsin D can regulate the affinity of its phosphorylated oligosaccharides in a receptor-type-dependent manner.