2 Institut für Physiologische Chemie, Universität Bonn, Bonn, Germany; 3 Department of Pediatrics, Division of Neonatal Intensive Care, Gent University Hospital, Gent; and 4 Department of Pediatrics, Division of Neurology and Metabolic Diseases, Gent University Hospital, Gent
Received on February 18, 2001; revised on March 15, 2002; accepted on March 18, 2002
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Abstract |
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The human glucosidase I gene contains four exons separated by three introns with exon-4 encoding for the large 64-kDa catalytic domain of the enzyme. The two base mutations giving rise to substitution of Arg486 by Thr and Phe652 by Leu both reside in exon-4, consistent with their deleterious effect on enzyme activity. Incorporation of either mutation into wild-type glucosidase I resulted in the overexpression of enzyme mutants in COS 1 cells displaying no measurable catalytic activity. The Phe652Leu but not the Arg486Thr protein mutant showed a weak binding to a glucosidase Ispecific affinity resin, indicating that the two amino acids affect polypeptide folding and active site formation differently.
Key words: CDG type II/genomic DNA/glucosidase I deficiency/glycoprotein processing/sialotransferrin
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Introduction |
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Given the very complex nature of the N-glycosylation pathway, it is not surprising that genetic defects resulting in aberrant N-glycan chain structures have a dramatic impact on many intra- and extracellular functions. Several congenital disorders of glycosylation (CDGs; previously known as carbohydrate-deficient glycoprotein syndromes) have been identified that can be attributed to individual enzyme defects in the biosynthesis of N-glycoproteins (Marquardt and Freeze, 2001; Schachter, 2001
). The CDGs are multisystem diseases, often associated with delayed development and neurological dysfunction up to and including severe mental retardation, as well as with dysfunction of organs or the endocrine and coagulation system. A recent definition classifies the CDGs into two groups: type I CDGs comprise defects for enzymes catalyzing formation of dolichol-PP-activated GlcNAc2-Man9-Glc3 and its transfer by oligosaccharyltransferase (OST) on to protein, whereas type II CDGs include defects for enzymes involved in the processing of the asparagine-linked oligosaccharide precursor to its mature structure (Participants of the First International Workshop on CDGS, 2000).
We have previously reported on a novel type of CDG (type IIb) in a neonate that was shown to be caused by a deficiency of processing glucosidase I (De Praeter et al., 2000). The clinical course of the disease was progressive and characterized by hepatomegaly, hypoventilation, feeding problems, seizures, and fatal outcome at 74 days after birth. The patient was compound-heterozygous for two mutations in the glucosidase I gene with a G
C transition in the maternal allele and a T
C transition in the paternal allele, resulting in the substitution of arginine-486 by threonine and phenylalanine-652 by leucine, respectively. Each substitution gave rise to an inactive enzyme protein. In this article, we study the functional and cellular consequences associated with this glucosidase I deficiency in cultured fibroblasts of the patient, including potential effects on other processing enzymes in the glycosylation pathway and on the structure of N-linked glycans.
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Results |
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High-performance liquid chromatography (HPLC) analysis of the endo Hsusceptible [3H]glycan fraction obtained from control fibroblasts indicated a range of high-mannose oligosaccharides from Man5-GlcNAc to Glc1-Man9-GlcNAc, with the Man96-GlcNAc structures being in the majority (Figure 1A). The relative amount of Man9-GlcNAc, Man8-GlcNAc, Man7-GlcNAc, and Man6-GlcNAc was estimated to be 23%, 27%, 19%, and 22%, respectively, with only 6% of Man5-GlcNAc and 3% of Glc1-Man9-GlcNAc, based on the total number of mannose residues (Figure 1E). An identical pattern of high-mannose intermediates was found after endo H treatment of the [3H]glycoprotein fraction isolated from fathers (Figure 1B and 1E) and mothers fibroblast cells (Figure 1C and 1E). By contrast, the [3H]oligosaccharide pattern derived from N-glycoproteins synthesized by the patients fibroblasts differed, in particular, by containing two larger species (Figure 1D; Pk-2 and Pk-3) as well as an increased proportion of an intermediate that was eluted from the column in the position of Glc1-Man9-GlcNAc (Pk-1). Apart from these larger compounds, however, 66% of the high-mannose glycans were converted to Man95-GlcNAc. Furthermore, the relative ratio of these intermediates to one another was similar to that seen in control cells and fibroblast cells from both parents (Figure 1E).
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Immunoblot analysis of glucosidase I in fibroblasts
Aliquots of detergent extracts prepared from cultured fibroblasts of the parents, the patient, and a healthy individual were subjected to sodium dodecyl sulfatepolyacrylamide gel electrophoresis (SDSPAGE), followed by immunoblotting using a polyclonal antibody against glucosidase I for detection. The results in Figure 4 show that the antiglucosidase I antibody stained a 95-kDa protein, identical in molecular mass to that of human glucosidase I overexpressed in COS 1 cells (panel A, lane 1) with a similar staining intensity for control (lane 2) and for maternal fibroblast cells (lane 4), whereas the immunoreaction was markedly reduced in cell homogenates from fibroblasts of the patient and the father (lanes 3 and 5). This suggests that the inactive form of glucosidase I, encoded for by the paternal allele and containing the F652L mutation, appears to be less stable than the R486T mutant protein encoded for by the maternal allele. This difference in antibody response is unlikely to be caused by unequal protein loading of the gel as shown by the observation that under identical loading conditions immunostaining of the glucosidase II- subunit was similar in all cell samples (panel B, lanes 25) (Hentges and Bause, 1997
).
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Binding of glucosidase I mutants to CP-dNM-Sepharose
The two inactive R486T and F652L protein mutants were tested for their ability to bind to a glucosidase Ispecific affinity resin; this resin contained N-5-carboxypentyl-1-deoxynorjirimycin covalently attached to AH-Sepharose (CP-dNM-Sepharose). CP-dNM-Sepharose has previously been shown to bind glucosidase I specifically, allowing efficient purification of the enzyme from calf and pig liver (Hettkamp et al., 1984; Bause et al., 1989
). The binding experiments were carried out batchwise by adding the affinity resin to the detergent extracts prepared from transfected COS 1 cells. After 12 h, the affinity resin was separated by centrifugation and bound enzyme protein eluted with 100 mM dNM in binding buffer. Aliquots of the detergent extracts before and after affinity binding, as well as the dNM eluate, were then analyzed by immunoblotting.
The results, summarized in Figure 7, show that wild-type glucosidase I as well as the inactive R486T and F652L enzyme mutants were overexpressed efficiently (panel A, lanes 13). After CP-dNM-Sepharose treatment the supernatant was found to be depleted significantly in wild-type glucosidase I (panel B, lane 1), whereas the amounts of both the R486T and F652L proteins were not severely reduced (lanes 2 and 3). This shows that the catalytically active and inactive enzyme species must differ substantially in their affinity for the CP-dNM-Sepharose. As expected, the wild-type enzyme could be eluted from the affinity resin by 1-dNM (panel C, lane 1), whereas the F652L protein was essentially not detectable in the dNM eluate fraction (panel C, lane 3). By contrast, a specific 95-kDa protein band was observed on the immunoblot in case of the R486T mutant, indicating that this protein does have some affinity for CP-dNM-Sepharose (panel C, lane 2). Thus the R486T mutation interfers less severely with active site structure than does the F652L mutation.
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Discussion |
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The observed increase in endo-1,2-mannosidase activity indicates that the glucosidase I- and endo-
1,2-mannosidase-mediated pathways are not operating independently. It seems rather that their individual processing capacity may be up- or down-regulated depending on the particular situation within the cell. In contrast to the observed differences for endo-
1,2-mannosidase, neither the activity of OST nor the activities of other processing enzymes downstream from the glucosidase I block (including glucosidase II and Golgi-Man9-mannosidase), were affected in the patients fibroblasts. These data, together with the structural information provided by the endo H/PNGase F digestion experiments, lend support to the supposition that, independently of the glucosidase I deficiency, relatively "normal" N-glycosylation by OST, as well as further remodeling of the Glc3-Man9-GlcNAc2 precursor to cell-specific glycan structures, should take place in the patients fibroblasts as well as in control or parental cells; this will occur as long as the glucose residues are removed by endo-
1,2-mannosidase. It is not surprising, therefore, that the serum sialotransferrin pattern determined by IEF was found to be normal in the patient.
The presence in the endo Hsusceptible fraction of approximately 16% N-linked glycans containing Glc3 indicates on the other hand that endo-1,2-mannosidase is not capable of fully compensating for the glucosidase I defect. Several mechanisms could be used to explain this observation: (1) the processing capacity of endo-
1,2-mannosidase is (despite a two- to threefold increase) still too low to allow complete precursor degradation (see incubation times in Figure 3D and F); (2) the N-glycoproteins that still contain Glc3 are not recognized and accepted as substrates; and (3) the N-glycoprotein fraction is retained in the ER and thus is not accessible to endo-
1,2-mannosidase, which is located in the Golgi (Lubas and Spiro, 1987
; Zuber et al., 2000
). This spatial restriction obviously does not hold for the bulk of N-glycoproteins in the patients fibroblasts, which have acquired correctly processed N-glycan chains. Transport of Glc3-Man9-GlcNAc2-containing N-glycoproteins to the Golgi and removal of the Glc3-unit in the Golgi would imply that this N-glycoprotein fraction is not subject to the ER-resident quality control system (Ellgaard and Helenius, 2001
). This suggests that the proportion of cellular N-glycoproteins, processed by the ER system, is smaller than generally expected. It should be noted, however, that these conclusions are derived from structural and enzymatic data determined in fibroblast cells and may not necessarily reflect the situation in other cell types. Recent studies using various cell lines showed that utilization of the endo-
1,2-mannosidase-mediated deglucosylation route was cell typespecific with catalytic activity differing over a surprisingly wide range (Karaivanova et al., 1998
; Dong et al., 2000
).
The endo-1,2-mannosidase-catalyzed deglucosylation pathway fails to explain the occurence of Man9-GlcNAc2 in the endo Hsusceptible glycan fraction from the patient, suggesting that this intermediate may be generated by the concerted action of glucosidase I and II. This seems rather unlikely, however, because we were unable to detect glucosidase I activity in the patients cell extracts. Also, neither the R486T nor the F652L glucosidase I protein mutant were found to display measurable glucosidase I activity when overexpressed in COS 1 cells. Thus deglucosylation of Glc3-Man9-GlcNAc2 or formation of Man9-GlcNAc2 may occur by an as-yet-unknown mechanism. A likely explanation is that OST transfers not only natural Glc3-Man9-GlcNAc2 but also nonglucosylated or Glc21-containing Man9-GlcNAc2 structures, as observed in lower eukaryotes and mammalian cells (Parodi, 2000
; Romero and Herscovics, 1986
). Also, it is possible that Man8-GlcNAc2 generated by endo-
1,2-mannosidase may be subject to remannosylation as part of a quality control mechanism for protein folding in the Golgi. This would be comparable to the de-/reglucosylation system in the ER but involving
1,2-specific mannosidases and mannosyltransferases as central components (Ellgaard and Helenius, 2001
).
Glucosidase I is an ER-resident type II membrane protein containing a short cytosolic tail, a highly hydrophobic transmembrane sequence and a large catalytic domain directed towards the lumen. The two base mutations in the glucosidase I gene resulting in the expression of inactive enzyme proteins are located within exon-4, encoding for the catalytic domain of the enzyme. Both the substitution of Arg486 by Thr and of Phe652 by Leu affect positions which are highly conserved in the glucosidase I polypeptide, pointing to the functional significance of these regions for catalysis. Several reasons can be put forward to explain loss of catalytic activity: (1) both amino acid substititions located in the 64-kDa domain of the glucosidase I protein, interfere with polypeptide folding; or (2) arginine-486 and/or phenylalanine-652 are directly involved in substrate binding and/or catalysis. The observation that the glucosidase I mutant carrying the Arg486-Thr substitution maintained some affinity for CP-dNM-Sepharose indicates that substrate binding is less affected for this mutation than for the Phe652-Leu mutation. Although a direct involvement of Arg486 and Phe652 in substrate binding and/or catalysis cannot be excluded by these data, it appears more likely that failure of the glucosidase I chain to adopt its native conformation may be the key for the loss of activity in the mutants. The weak binding of the Arg486-Thr glucosidase I mutant to the affinity resin shows, on the other hand, that this protein is still able to recognize the affinity ligand. It may also have residual catalytic activity responsible for the occurrence of Man9-GlcNAc2 in the high-mannose oligosaccharide fraction, although we have been unable to reliably measure any activity given the high endogenous level for glucosidase I in COS 1 cells.
Our data show that the endo-1,2-mannosidase-dependent deglucosylation pathway in the patient is able to bypass the glucosidase I defect to a considerable extent. The observation that
16% of N-linked glycans appear as Glc3 intermediates indicates, however, that sequential deglucosylation by glucosidase I and II in the ER is essential for the oligosaccharide maturation of certain N-glycoproteins. This highlights the functional significance of the glucosidase I enzyme for normal development and life.
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Materials and methods |
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Cell culture and COS 1 cell transfection
Fibroblast cells and COS 1 cells were grown at 37°C and 5% CO2 as monolayer cultures in Dulbeccos modified Eagle medium supplemented with 10% fetal bovine serum, 50 U/ml penicillin, and 100 µg/ml streptomycin. Transfection of COS 1 cells with the glucosidase Ispecific vector constructs was carried out using the DEAE-dextran/chloroquine method (Ausubel et al., 1987).
[3H]Mannose labeling and structural analysis of N-linked [3H]glycans
Fibroblast cells were grown on 100-mm culture dishes. After the cells had reached 60% confluency, 1 mCi [3H]mannose (specific activity 26 Ci/mmol) was added to the medium. The cells were cultured for a further 24 h, harvested by scraping, and washed several times with phosphate buffered saline to remove excess [3H]mannose. The cell pellets were then taken up in chloroform/methanol/water (3/2/1 by volume) to precipitate the [3H]labeled glycoproteins, followed by centrifugation for 5 min at 1000 x g (Wessel and Flügge, 1984
). The precipitate at the chloroform/water interface containing the [3H]glycoprotein fraction was removed and after reextraction solubilized by heating in 2% SDS/water at 80°C for 10 min. Aliquots of the solution were then diluted with 50 mM citrate buffer, pH 5.5, and with 50 mM sodium phosphate buffer, pH 7.5, followed by incubation with endo H and PNGase F, respectively (Bieberich and Bause, 1995
). After 12 h at 25°C, the reaction mixtures were made biphasic by the addition of chloroform/methanol/water (3/2/1 by volume). Released [3H]oligosaccharides, which partitioned into the aqueous upper phase, were measured by scintillation counting. The [3H]labeled high-mannose intermediates obtained after endo H cleavage were separated by HPLC on a NucleosilR-NH2-column as previously described (Schweden et al., 1986
; Bause et al., 1992
).
For structural characterization of the Pk-3, Pk-2, and Pk-1 glycans present in the endo Hsusceptible [3H]oligosaccharide fraction from the patient, aliquots of the purified compounds were incubated either with detergent extracts prepared from COS 1 cells overexpressing glucosidase I and II or with detergent extracts prepared from pig liver microsomes (endo-1,2-mannosidase). Incubations were carried out in the presence of either 2 mM 1-deoxymannojirimycin (glucosidase I/II assay) or in the presence of 2 mM 1-dNM and 1 mM 1-deoxymannojirimycin (endo-
1,2-mannosidase assay) to prevent nonspecific substrate degradation (Hettkamp et al., 1984
; Bause and Burbach, 1996
).
Enzyme assays
Cultured fibroblasts were taken up in 50 mM sodium phosphate, pH 6.8, containing 1% Thesit. After disruption with ultrasound, the suspensions were kept on ice for 30 min and then centrifuged at 5000 x g for 10 min. The activity of -glycosidases was measured by incubating 1040-µl aliquots of the resulting supernatants with [14C]labeled oligosaccharide (see methods discussed later). Reactions were run at 37°C and stopped at given times by the addition of an equal volume of acetic acid, followed by separation of the cleavage products by paper chromatography using acetic acid/methanol/water (Hettkamp et al., 1984
; Bause and Burbach, 1996
). The activities of glucosidase I, glucosidase II, and Man9-mannosidase were measured using 500 cpm of [14C]Glc3-Man9-GlcNAc2, [14C]Glc1-Man9-GlcNAc2, and [14C]Man5-GlcNAc2, respectively; the
-mannosidase assay was supplemented with 1 mM CaCl2 (Schweden and Bause, 1989
). Endo-
1,2-mannosidase activity was determined using 2000 cpm of [14C]Glc3-Man9-GlcNAc2 in the presence of 1 mM ethylenediamine tetra-acetic acid and 2 mM 1-dNM to inhibit nonspecific degradation of [14C]Glc3-Man9-GlcNAc2 by glucosidase I and II (Bause and Burbach, 1996
).
OST activity was measured using fibroblast cells suspended in 50 mM TrisHCl buffer, pH 7.5, containing 500 mM sodium acetate, 10 mM MnCl2, 1 M sucrose, and 0.8% Triton-X100. After centrifugation, 40-µl aliquots of the detergent extract were added to 60 µl lysis buffer (see procedure previously dicussed) containing 2000 cpm of Dol-PP-[14C]GlcNAc2 and 1.7 mM acceptor tripeptide (N-benzoyl-Asn-Gly-Thr-NHCH3). Reactions were carried out at 25°C and stopped at given times by the addition of 500 µl methanol. Isolation and quantification of [14C]glycopeptides were done as described previously (Bause et al., 1995).
Binding of glucosidase I mutants to CP-dNM-Sepharose
COS 1 cells grown to 60% confluency were transfected with 15 µg pSV-GIwt, pSV-GIR486T, and pSV-GIF652L vector DNA using the DEAE-Dextran/chloroquine method. Forty-eight hours after transfection cells were harvested, washed with phosphate buffered saline, and solubilized in 500 µl lysis buffer containing 200 mM sodium phosphate, pH 6.5, 1% Triton-X100, and 10 µM phenylmethanesulfonylfluoride. The detergent extracts were centrifuged at 5.000 gav for 5 min and the resulting supernatants incubated with 30 µl of CP-dNM-Sepharose previously equilibrated in lysis buffer (Hettkamp et al., 1984
). After stirring the suspension for 12 h at 4°C, the affinity resin was removed by centrifugation and washed several times with 10 ml lysis buffer. Bound glucosidase I protein was then eluted batchwise by treatment of the affinity resin for 3 h at 4°C with 200 µl lysis buffer containing 100 mM 1-dNM. Aliquots of the detergent extracts before and after affinity binding, as well as of the dNM eluate, were then analyzed by SDSPAGE and immunoblotting.
RT-PCR
Total RNA isolated from cultured fibroblasts using the acidic phenol procedure (Chomczynski and Sacchi, 1987), was incubated with DNase I, followed by extraction with phenol/chloroform (1:1 by volume), chloroform, and precipitation by addition of iso-propanol. The RNA was taken up in water previously treated with diethylpyrocarbonate and its quality checked by gel electrophoresis. First-strand cDNA was synthesized from 1 µg of RNA by using the Omniscript reverse transcriptase. Aliquots of the incubation mixture were then subjected to PCR amplification using the platinum Taq polymerase. Amplified cDNA fragments were separated by gel electrophoresis and either visualized by staining with ethidium bromide or quantitated by hybridization with radiolabeled cDNA probes after blotting onto nylon membranes. The following sense/antisense primer combinations were used for cDNA synthesis and PCR amplification: glucosidase I, ggagagtgactgtagagc/ggtccagaagacattgtag; endo-
1,2-mannosidase, gtgggcccaggatacatagatac/ttatgaaacaggcagctggcgatc; glyceraldehyde-3-phosphate-dehydrogenase, caagaccccttcattgacctc/taagcaggtggtggtgcagga.
Screening for human genomic clones
A human placenta genomic DNA library (in EMBL3) was screened for by plaque hybridization with a 728-bp cDNA fragment, previously synthesized by PCR amplification using the glucosidase Ispecific full-length cDNA (Kalz et al., 1995). One glucosidase Ispecific lambda clone was isolated containing a
15-kb insert that was processed further by digestion with either BamHI and NcoI, BamHI and HindIII, or EcoRI. Resulting restriction fragments were cloned into pUC-BM 20 and glucosidase Ispecific subclones screened for using colony hybridization, followed by sequencing.
Vector construction and generation of glucosidase I mutants
The full-length cDNA encoding human glucosidase I was subcloned into the mammalian expression vector pSV.SPORT1 using common restriction sites (Kalz et al., 1995). The recombinant vector (pSV-GIWT) contained the complete 2505-bp ORF of glucosidase I as well as 196 bp and 130 bp from the noncoding 3'- and 5'-sequence, respectively. Using pSV-GIWT as the template, vector constructs containing either the G
C mutation at position 1446 of the ORF (pSV-GIR486T) or the T
C mutation at position 1974 (pSV-GIF652L) were generated by mutagenesis following the Amersham Bioscience manual. Target mutagenic primers of 167 bp and 139 bp length for mutant DNA synthesis were generated by PCR amplification using the sense/antisense primer combinations ctggattgggacggagcagatactg/ctctagcatatgggctacag and gagctaggagtccttgcagactttg/gactgacatagccaagagc, respectively. Base exchanges (shown in boldface type) were verified by sequencing.
General methods
Library screening, subcloning, PCR amplification, and other standard techniques were performed as described elsewhere (Ausubel et al., 1987; Sambrook et al., 1989
; White, 1993
). SDSPAGE, western blotting, and immunoblotting were carried out as detailed by Laemmli (1970)
, Blake et al. (1984)
, and Schweden and Bause (1989)
. [14C]Glc31-Man9-GlcNAc2, [14C]Man5-GlcNAc2, Dol-PP-[14C]GlcNAc2, and N-benzoyl-Asn-Gly-Thr-NHCH3 were synthesized as described by Hettkamp et al. (1982)
, Schweden et al. (1986)
, and Bause et al. (1995)
. Polyclonal antibodies against glucosidase I and glucosidase II were prepared as detailed by Bause et al. (1989)
and Hentges and Bause (1997)
. Synthesis of CP-dNM and preparation of CP-dNM-Sepharose followed the procedures described by Hettkamp et al. (1984)
.
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Acknowledgments |
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Abbreviations |
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Footnotes |
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References |
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