(Received for publication, April 15, 1997, and in revised form, May 20, 1997)
From the Department of Biochemistry and Cell Biology, Institute for Cell and Developmental Biology, State University of New York, Stony Brook, New York 11794-5215
O-Linked fucose is an unusual form of
glycosylation recently shown to modify the hydroxyls of serine or
threonine residues at a strict consensus site within epidermal growth
factor-like domains of several serum proteins. Here we demonstrate that
Chinese hamster ovary cells modify numerous proteins with
O-linked fucose and that the fucose is elongated on
specific proteins. We have identified at least two forms of
O-linked fucose elongation in Chinese hamster ovary cells:
a disaccharide (Glc1,3Fuc) and a larger oligosaccharide of
indeterminate structure. Interestingly, it appears that the level of
monosaccharide accumulates in the cells over time whereas the
disaccharide does not. Analysis of the O-linked
fucose-containing saccharides on individual proteins revealed that some
proteins are modified with the monosaccharide only, whereas others are
modified with monosaccharide and disaccharide, or monosaccharide and
oligosaccharide. These results suggest that elongation of the
O-linked fucose monosaccharide is a protein-specific phenomena. The presence of elongated O-linked fucose
moieties suggests that a novel glycosylation pathway exists in
mammalian cells with O-linked fucose as the core.
In the past few years, a number of proteins have been shown to be modified with the monosaccharide L-fucose on the hydroxyls of serine or threonine residues (O-linked fucose) (1). Urokinase-type plasminogen activator was the first protein identified with this form of glycosylation (2) followed quickly by tissue-type plasminogen activator (3), factor VII (4), factor XII (5), and factor IX (6). Through comparison of the sites of glycosylation from these five proteins, a consensus sequence (CXXGG(S/T)C, where S/T is the modified residue) for the addition of O-linked fucose was proposed (7). Interestingly, in all cases this motif occurs within an epidermal growth factor-like (EGF)1 domain. Although these five proteins are all serum proteins involved in clot formation or dissolution, data base searches have revealed that many other types of proteins also contain this consensus sequence (1, 7).
Although L-fucose can be found internally linked in
polysaccharides from plants and algae, in mammalian systems it is
normally thought of as a terminal modification. Nonetheless, over 20 years ago the amino acid fucoside Glc1,3Fuc
1-O-Ser/Thr
was isolated from human urine, demonstrating that fucose residues can
be found internally linked in mammalian systems (8, 9). More recently it was shown that the O-linked fucose moiety on factor IX is
elongated into a tetrasaccharide with the structure
NeuAc
2,6Gal
1,4GlcNAc
1,3Fuc
1-O-Ser (7). To date,
factor IX is the only protein reported to be modified with this
tetrasaccharide structure and the only mammalian protein identified
with an elongated fucose of any kind.
To study O-linked fucose in mammalian cells, we have used a
Chinese hamster ovary (CHO) cell line, Lec1, which is deficient in the
enzyme, N-acetylglucosaminyltransferase I (10, 11). These
cells are unable to synthesize complex or hybrid-type
N-linked glycans. Since the addition of fucose to
N-linked glycans was believed to occur only on complex or
hybrid-type chains, we predicted fucose would be incorporated only into
O-linked structures in these cells. Surprisingly, we found
that small oligomannose N-glycans (Man4-Man5) were labeled with fucose on the
core GlcNAc in these cells suggesting that the core
1,6-fucosyltransferase does have some affinity for these structures
(12). Nonetheless, the incorporation of fucose into
N-glycans was greatly reduced and allowed for a better
observation of O-linked fucose structures. Stults and
Cummings (13) have utilized this same cell type for studying
O-linked fucose, demonstrating that several proteins are
modified with O-linked fucose monosaccharide in these
cells.
We report here that CHO cells not only modify several endogenous
proteins with O-linked fucose but that the
O-linked fucose becomes elongated on a subset of the
proteins. The major form of elongation is a simple disaccharide
consisting of a -linked glucose at the 3-position of the
O-linked fucose (Glc
1,3Fuc), identical with the structure
found previously on amino acid fucosides (8, 9). A larger
oligosaccharide also appears to exist, although in smaller and variable
amounts. Over 15 proteins from CHO cells appear to be modified with
O-linked fucose saccharides, and the elongation of
O-linked fucose appears to be a protein-specific event. The
presence of these elongated forms of O-linked fucose suggests the presence of a novel glycosylation pathway in mammalian cells with several potential end points all containing
O-linked fucose as the core sugar.
Lec1 cells were developed by Dr. Pamela Stanley
(11, 14). They were obtained from ATCC and grown as described (12). L-[6-3H]Fucose (86.5 Ci/mmol) was from DuPont
NEN. -Glucosidase (sweet almond),
-hexosaminidase (jack bean),
and
-galactosidase (bovine testes) were from Sigma. Peptide
N-glycosidase F (PNGase F) was purified from the culture
filtrate of Flavobacterium menigisepticum as described (15).
Alditol sugar standards were prepared by reduction of the corresponding
sugar with sodium borohydride as described (16). The
-linked
glucosylfucose standards (Glc
1,2Fuc, Glc
1,3Fuc, and Glc
1,4Fuc)
were synthesized, characterized, and generously provided by Dr. Khushi
Matta (Roswell Park Memorial Institute, Buffalo,
NY).2 All other reagents were of the
highest quality available.
For short term labeling, cells were grown and radiolabeled essentially as described (12). For long term labeling, cells were incubated for 24 h in the presence of medium containing 50 µCi/ml [6-3H]fucose. For pulse-chase studies, cells were radiolabeled for 1 h in the presence of 100-300 µCi/ml [6-3H]fucose. The cells were collected by centrifugation, washed once with Tris-buffered saline (10 mM Tris-HCl, pH 7.5, 0.15 M NaCl), and resuspended in media containing 10 mM non-radioactive fucose. The radiolabeled cells were then incubated for various chase times before washing and lysing.
Lysis of Labeled Lec1 CellsRadiolabeled cells were collected by centrifugation and washed three times with cold Tris-buffered saline. Cells were lysed by addition of lysis buffer (Tris-buffered saline containing 1% (w/v) Nonidet P-40 and protease inhibitor mixtures I and II (17)) and incubated for 1 h with rocking at 4 °C. The lysate was clarified by centrifugation (12,000 × g, 10 min, 4 °C). The unincorporated radiolabel was separated from the protein fraction on a Sephadex G50-150 column (1 × 30 cm) developed in 50 mM ammonium formate containing 0.1% sodium dodecyl sulfate.
Chromatographic Analysis of SugarsN-Linked
oligosaccharides were removed from the
[6-3H]fucose-labeled proteins prior to analysis of the
O-linked sugars by digestion with PNGase F as described
(12). The O-linked sugars were released from proteins by
alkali-induced -elimination as described (12). The released
O-linked sugar alcohols were size fractionated on a Superdex
peptide column (Pharmacia Biotech Inc.) using partially hydrolyzed
dextran as size standards (18). High pH anion-exchange chromatography
(HPAEC) was performed on a Dionex DX300 HPLC system equipped with
pulsed amperometric detection (PAD-2 cell). Samples were
chromatographed on a CarboPac MA-1 column (Dionex Corp.) at 0.4 ml/min
using the following gradient: 0-11 min, 0.1 M NaOH; 11-21
min, 0.1-0.7 M NaOH; 21-40 min, 0.7 M NaOH.
Radioactive samples were mixed with standards (1 nmol each of fucitol,
fucose, and glucose or the disaccharide standards Glc
1,2fucitol,
Glc
1,3fucitol, and Glc
1,4fucitol) prior to injection. Fractions
(0.2-0.5 min) were collected and monitored for radioactivity by
scintillation counting. Standards were followed by pulsed amperometric
detection.
The saccharides were hydrolyzed in 2 M trifluoroacetic acid at 100 °C for 2 h. The hydrolyzed samples were then dried in a Speed Vac evaporator (Savant) and resuspended in water prior to analysis by HPAEC.
Exoglycosidase Digestions-Glucosidase digestions were
performed by incubating samples in
-glucosidase digestion buffer (50 mM sodium acetate, pH 5.0, 0.1 M NaCl, 0.1 mM zinc sulfate, 10 mg/ml bovine serum albumin) with
-glucosidase (25 units/ml) overnight at 37 °C. Mock digestions lacking enzyme were performed as a control. To stop the digestion, the
sample was heated to 100 °C for 5 min. Digestions with
-galactosidase and
-hexosaminidase were performed as described
(12). Digested samples were diluted into water and analyzed by HPAEC as
described above.
[6-3H]Fucose-labeled proteins (100 µg/lane), either treated with PNGase F or mock treated, were
separated on 8% SDS-PAGE (19), stained with Coomassie Blue, and
fluorographed. Additional samples (6 × 100 µg) of PNGase
F-treated [6-3H]fucose-labeled proteins were separated on
the same gel. After electrophoresis, the lanes containing these samples
were cut into 2-mm horizontal slices, and the protein was extracted
from the gel slices by incubation overnight in 1% SDS, 1%
2-mercaptoethanol at room temperature. The eluted proteins were
concentrated by acetone precipitation (8 volumes, 20 °C,
overnight) and analyzed for O-linked saccharides as
described above.
Previously, we have shown that the majority (68%) of
the [3H]fucose incorporated into proteins of Lec1 cells
could be released by digestion with PNGase F (12). Subsequent analysis
showed these glycans to be core-fucosylated oligomannose-type
N-linked glycans of the Man4-Man5
size (12). The majority of the PNGase F-resistant
[3H]fucose could be released by alkaline-induced
-elimination, implying an O-linkage to the protein (12).
Analysis of the material released by
-elimination on a
calibrated Superdex sizing column revealed three radiolabeled species
(Fig. 1A, peaks MS, DS, and OS). MS represents a monosaccharide as it migrates at a
position slightly larger than 1 glucose unit. DS migrates at
approximately 2 glucose units, representing a disaccharide. OS is a
oligosaccharide migrating at a position larger than 10 glucose units.
The amount and migration position of the oligosaccharide species varied
with the labeling conditions (Fig. 1B) and the
preparation.
To determine which of the three species was linked to protein through
an O-linked fucose, each peak was analyzed for the presence of fucitol after acid hydrolysis. The sodium borohydride in the -elimination solution converts the reducing end sugar to the alditol
form (e.g. fucose to fucitol) after being released from the
protein. Therefore, fucose, which had been directly linked to protein
(as in O-linked fucose), would be converted to fucitol. All
other forms of fucose (terminal modifications) should remain unreduced
(fucose). Acid hydrolysis was performed to break the di- and
oligosaccharide species into monomers, and HPAEC was used to separate
fucose from fucitol. The monosaccharide comigrated with the fucitol
standard before and after acid hydrolysis, suggesting that this species
is derived from O-linked fucose (Fig.
2A). When the disaccharide was analyzed prior
to acid hydrolysis, it migrated at a unique position relative to
fucitol, fucose, and glucose (Fig. 2B). Acid hydrolysis of
the disaccharide converted all of the radioactivity to fucitol,
indicating that the disaccharide contains O-linked fucose
(Fig. 2C). Unhydrolyzed oligosaccharide was not recovered
from the HPAEC analysis, suggesting that it might be negatively
charged. This observation was supported by the analysis of
oligosaccharide material on QAE-Sephadex. The majority of the
oligosaccharide material bound to QAE-Sephadex and eluted with 70-140
mM NaCl (data not shown). Acid hydrolysis of the
oligosaccharide converted the majority of the radiolabel to fucitol,
again indicating that the oligosaccharide material contains
O-linked fucose (Fig. 2D). A small amount of
unreduced fucose is also recovered from the oligosaccharide fraction.
This may be due to a modification of the O-linked fucose
oligosaccharide with another fucose, or there may be some contaminants
with terminal fucose residues present in this fraction. Further work is
required to determine the structure(s) of the O-linked
fucose-containing saccharides in the oligosaccharide peak. Thus, all
three peaks from the Superdex column represent O-linked
fucose-containing saccharides: the monosaccharide, a disaccharide, and
an oligosaccharide.
The Disaccharide Is Glucose
We initially
suspected the disaccharide to be a precursor in the synthesis of the
known O-linked fucose tetrasaccharide on factor IX (7). If
this were the case, then the disaccharide would consist of an
O-linked fucose elongated with a -linked N-acetylglucosamine. Upon digestion with jack bean
-hexosaminidase, we observed no shift in migration of the
disaccharide (data not shown); we also did not observe a shift after
digestion with
-galactosidase. Surprisingly, when we subjected the
disaccharide to digestion with
-glucosidase, we observed a shift to
fucitol (data not shown) indicating that the disaccharide is fucitol
modified with a
-linked glucose.
In an effort to determine the exact structural identity of the
O-linked fucose-containing disaccharide, standards for the three possible configurations where glucose is -linked to
fucose were synthesized. The three disaccharide standards were
each reduced with alkaline borohydride, yielding
Glc
1,2fucitol, Glc
1,3fucitol, and Glc
1,4fucitol.
These alditol standards were analyzed by HPAEC as described under
"Experimental Procedures" and shown to migrate at unique positions
(Fig. 3). Analysis of the disaccharide from Lec1 cells
showed that it migrates exclusively with the Glc
1,3fucitol standard,
demonstrating that the glucose is linked to the third position of the
fucose.
The Disaccharide to Monosaccharide Ratio Decreases with Time
Although Stults and Cummings (13) also utilized Lec1 cells
to examine O-linked fucose, they did not observe the
disaccharide or oligosaccharide species. We believe that the difference
in our findings results mainly from a difference in labeling
conditions. Our initial studies were done on cells labeled for 3-5 h
with fairly high concentrations of [6-3H]fucose (100-300
µCi/ml). Stults and Cummings (13) labeled Lec1 cells under
equilibrium conditions (24 h, 10 µCi/ml). We examined incorporation
of [3H]fucose into the disaccharide under both
conditions. Interestingly, we observed a marked decrease in the amount
of labeled disaccharide relative to monosaccharide in the long term
labeling (compare Fig. 1B with Fig. 1A). This
suggests that the monosaccharide accumulates during the longer labeling
whereas the disaccharide does not. To more closely examine this
phenomenon, we labeled cells for 1 h with [3H]fucose
and then chased them with cold fucose for 0-5 h. Analysis of the
O-linked fucose saccharides clearly shows that the ratio of
disaccharide to monosaccharide decreases during the chase, consistent
with the idea that the monosaccharide accumulates whereas the
disaccharide does not (Fig. 4). Although the
oligosaccharide does not change significantly in amount between long
and short term labelings, it does appear to change in size (compare
Fig. 1, A and B). We are currently investigating
this phenomenon.
Lec1 Cells Synthesize Numerous O-Linked Fucose-modified Proteins Bearing Different Combinations of O-Linked Fucose Saccharides
We
next sought to begin identifying proteins in Lec1 cells that contain
these O-linked fucose modifications. Radiolabeled proteins
from Lec1 cells were treated with or without PNGase F and separated by
SDS-PAGE (Fig. 5A). The labeled bands that
remained after PNGase F treatment represent O-linked
fucose-containing proteins. Over 15 protein species can be identified
that appear to be modified with O-linked fucose saccharides.
Identical PNGase F-treated samples were separated on the same gel, the
gel was cut into 2-mm strips, the proteins were extracted, and each
fraction was analyzed for the presence of MS, DS, and OS by size
fractionation. As shown in Fig. 5, B-E, different proteins
contain different sugar structures. Some protein bands contained only
monosaccharide (Fig. 5C), whereas others contained both
monosaccharide and disaccharide (Fig. 5, D and
E), or monosaccharide and oligosaccharide (Fig. 5B). Interestingly, the DS-bearing proteins appeared to be
localized mainly to lower molecular weight species. Thus, the
elongation of O-linked fucose appears to be a
protein-specific phenomenon.
In this report we have demonstrated that CHO cells not only modify numerous proteins with O-linked fucose but that the O-linked fucose is elongated on a subset of these proteins. At least two forms of elongation occur in these cells: a disaccharide and an oligosaccharide. The elongation appears to be protein-specific since some proteins bear only monosaccharide, some monosaccharide and disaccharide, and some monosaccharide and oligosaccharide. In addition, the ratio of disaccharide to monosaccharide on proteins in these cells decreases over time.
We have identified the disaccharide as Glc1,3Fuc based on
sensitivity to
-glucosidase digestion and comigration of the
reduced,
-eliminated product with a Glc
1,3fucitol standard on
HPAEC. A disaccharide with this structure was originally reported as an
amino acid fucoside (Glc
1,3Fuc
1-O-Ser/Thr) isolated
from human urine over 20 years ago (8). Very little has been reported since then about the occurrence of this disaccharide on intact proteins. One report showed that a disaccharide tentatively identified as glucosylfucitol could be released by alkaline borohydride treatment of proteins from newborn rat kidney cells (20). Nonetheless, our data
demonstrate that CHO cells are capable of modifying O-linked fucose with a
-linked glucose in the 3-position. This is an
important finding in that several companies now use CHO cells to
produce genetically engineered proteins that are used clinically, some of which are known to be modified with O-linked fucose
(e.g. tissue-type plasminogen activator).
The observed change in the level of disaccharide relative to
monosaccharide over time could have several potential explanations. For
instance, it is possible that the change in ratio of disaccharide to
monosaccharide could be the result of the removal of the glucose residue by a novel processing -glucosidase activity. Alternatively, the disaccharide-modified proteins could be preferentially secreted from the cells. Another potential explanation is that the proteins modified with disaccharide turn over more rapidly than the proteins modified with monosaccharide. Finally, the disaccharide could be a
precursor to the oligosaccharide. Further work is necessary to test
these possibilities and determine an explanation for the disappearance
of the disaccharide.
The oligosaccharide reported here may be related to the tetrasaccharide found on factor IX, since preliminary results indicate that the oligosaccharide is negatively charged and therefore may contain sialic acid. Alternatively, the oligosaccharide may be a novel structure unrelated to the tetrasaccharide. As mentioned above, the oligosaccharide could result from elongation of the disaccharide, although further work needs to be done to analyze the relationship between these two structures. Work on the structure and composition of this oligosaccharide is under way.
The fact that the disaccharide and the oligosaccharide are found on discrete populations of proteins suggests there may be specific signals for the elongation of O-linked fucose on certain proteins. In such a model, an enzyme that adds a sugar to O-linked fucose would need to recognize the fucose as well as some protein determinant that directs the elongation. This paradigm is not without precedent, as both the lysosomal enzyme GlcNAc-1-phosphotransferase (21) and the glycoprotein hormone GalNAc transferase (22, 23) are examples of protein-specific glycosyltransferases that recognize specific protein motifs and the sugar to be modified. This finding of protein-specific elongation of O-linked fucose is consistent with the finding of the tetrasaccharide modification on factor IX and only monosaccharide on the other known O-linked fucose modified proteins. To our knowledge, no proteins containing the glucosylfucose disaccharide modification have been identified, although we have identified several potential candidates in CHO cells.
The identification of the various O-linked fucose-containing
saccharide structures has revealed an entirely new glycosylation pathway (see Fig. 6). The first step in the pathway is
the addition of O-linked fucose to a consensus sequence by
an O-fucosyltransferase (Fig. 6, see A). This
enzyme has recently been identified and was initially characterized
(24). Interestingly, it appears to require an intact EGF domain
containing the consensus site for efficient glycosylation to occur. For
some proteins, this is the end of the pathway. For others, the fucose
can be elongated on the 3-position by either a Glc or a GlcNAc. These
reactions are catalyzed by as yet undescribed enzymes: an
O-linked fucose 1,3-glucosyltransferase or an
O-linked fucose
1,3-N-acetylglucosaminyltransferase, respectively (Fig.
6, see B and C). Other yet to be identified forms
of elongation are also possible (indicated by the question marks). For instance, an unidentified, neutral,
O-linked fucose-containing structure ("TS" for
trisaccharide) was reported by Morton and Steiner (20) and may
represent an elongated form of the disaccharide or a novel
structure. The oligosaccharide we observed here may also result from
elongation of Glc
1,3Fuc, or it may be related to the
tetrasaccharide. For the GlcNAc
1,3Fuc-modified proteins the pathway
continues with the addition of galactose and sialic acid (presumably by
standard Golgi galactosyl- and sialyltransferases) to form the
tetrasaccharide structure represented on factor IX (7). The entire
pathway most likely occurs in the Golgi apparatus since there are
apparently no GDP-fucose transporters in the endoplasmic reticulum
(25). The O-linked fucose pathway appears to be widespread in biology. Proteins bearing O-linked fucose have been
reported from insects to humans (1, 7, 26).
Although a specific function has not yet been assigned to any of the O-linked fucose saccharides, several intriguing observations have been made in the past few years. First, two interesting studies have shown that O-linked fucose on the EGF domain of urokinase is necessary for a mitogenic/growth factor-like activity of the domain (27, 28). Growth factor domains lacking the fucose could bind to urokinase receptors but could not induce mitogenesis. These results suggest that the fucose is necessary for transmission of the mitogenic signal into the cell. Hajjar and Reynolds (29) have suggested that O-linked fucose within the EGF domain of tissue plasminogen activator plays a role in the serum half-life of the protein, although other workers have suggested that this is not the case (30). Also, the list of proteins that are predicted to be modified contains several cell surface receptors, which are involved in cell signaling and developmental regulation (7). Interestingly, some of these proteins have multiple O-linked fucose consensus sites (e.g. Notch-12 sites (31), Delta-6 sites (32), Jagged-4 sites (33)) and are known to interact with each other through their EGF domains (34). Modification of these domains with O-linked fucose saccharides may provide a means of modulating these interactions. Ultimately, the functional importance of O-linked fucose and its variations will become clearer as we learn more about this unusual form of glycosylation.
We thank Glenn Philipsberg, Kathleen Grove, and Dr. James Trimmer for critical reading and helpful discussions. We also thank Dr. Khushi Matta for the generous provision of disaccharide standards used in this study.