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J. Biol. Chem., Vol. 277, Issue 18, 16332-16339, May 3, 2002
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From the
Received for publication, December 20, 2001, and in revised form, February 25, 2002
VIP36, an intracellular lectin that recognizes
high mannose-type glycans (Hara-Kuge, S., Ohkura, T., Seko, A., and
Yamashita, K. (1999) Glycobiology 9, 833-839), was shown
to localize not only to the early secretory pathway but also to the
plasma membrane of Madin-Darby canine kidney (MDCK) cells. In the
plasma membrane, VIP36 exhibited an apical-predominant distribution,
the apical/basolateral ratio being ~2. Like VIP36, plasma membrane
glycoproteins recognized by VIP36 were found in the apical and
basolateral membranes in the ratio of ~2 to 1. In addition, secretory
glycoproteins recognized by VIP36 were secreted ~2-fold more
efficiently from the apical membrane than from the basolateral
membrane. Thus, the apical/basolateral ratio of the transport of
VIP36-recognized glycoproteins was correlated with that of VIP36 in
MDCK cells. Upon overproduction of VIP36 in MDCK cells, the
apical/basolateral ratios of both VIP36 and VIP36-recognized
glycoproteins were changed from ~2 to ~4, and the secretion of
VIP36-recognized glycoproteins was greatly stimulated. In contrast to
the overproduction of VIP36, that of a mutant version of VIP36, which
has no lectin activity, was of no effect on the distribution of
glycoproteins to apical and basolateral membranes and inhibited the
secretion of VIP36-recognized glycoproteins. Furthermore, the
overproduction of VIP36 greatly stimulated the secretion of a major
apical secretory glycoprotein of MDCK cells, clusterin, which was found
to carry at least one high mannose-type glycan and to be recognized by
VIP36. In contrast to the secretion of clusterin, that of a
non-glycosylated apical-secretion protein, galectin-3, was not
stimulated through the overproduction of VIP36. These results indicated
that VIP36 was involved in the transport and sorting of glycoproteins
carrying high mannose-type glycan(s).
Newly synthesized secretory and membrane proteins exit from the
ER1 in transport vesicles
targeted to the Golgi apparatus. Vesicular transport through the Golgi
is often accompanied by post-translational modifications, such as
glycosylation of cargo proteins until they have reached the
trans-Golgi Network. In the trans-Golgi Network, proteins are sorted into vesicles bound for different destinations including the plasma membrane, the endosome/lysosome, and secretory granules. The protein sorting has been one of the most interesting issues in the study of vesicular protein traffic processes, but its
molecular mechanisms remain largely unresolved.
It has been recently demonstrated that intracellular lectins play
important roles in vesicular transport: for example,
mannose-6-phosphate receptor (1) as a receptor recognizing the marker
for lysosomal enzymes, calnexin (2, 3) and calreticulin (4) as
molecular chaperones, and ERGIC-53 (5) possibly as a transport cargo receptor. ERGIC-53 is an intermediate compartment marker (6), and it is
identical to MR60, a mannose-specific membrane lectin (7) with a
carbohydrate-binding domain homologous to that of lectins of leguminous
plants (8). The N-terminal luminal domain of ERGIC-53, which includes
the carbohydrate-binding domain, has an amino acid sequence similar to
that of vesicular integral membrane protein of 36 kDa (VIP36) (9).
VIP36 has been originally isolated from MDCK cells as a component of
detergent-insoluble, glycolipid-enriched complexes containing apical
marker proteins (10), and it has been recently shown to exist in early
secretory pathway (11). In addition, we have shown that VIP36 has
lectin activity recognizing high mannose-type glycans containing over
seven mannose residues (12). These observations have implied that VIP36
is an intracellular lectin involved in the intracellular transport of
glycoproteins carrying high mannose-type glycan(s). In this
study, to address the function of VIP36, we reexamined the localization
of VIP36 and investigated the effect of overproduction of VIP36 and a
mutant VIP36 defective in lectin activity on the metabolism and
transport of VIP36-recognized glycoproteins in MDCK cells.
Cell Culture--
MDCK cells, strain II, were donated by Dr. M. Tashiro (National Institute of Infectious Diseases, Tokyo, Japan). MDCK
cells were maintained in minimum Eagle's medium supplemented
with 5% fetal bovine serum, and MDCK/VIP36 and MDCK/mVIP36 cells were cultured in the same medium containing 500 µg/ml G418 (Geneticin) (Invitrogen) in plastic dishes. For polarization, cells were
seeded at confluence on polycarbonate filters in 6-well dishes
(Transwells, Costar, Inc.) as described previously (13). Under the
condition of confluent on a polycarbonate filter, the numbers of cells
were 5.0 ± 0.3 × 105 cells corresponding to
0.70 ± 0.04 mg of protein in all cases of MDCK, MDCK/VIP36, and
MDCK/mVIP36 cells.
Preparation of Antibodies--
Anti-VIP36 polyclonal antibody
was prepared by immunization of a rabbit with GST-Vip36 as
antigen, and antibody molecules specific for the glutathione
S-transferase (GST) fusion partner were removed by
adsorption using a GST protein matrix. Anti-galectin-3 polyclonal
antibody was prepared by immunization of a rabbit with recombinant
human galectin-3. Anti-clusterin goat polyclonal IgG was purchased from
Santa Cruz Biotechnology, Inc.
Immunofluorescence Microscopy--
The MDCK cells were immersed
in a fixative composed of 1% paraformaldehyde and 0.1% picric acid in
0.01 M PBS for 24 h at 4 °C, washed with PBS,
immersed in 30% sucrose in PBS overnight at 4 °C, and permeabilized
with 1% Triton X-100 for 1 h in some cases. These samples were
treated with 1% normal goat serum for 1 h and then with
anti-VIP36 antibody (1:100) with PBS containing 1% bovine serum
albumin for 24 h at 4 °C. After washing, the samples were
incubated with purified fluorescein isothiocyanate-conjugated anti-rabbit immunoglobulin (1:500) for 30 min at room temperature, washed, and mounted in 50% glycerol in PBS (pH 8.6) containing 50 mg/ml 1,4-diazabicyclo-octane (Aldrich), an anti-bleaching agent.
Immunogold Electron Microscopy--
Cells were fixed with 1%
paraformaldehyde, 0.125% glutaraldehyde, and 0.1% picric acid in 0.01 M PBS, pH 7.2, for 24 h at 4 °C. After fixation,
the tissues were dehydrated with a graded ethanol series at 0 °C,
embedded on Lowicryl K4M, and then cured for 3 days at Preparation of Domain-selectively Biotinylated Plasma Membrane
Proteins--
Cell surface molecules were domain-selectively
biotinylated using a membrane-impermeable biotin analog
sulfo-NHS-biotin (Pierce) as described by Lisanti et al.
(14) with slight modifications described below. After washing the
cells, which were grown to confluence on polycarbonate filters, three
times with ice-cold PBS, either the apical or basolateral surface
proteins were biotinylated in PBS containing 1 mg/ml sulfo-NHS-biotin
for 45 min at 4 °C followed by blocking with 50 mM
glycine in PBS. For preparation of domain-selective plasma membrane
glycoproteins, the cells were washed three times with ice-cold PBS, and
either the apical or basolateral surface proteins were biotinylated.
Then the cells were lysed by incubation on ice for 30 min in lysis
buffer (1% Nonidet P-40, 150 mM NaCl, 50 mM
Tris-HCl, pH 7.0) containing protease inhibitor mixture. The lysate was
centrifuged for 10 min at 3000 rpm, and the supernatant was referred to
as the detergent extract. Biotinylated apical or basolateral surface
proteins in the supernatants were purified by means of an Immunopure
Monomeric Avidin (Pierce) column (1 ml) equilibrated with PBS-0.1%
Triton X-100.
Immunoblot and Immunoprecipitation--
MDCK cells were lysed by
incubation on ice for 30 min in lysis buffer (1% Nonidet P-40, 150 mM NaCl, 50 mM Tris-HCl, pH 7.0) containing
protease inhibitor mixture. The lysate was centrifuged for 10 min at
3000 rpm, and the supernatant was referred to as the detergent extract.
For immunoblot, the proteins were separated on 12 or 15%
polyacrylamide gel and transferred to nitrocellulose membranes. The protein was detected by immunoblot with anti-VIP36 antibody (1:200) or
anti-clusterin antibody (1:2000) followed by an HRP-conjugated secondary antibody and then visualized using enhanced
chemiluminescence reagent (Amersham Biosciences) according to
the manufacturer's instructions.
For immunoprecipitation, detergent extract or secreted protein in
apical medium was incubated for 1 h at 4 °C with antibody. Protein A-Sepharose was added, and incubation continued for 1 h at
4 °C. After washing the Sepharose beads with lysis buffer or PBS,
the precipitated proteins were subjected to SDS-PAGE. The proteins were
detected by using streptavidin-HRP and enhanced chemiluminescence
reagent as described above for biotinylated proteins or by
autoradiography for metabolic labeled proteins.
Preparation of Domain-selective 35S-Secretory
Glycoproteins--
For preparation of 35S-labeled
secretory proteins, the confluent cells cultured on polycarbonate
filters were incubated for 30 min in starvation medium lacking
methionine and cysteine and then labeled for 1 h with 250 µCi/ml
(9.25 MBq/ml) Expre35S35S (PerkinElmer Life
Sciences). After removing the labeling medium, the cells were washed
three times with normal culture medium and incubated for another 2 h in the culture medium. The medium was collected from the apical and
basolateral chambers separately and applied to a PD-10 (Amersham
Biosciences) column to separate the labeled secretory proteins
from free [35S]methionine/cysteine, and
concentrated with Centriplus 10 (Amicon Inc.).
Plasmid Construction and Isolation of Clones Showing Stable
Overproduction--
Expression of the GST fusion protein GST-Vip36 in
Escherichia coli and confirmation of its functionality have
been described previously (12). Site-directed mutagenesis was performed
by a two-step polymerase chain reaction method (15) using cDNA of
GST-Vip36 as the template and sets of appropriate primers that overlap
in the region where the mutation was introduced. The cDNA of
mutated GST-Vip36(D131N) was cloned into pGEX-2TK (Amersham Biosciences).
The full-length cDNA encoding VIP36 was amplified by performing a
polymerase chain reaction using cDNA reverse-transcribed from total
RNA of MDCK cells as a template and subcloned into pSVOKneo (16). A
full-length cDNA encoding mutant VIP36 (D131N) was also prepared by
a two-step polymerase chain reaction method using VIP36 cDNA as the
template and subcloned into pSVOKneo. 105 MDCK cells were
seeded on 60-mm dishes. The next day, the cells were transfected with 2 µg of plasmid DNA using LipofectinTM reagent
(Invitrogen). G418-resistant clones were selected in medium containing
500 µg/ml G418 (Geneticin).
Assay of Binding of GST-Vip36 to 35S-Labeled Proteins
in Vitro--
The binding of GST-Vip36 to 35S-labeled
proteins has been described previously (12). Briefly, binding buffer
containing GST-Vip36, mutated GST-Vip36(D131N), or GST and
35S-detergent extracts (4-5 × 106 dpm)
from MDCK cells in a total volume of 100 µl was incubated for 60 min
at 37 °C. After incubation, the bound proteins were collected and
washed using glutathione-Sepharose beads, and the radioactivity was
counted. The radioactivity obtained in control samples with GST was
taken as background.
Analysis of Glycan Structures of Clusterin--
For steady-state
determination, cells grown to confluence on polycarbonate filters were
labeled with 0.5 ml of minimum Eagle's medium containing one-tenth of
the normal concentration of glucose (100 mg/liter) and 100 µCi (3.7 MBq) of D-[1,6-3H(N)]-glucosamine
(35-75 Ci/mmol) (PerkinElmer Life Sciences) for 24 h.
For preparation of clusterin, metabolic-labeled clusterin in medium was
immunoprecipitated for 1 h at 4 °C with anti-clusterin antibody
and Protein A-Sepharose. The bound materials were eluted with 0.4 N acetic acid, neutralized with pyridine, and dried. N-glycans were released by treatment with 5 units of
N-glycanase (Roche Diagnostic GmbH) at 37 °C for 18 h.
Purified [3H]glucosamine-labeled glycoproteins were
subjected to hydrazinolysis at 100 °C for 8 h to release
3H-glycans from glycoproteins (17). After
N-acetylation and reduction with NaBH4, neutral
oligosaccharides were separated by high voltage paper electrophoresis
with pyridine-acetate buffer, pH 5.4 (pyridine:acetic acid:water,
3:1:387) at a potential of 73 V/cm for 60 min and applied to Con
A-Sepharose columns (1 ml) equilibrated with PBS. Oligosaccharides were
eluted with 5 mM VIP36 Is Localized Not Only to the Early Secretory Pathway but Also
to Plasma Membrane--
We previously determined that VIP36 binds to
high mannose-type glycans bearing Man 1
In addition, when plasma membrane proteins of intact MDCK cells were
biotinylated by a membrane-impermeable sulfo-NHS-biotin, plasma
membrane proteins were isolated using a monomeric avidin-Sepharose by
using intact cells. As shown in Fig. 2,
the amount of VIP36 biotinylated by using intact cells was estimated to
be ~15% of the total cellular VIP36. These results indicated that
endogenous VIP36 was localized not only to the early secretory pathway
but also to the plasma membrane of MDCK cells.
VIP36 Existed in Both the Apical and Basolateral Domains of the
Plasma Membrane of MDCK Cells in the Ratio of ~2:1--
Next we
examined whether VIP36 existed in the apical or basolateral plasma
membrane, or in both plasma membrane domains, of polarized MDCK cells.
To discriminate between apical and basolateral VIP36, the apical and
basolateral membrane proteins of MDCK cells were metabolically labeled
with [35S]methionine/cysteine and then selectively
biotinylated by the addition of membrane-impermeable sulfo-NHS-biotin
in the apical or basolateral chamber. After extraction with detergent,
proteins from apically and basolaterally biotinylated MDCK cells,
preparations of which had the same total radioactivity, were subjected
to immunoprecipitation using anti-VIP36 antibody. The
immunoprecipitated proteins were fractionated by SDS-PAGE and then
transferred to a nitrocellulose membrane followed by detection of
biotinylated VIP36 using streptavidin-HRP and chemiluminescence
reagent. As shown in Fig. 3 (lanes
1 and 2), bands of VIP36 were found in both
preparations from apically and basolaterally biotinylated MDCK cells.
When the chemiluminescence of the VIP36 bands was measured using Image
Gauge, the chemiluminescence level of the apical VIP36 band was
~2-fold more than that of the basolateral VIP36 band (Fig. 3,
lanes 1 and 2). These results indicated that
VIP36 existed in both the apical and basolateral domains of the plasma
membrane of MDCK cells in the ratio of ~2:1.
VIP36-recognized Glycoproteins Were Transported to Both the Apical
and Basolateral Domains of the Plasma Membrane of MDCK Cells in the
Ratio of ~2:1--
To examine whether there is a correlation between
the distribution of VIP36 and VIP36-recognized glycoproteins in the
polarized plasma membrane, we determined also the distribution of the
VIP36-recognized glycoproteins in the polarized plasma membrane of MDCK
cells. The apical and basolateral plasma membrane proteins were
separately biotinylated, detergent extracts were prepared, and these
preparations were incubated with a recombinant fusion protein,
GST-Vip36 (12), which consisted of GST and a VIP36-derived
peptide, or with GST alone. The membrane proteins bound to GST-Vip36
and GST were collected using glutathione-Sepharose beads, fractionated
by SDS-PAGE, and then transferred to a nitrocellulose membrane followed
by detection of biotinylated proteins using streptavidin-HRP and
chemiluminescence reagent. As shown in Fig.
4, the apical membrane contained more glycoproteins bound to GST-Vip36 than the basolateral membrane. When
the chemiluminescence of each lane was measured using Image Gauge (Fuji
Photo Film), the amount of VIP36-binding glycoproteins in the apical
membrane was estimated to be ~2-fold more than that in the
basolateral membrane, although the total amount of biotinylated proteins derived from the apical membrane was similar to that of
biotinylated proteins derived from the basolateral membrane (Table
I). In addition, the amount of
VIP36-binding glycoproteins decreased markedly upon treatment of the
apical and basolateral proteins with Endo H (Fig. 4 and Table I). This
confirmed that VIP36 recognized high mannose-type glycans and indicated
that our assay system for measuring VIP36-binding glycoproteins worked well.
We also examined the amount of apical and basolateral secretory
glycoproteins that was capable of binding to VIP36. The apical and
basolateral secretory proteins of MDCK cells were metabolically labeled
with [35S]methionine/cysteine, collected separately, and
then incubated with GST-Vip36 or GST. When the secretory glycoproteins
bound to GST-Vip36 and GST were isolated using glutathione-Sepharose beads, the radioactivity of VIP36-binding glycoproteins in the apical
preparation was ~2-fold more than that in the basolateral preparation, although the total radioactivity of the apical secretory proteins was similar to that of the basolateral secretory proteins (Table I). Upon Endo H treatment of the apical and basolateral secretory proteins, the radioactivity of VIP36-binding glycoproteins became negligible (Table I). These results indicated that the membrane
and secretory glycoproteins, which were capable of binding to VIP36,
were transported ~2-fold more efficiently to the apical domain than
to the basolateral domain of polarized MDCK cells. Thus, the
apical/basolateral ratio of the transport of VIP36-recognized glycoproteins was correlated with that of VIP36 in MDCK cells.
The Effects on Distribution of VIP36 Itself and VIP36-recognized
Glycoproteins by Overproduction of VIP36 or Mutant VIP36 Defective in
Lectin Activity--
To address the function of VIP36, we constructed
strains of MDCK cells that overproduced VIP36 and a mutant VIP36
defective in its lectin activity. The N-terminal luminal domain of
VIP36 shows homology to lectins of leguminous plants (9). In
particular, the carbohydrate-binding sites and the metal-binding site
of leguminous plant lectins are well conserved in VIP36. Based on
sequence similarity among plant lectins and VIP36, Asp-131 of VIP36 was
assumed to be a residue essential for its lectin activity. Therefore,
we prepared a bacterially produced mutant GST-Vip36 in which the Asp
residue corresponding to Asp-131 of VIP36 was replaced with Asn (Fig.
5A), and we examined the
binding activity to glycoproteins. Unlike the original
GST-Vip36, the mutant GST-Vip36 was incapable of binding to
35S-glycoproteins of MDCK cells at all (Fig.
5B). This indicated that the mutation changing Asp-131 to
Asn (D131N) in VIP36 resulted in loss of lectin activity.
We introduced the D131N mutation into a full-length VIP36 cDNA
clone carried by a mammalian expression vector and then introduced the
wild type VIP36 cDNA and the mutant VIP36 cDNA into MDCK cells by transfection. Stable transfectants obtained (designated as MDCK/VIP36 and MDCK/mVIP36, respectively), which overproduced the wild
type of VIP36 or the D131N-mutant VIP36 at a similar level,
were purified and subjected to biochemical characterization. When the
distribution of VIP36 (or mutant VIP36) in MDCK, MDCK/VIP36, and
MDCK/mVIP36 cells was analyzed, we unexpectedly found that overproduction of VIP36 enhanced the apical distribution of VIP36; the
apical/basolateral ratios of VIP36 in MDCK/VIP36 and MDCK/mVIP36 were
3.5 and 3.6, respectively, whereas it was 1.9 in MDCK cells (Fig. 3).
This finding led us to examine whether or not the enhancement of apical
distribution of VIP36 had an effect on the distributions of
VIP36-recognized glycoproteins in polarized plasma membrane. The
apical/basolateral ratios of membrane and secretory proteins that were
capable of binding to VIP36 were 4.6 and 5.8, respectively, in the case
of MDCK/VIP36 cells and 2.4 and 1.9, respectively, in the case of MDCK
cells (Table II). Thus, in MDCK/VIP36
cells, the apical distribution of both VIP36 and VIP36-recognized
glycoproteins was enhanced coincidentally. In contrast to MDCK/VIP36
cells, the MDCK/mVIP36 cells exhibited normal apical/basolateral ratios of VIP36-recognized membrane glycoproteins and secretory glycoproteins, similar to those exhibited by MDCK cells (Table II). Furthermore, overproduction of VIP36, but not that of the mutant, led to a striking
increase in the apical secretion of glycoproteins that bound to VIP36
(Table II). In contrast, overproduction of the mutant VIP36 inhibited
the secretion of glycoproteins that bound to VIP36. These results
involving MDCK/VIP36 and MDCK/mVIP36 suggested that VIP36 was involved
in the transport and sorting of glycoproteins bearing high mannose-type
glycan(s).
VIP36 Is Involved in the Intracellular Transport of
Clusterin--
As described above, the results obtained from the
experiments involving bulk membrane and secretory glycoproteins
suggested that VIP36 was involved in the transport and sorting of
glycoproteins. To confirm the involvement of VIP36 in the transport of
glycoproteins, next we performed experiments focusing on a major apical
secretory glycoprotein in MDCK cells. Clusterin is an 80-kDa
glycoprotein, and it is released as a disulfide-linked heterodimeric
complex (after intracellular proteolytic maturation) from the apical
surface of the polarized MDCK cells (22). Clusterin contains seven
potential N-glycosylation sites, three in the 35-kDa subunit
and four in the 45-kDa subunit, and all N-glycosylation
sites are used (23). The following results indicated that clusterin
carried at least one high mannose-type glycan recognized by VIP36.
After immunoprecipitation of [3H]glucosamine-labeled
clusterin, the 3H-labeled N-glycans were
released from clusterin precipitated by Protein A beads as described
under "Experimental Procedures." As shown in Table
III, 92.5% of the total radioactivity of
3H-labeled N-glycans was recovered as complex
type glycans, consistent with the previous results (22). However, the
radioactivity, which amounted to 7.5% of the total radioactivity, was
recovered in a high mannose-type glycan fraction. Since a high
mannose-type glycan contains only 2 mol of
N-acetylglucosamine residues, whereas most of complex
type glycans abundant in MDCK cells contain 5 mol of
N-acetylglucosamine,2
this result indicated that over 15% of total N-glycans of
clusterin was of high mannose-type glycans. Thus, one of seven
N-glycans of clusterin was most likely of high mannose-type
glycan.
To examine whether the high mannose-type glycan of clusterin,
Man8or9GlcNAc2, is recognized by VIP36, the
detergent extract from MDCK cells was subjected to immunoprecipitation
with anti-VIP36 antibody followed by immunoblot with anti-clusterin
antibody. As shown in Fig. 6a,
clusterin was co-precipitated with VIP36 (lane 1). This
co-precipitation was not observed when the detergent extract was
treated with Endo H (Fig. 6a, lane 2). When the
detergent extract was subjected to immunoprecipitation with
anti-clusterin antibody, VIP36 was co-precipitated with clusterin (Fig.
6b, lane 1). These results indicated that the
high mannose-type glycan of clusterin was recognized by VIP36 and that
the remaining glycans were processed to complex type glycans during
intracellular transport (Table III).
To examine whether or not overproduction of VIP36 has an effect on the
secretion of clusterin, MDCK, MDCK/VIP36, and MDCK/mVIP36 cells were
subjected to the pulse-chase experiment with
[35S]methionine/cysteine followed by the
immunoprecipitation of clusterin secreted from the apical plasma
membrane. In 30 min of chase time, a significant amount of
[35S]clusterin was secreted by MDCK/VIP36 cells (see Fig.
8, lane 3) but not by MDCK cells (see Fig. 8, lane
7), implying that the rate of secretion of clusterin from
MDCK/VIP36 cells was faster than that in MDCK cells (Fig.
7, a and c, and
Fig. 8). On the other hand,
overproduction of mutant VIP36 inhibited
the secretion of clusterin, with the result that the rate of
secretion of clusterin from MDCK/mVIP36 cells was slower than that in
MDCK cells (Fig. 7, a and c). At the chase time
of 2 h, MDCK/VIP36, MDCK, and MDCK/mVIP36 cells, respectively,
secreted 54, 33, and 25% of the radioactivity incorporated into
clusterin during the pulse-labeling period (Fig. 7c). These
results indicated that the overproduction of VIP36 in MDCK cells led to
an increase in the rate of clusterin transport. In contrast to the
secretion of glycosylated clusterin, the secretion of galectin-3, which
is a non-glycosylated apical secretory protein in MDCK cells (24), was
not affected by the overproduction of VIP36 (Fig. 7, b and
d). Thus, VIP36 seemed to be involved in the transport of
glycoproteins such as clusterin.
Intracellular protein transport is one of the issues most
enthusiastically studied in cell biology. Recently, it has become evident that some specific glycans and intracellular lectins
recognizing specific glycans play important roles in intracellular
glycoprotein transport (1-5). In the present study, we have examined
the functional role of an intracellular lectin, VIP36, which recognizes
high mannose-type glycans containing Inconsistent with our finding that a significant fraction of VIP36 is
localized to the plasma membrane, Füllekrug et al. (11) have reported that, unlike overexpressed VIP36, endogenous VIP36
is not detected on the plasma membrane of MDCK cells. This inconsistency might be attributed to the difference in the antibody used for the detection and/or to the alteration of property of MDCK
cells during cell passages. VIP36 is localized to the early secretory
pathway, cycling between ER-Golgi intermediate structures and the Golgi
complex (21), and it is localized also to the plasma membrane in a
significant amount, at least in the case of our MDCK cells. Therefore,
it is likely that, at the late Golgi or trans-Golgi Network,
a large fraction of VIP36 is retrieved to ER-Golgi intermediate
structures, and a small but significant fraction of VIP36 is exported
out to the plasma membrane.
It is uncertain whether VIP36 cycles between the plasma membrane and
the Golgi complex or endosomes. VIP36 has no obvious internalization
signal in its short cytoplasmic tail. However, there is the possibility
that VIP36 is associated with plasma membrane protein(s) carrying
cytoplasmic internalization signal and is therefore co-internalized
with such proteins. It is also possible that VIP36 has an unknown
internalization signal. To clarify the functional role of VIP36, we are
currently examining whether VIP36 is internalized at the cell surface
or not.
In the polarized plasma membrane of MDCK cells, both VIP36 and
VIP36-recognized membrane proteins exhibited an apical-predominant distribution, their apical/basolateral ratios being ~2. In addition, secretory glycoproteins recognized by VIP36 were secreted ~2-fold more efficiently from the apical membrane than from the basolateral membrane. Thus, the apical/basolateral ratio of the transport of
VIP36-recognized glycoproteins was correlated with that of VIP36 in
MDCK cells. When VIP36 was overproduced in MDCK cells, the
apical/basolateral ratio of plasma membrane VIP36 was changed from
~1.9 to ~3.5. Furthermore, the overproduction of VIP36 induced a
marked enhancement of the apical distribution of VIP36-recognized glycoproteins and strikingly stimulated the apical secretion of VIP36-recognized glycoprotein. In contrast, the overproduction of a
mutant VIP36 without lectin activity did not affect the distribution of
VIP36-recognized glycoprotein in the plasma membrane, although the
apical/basolateral ratio of the plasma membrane mutant VIP36 was very
similar to that of overproduced VIP36 and 1.9-fold more than that of
VIP36 produced at the usual (non-overproduction) level. Interestingly,
the overproduction of mutant VIP36 inhibited the secretion of
VIP36-recognized glycoproteins. In addition, we showed that a major
apical secretory glycoprotein of MDCK cells, clusterin, carried at
least one high mannose-type glycan, which was recognized by VIP36, and
that the rate of clusterin transport was increased by the
overproduction of VIP36 in MDCK cells. These results indicated that
VIP36 is involved in the transport and sorting of glycoproteins through
its lectin activity in polarized MDCK cells.
Consistent with the view that the lectin activity of VIP36 is involved
in the transport and sorting of glycoproteins, several reports have
indicated that N-linked glycans are one of the sorting signals for apical transport. An apical secretory protein,
erythropoietin, is secreted equally from the apical and basolateral
domains of the plasma membrane when its three
N-glycosylation sites are removed by site-directed
mutagenesis (25). Similarly, Scheiffele et al. (26) have
shown that a growth hormone, HG, which is a non-glycosylated protein secreted equally from the apical and basolateral domains of the
plasma membrane, is secreted preferentially from apical membrane when
an N-glycosylation site is introduced by mutagenesis. Furthermore, glycine transporter GLYT2, which localizes in the apical
surface in polarized MDCK cells, was distributed in a non-polarized manner by unglycosylation (27).
The intracellular lectins calnexin and calreticulin are chaperons,
functioning in quality control of newly synthesized glycoproteins in
the ER (2, 3 and 4). Another intracellular lectin, ERGIC-53, may
function as a receptor for cargo glycoprotein in the ER-to-ERGIC transport vesicle (5). In this study, VIP36 was shown to be involved in
the transport and sorting of glycoproteins and localized to the early
secretion pathway and to the plasma membrane. Interestingly, all
intracellular lectins identified so far recognize high mannose-type glycans, although the recognized mannosyl residues in high mannose-type glycans are different among them. These observations concerning the
localization and binding specificity of intracellular lectins raise the
possibility that intracellular lectins cooperate in the ER-to-plasma
membrane transport of glycoproteins carrying high mannose-type glycans.
We thank Y. Kanaya for technical support.
*
The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
Published, JBC Papers in Press, February 28, 2002, DOI 10.1074/jbc.M112188200
2
T. Ohkura, S. Hara-Kuge, A. Seko, and K. Yamashita, manuscript in preparation.
The abbreviations used are:
ER, endoplasmic
reticulum;
Endo H, endo-
Involvement of VIP36 in Intracellular Transport and Secretion
of Glycoproteins in Polarized Madin-Darby Canine Kidney
(MDCK) Cells*
§,§,§
Department of Biochemistry, Sasaki
Institute, 2-2 Kanda-Surugadai, Chiyoda-ku, Tokyo 101-0062, § CREST (Core Research for Evolutional Science and
Technology) of the Japan Science and Technology Corporation (JST)
2-3 Kanda-Surugadai, Chiyoda-ku, Tokyo 101-0062, and the
¶ Department of Anatomy, Yamanashi-Medical University, 1110 Tamahocho, Nakakoma-gun, Yamanashi 409-3898, Japan
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
35 °C.
Ultrathin sections were treated with 3% hydrogen peroxide for 10 min
and 1% normal goat serum for 1 h and then incubated with
anti-VIP36 antibody (1:100) with PBS containing 1% bovine serum
albumin. After rinsing with PBS, the sections were incubated for 1 h with 10-nm colloidal gold-labeled anti-rabbit immunoglobulin (1:200)
followed by rinsing with PBS and then distilled water. Finally, the
sections were stained with uranyl acetate and lead citrate and examined
with an electron microscope (Hitachi H-800).
-methyl-D-glucoside
(elution for biantennary glycans) and then 0.2 M
-methyl-D-mannoside (elution for high mannose-type
glycans) in PBS (18). The fractions of high mannose-type glycans were
further fractionated by Bio-Gel P-4 (extra fine, 2 × 100 cm)
column chromatography (19). The peak fractions from Bio-Gel P-4
chromatography were digested with 1 unit of -mannosidase
(Aspergillus saitoi) (20) in 0.1 M acetate buffer (pH 4.5) in a total volume of 50 µl at 37 °C for 18 h
and then fractionated by Bio-Gel P-4 chromatography to determine the high mannose-type glycan structures.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
2 residue(s) (12). To
elucidate the functional role of VIP36, we first analyzed the
localization of VIP36 histochemically using an affinity-purified
polyclonal anti-VIP36 antibody raised against GST-Vip36 (12). Using
immunogold electron microscopy, we confirmed for the first time that
endogenous VIP36 is predominantly localized to the early secretory
pathway (Fig. 1a). Fig.
1a supports the results of Füllekrug et al.
(11) and Dahm et al. (21), who recently showed that
endogenous VIP36 localizes to the early secretory pathway, cycling
between ER-Golgi intermediate structures and the Golgi complex. To
examine whether or not endogenous VIP36 is localized not only to the
early secretory pathway but also to the plasma membrane, a section with
plasma membrane (Fig. 1b) was examined, and several
immunogold particles were observed on plasma membrane. Furthermore,
immunofluorescence staining of MDCK cells was performed with or without
Triton X-100 treatment. When immunofluorescence staining was performed
after Triton X-100 treatment, which enabled the antibody to permeate through plasma membrane, VIP36 seemed to exist broadly in MDCK cells
(Fig. 1d). Even without Triton X-100 treatment, the antibody reacted with the preparation, and staining of plasma membranes was
observed (Fig. 1e), suggesting that VIP36 existed on the
cell surface as shown before (10).
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Fig. 1.
Distribution of VIP36 in MDCK cells.
Immunoelectron micrograph of VIP36 in a MDCK cell showed VIP36
localized on ER and Golgi complex (a) and on plasma membrane
(b). Nuc, nucleus. Immunoelectron
micrograph without primary anti-VIP36 antibody (c) is shown
as control. Bar = 1 µm. Immunofluorescence of VIP36
in a MDCK cells with (d) or without (e) treatment
with Triton X-100 showed that VIP36 is distributed from ER to plasma
membrane throughout the cell. Immunofluorescence micrograph without
primary anti-VIP36 antibody (f) is shown as control
corresponding to the phase contrast micrograph (g). The
length of one side = 40 µm.
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Fig. 2.
Localization of VIP36 in plasma
membrane. The plasma membrane proteins of MDCK cells were labeled
with (lanes 1 and 2) or without (lanes
3 and 4) membrane-impermeable biotin reagent, and the
cells were then lysed with Nonidet P-40 lysis buffer. The cell lysate
was incubated with monomeric avidin-Sepharose to purify plasma
membrane. The avidin-bound proteins (lane 1, plasma
membrane, and lane 3, background) and avidin-unbound
proteins (lane 2, proteins without plasma membrane, and
lane 4, total proteins) were subjected to immunoblot using
anti-VIP36 antibody. When the chemiluminescence of the VIP36 bands was
measured using Image Gauge, the chemiluminescence level of the VIP36
band in the plasma membrane (lane 1) was 15%. Results are
the means of three experiments. (Standard deviations were less than
5.)
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Fig. 3.
Distribution of VIP36 in polarized plasma
membrane. Lanes 1, 2, and
7, MDCK wild type; lanes 3 and 4,
MDCK/VIP36 clone; lanes 5 and 6, MDCK/mVIP36
clone; lanes 1, 3, 5, and
7, apical domain; lanes 2, 4, and
6, basolateral domain. The chemiluminescence of the VIP36
bands was measured using Image Gauge, and the value of control without
primary anti-VIP36 antibody (shown in lane 7) was used as
background. The results are shown below the gel.
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Fig. 4.
SDS-PAGE analysis of apical and basolateral
membrane glycoproteins recognized by VIP36. Lanes 1-3,
apical membrane glycoproteins; lanes 4-6, basolateral
membrane glycoproteins; lanes 1 and 4, total
labeled membrane proteins; lanes 2 and 5,
VIP36-bound membrane glycoproteins; lanes 3 and
6, VIP36-bound membrane glycoproteins treated with Endo
H.
Distribution of VIP36-recognized glycoproteins in polarized of MDCK
cells
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Fig. 5.
The mutation changing Asp-131 to Asn (D131N)
in VIP36 results in loss of lectin activity. One hundred µl of
the binding buffer containing the indicated amount of GST-Vip36 or
mutated D131N GST-Vip36 and 4-5 × 106 dpm of
35S-detergent extract was incubated for 60 min at 37 °C.
The bound proteins were precipitated by the addition of
glutathione-Sepharose beads, and the amount of radioactivity was
determined by scintillation counting. ( 
), GST-Vip36; (
), mutated
D131N GST-Vip36
Plasma membrane and secretory glycoproteins that bound to VIP36 in
polarized MDCK, MDCK/VIP36, and MDCK/mVIP36 cells
The N-glycan structures of clusterin
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Fig. 6.
Binding of VIP36 to clusterin.
a, detergent extracts from MDCK cells immunoprecipitated
with anti-VIP36 antibody. The precipitated proteins were separated by
SDS-PAGE followed by transfer to nitrocellulose membrane. Clusterin was
detected by immunoblot with anti-clusterin antibody. Clusterin was not
detected when the detergent extract was treated with Endo H (lane
2). b, detergent extracts from MDCK cells
immunoprecipitated with clusterin antibody. The precipitated proteins
with (lane 1) or without (lane 2) treatment with
Endo H were separated by SDS-PAGE followed by transfer to
nitrocellulose membrane. VIP36 was detected by immunoblot with
anti-VIP36 antibody.
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Fig. 7.
Transport of newly synthesized clusterin and
galectin-3 in MDCK, MDCK/VIP36, and MDCK/mVIP36 cells. The
polarized MDCK, MDCK/VIP36, and MDCK/mVIP36 cells were pulse-labeled
with [35S]methionine/cysteine for 20 min and chased for
the indicated periods. The cell lysate and apical medium were subjected
to immunoprecipitation with anti-clusterin antibody and anti-galectin-3
antibody. The radioactive counts of clusterin (a) and
galectin-3 (b) or the percentage ratios against the
radioactive counts at the end of pulse-labeled of clusterin
(c) and galectin-3 (d) are shown. and ,
MDCK; 
and 
, MDCK/VIP36; 
and 
, MDCK/mVIP36; , , and
, cell; , , and , medium
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Fig. 8.
Autoradiography of newly synthesized
clusterin in MDCK and MDCK/VIP36 cells. The polarized MDCK/VIP36
(lanes 1-4) and MDCK (lanes 5-8) cells were
pulse-labeled with [35S]methionine/cysteine for 20 min
and chased for the indicated periods. Clusterin was immunoprecipitated
using cell lysate (lanes 1, 2, 5, and
6) or apical medium (lanes 3, 4,
7, and 8) in the apical chamber at the indicated
times followed by SDS-PAGE (15%) and autoradiography.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
12 mannose residues
(12).
ACKNOWLEDGEMENT
FOOTNOTES
To whom correspondence should be addressed: Dept. of
Biochemistry, Sasaki Institute, 2-2 Kanda-Surugadai, Chiyoda-ku,
Tokyo 101-0062, Japan. Tel.: 3-3294-3286; Fax: 3-3294-2656;
E-mail: yamashita@sasaki.or.jp.
ABBREVIATIONS
-N-acetylglucosaminidase H;
GST, glutathione S-transferase;
VIP36, vesicular integral-membrane protein
of 36 kDa;
mVIP36, mutant VIP36;
PBS, phosphate-buffered saline;
sulfo-NHS-biotin, sulfo-N-hydroxysuccinimide-biotin;
HRP, horseradish peroxidase.
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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