(Received for publication, December 23, 1996, and in revised form, May 20, 1997)
From the Departments of Biochemistry and
§ Medicine, Medical College of Wisconsin and Veterans
Administration Medical Center, Milwaukee, Wisconsin 53226
Transcobalamin II-receptor (TC II-R) contains 10 half-cysteines, of which 8 are involved in intramolecular disulfide
bonding. Reduction followed by alkylation with
N-ethylmaleimide (NEM) of the 62-kDa TC II-R monomer
in vitro or treatment of human intestinal epithelial Caco-2
cells with low concentrations (106 M) of NEM
resulted in TC II-R exhibiting a loss of ligand binding and an increase
in its apparent molecular mass by 10 kDa to 72 kDa. Domain-specific
biotinylation studies using NEM-treated filter-grown cells revealed
loss of TC II-R but not cation-independent mannose 6-phosphate receptor
protein at the basolateral cell surface. Pulse-chase labeling of
NEM-treated cells with [35S]methionine revealed that the
modified 72-kDa TC II-R, like the native 62-kDa TC II-R in untreated
cells, turned over rapidly with a t1/2 of 7.5 h and was sensitive to treatment with peptide N-glycosidase
F, sialidase alone, or sialidase and O-glycanase but not to
treatment with endoglycosidase H. Labeled 72-kDa TC II-R, which was
retained intracellularly following treatment of Caco-2 cells with
methyl methanethiosulfonate, returned to the basolateral cell surface
following withdrawal of cells from methyl methanethiosulfonate
treatment and exposure to dithiothreitol. Based on these results, we
suggest that formation and maintenance of intramolecular disulfide
bonds of TC II-R is important for its acquisition of ligand binding and
post-trans-Golgi trafficking to basolateral surface membranes but not
for its turnover and exit from the endoplasmic reticulum or trafficking
through the Golgi.
Transcobalamin II-receptor (TC II-R)1 is a single chain glycoprotein with a molecular mass of 62 kDa (1) containing about 27% carbohydrate. It promotes plasma transport of cobalamin (Cbl; vitamin B12) bound to transcobalamin II (TC II) (2). TC II-R functions as a noncovalent homodimer with a molecular mass of 124 kDa in tissue membranes (1), and its dimerization occurs not in the ER, where it is a monomer, but rather in the plasma membrane (3). In addition, the dimerization of TC II-R is a membrane fluidity-driven event requiring a highly ordered rigid bilayer (4). In polarized epithelial Caco-2 cells, TC II-R is predominantly present in basolateral membranes (5), where it functions in the delivery of Cbl to be utilized as coenzymes (6). Treatment of the basolateral surface of Caco-2 cells with TC II-R antiserum in vitro or circulating TC II-R antibody in vivo results in a failure of TC II-Cbl uptake, causing intracellular Cbl deficiency (6). These studies have suggested that plasma membrane delivery of TC II-R is extremely important for cells to obtain their Cbl from the circulation to maintain their normal metabolic, differentiation, and proliferation status. Despite the importance of plasma membrane expression of TC II-R in the tissue transport of Cbl, no information is available regarding its intracellular trafficking and plasma membrane expression.
Recent studies have shown that formation of intracellular inter- or
intrachain disulfide bonds and their final rearrangement by
thiol-disulfide exchange reaction is one of the co/post-translational modifications of some proteins (7, 8). The correct formation of
intrachain and, in the case of oligomeric proteins, interchain disulfide bonds is crucial for the proper assembly of secretory and
plasma membrane proteins, which in turn determines their stability, intracellular transport, maturation, and function (9-11). Inhibition of disulfide bond formation by DTT treatment has been shown to affect
secretion of albumin and H1 subunit of asialoglycoprotein receptor from
fibroblasts (12) and of gp80 (clusterin, apolipoprotein J) in polarized
Madin-Darby canine kidney cells (13). However, the secretion of
non-disulfide bond-containing proteins such as 1-antitrypsin (14) in HepG2 cells or of a 20-kDa peptide
derived from osteoponin in Madin-Darby canine kidney cells (13) is not affected. These studies have proposed that the retention of proteins in
the ER following treatment with DTT is due to a failure of these
proteins to form disulfide bonds, which then fold improperly. As a
consequence, these misfolded proteins fail to achieve a conformation essential for their function as well as their exit from the ER for
further processing and targeting (15).
Human TC II-R contains 10 half-cysteines (16), and recent immunoblot studies of placental plasma membrane proteins under nonreducing and reducing conditions (1) have shown that TC II-R dimers contain intramolecular disulfide bonds that, upon reduction, increase the apparent molecular mass of the dimer by 20 kDa. Taken together, these results have suggested that some if not all of the SH groups of TC II-R monomer may be involved in the formation of intramolecular disulfide bonds, which remain intact during its transport to and dimerization in the plasma membranes. Furthermore, the increase in apparent molecular mass of the reduced TC II-R dimer may be related to its attainment of an extended or a more linear structure. However, it is not known whether the TC II-R monomers contain intrachain disulfide bonds that, when reduced, form extended structures and whether such a modification has any effect on their ligand binding, turnover, and trafficking to the basolateral membranes. The current studies have addressed these issues in vitro using pure TC II-R and in vivo using human intestinal epithelial Caco-2 cells as a model system. The results of this study show that TC II-R monomers contain four intramolecular disulfide bonds that are required for activity and two free SH groups that have no role in ligand binding. Sulfhydryl group modification of either isolated TC II-R monomer or that expressed in Caco-2 cells by SH-modifying agents demonstrated a more linear extended form of an inactive receptor with a molecular mass of 72 kDa. The extended 72-kDa form of TC II-R, like the native 62-kDa form, turned over rapidly in cells with a t1/2 of 7.5 h. In addition, it was able to exit ER and transit through the Golgi as revealed by the sialylation of both its N- and O-linked sugars. However, the 72-kDa form of TC II-R was unable to undergo transport from the trans-Golgi to its destination in the basolateral membranes.
The following chemicals were
purchased as indicated: [57Co]CN-Cbl (15 µCi/µg) and
carrier-free Na125I (17.4 Ci/mg) (Amersham Corp.);
[35S]methionine (1175 Ci/mmol) and [3H]NEM
(60 Ci/mmol) (NEN Life Science Products); 125I-protein A
(>30 Ci/µg) (ICN Radiochemicals, Irvine, CA);
N-ethylmaleimide, iodoacetamide, methyl
methanethiosulfonate, dithiothreitol, protein A-Sepharose, and
sialidase from Clostridium perifringens (from Sigma);
5,5-dithiobis(2-nitrobenzoic acid), sulfosuccin imidobiotin and
disuccinimidyl suberate (Pierce); Millicell-HA culture plate inserts
(Millipore); cellulose nitrate membranes (Schleicher and Schuell).
Endo-
-N-acetylglucosaminidase from Streptomyces
plicatus, Peptide-N-glycosidase from
Flavobacterium meningosepticum, and O-glycanase
from Diplococcus pneumonia (Boehringer Mannheim). All
chemicals purchased were used as such except that iodoacetamide was
recrystallized in water. Pure TC II-R (specific activity, 14-15 nmol
of ligand binding/mg of protein) was purified from human placenta, and
its antiserum was prepared as described earlier (1). Antiserum to
bovine CI-MPR was a gift from Dr. Nancy M. Dahms (Department of
Biochemistry, Medical College of Wisconsin, Milwaukee). Partially
purified human TC II used for ligand binding was prepared from human
plasma according to Lindemans et al. (17). Human TC II was a
gift from Charles A. Hall (Nutrition Assessment laboratory, Albany,
NY). Pure TC II (5 µg) or streptavidin (50 µg) was iodinated with
0.5 mCi of Na125I and IODO-GEN as recommended by the
manufacturer. The iodinated proteins were separated from free iodine on
a Sephadex G-25 column using 10 mM Tris-HCl, pH 7.5, buffer
containing 140 mM NaCl and 1 mg/ml bovine serum albumin.
The specific activity of 125I-TC II and
125I-streptavidin was between 70 and 80 µCi/µg.
Pure TC II-R (5 µg) was treated with 130 mM of iodoacetamide (IAM) or NEM or methyl methanethiosulfonate (MMTS) for 1 h at room temperature in the presence or absence of 4 M urea or 2-mercaptoethanol (40 mM). The receptor was first incubated with 4 M urea (15 min) or 2-mercaptoethanol (1 h in the dark) prior to the addition of the SH-modifying agent. In some experiments, the receptor was first treated with urea for 15 min followed by 2-mercaptoethanol treatment for 1 h and finally treated with the SH reagent. All samples (1.5 ml) were dialyzed for 12 h against 5 liters of 10 mM Tris-HCl, pH 7.4, containing 140 mM NaCl and 0.1 mM PMSF. The dialyzed samples were assayed for TC II-[57Co]Cbl (1.5 pmol) binding by the DEAE-Sephadex method of Seligman and Allen (16). TC II-R that was reduced and treated with each of the SH-modifying agents was treated with DTT (200 mM), dialyzed, and assayed for the ligand binding as stated above. In some experiments, TC II-R reduced in the presence of urea and treated with IAM, NEM, or MMTS was cross-linked with 125I-TC II-Cbl (200,000 dpm/2 pmol Cbl binding capacity) in the presence and absence of excess (20-fold) unlabeled TC II-Cbl. Reduced and SH group-modified TC II-R (2 µg) was incubated with and without cold TC II-Cbl for 30 min at room temperature. The samples were then incubated with 125I-TC II-Cbl for 2 h at room temperature, the cross-linking agent disuccinimidyl suberate (4 mM) was added, and they were incubated for an additional 30 min. The reaction was stopped by the addition of glycine (0.1 mM). The reaction mixture was subjected to nonreducing SDS-PAGE, and the bands were visualized by autoradiography.
Titration of Pure TC II-R with DTNB and Labeled NEMPure TC
II-R (50 µg), unreduced or reduced in the presence or absence of urea
(4 M) in Tris-glycine buffer, pH 8.0, containing 0.2 mM EDTA was incubated with DTNB (10 µg) for 1 h at
22 °C. The absorbance of the samples was measured at 412 nm, and the spectrophotometric titrations of thiol groups were calculated based on
the known extinction coefficient of DTNB (13,600 mol1/cm
1) according to Habeeb (18).
Titration of pure TC II-R (5 µg) was carried out using
[3H]NEM (760,000 dpm/100 mM) under reducing
and nonreducing conditions and in the absence and the presence of urea
as described above for DTNB titration. The samples were dialyzed and
counted for the bound radioactivity.
Pure native, reduced, and
SH-modified TC II-R (0.2-2 µg of protein), Caco-2 cell homogenate
(50 µg), or Triton X-100 (1%) extract of total Caco-2 cell membrane
(200 µg), and labeled TC II-R immunoprecipitated from NEM treated and
untreated cells were subjected to nonreducing SDS-PAGE (7.5%)
according to Laemmli (19). In some experiments separated proteins were
subjected to immunoblotting to detect either the monomer or the dimer
form of TC II-R as described before (4). The bands were visualized by
autoradiography at 70 °C using X-Omat plates. The bands were quantified by the AMBIS radioimaging system, and the image density was
found to be in the linear range (3).
Caco-2 cells (passages 76-80) were grown in DMEM (25 mM glucose) supplemented with 20% heat-inactivated fetal bovine serum, 4 mM glutamine, 100 units/ml penicillin, and 100 µg/ml streptomycin in a humidified atmosphere containing 5% CO2. Confluent monolayers were subcultured every 7 days by treatment with 0.05% trypsin-EDTA in phosphate-buffered saline. In some experiments, the cells were plated at a density of 2 × 106 cells on plastic tissue culture 75-cm2 flasks and were harvested 3-12 days after plating. For the ligand uptake studies, cells were grown as epithelial layers by high density seeding (1.5 × 106 cells/filter) onto nitrocellulose membrane filter inserts (Millicell-HA, 30-mm diameter, 0.45 µM pore size). The formation and integrity of monolayers were assessed by the development of significant transepithelial resistance of 250-300 ohms/cm2 over the resistance of filter alone. The filter grown cells that were treated with NEM were also measured for transepithelial resistance, which was found to be similar to that of cells not treated with NEM. All resistance readings were measured with a Millicell-ERS Voltohmeter (Millipore Corp.).
NEM Treatment of Postconfluent Caco-2 Cells Grown on Culture InsertsFilter grown Caco-2 cells were incubated with NEM
(1012 to 10
6 M) for 16 h,
and the cells were harvested and homogenized in 1 ml of 10 mM Tris-HCl buffer containing 140 mM NaCl and
0.1 mM PMSF. Untreated and NEM-treated cell homogenates
were subjected to nonreducing SDS-PAGE and immunoblotting. Using
another set of filters similarly treated with NEM, the basolateral
binding of the ligand, TC II-[57Co]Cbl (500 fmol), was
determined as described earlier (6). Total TC II-R activity was
determined in these cells by the DEAE-Sephadex method using Triton
X-100 (1%) extract of the harvested cell homogenates prepared using 1 ml of 10 mM Tris-buffered saline containing 0.1 mM PMSF.
Postconfluent Caco-2
cells were first incubated with NEM (106 M)
for 8 h, the medium was replaced with fresh medium containing [3H]NEM (4 × 106 dpm/T-75 flask,
10
6 M), and the cells were incubated for an
additional 8 h at 37 °C. The cells were harvested, homogenized
in Tris-HCl buffer, pH 7.5, containing 140 mM NaCl and 0.1 mM PMSF (TBS). The homogenate was centrifuged for 60 min at
100,000 × g, and the pelleted membrane was
rehomogenized in the same buffer and extracted with Triton X-100 (1%).
The cellular homogenate, total membranes, cytosol, and the
immunoprecipitated fraction obtained using Triton X-100 extract of the
total membranes and antiserum to TC II-R or CI-MPR were subjected to
nonreducing SDS-PAGE. The gel was treated with EN3HANCE and
dried, and the bands were visualized by fluorography. In some
experiments, the cells were incubated for 8 h with NEM (10
6 M), and then
[35S]methionine (200 µCi/flask) was added and cells
were incubated for an additional 8 h. Prior to labeling, the cells
were incubated with methionine-free DMEM for 30 min. Further
processing, extraction, and immunoprecipitation of labeled TC II-R was
carried out as above.
Cells were first
incubated with or without NEM (106 M) for
8 h and then with methionine-free medium for 30 min. The medium was removed, and fresh medium containing [35S]methionine
(200 µCi/flask) was added and incubated for 1 h in the presence
and absence of NEM (10
6 M). The medium was
removed, and the cells were washed with medium maintained at 4 °C
and incubated with fresh medium in the absence and presence of NEM
(10
6 M) but containing methionine (20 mM) for 0-16 h. Cells were harvested and extracted with
Triton X-100, and the radioactivity was immunoprecipitated with TC II-R
antiserum and protein A-Sepharose. The immunoprecipitated material was
treated with SDS, and the liberated radioactivity was subjected to
nonreducing SDS-PAGE (7.5%), and the bands were visualized by
fluorography.
Biotinylation of the basolateral
surface of Caco-2 cells incubated with NEM (1012 to
10
6 M) was carried out by adding
5,5
-dithiobis(2-nitrobenzoic acid), sulfosuccin imidobiotin (0.5 mg/ml) to the basolateral compartments of filter-grown monolayers
(12-day growth) and was performed a total of three times for 30 min
each at 4 °C in PBS containing 0.1 mM CaCl2,
1.0 mM MgCl2. The cells were then washed six
times in PBS containing 0.1 mM CaCl2,
MgCl2 and 50 mM glycine (5 min each) at
4 °C. The cells were then harvested and extracted with PBS
containing Triton X-100 (1%). The extract was immunoprecipitated with
TC II-R or CI-MPR antiserum (25 µl) and protein A-Sepharose (100 µl
of 1:1 suspension in PBS). The washed immunopellet was subjected to
nonreducing SDS-PAGE (7.5%), the bands were transferred to
Nitrocellulose membranes and probed with 125I-streptavidin
(3 × 107 dpm/blot), and the bands were visualized by
autoradiography as described above. In some experiments, filter-grown
Caco-2 cells incubated first with NEM (10
6 M)
for 16 h were washed with DMEM and then incubated for 15 min with
DMEM containing cycloheximide (200 µg/ml) and then chased for 0-60
min with the same medium but in the absence of NEM. Basolateral surfaces of cells that were not incubated with either NEM or
cycloheximide or with both were biotinylated and processed for SDS-PAGE
and detection for biotinylated TC II-R as before.
To study the effects of NEM and other SH-reagents on the
basolateral expression of de novo synthesized TC II-R,
filter-grown Caco-2 cells were metabolically labeled and processed as
follows; NEM-treated (106 for 16 h) cells were
pulsed with [35S]methionine (200 µCi/filter) for 1 h at 37 °C. The cells were then washed with DMEM and chased with
NEM-free DMEM containing nonradioactive methionine (10 mM)
for 0-2 h. At each time interval, the cells were washed with ice-cold
DMEM, followed by treatment of the basolateral surface with TC II-R
antiserum (25 µl) for 45 min at 5 °C. The cells were washed with
cold Tris-buffered saline to remove the excess antiserum, harvested,
and extracted with Tris-buffered saline containing Triton X-100 (1%).
The extract was treated with protein A-Sepharose (150 µl of 1:1
suspension), and the radioactivity precipitated was released using
SDS-sample buffer. The samples were subjected to nonreducing SDS-PAGE
as described before.
In some experiments, filter-grown cells were first treated with MMTS
(106 M) for 16 h and then pulsed for
1 h with [35S]methionine (200 µCi/filter) at
37 °C. The cells were then chased with MMTS-free DMEM containing
nonradioactive methionine (10 mM) and DTT
(10
4 M) for 0-120 min. At each time
interval, the basolateral cell surface was treated with TC II-R
antiserum as above. Following the separation of [35S]TC
II-R present in the basolateral surface by immunoprecipitation with
protein A-Sepharose, the immune supernatant (representing intracellular
labeled TC II-R) was reimmunoprecipitated with TC II-R antiserum and
protein A-Sepharose as before. The intracellular and the basolateral
labeled TC II-R immunprecipitated was subjected to SDS-PAGE, the bands
were visualized by fluorography, and the image density was quantified
by the AMBIS radioimaging system.
Protein in all samples was determined according to Bradford (20). In some experiments, [35S]TC II-R (10,000-15,000 dpm) obtained from NEM-treated and untreated cells was digested with Endo H or PNGase F or with sialidase followed by treatment with O-glycosidase as described earlier (1, 21).
TC II-R reduced and treated with the sulfhydryl-modifying agents, NEM, IAM, or MMTS (Table I), was assayed for TC II-[57Co]Cbl binding by the DEAE-Sephadex method (16). This method, which uses charge-based separation of receptor bound and free ligand, revealed >90% loss of ligand binding activity only when these reagents were added following the reduction of TC II-R in the presence of 4 M urea. Treatment with urea alone or with urea and the SH reagents had no effect on ligand binding by TC II-R. In the absence of urea but following reduction, all three reagents inhibited ligand binding by about 74%. Nearly 85% of the activity lost was regained following treatment of the MMTS-modified TC II-R with DTT, while treatment with DTT of TC II-R alkylated with IAM or NEM had no effect (Table I). To confirm that loss of ligand binding as assessed by the DEAE-Sephadex method was not due to an artifact of an altered charge on the modified TC II-R molecule, we carried out chemical cross-linking of the reduced and SH-modified TC II-R with 125I-TC II-Cbl (Fig. 1). 125I-TC II-Cbl was able to bind only to the native untreated (UT) receptor in the absence of excess unlabeled TC II-Cbl but not in its presence. The size of the 105-kDa band detected was consistent with the size of the TC II-R·TC II-Cbl complex (62 plus 43 kDa). No cross-linked product was noted using reduced TC II-R that was treated with SH-modifying agents, NEM, IAM, or MMTS.
|
To quantify the number of free and disulfide-bonded SH groups of TC II-R, pure TC II-R was titrated with DTNB and [3H]NEM (Table II). When either of these two reagents was added to TC II-R, no SH groups were revealed, and no ligand binding was lost. However, in the presence of 4 M urea, both reagents revealed the presence of two free SH groups, and modification of these two free SH groups did not result in loss of ligand binding. When the receptor was reduced with 2-mercaptoethanol and then modified, six SH groups were revealed with 75% loss of ligand binding. These results suggested that at least three disulfide bonds are accessible to the reducing agent, reduction of which resulted in nearly 75% loss of ligand binding. When TC II-R was reduced in the presence of 4 M urea and then treated with DTNB or [3H]NEM, the loss of binding was complete with the modification of 10 SH groups (Table II). Taken together, these results suggested that the two free and the two SH groups that form one of the disulfide bonds are buried within the molecule. While the modification of the free buried SH groups had no effect on the ligand binding activity, the disruption of disulfide bonds by reduction altered the folding of TC II-R such that it assumed a more linear conformation as revealed by mobility changes on nonreducing SDS-PAGE. The consequence of disruption of all the disulfide bonds was complete loss of ligand binding.
|
Direct evidence for the increase in the apparent molecular mass of TC
II-R following its reduction was obtained by determining the size of TC
II-R on SDS-PAGE (Fig. 2). The size of TC
II-R modified by MMTS (lane 3) was 10-kDa higher than the
untreated TC II-R (lane 1) or TC II-R that was first
modified by MMTS and then treated with DTT (lane 2). Similar
reduced mobility on nonreducing SDS-PAGE with apparent increase in the
molecular mass by 10 kDa was also noted following reductive alkylation
with NEM or IAM (data not shown). These results clearly indicated that
disruption of disulfide bonds of TC II-R and the resulting folding
alterations are responsible for the loss of ligand binding. Although
in vitro studies revealed that intramolecular disulfide
bonds are important in ligand binding, we sought to examine their
importance in the in vivo folding and trafficking of TC
II-R.
Effect of NEM on TC II-R Activity and Protein Levels in Caco-2 Cells
Incubation of postconfluent Caco-2 cells grown on culture
inserts with NEM (1012 to 10
6
M) for 16 h resulted in a progressive and parallel
loss of TC II-[57Co]Cbl binding to the cell extracts
(determined using Triton X-100 (1%) extract of the cell homogenate)
and in the basolateral surface (determined by binding the ligand to the
basolateral surface at 4 °C). Nearly 50 and 90% of both the total
and basolateral cell surface receptor activity was lost at NEM
concentrations of 10
8 and 10
6
M, respectively (Fig. 3,
left panel). Loss of TC II-R activity was not due to loss of
TC II-R protein, since quantitative immunoblot analysis using the cell
homogenates from NEM-treated cells (Fig. 3, right panel)
revealed no changes of TC II-R protein levels at any concentration of
NEM. However, the physical state of TC II-R was different, being a
dimer of molecular mass of 124 kDa below an NEM concentration of
10
8 M or a monomer of 72 kDa at NEM
concentrations of 10
8 M or higher.
The molecular mass of 72 kDa noted for the TC II-R monomer when the
cells were incubated with NEM concentrations 10
8
M was 10 kDa higher than the molecular mass of TC II-R
monomers detected by immunoblotting using Triton X-100 extract of
Caco-2 cell homogenates from cells that were not exposed to NEM (Fig. 4A, left part,
lane 2), or pure placental TC II-R monomer (lane 1). This observation suggested that the monomer with a molecular mass of 72 kDa may be formed due to intracellular alkylation of TC II-R
that caused it to attain a more linear extended structure with
decreased mobility on SDS-PAGE. To address this issue, filter-grown Caco-2 cells were labeled with [3H]NEM (Fig.
4A, right part, lane 1) alone or with
[35S]methionine (lane 2) in the presence of
10
6 M NEM. Nonreducing SDS-PAGE (Fig.
4A, right part) of immunoprecipitates obtained
from cell extracts from both [3H]NEM (lane 1)
and [35S]methionine (lane 2) labeled cells
revealed a single band of molecular mass of 72 kDa. These experiments
together with the observation that immunoblot analysis of NEM-treated
cells revealed no 62-kDa form of the unmodified TC II-R (Fig. 3,
right panel) suggest strongly that NEM modified newly
synthesized TC II-R. It is interesting to note that under our
experimental conditions only six or seven cellular proteins were
labeled by [3H]NEM (Fig. 4B, lane
1). The cytosol (lane 2) and the Triton X-100 insoluble
membrane fraction (lane 3) demonstrated a very similar pattern of three labeled proteins, but with a higher proportion of
these proteins in the insoluble fraction (lane 3). On the
other hand, the Triton X-100 soluble fraction (lane 4)
revealed a major protein with a molecular mass of 72 kDa and a few
minor bands. This major band was immunoprecipitated with antiserum to
TC II-R (lane 5), and no radioactivity from this fraction
could be immunoprecipitated with antiserum to CI-MPR (lane
6). These results have shown that treatment of Caco-2 cells with
low concentrations of [3H]NEM results in the
incorporation of the label into very few cellular proteins, and density
scanning of the fluorograph (lane 1) revealed that labeled
TC II-R represented nearly 25% of the total radioactivity incorporated
into proteins.
The lack of detection of the unmodified TC II-R by immunoblotting
suggested that the half-life of TC II-R is considerably less than
16 h, the time period of incubation of cells with NEM. In
addition, this observation also suggested that NEM alkylated the
newly synthesized TC II-R before it had a chance to form its disulfide
bonds. To address this issue, pulse-chase labeling of Caco-2 cells was
carried out with [35S]methionine in the absence and
presence of NEM (Fig. 5) to determine the
half-life of TC II-R. Nonreducing SDS-PAGE of [35S]TC
II-R immunoprecipitated from cell extracts revealed a single band with
molecular mass of 72 and 62 kDa, when the cells were labeled in the
presence and absence of NEM, respectively (left panel).
Quantitation of these bands demonstrated a very similar decay pattern
(right panel) following a chase period of up to 16 h,
and the t1/2 for both the native 62-kDa and modified
72-kDa TC II-R was 7.5 h. The lack of surface expression of TC
II-R activity in NEM-treated cells (Fig. 3), despite the lack of effect
on its turnover and protein levels, suggested that either the inactive extended monomer reaches the surface membrane or it is retained in the
intracellular compartments due to misfolding. To test directly these
possibilities, basolateral surface TC II-R protein levels were
determined during the incubation of cells with various concentrations of NEM as well as during the recovery of cells from NEM treatment.
TC II-R Protein Is Not Expressed in the Basolateral Surface of NEM-treated Cells
Domain-specific biotinylation of the
basolateral cell surface of filter-grown Caco-2 cells treated with
various concentrations of NEM revealed that TC II-R protein gradually
disappeared from the basolateral cell surface (Fig.
6A), and quantitation of cell surface protein levels revealed that at NEM concentrations of 108 and 10
6 M, the cell surface
loss of TC II-R protein was 50 and 100%, respectively. To test whether
the loss of cell surface TC II-R protein could be reversed,
domain-specific biotinylation of the basolateral cell surface was
carried out using cells that were treated with 10
6
M NEM for 16 h and then washed with NEM-free medium,
incubated for 15 min with medium containing cycloheximide (to inhibit
protein synthesis), and then chased in NEM-free medium containing
cycloheximide for up to 60 min (Fig. 6B). Although cell
surface TC II-R protein levels in cells treated with cycloheximide
alone for 15 min (lane 1) were lower than surface levels
from cells that were not treated (lane 2), no TC II-R could
be detected on the cell surfaces of cells that were chased with
NEM-free medium for 0 (lane 3), 30 (lane 4), and
60 (lane 5) min. Similar results were obtained following chase of cells that were treated with NEM and then metabolically pulsed
with [35S]methionine for 1 h in the presence of
10
6 M NEM (Fig. 6C). Labeled TC
II-R noted in the basolateral cell surface in control cells (lane
1) was absent following chase for 30 (lane 2), 60 (lane 3), 120 (lane 4), and 240 (lane
5) min in the presence of NEM-free medium. These results clearly
established that in NEM-treated cells, cell surface expression of TC
II-R is inhibited and that this inhibition is due to intracellular retention of a misfolded protein. To test whether NEM treatment affected the basolateral delivery of other proteins, steady state levels of CI-MPR (Fig. 6D) was determined by biotinylation
of the basolateral domain of NEM-treated (lane 1) and
untreated cells (lane 2). NEM treatment of Caco-2 cells did
not result in the loss of steady-state levels of CI-MPR (~275 kDa) at
this location.
Inhibition of Disulfide Bonding of TC II-R Affects Its Post-TGN Trafficking
TC II-R obtained from cells labeled with
[35S]methionine either in the presence or absence of NEM
was insensitive to Endo H treatment but was equally sensitive to
treatment by PNGase F, revealing a mobility shift of 2 kDa (Fig.
7, top). These results indicate that both the native 62-kDa and the NEM-modified 72-kDa forms
of TC II-R are processed similarly with respect to the maturation of
their single high mannose type of N-linked sugar chain to
the complex type. When the native or the modified forms of TC II-R (Fig. 7, bottom) were digested with either sialidase alone
or with sialidase and O-glycanase, a shift in the mobilities
was also noted. However, the shift corresponding to about 4 kDa noted with sialidase treatment of the NEM-modified TC II-R was less than the
shift of about 8 kDa noted by sialidase treatment of the native 62-kDa
TC II-R. To test whether the intracellular retention of TC II-R in
NEM-treated cells is due to its misfolding caused by disulfide bond
disruption, the cells were treated with MMTS instead of NEM.
When the cells grown on culture inserts were first treated with MMTS
and later withdrawn from exposure to MMTS and incubated with DTT for
various intervals of time (Fig. 8,
left, top part), the basolateral surface ligand
binding activity rose gradually with time, and 90% of steady state
ligand binding was recovered in 120 min of exposure with DTT. Upon
pulse labeling of cells with [35S]methionine in the
presence of MMTS for 1 h, followed by chase with MMTS-free medium
containing nonradioactive methionine and DTT, labeled TC II-R with a
molecular mass of 72 kDa disappeared slowly from the cell interior with
the appearance of the 62-kDa form of TC II-R on the basolateral cell
surface. By 120 min, modified labeled TC II-R present inside the cells
was completely converted to the native receptor and was expressed on
the basolateral cell surface (Fig. 8, right). Quantitation
of the these radioactive bands (Fig. 8, left, bottom
part) revealed that the t1/2 for the conversion
to the native fully folded form and basolateral surface expression was
approximately 25 min.
The role of disulfide bond formation in the folding process and in
the acquisition of transport competence has been well established for a
number of proteins (22, 23). One approach to study the mechanism of
disulfide bond disruption and its effect on the intracellular vesicular
transport and function of cellular proteins is to expose the cells to
the thiol-reducing agent DTT. When used below the concentration of 1 mM, DTT has been known to inhibit the disulfide bond
formation of newly synthesized proteins without affecting the redox
state of living cells (24). While this approach may be suitable for
studying the role of disulfide bonds in the vesicular transport of
secretory proteins that are secreted constitutively, it may not be
suitable for studying the membrane-targeted proteins. To date, no
studies are available describing the effect of SH group modification of
a membrane protein and the resulting misfolding on its vectorial
targeting to the plasma membrane domain in a polarized epithelial cell.
We have addressed the issue of the role of intramolecular disulfide
bonding of TC II-R in ligand binding and intracellular trafficking in
human intestinal epithelial Caco-2 cells by exposing these cells to
very low concentrations (106 M) of
SH-modifying agents, such as NEM and MMTS. However, prior to studies
with cells, it was important to establish the number and nature (free
or disulfide-bonded) of SH groups present in human TC II-R.
Titration (Table II) of TC II-R with DTNB and [3H]NEM
revealed 10 half-cysteines, of which two were free and eight were
involved in intramolecular disulfide bonding. Furthermore, the two free half-cysteines and the two SH groups that are involved in
intramolecular disulfide bonding are buried in the molecule and could
be titrated only in the presence of urea. The other six cysteines that
are involved in disulfide bonding are easily accessible to the
SH-modifying agents. Although modification of the free SH groups of TC
II-R had no effect on its ligand binding, disulfide bond disruption of
TC II-R resulted in complete loss of ligand binding (Table I and Fig.
1), and this was due to the formation of a more linear form of TC II-R.
Furthermore, loss of receptor activity and the formation of an extended
TC II-R molecule by all of the SH-specific reagents suggest that the
same reduced SH groups are modified by all three reagents. NEM and IAM
are known to modify free SH groups in proteins by forming a
nonreversible thio-ether bond with the reduced thiol group (25). In
contrast, MMTS introduces a much smaller group (-SCH3) into
proteins by forming a disulfide bond with the reduced cysteines. This
disulfide bond is susceptible to cleavage by reducing agents like DTT,
and therefore the effects of MMTS are reversible (26). When modified
with MMTS, TC II-R lost activity and demonstrated an extended more
linear molecule (Fig. 2), and both effects were reversed following DTT
treatment of the MMTS-modified receptor. These results have
demonstrated that the loss of TC II-R activity following disulfide bond
disruption is not due to the nature and the size of the reactive group
of the SH-modifying agent, since IAM and MMTS with smaller groups also
inhibited as effectively as NEM, which contains a bulkier group. The
apparent increase in molecular mass of TC II-R due to disulfide bond
disruption noted in this study is not a unique situation. Other
receptors such as the cation-independent mannose 6-phosphate receptor
(27), neurotensin receptor (28), and -adrenergic receptor (29)
behave similarly on nonreducing SDS-PAGE following their reductive
alkylation.
The loss of total and basolateral TC II-R activity without loss of total cellular TC II-R protein (Fig. 3) suggested that NEM treatment of Caco-2 cells resulted in the inactivation of ligand binding and that this inactivation was not due to the loss of cellular TC II-R protein. Immunoblotting (Fig. 3), using homogenates of Caco-2 cells treated with NEM, or SDS-PAGE (Fig. 4A) of the immunoprecipitates of cell extracts from cells labeled with [3H]NEM or with [35S]methionine in the presence of NEM revealed the presence of TC II-R monomers with a molecular mass of 72 and not 62 kDa. The detection of only the modified 72-kDa TC II-R in NEM-treated Caco-2 cells (Figs. 3 and 4A) clearly indicated that incubations with NEM resulted in the alkylation of TC II-R either co-translationally or soon after synthesis before it can form intramolecular disulfide bonds. These results suggested that TC II-R turns over rapidly in these cells with a t1/2 less than 16 h, the time period that cells were exposed to NEM. Pulse-chase (Fig. 5) labeling in the presence and absence of NEM confirmed this observation and showed that the 72-kDa species of TC II-R in NEM-treated cells had the same time of decay with a t1/2 of 7.5 h as the native labeled 62-kDa TC II-R. These results have clearly established that due to its rather fast turnover, TC II-R is selectively modified by NEM. Nearly 45-50% of the [3H]NEM in the Triton X-100 extract of Caco-2 cells (which completely solubilizes membrane-bound TC II-R (1)) was on TC II-R, the rest being on three other proteins with molecular masses of 116, 60, and 55 kDa (Fig. 4B, lane 4).
Lack of a more rapid degradation of the misfolded TC II-R relative to the native TC II-R is a surprising result, since inhibition of disulfide bonding in some proteins leads them to undergo rapid degradation in the ER by a nonlysosomal pathway (30, 31). However, lack of rapid degradation of the misfolded 72-kDa TC II-R in the ER may be due to (a) failure of the ER quality control mechanism to detect and direct the modified (misfolded) TC II-R for degradation or (b) relatively rapid exit of the misfolded TC II-R from the ER. Further studies are needed to address these issues. In contrast to TC II-R, NEM treatment of Caco-2 cells did not result in either modification or the basolateral secretion of TC II, the ligand (data not shown). TC II, a nonglycoprotein Cbl binder that contains intramolecular disulfide bonds,2 is basolaterally secreted in these cells (32). In addition, under our experimental conditions, treatment of cells with low concentrations of NEM did not affect the steady-state levels of CI-MPR at the basolateral cell surface (Fig. 6D). CI-MPR, a single polypeptide of molecular mass ~275 kDa and a transmembrane protein that contains several intramolecular disulfide bonds (27), is also targeted basolaterally in Caco-2 cells (33). The inability of low concentrations of NEM to modify CI-MPR and thus inhibit its basolateral targeting may be due to its longer half-life (t1/2 = 25-27 h).3 It is interesting to note that under our experimental conditions of labeling, the bulk (>95%) of the labeled NEM was incorporated into six or seven proteins ranging in molecular mass between 43 and 116 kDa (Fig. 4B, lane 1).
The similar apparent size alterations due to inhibition of disulfide bonding of the isolated mature 62-kDa TC II-R and TC II-R synthesized in Caco-2 cells suggested that in these cells the MMTS- or NEM-modified TC II-R is processed similarly to the native receptor. These observations were confirmed by the demonstration of insensitivity of both the native and NEM-modified TC II-R to treatment with Endo H but sensitivity to treatments with PNGase F and with O-glycanase. However, the mobility shift following digestion by sialidase alone was not the same for the native and the modified TC II-R, suggesting that not all O-linked sugars are sialylated. This difference could be due to differences in the in vitro affinity of sialidase toward the modified receptor or to an in vivo altered affinity of the sialyltranferase toward the modified TC II-R. Despite this uncertainty, the observation that both the N-linked and O-linked sugars of TC II-R are sialylated indicated strongly that the modified TC II-R is able to exit the ER and reach the trans-Golgi region, the site where sialylation of both N-linked and O-linked sugars occur (34-36).
Treatment of Caco-2 cells with NEM resulted in the loss of basolateral TC II-R activity (Fig. 3) and protein (Fig. 6, A-C). These results indicated that NEM-modified TC II-R, although able to travel to the trans-Golgi, was unable to undergo further trafficking to the basolateral membranes. Since the modified TC II-R, as demonstrated by enzymatic deglycosylation, contains sialic acid and thus is able to undergo sialylation of both its N- and O-linked sugars, the site of its intracellular retention is most probably the TGN. Several possibilities exist as to why the modified TC II-R does not undergo post-TGN trafficking. TC II-R, which is synthesized as a single polypeptide with a molecular mass of 45 kDa, is post-translationally modified to a mature form with a molecular mass of 62 kDa and then expressed in the plasma membranes as a homodimer with a molecular mass of 124 kDa. Following reductive alkylation of the membranes, the apparent molecular mass of membrane-bound TC II-R is 144 kDa (1). This observation suggests that both monomers of TC II-R maintain their intramolecular disulfide bonds during their dimerization. Thus, it is possible that the modified TC II-R is unable to dimerize in the plasma membranes or in the post-TGN vesicles. However, this is unlikely, since the reduced and alkylated 72-kDa TC II-R when reconstituted in egg phosphatidylcholine/cholesterol (4:1 molar ratio) liposomes was able to dimerize, like the native 62-kDa TC II-R (data not shown). Moreover, dimerization of TC II-R is due to its strong hydrophobic interactions with a rigid ordered lipid bilayer and does not appear to be affected by its folding alterations (4). A more likely possibility is that the folding alterations of TC II-R due to inhibition of disulfide bond formation are responsible for the inhibition of post-TGN trafficking to the basolateral membranes. The conversion of the 72-kDa modified TC II-R to the native 62-kDa TC II-R and the appearance of basolateral TC II-R activity and protein by DTT incubation of MMTS-treated cells support the idea that disulfide bonding is required for the final stages of TC II-R trafficking from the TGN to its location in basolateral membranes.
How does altered folding of TC II-R due to disulfide bond disruption inhibit its post-TGN trafficking to the basolateral surface without affecting its vesicular transport from the ER and through the Golgi? Sorting of basolateral membrane-destined proteins from the TGN is initiated following the interaction of the cargo protein containing the conformationally accessible sorting signal with either coat protein of N-ethylmaleimide-sensitive factor (NSF)-dependent coated vesicles (37-39) or with adapter proteins, such as AP-1, of clathrin-coated vesicles (40). This interaction leads to the basolateral localization of the cargo protein. Although the misfolded TC II-R is able to be transported up to the TGN independent of the vesicular pathway (NSF-dependent or clathrin-coated vesicular pathway) involved, the mechanism of its retention in the TGN is not known. It is possible that disruption of disulfide bonds of TC II-R may lead to the inaccessibility of the basolateral targeting sequence/signals to be recognized and interact with either the coat protein or with other adapter proteins. Other possibilities for the inhibition of post-TGN trafficking of TC II-R due to NEM or MMTS treatment of Caco-2 cells must also be considered. Inhibition may be due to the inactivation of the N-ethylmaleimide-sensitive factor/soluble NSF attachment protein/SNAP receptor (NSF-SNAP-SNARE) machinery, which has been shown to be important in the basolateral targeting of proteins from the TGN in polarized Madin-Darby canine kidney cells (41). Alternatively, NEM may also inactivate other chaperons such as Rab 8, a small GTPase that is thought to be involved in the post-Golgi trafficking of basolateral proteins in polarized epithelial Madin-Darby canine kidney cells (42). However, these possibilities are unlikely for the following reasons. First, in many of the in vitro membrane transport reconstitution assays, inactivation of NSF was achieved using 0.4-1 mM of NEM (43-45), a concentration nearly 400-1000-fold higher than the maximum NEM concentration of 0.001 mM used in this study. Second, at NEM concentrations as low as 10 nM, an effect on TC II-R trafficking could be noted, with nearly 50% of it being retained intracellularly. Furthermore, it is not known whether such low levels of NEM or MMTS used in this study can modify any of the proteins involved in vesicular budding, transport, or fusion events or whether Rab 8 is a NEM-sensitive protein. Third, the ability of DTT to reverse the misfolding and intracellular retention of TC II-R that resulted in its increased basolateral expression suggests strongly that disulfide bond disruption of TC II-R is responsible for the inhibition of its transport to the basolateral membranes. Finally, incubations with NEM had no effect on the basolateral targeting of CI-MPR in these cells, suggesting strongly that the noted effects of NEM on post-TGN trafficking of TC II-R are not due to NEM inactivation of the chaperons that are implicated in basolateral targeting of proteins in polarized epithelial cells.
In summary, the results presented in this study have shown that intramolecular disulfide bond formation by TC II-R is important for the acquisition of ligand binding and post-TGN but not for trafficking from the ER. Further studies are needed to understand how the lack of disulfide bond formation of TC II-R affects its interaction with vesicular chaperons that are responsible for its basolateral delivery.
We thank Drs. Nancy M. Dahms and Mary C. Kennedy for critical evaluation of the manuscript.