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J Virol, July 1998, p. 5360-5365, Vol. 72, No. 7
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Role for 
2-Microglobulin in Echovirus Infection
of Rhabdomyosarcoma Cells
Trevor
Ward,1
Robert M.
Powell,1
Pamela A.
Pipkin,2
David J.
Evans,1
Phillip D.
Minor,2 and
Jeffrey W.
Almond1,*
School of Animal and Microbial Sciences,
University of Reading, Whiteknights, Reading RG6
6AJ,1 and
National Institute of
Biological Standards and Control, South Mimms, Potters Bar EN6
3QG,2 United Kingdom
Received 5 November 1997/Accepted 13 March 1998
 |
ABSTRACT |
A monoclonal antibody (MAb) that blocks most echoviruses (EVs) from
infecting rhabdomyosarcoma (RD) cells has been isolated. By using the
CELICS cloning method (T. Ward, P. A. Pipkin, N. A. Clarkson,
D. M. Stone, P. D. Minor, and J. W. Almond, EMBO J. 13:5070-5074, 1994), the ligand for this antibody has been identified
as 
2-microglobulin (2m), the 12-kDa protein that associates with
class I heavy chains to form class I HLA complexes. A commercial MAb
(MAb 1350) against 2m was also found to block EV7 infection without
affecting binding to its receptor, DAF, or replication of EV7 viral RNA
inside cells. Entry of EV7 into cells was reduced by only 30% by
antibody and cytochalasin D, an inhibitor of endocytosis mediated by
caveolae and clathrin-coated pits, but was not significantly reduced by
sodium azide. The block to virus entry by cytochalasin D was additive
to the block induced by antibody. We suggest that EV7 rapidly enters
into a multicomponent receptor complex prior to entry into cells and
that this initial entry event requires 2m or class I HLA for
infection to proceed.
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INTRODUCTION |
Echoviruses (EVs) are members of the
Enterovirus genus of the family Picornaviridae
and are important human pathogens. They are associated with a wide
spectrum of clinical syndromes, including rashes, diarrhea, aseptic
meningitis, respiratory disease, and possibly conditions such as
chronic fatigue syndrome. This range of clinical manifestations is
probably a reflection of virus tissue tropisms, which seem to be
mediated, at least in part, by utilization of a range of cellular
receptors.
Anti-cell surface monoclonal antibodies (MAbs) that block EV infection
have been isolated previously and have been used to determine the
identity of some of these receptors. In 1992 Bergelson et al.
demonstrated that EV serotypes 1 and 8 use the collagen receptor VLA-2
(6) by attaching to the 
2 subunit (7).
Previously, we and others have shown that a regulator of complement
activity, decay-accelerating factor (DAF), is the receptor for a range
of hemagglutinating EVs (3, 37). Other EVs appear to use
neither of these, but the identity of their receptor(s) is unknown.
Mbida et al. have isolated a MAb (MAb 143) that blocks most EV
serotypes from infecting a range of cell types. MAb 143 was also found
to block coxsackievirus A9 but not poliovirus or coxsackievirus
serotypes B1 to B6 (21). The ligand for MAb 143 was found by
affinity purification to be an unknown 44-kDa glycoprotein
(22). It was therefore suggested that the 44-kDa protein was
part of a multicomponent receptor complex used by most EVs to infect
cells. A direct role for the 44-kDa protein in virus attachment seems
unlikely, since MAb 143 blocks infection by the viruses that have been
shown to use other proteins, such as DAF (3, 37) and VLA-2
(6), as their primary receptors.
Here, we report the isolation of a MAb similar to that described by
Mbida et al. (21, 22) and describe the cloning and identification of its ligand. The ligand is 2-microglobulin (2m), a 12-kDa protein that associates with the class I HLA heavy chains (44 kDa) and presents antigenic peptides (20). We show that MAbs
to 2m block EV infection partly by reducing the entry of virus into
cells, although other postbinding effects cannot be ruled out.
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MATERIALS AND METHODS |
Cell culture and virus propagation.
Rhabdomyosarcoma (RD)
cells, Ohio HeLa cells, and COS cells were grown in Dulbecco's
modified Eagle's medium (DMEM) supplemented with 10% fetal calf serum
(FCS) unless otherwise stated. All EV serotypes (prototype strains)
were obtained from Colindale (Public Health Laboratory Service,
Colindale, United Kingdom) and were propagated in RD cells in
serum-free DMEM. Poliovirus (type 3, Leon) was propagated in Ohio HeLa
cells. The titers of stock virus preparations were determined as the
50% tissue culture infective dose (TCID50) in RD cells.
Antibodies and chemicals.
MAbs 854 and 918 were isolated
after immunizing mice with Ohio HeLa cell membrane extracts, as
described previously (23). MAb 854 is reactive against DAF
(37). The goat anti-mouse immunoglobulin--galactosidase conjugate used in the immunofocal assays (11) was from
Harlan Seralab, Loughborough, United Kingdom, and was used at a
dilution of 1/400. The anti-2m antibody, MAb 1350, was obtained as
ascitic fluid from Chemicon International Inc., Temecula, Calif. The
anti-enterovirus MAb 5-D8/1 was from Dako A/S, High Wycombe, United
Kingdom, and was used at a dilution of 1/200. In the immunofocal
assays, antibodies were used after dilution in phosphate-buffered
saline (PBS) containing 0.5% bovine serum albumin (Fraction V; Sigma).
Unless otherwise stated, all other chemicals were purchased from Sigma.
Soluble DAF (sDAF) was expressed in the yeast Pichea
pastoris and purified to >95% purity (26).
Virus-blocking assays.
Ninety-six-well plates of RD cells at
80% confluency were washed with serum-free DMEM and incubated with
50-µl volumes of MAb 1350 for 1 h at 37°C before the addition
of 50-µl volumes of EV. The plates were incubated at 37°C in a 5%
CO2 atmosphere for 24 or 48 h, and the cells were then
fixed and stained with Giemsa crystal violet.
Cloning of the MAb 918 ligand.
The previously described
(37) cloning technique CELICS was used. Briefly,
108 COS cells were transfected by electroporation
(10) with 100 µg of cDNA library from human umbilical vein
endothelial cells (HUVEC) in the high-expression vector pCDM8
(29) (a kind gift from Dave Simmons, Imperial Cancer
Research Fund, Oxford, United Kingdom). After 48 h of incubation
in tissue culture, transformants were screened by an immunofocal assay
(11) for MAb 918-reactive cells. MAb 918-reactive cells
stained blue and were isolated by using a fine capillary tube. Plasmid
DNA was then extracted from the isolated blue cells and transformed
into Escherichia coli (MC1063/P3) by electroporation
(15). The resultant E. coli colonies were then
pooled, and their plasmid DNA was extracted (8) and transfected into COS cells for a further round of CELICS. The E. coli clones from the second round of CELICS were grown
individually in Luria-Bertani broth overnight, and small-scale
preparations of their plasmid DNA were transfected into COS cells and
screened for MAb 918 reactivity. Positive cDNA clones were thus
isolated and sequenced.
Virus neutralization assay.
EV7 (1,000 TCID50)
in 40-µl volumes was incubated with purified 2m (0 to 20 µg in
PBS; Scripps Laboratories, San Diego, Calif.) for 1 h at 37°C.
Virus was then added to RD cells at 80% confluency in 96-well plates.
The RD cells were then incubated at 37°C (5% CO2) for 1 or 2 days before being fixed and stained with Giemsa crystal violet.
EV7 replication in RD cells.
RD cells (80% confluent) in
25-cm2 flasks were incubated in the presence or absence of
MAb 1350 (5 ml, diluted 1/250 in DMEM containing 10% FCS) for 1 h
at 37°C. The antibody was then removed, and 1 ml of EV7 at 1 TCID50/cell was added to the cells and allowed to adsorb
for 1 h at 37°C. The cells were then washed four times with 5-ml
volumes of DMEM. Antibody was added back to the cells, which were then
incubated for 16 h under normal growth conditions. An equal amount
of antibody was added to the control flask. The anti-2m MAbs were
then sequestered by addition of 20 µg of purified 2m to both
flasks. Virus yields from the flasks were titered on RD cells.
EV7 vRNA replication in RD cells.
Cells (5 × 106) were incubated in the presence or absence of MAb 1350 (5 ml, diluted 1/250 in DMEM with 10% FCS) for 1 h at 37°C. The
cells were then transfected with 6 µg of purified EV7 viral RNA
(vRNA) or poliovirus vRNA (27) by electroporation at 300 V
and 250 µF (10). The cells were seeded in 6-well dishes and incubated in DMEM containing 10% FCS and HEPES at 10 mM for 6 h. The cells were then washed four times with 3-ml volumes of PBS,
fixed with acetone-methanol (1:1) for 3 min, washed four times with
PBS, and stained for EV7-infected cells by using the anti-enterovirus
MAb 5-D8/1 in an immunofocal assay (11).
Anti-2m time-dependent block to entry of EV7.
RD cells
(2 × 107) were harvested from fully confluent
75-cm2 flasks by washing with PBS alone and then
resuspended in 1 ml of DMEM (10% FCS) at 4°C. MAb 1350 (1/50) was
added to the cells, which were then aliquoted into ice-cold 1.5-ml
plastic tubes at 2 × 106/tube. The tubes were
transferred to a 37°C water bath and incubated for various periods up
to 1 h before being placed back on ice. Radiolabelled EV7
(104 cpm) was then added to the cells and allowed to adsorb
for 1 h on ice. Nonadsorbed virus was removed by three washes with
1-ml volumes of ice-cold DMEM, each followed by centrifugation at 2,000 rpm in a Microfuge (MSE; Micro Centaur). The cells were incubated at
37°C for 5 min to allow adsorbed virus to enter. The cells were then
pelleted by centrifugation, and the amount of eluted radiolabelled
virus in the supernatants was determined by scintillation counting. The
cells were then resuspended in 100 µl of sDAF (100 µg/ml in PBS)
for 1 h on ice; sDAF was added in order to remove from the cell
surface by competition any virus that had not yet entered the cells or
become irreversibly bound into virus-cell complexes (26).
The cells were then pelleted, and the 35S counts in both
the supernatant and the cells were determined by scintillation
counting.
Time course of EV7 entry into RD cells.
RD cells were
harvested from fully confluent 75-cm2 flasks by washing
with PBS alone and were resuspended in 1 ml of DMEM (10% FCS) at
4°C. MAb 1350 (1/50) was then added to the cells, which were placed
in 1.5-ml plastic tubes at 2 × 107/tube. The tubes
were then transferred to a warm (37°C) room and were rotated for
1 h (six revolutions/min) to keep the cells in suspension. The
cells were then chilled on ice for 5 min before the addition of
105 cpm of radiolabelled EV7, which was allowed to adsorb
to the cells for 1 h on ice. Nonadsorbed virus was then removed by
three washes with 1-ml volumes of ice-cold DMEM, each followed by
centrifugation at 2,000 rpm in a Microfuge (MSE; Micro Centaur) in a
cold (4°C) room. The cell pellets were then resuspended in 1 ml of
DMEM with or without antibody, and the cells were aliquoted into fresh
1.5-ml tubes at 2 × 106/tube. The cells were
incubated at 37°C from 0 to 60 min to allow adsorbed virus to enter
them. The cells were then pelleted by centrifugation, and eluted
radiolabelled virus in the supernatant was determined by scintillation
counting. The cells were resuspended in 100 µl of sDAF (100 µg/ml
in PBS) for 1 h on ice; sDAF was added in order to remove from the
cell surface by competition any virus that had not yet entered the
cells (26). The cells were then pelleted by centrifugation,
and the 35S counts in both the supernatant and the cells
were determined by scintillation counting.
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RESULTS |
MAb 918 blocks EV infection.
We have previously described the
isolation of MAbs against the cell surface that block infection by
various enteroviruses (23, 37). As described previously, we
observed that one antibody, MAb 918, blocked infection of RD cells by a
range of EVs, including serotypes 1 to 6, 9, 12 to 19, 21, 24, 26, 27, and 29 to 33, and enterovirus 70. This includes viruses that have
previously been shown to utilize DAF (e.g., EV6, -13, -21, -29, and
-33) and VLA-2 (EV1) as their primary receptors (3, 6, 37).
We first determined that MAb 918 was not (and did not contain) an
antibody against DAF; this was done by transfecting a DAF cDNA clone
into mouse WOP cells and assessing antibody binding. Such cells did not
bind MAb 918, whereas they strongly bound the anti-DAF antibody MAb 854 (data not shown). Moreover, we were able to conclude that the MAb 918 blocking was a specific rather than a general property of ascites,
since other MAbs isolated at the same time had different enterovirus-blocking properties; most MAbs did not block EV infection, and one blocked poliovirus infection (MAb 280 [23]).
We then determined whether MAb 918 was directed against a cell surface
protein involved in attachment by assessing its ability to block the
binding of radiolabelled virus as described previously (37).
We included EV6 and -7 as well those viruses that do not utilize DAF
(or VLA-2), namely, EV4, -14, -18, and -31, in our assay. In no case
was blocking observed (data not shown). We therefore concluded that the
ligand for MAb 918 was not a primary receptor and therefore was
probably a secondary factor required for EV infection of RD cells after
the virus has attached to its receptor.
Identification of the MAb 918 ligand, using CELICS.
To
identify the putative secondary factor involved in EV infection, we
used CELICS to clone the MAb 918 ligand (37). The CELICS
method was developed for the cloning of cell surface proteins and is
based on a sensitive immunofocal screen exploiting anti-species antibodies conjugated to -galactosidase (11).
Approximately 108 COS cells were transfected with a HUVEC
cDNA library in pCDM8. Rare MAb 918-reactive cDNA-transformed cells
were identified by being stained blue after sequential incubations with
MAb 918, goat anti-mouse immunoglobulin--galactosidase-conjugated
antibody, and the -galactosidase chromogenic substrate
5-bromo-4-chloro-3-indolyl--D-galactoside (X-Gal). Just
four blue cells were found and isolated in the first round of
screening. No blue cells were found among control COS cells. Plasmid
DNA extracted from these four blue cells gave about 104
E. coli (MC1063/P3) colonies after transformation by
electroporation (15). The E. coli colonies were
pooled, and a small-scale preparation of their plasmid DNA was
transfected into 107 fresh COS cells. In this second round,
over 103 MAb 918-reactive blue cells were observed, and 40 were picked. Plasmid DNA was then extracted from the isolated blue
cells and transformed into E. coli. Many colonies were
obtained, and to determine which clones were MAb 918 reactive,
small-scale preparations of the cloned plasmid DNA were transfected
into COS cells. Of the 10 cDNA clones screened, 2 were MAb 918 positive, as indicated by their ability to cause the majority of cells
to turn blue in a CELICS assay. These clones contained inserts of 1 kb,
the sequences of which were 100% concordant with the cDNA sequence of
human 2m in the EMBL database (accession no. X07621).
2m was confirmed as the MAb 918 ligand by enzyme-linked
immunosorbent assay on purified commercial protein. Moreover,
fluorescence-activated cell sorter analysis of known 2m-negative and
-positive cells was consistent with this conclusion (data not shown).
Other anti-2m MAbs but not anti-major histocompatibility complex
antibodies block EV infection of RD cells.
To confirm a role for
2m in EV infection of RD cells, we repeated the blocking assays with
a commercially available anti-2m MAb, MAb 1350. This antibody was
higher titer than MAb 918 and, in addition, blocked infection by EV7
(Fig. 1A), -8, -11, -25, and -28 and CA9.
To further check that these blocking results were anti-2m specific,
we also performed the blocking assay in the presence of excess purified
2m. The results of this experiment (Fig. 1B) show that free 2m
protein inhibits the blocking action of MAb 1350. This indicates that
the blocking of EV infection is anti-2m specific. MAb 1350 was also
found to have no affect on poliovirus infection of RD cells (Fig. 1C).
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FIG. 1.
Anti-2m MAb 1350 blocks EV7 infection of RD cells. RD
cells in 96-well plates were incubated with MAb 1350 for 1 h in
tissue culture in the absence (A) or presence (B) of 2m (200 ng/well) and were then infected with 10 TCID50/cell of EV7.
MAb 1350-treated RD cells were also infected with the same titer of
poliovirus (C). After infection, the cells were incubated in tissue
culture for 24 h and then fixed and stained with Giemsa crystal
violet. Lane 1, no MAb; lanes 2 to 12, MAb 1350 at dilutions of 1/125
to 1/128,000.
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2m molecules are coexpressed on the cell surface with class I HLA
heavy chains. We therefore investigated the possible involvement
of the
class I heavy chain in EV infection. The panspecific anti-class
I MAb
W6/32 (
2) was used in virus infection-blocking assays.
This
MAb did not inhibit EV infection, suggesting that class I
antigens
recognized by W6/32 are not involved.
EV7 binding and neutralization.
We chose to study the
involvement of 2m in EV7 infection of RD cells. EV7 binding to these
cells is well characterized and can be blocked by an anti-DAF MAb, MAb
854 (12, 37). Neither MAb 1350 nor purified 2m protein at
concentrations of up to 20 µM inhibited EV7 binding to RD cells,
whereas the anti-DAF MAb blocked over 95% of binding (12,
37). Furthermore, in virus neutralization assays micromolar
concentrations of 2m had no effect on EV7 or EV11 virus titer. These
results indicate that EV7 does not interact directly with free 2m in
solution. However, they do not rule out the possibility that
cell-bound 2m directly interacts with viruses at a postattachment
stage.
2m is not involved in EV7 infection of all cell types.
We
next investigated whether semipermissive Ohio HeLa cells and permissive
MRC5 cells were also protected from infection by anti-2m antibody.
Like RD cells, MRC5 cells were protected by MAb 1350. Surprisingly,
however, neither MAb 1350 nor MAb 918 blocked infection of HeLa cells
even though these cells were shown by fluorescence-activated cell
sorter analysis to express levels of 2m similar to those of RD cells
(data not shown). In experiments performed to show whether 2m was
required for infection, Daudi cells, a B-cell line that does not
express 2m, were inoculated with EV7 and the infection of cells was
measured by immunofocal assay and compared with that of inoculated Raji
cells, a 2m-positive cell line. Both cell lines supported virus
infection. These results suggest a role for 2m in EV infection of
some but not all cell types.
Effect of anti-2m MAb 1350 on EV7 replication in RD cells.
The infection of RD cells by EV7 could be quantified easily by the
immunofocal staining method with a commercial MAb against EV coat
protein (MAb 5-D/8; Dako). Pretreatment of cells for 1 h with a
1/250 dilution of the anti-2 antibody (MAb 1350) resulted in a 95%
decrease in the number of cells that stained blue with the anti-coat
protein MAb at 6 h postinfection. Moreover, the same concentration
of MAb 1350 was found to cause a 95% reduction in EV7 yield at 16 h postinfection, as measured by TCID50 assay (Fig.
2). This latter assay was made possible
by the addition of purified 2m to the virus preparations to
sequester excess antibody so that replication was not blocked on
recipient cell monolayers, as described in Materials and Methods. The
absence of detectable virus coat protein in the majority of cells by
6 h postinfection suggests that the block to infection occurs at an early stage, possibly at penetration and/or uncoating. This conclusion was reinforced by transfecting EV7 and poliovirus vRNAs into
MAb 1350-treated cells. No significant inhibition was observed by the
immunofocal assay (data not shown).
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FIG. 2.
EV7 infection is blocked by MAb 1350. RD cells (80%
confluent) in 25-cm2 flasks were incubated in the presence
or absence of MAb 1350 as described in the text. The antibody was then
removed, and 1 ml of EV7 at 1 TCID50/cell was added to the
cells and allowed to adsorb for 1 h at 37°C. The cells were
washed, and the antibody was added back to the cells, which were then
incubated for 16 h under normal growth conditions. Antibody was
then added to the control flask, followed by the addition of 20 µg of
purified 2m to both flasks. The virus yields were then measured (see
text).
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MAb 1350 causes only a partial inhibition of EV7 entry into RD
cells.
Having established that MAb 1350 blocks neither virus
binding nor translation and replication of transfected vRNA, we
investigated the postbinding entry of virus into RD cells in the
presence of the antibody. We have shown previously that EV7 bound to
cells at 4°C can be displaced by the addition of excess recombinants DAF (26). To determine the dynamics of the MAb 1350-induced block to EV7 entry, RD cells were preincubated with MAb 1350 at 37°C
from 0 to 60 min before the addition of virus, which was allowed to
attach at 4°C. The cells were then moved to 37°C for 5 min and
resuspended in PBS containing sDAF at a level known to displace ~90%
of bound virus from the cell surfaces. Noneluted virus was measured and
compared to the levels in control cells, which had not been pretreated
with MAb 1350. Antibody treatment was found to induce a partial block
to entry of EV7 within minutes and reached a maximum block of 30%
after 60 min (Fig. 3). However, the
extent of this inhibition was significantly less than the 95% block to
virus infection observed under similar conditions. This result suggests
that although the anti-2m MAb has some effect on virus entry, its
inhibition of virus infection may involve other mechanisms.
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FIG. 3.
Anti-2m time-dependent block to virus entry. RD cells
were incubated with MAb 1350 for 0 to 60 min at 37°C and then chilled
on ice (see text). The cells were then incubated with
35S-radiolabelled virus on ice for 1 h before being
washed to remove nonadsorbed virus. The entry of virus into the cells
was then stimulated by incubation at 37°C for 5 min, the cells were
placed back on ice, and supernatants were removed. Nonentered virus was
then competed off the cell surfaces by the addition of sDAF (100 µg/ml), the cells were pelleted by centrifugation, and the
35S counts in the supernatant and the cell pellet were
determined by scintillation counting. The results shown are
representative of four independent experiments.
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In similar experiments, the rate of virus entry into cells was measured
after RD cells were pretreated with antibody for 1
h, after which
entry was allowed at 37°C for 0 to 60 min. Unlike
poliovirus
(
19), EV7 does not spontaneously elute from cells
in
substantial quantities (
26). MAb 1350 did not alter the rate
of spontaneous elution; most virus (~90%) remained associated
with
the cells at 1 h (Fig.
4A). Virus
entry (as measured by virus
becoming resistant to displacement by sDAF)
was rapid, reaching
a plateau by approximately 10 min (Fig.
4B and C).
Similar results
were obtained for virus entry as measured by virus
becoming resistant
to displacement by proteinase K (data not shown). As
discussed
above, MAb 1350 inhibited entry by about 30%, and this was
apparent
at all time points analyzed. By contrast, neither MAb 1350 that
had been pretreated with purified
2m nor the anti-class I MAb
W6/32 had any effect on virus entry (data not shown). Similar
experiments measured EV7 entry into HeLa cells pretreated with
MAb
1350. The antibody had no measurable effect.
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FIG. 4.
Time course of EV7 entry into RD cells. RD cells were
incubated with MAb 1350 for 1 h at 37°C and placed on ice.
35S-radiolabelled virus was then added to the cells, and
1 h later nonadsorbed virus was washed away (see text). The entry
of virus into cells was stimulated by incubation at 37°C for 0 to 60 min, and the eluted counts in the supernatants were determined (A).
Nonentered virus was then competed off the cell surfaces by the
addition of sDAF (100 µg/ml) and counted (B). Counts remaining in the
cell pellet were also determined (C). The results are expressed as
percent total virus bound and are representative of four independent
experiments.
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The use of RD cells in suspension in these experiments is unlikely to
have influenced their permissiveness for virus compared
to that of
cells in monolayers. This is because RD cells kept
in suspension for up
to 6 h postinfection showed productive infection
at a level
comparable to that of those in monolayers (data not
shown).
These results indicate that the anti-
2m antibodies partially inhibit
entry of EV7. However, the extent of this inhibition
of entry is not
sufficient to account for the full extent of the
block on infection. We
therefore considered whether virus might
enter cells via more than one
mechanism, only one of which would
be productive and subject to
inhibition by anti-
2m antibodies.
To determine whether caveolae or
non-clathrin- or clathrin-coated
pits have a role in EV7 infection,
these routes of endocytosis
were inhibited by preincubating cells with
cytochalasin D, a potent
inhibitor of actin-myosin polymerization and
thus of endocytosis
via pits and caveolae (
25). We found
that cytochalasin D treatment
also caused a partial block to EV7 entry
into RD cells, although
it did not block infection as determined by
cytopathic effect
and immunofocal assay. However, the time course of
entry of the
noninhibited fraction was consistently different from that
in
antibody-treated cells (Fig.
5).
Moreover, the block to entry
found in cells treated with both
cytochalasin D and antibody was
double that of the cells which received
single treatments. In
addition, a 1 h preincubation of cells in
0.1% sodium azide had
little effect on the entry of virus (data not
shown). Since both
of these chemical treatments inhibit endocytosis via
caveolae
and pits, the most likely explanation for these results is
that
our assay not only measures penetration of virus into cells but
also entry of virus into proteinase K-resistant receptor complexes
at
the cell surface. Formation of such receptor complexes would
prevent
elution of EV7 by recombinant sDAF. Our recently published
results on
EV7-DAF interaction also suggest that EV7 escapes neutralization
by
recombinant sDAF by entering into a receptor complex (
26).
Therefore, the results showing that the blocks to entry for
cytochalasin
D and antibody are additive indicate that recruitment of
virus
into a receptor complex may be inhibited by MAbs against
2m.
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FIG. 5.
Effect of cytochalasin D on EV7 entry into RD cells. RD
cells were incubated with cytochalasin D (cyt. D; 2 µg/ml) and/or MAb
1350 (anti-2m) for 1 h at 37°C and placed on ice.
35S-radiolabelled virus was then added to the cells, and
1 h later nonadsorbed virus was washed away (see text). The entry
of virus into the cells was stimulated by incubation at 37°C for 0 to
60 min. Nonentered virus was then competed off the cell surfaces by the
addition of sDAF (100 µg/ml). Counts remaining in the cell pellet
were determined. The results are expressed as percent total virus bound
and are representative of four independent experiments.
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Treatment of RD cells with specific inhibitors of caveolae uptake,
i.e., the phorbol ester phorbol myristate acetate (10 µM)
(
1,
33) or nystatin (25 µg/ml) (
1), 1 h before the
addition
of virus failed to block EV7 infection as measured by
immunofocal
staining at 6 h postinfection (data not shown). These
results
suggest that caveolae are not involved in the EV7 infectious
pathway.
| |
DISCUSSION |
A MAb directed against RD cells, MAb 918, was found to block EV
infection. We therefore cloned the cDNA encoding the ligand of MAb 918 by the CELICS cloning method. The ligand was identified as 2m. Use
of a commercial anti-2m antibody, MAb 1350, confirmed that
antibodies to 2m block EV infection of RD and MRC5 cells.
An antibody with properties similar to those described here has been
reported previously by Mbida et al. (21, 22). Their antibody, MAb 143, blocks infection by most EVs in a variety of human
and primate cell lines, including KB, P2002, Wish, Vero, and BGM cells,
although its action on RD and MRC5 cells was not reported. Since MAb
143 was found to affinity purify a 44-kDa protein, it is possible that
MAb 143 is directed against either 2m or class I HLA heavy chains.
These proteins would be expected to copurify as a complex under the
conditions used (22). Mbida et al. reported that their
purified protein neutralized EV11 in vitro (22). However, we
found that neither EV11 nor EV7 is neutralized by purified 2m, and
we also found that this protein does not induce A-particle formation in
the presence of the purified soluble receptor, DAF (unpublished data).
Also, we were unable to show blocking of virus infection by an
anti-class I HLA antibody. However, given that 2m exists primarily
on the cell surface as a complex with many haplotypes of class I HLA,
we cannot rule out the possibility that other anti-class I HLA
antibodies may block infection. An observation that argues against a
direct role for class I HLA is that Daudi cells, which do not express
HLAs, can be infected by EVs. However, Daudi cells may express other
cell surface proteins that can substitute for 2m in infection. The
inability of the anti-2m MAbs to block EV infection of HeLa cells
may also be due to the possible expression of other cell surface
proteins that can substitute for 2m and play a role in infection.
Some picornaviruses have been reported to have the capacity to use more
than one primary receptor (4, 5, 24, 30, 31). It is possible
that EVs can also use more than one secondary factor for infection.
It is not clear from our results at precisely what stage antibodies to
2m block EV infection. Naked vRNA transfected into RD cells was not
inhibited by the anti-2m antibodies. This suggests that the block
may occur at a stage in replication up to, and including, uncoating. We
measured virus uptake on the basis of labelled virus becoming attached
to the cell and progressing into a state in which it could not be
eluted with excess soluble receptor (DAF) or by protease digestion.
Although the anti-2m antibodies caused a partial block to this virus
uptake, the level of the block may be insufficient to account for the
95% block to virus infection. However, cytochalasin D or other
inhibitors of pit and/or caveoli entry did not inhibit EV7 infection.
This, together with the observation that the block to entry caused by
cytochalasin D was additive to that caused by the anti-2m
antibodies, suggests that entry via clathrin-coated pits and caveolae
may constitute dead-end entry mechanisms. Moreover, since uptake of EV7
is azide resistant, we suggest that virus may enter into receptor
complexes prior to penetration. We also speculate that anti-2m
antibodies block EV7 infection by affecting virus-receptor complex
formation.
The best-characterized role of 2m is its association with the 44-kDa
class I heavy chains forming the HLA complex at the cell surface. This
complex presents foreign antigens to T cells. There is, however, strong
evidence that the HLA and/or MHC complex has other roles in the biology
of the cell. Contact inhibition (14), platelet aggregation
(13), and many hormone receptor signal transduction systems
are influenced by class I expression. For example, it has been shown
that class I antigen heavy chains interact with the luteinizing hormone
receptor after binding its ligand, and it is thought that this
interaction is essential for luteinizing hormone receptor
micro-aggregation prior to signal transduction (34, 35).
Also, the insulin receptor contains the class I heavy chain, and its
activity can be blocked by antibodies to class I antigen
(16). Indeed, it has been suggested that class I antigen may
influence many receptors by facilitating their aggregation, which is
required for efficient signal transduction (16, 28, 34, 35).
If antibodies to 2m block aggregation and thereby influence signal
transduction events, they may induce a general down regulation of a
variety of cellular activities, some of which may be necessary for
productive entry of EVs.
This is the first reported observation that MAbs against 2m block EV
infection. However, it has previously been shown that MAbs to class I
antigen and 2m can block infection by other pathogens, e.g., simian
virus 40 (9, 36), adenovirus 2 and 5 (18), and
Theileria parva (32). These pathogens are thought
to use class I antigen as a receptor. Salmonella typhimurium
may also require class I antigen for invasion of cells (17).
On binding to the epidermal growth factor receptor, EGFR, the
signalling of which is regulated by class I antigen (28),
Salmonella induces a selective microaggregation of class I
antigen, 2m, CD44, and the fibronectin receptor,
51. It is therefore possible that some
invasive pathogens may share with EVs entry pathways or receptor complexes that are regulated by HLA and/or MHC antigens.
In conclusion, our results show that 2m, possibly as part of the HLA
class I complex, is required for EV infection of certain, but not all,
cell types. The block to infection is postattachment but prior to RNA
translation and replication. The precise mechanism by which 2m plays
a role in infection, including its possible role in signal transduction
mechanisms, is under further investigation.
| |
ACKNOWLEDGMENTS |
We thank Moy Robson for excellent technical support.
This work was funded by the Medical Research Council Programme Grant
G006199.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: School of Animal
and Microbial Sciences, University of Reading, Whiteknights, P.O. Box
228, Reading RG6 6AJ, United Kingdom. Phone: 44 118 318 901. Fax: 44 118 9316 537. E-mail: j.w.almond{at}reading.ac.uk.
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Abstract
Introduction
