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J Virol, March 1998, p. 1941-1948, Vol. 72, No. 3
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Mutational Analysis of the Virus and Monoclonal
Antibody Binding Sites in MHVR, the Cellular Receptor of the Murine
Coronavirus Mouse Hepatitis Virus Strain A59
David R.
Wessner,1
Paul C.
Shick,1
Jin-Hua
Lu,1,
Christine B.
Cardellichio,1
Sara E.
Gagneten,1,
Nicole
Beauchemin,2
Kathryn V.
Holmes,1,* and
Gabriela S.
Dveksler1
Department of Pathology, Uniformed Services
University of the Health Sciences, Bethesda, Maryland
20814,1 and
McGill Cancer Centre, McGill
University, Montreal, Quebec, Canada H3G 1Y62
Received 19 May 1997/Accepted 26 November 1997
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ABSTRACT |
The primary cellular receptor for mouse hepatitis virus (MHV), a
murine coronavirus, is MHVR (also referred to as Bgp1a or
C-CAM), a transmembrane glycoprotein with four immunoglobulin-like domains in the murine biliary glycoprotein (Bgp) subfamily of the
carcinoembryonic antigen (CEA) family. Other murine glycoproteins in
the Bgp subfamily, including Bgp1b and Bgp2, also can serve
as MHV receptors when transfected into MHV-resistant cells. Previous
studies have shown that the 108-amino-acid N-terminal domain of MHVR is
essential for virus receptor activity and is the binding site for
monoclonal antibody (MAb) CC1, an antireceptor MAb that blocks MHV
infection in vivo and in vitro. To further elucidate the regions of
MHVR required for virus receptor activity and MAb CC1 binding, we
constructed chimeras between MHVR and other members of the CEA family
and tested them for MHV strain A59 (MHV-A59) receptor activity and MAb
CC1 binding activity. In addition, we used site-directed mutagenesis to
introduce selected amino acid changes into the N-terminal domains of
MHVR and these chimeras and tested the abilities of these mutant
glycoproteins to bind MAb CC1 and to function as MHV receptors. Several
recombinant glycoproteins exhibited virus receptor activity but did not
bind MAb CC1, indicating that the virus and MAb binding sites on the N-terminal domain of MHVR are not identical. Analysis of the
recombinant glycoproteins showed that a short region of MHVR, between
amino acids 34 and 52, is critical for MHV-A59 receptor activity.
Additional regions of the N-terminal variable domain and the constant
domains, however, greatly affected receptor activity. Thus, the
molecular context in which the amino acids critical for MHV-A59
receptor activity are found profoundly influences the virus receptor
activity of the glycoprotein.
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INTRODUCTION |
Initial events in virus infection of
a cell include attachment of the virus to the cell, entry, and
disassembly of the virion. For most viruses, attachment is mediated
through a specific interaction between the virus attachment protein and
a cell surface receptor. Previous studies identified the murine biliary
glycoprotein MHVR (also referred to as Bgp1a or C-CAM) as
the primary cellular receptor for murine coronavirus mouse hepatitis
virus strain A59 (MHV-A59) (20, 53). This glycoprotein,
isolated from liver and intestinal brush border membranes of
MHV-sensitive BALB/c mice, binds to MHV-A59 virions in a solid-phase
viral overlay protein blot assay (9) and is recognized by an
antireceptor monoclonal antibody (MAb CC1) that protects cells
expressing MHVR from infection by MHV-A59 in vivo and in vitro
(20, 52, 53). A cDNA encoding an allelic variant of MHVR,
Bgp1b (also referred to as mmCGM2) (38),
was isolated from cells of MHV-resistant SJL/J mice (18,
53), and a second murine biliary glycoprotein, Bgp2, which is
expressed in the colons of both BALB/c and SJL/J mice, also has been
characterized (38). MHVR and Bgp1b consist of an
N-terminal immunoglobulin (Ig)-like variable domain, three Ig-like
constant domains, a transmembrane domain, and a cytoplasmic tail. The
Bgp2 glycoprotein exhibits a similar structure except that it contains
only one constant domain. The Bgp1b and Bgp2 glycoproteins
can serve as functional receptors for MHV-A59 when overexpressed in
MHV-A59-resistant hamster cells in transient transfection assays, but
these glycoproteins do not bind virus in solid-phase binding assays and
are not recognized by MAb CC1 (18, 38). Natural splice
variants of MHVR and Bgp1b yield glycoproteins containing
the N-terminal and fourth Ig-like domains, the transmembrane domain,
and the cytoplasmic tail (18, 21, 53).
A secreted three Ig domain murine glycoprotein called bCEA, a
pregnancy-specific glycoprotein in the murine carcinoembryonic antigen
(CEA) family, is expressed in C57BL/6 mouse brain and placenta and
exhibits a low level of MHV-A59 receptor activity when expressed in
COS-7 cells (11). To date, the only murine CEA-related
glycoprotein shown to have no MHV receptor activity in transient
transfection assays in MHV-A59-resistant hamster cells is Cea10
(formerly referred to as mmCGM3), a secreted glycoprotein consisting of
two variable Ig-like domains that does not bind MHV-A59 or MAb CC1
(26, 32).
Deletion mutagenesis studies showed that MHV-A59 and MAb CC1 bind to
the N-terminal Ig-like variable domain of MHVR (21). A
recombinant chimeric glycoprotein containing the N-terminal domain of
MHVR and the second, third, transmembrane, and cytoplasmic domains of
the mouse poliovirus receptor (Pvr) homolog serves as a functional
receptor for MHV-A59 when expressed in hamster cells (17).
Furthermore, a soluble recombinant glycoprotein consisting of only the
N-terminal domain of MHVR can inhibit MHV-A59 infectivity in a
concentration-dependent manner (19). MAb CC1 recognizes both
the MHVR/mph chimera and the soluble N-terminal domain of MHVR in
immunoblot assays. A chimeric glycoprotein consisting of the N-terminal
domain of Cea10, the three constant domains, transmembrane region, and
cytoplasmic tail of MHVR, however, does not bind MHV-A59 or MAb CC1
(32).
Sequence analysis of the various receptor-like glycoproteins in the
murine CEA family shows that the 108-amino-acid N-terminal domains of
MHVR, Bgp1b, and Cea10 are significantly different, with 29 amino acid differences between MHVR and Bgp1b and 43 amino
acid differences between MHVR and Cea10 (18, 26, 32). These
glycoproteins also differ significantly in their receptor activities. A
detailed analysis of the virus and MAb binding sites in the N-terminal
domain of MHVR was done to elucidate the molecular basis for these
observed differences in the receptor activities of the murine
CEA-related glycoproteins. We have constructed a series of recombinant
chimeric glycoproteins and tested their abilities to serve as
functional receptors for MHV-A59 in transient transfection assays. The
abilities of MAb CC1 to protect transfected cells from infection by
MHV-A59 and to bind the recombinant glycoproteins in an immunoblot
assay also were examined. Results of these assays indicate that amino
acids 34 to 52 of the glycoprotein are critical for receptor activity
and that binding of the MAb is very sensitive to any changes in the
tertiary structure of MHVR. Site-directed mutagenesis studies confirmed
the importance of these residues. Thus, this small region of the
N-terminal domain of MHVR is a critical determinant of MHV receptor
activity. These residues alone, however, are not sufficient for optimal
receptor activity. Additional amino acids within the N-terminal domain
of MHVR and the three Ig-like constant domains of MHVR also profoundly
affect receptor activity. The data suggest that these domains either influence the conformation of the virus-binding site or affect events
subsequent to virus binding that are required for infection.
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MATERIALS AND METHODS |
Viruses, cells, and antibodies.
MHV-A59 was propagated in
17Cl1 cells maintained in Dulbecco's modified Eagle's minimal
essential medium supplemented with 10% fetal bovine serum and
antibiotics and titered in L2 cells as previously described
(22). Recombinant vaccinia virus strain vTF7-3 was provided
by B. Moss (National Institutes of Health, Bethesda, Md.). The BHK-21
line of baby hamster kidney fibroblasts (American Type Culture
Collection) was maintained in Dulbecco's modified Eagle's medium
supplemented with 10% fetal bovine serum, 10% tryptose phosphate
broth, and antibiotics. MAb CC1 binds to the N-terminal domain of MHVR
and protects cells expressing MHVR from MHV infection (18, 21, 52,
53). The polyclonal rabbit anti-MHVR antibody 655, which
recognizes both MHVR and Bgp1b (20, 52, 53), was
preabsorbed against paraformaldehyde-fixed or acetone-fixed BHK-21
cells prior to use for surface immunofluorescence or immunoblotting
assays respectively as described below.
Construction of N-terminal domain chimeras.
All recombinant
chimeric glycoproteins were generated from the full-length MHVR or
Bgp1b cDNAs cloned into the
HindIII-NotI site of pBlueScript SK+
(Stratagene, La Jolla, Calif.) (18, 20) or a construct which
contained the cDNA encoding the N-terminal domain of Cea10 linked to
the second, third, fourth, transmembrane, and cytoplasmic domains of
MHVR. The amino acid sequences of the N-terminal domains of MHVR,
Bgp1b, and Cea10 are shown in Fig.
1. Briefly, recombinant cDNAs were constructed by digesting the plasmids with the appropriate restriction endonucleases and separating the resulting DNA fragments by
electrophoresis on agarose gels. DNA fragments of interest were eluted
from the agarose either by passage through GenElute agarose spin
columns (Supelco, Bellefonte, Pa.) or by elution with the Elu-Quick
system (Schleicher & Schuell, Keene, N.H.) according to the
manufacturers' recommendations. Aliquots of the isolated DNA were run
on agarose gels to estimate the amount of DNA recovered, and the
fragments were then ligated into the pcDNA3 expression vector
(InVitrogen, Carlsbad, Calif.), using Ready-to-Go T4 DNA ligase
(Pharmacia Biotech, Piscataway, N.J.). The ligated material was
transformed into Escherichia coli DH5
cells by using
standard procedures, and recombinant plasmids were confirmed by
restriction enzyme digestion and sequence analysis.
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FIG. 1.
Comparison of the amino acid sequences of the N-terminal
domains of the murine biliary glycoproteins MHVR (also referred to as
Bgp1a or C-CAM), Bgp1b, and Cea10. For
Bgp1b and Cea10, only amino acids that differ from MHVR are
shown.
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Chimeras were constructed by using the
BamHI restriction
site common to the cDNAs of MHVR, Bgp1
b, and Cea10 which
cleaves the cDNAs at nucleotides corresponding
to amino acid 70. To
further divide the N-terminal domains of
MHVR and Cea10,
KpnI and
ClaI restriction sites were engineered
into the cDNAs of MHVR and Cea10. These restriction enzyme sites
allowed for the construction of recombinants at amino acids 34
(
KpnI) and 52 (
ClaI). Introduction of the
ClaI site resulted in
the amino acid changes
S
52N
53M
54F
56 to IDRK in
MHVR and N
53R
54K
56 to DMF in Cea10.
Introduction of the
KpnI site resulted in the
amino acid
change K
35 to Q in MHVR and Cea10. These amino acid
changes
had no effect on the virus receptor activities of the
parental
constructs as determined by immunofluorescence assays.
PCR-directed mutagenesis was used to introduce the
KpnI and
ClaI restriction sites into the MHVR and Cea10 cDNAs and to
alter
individual amino acids within the various chimeric cDNAs
(
48).
Oligonucleotide primers for the PCR mutagenesis
containing the
nucleotide changes at their 5' ends were synthesized
with an Applied
Biosystems DNA synthesizer (Applied Biosystems Inc.,
Foster City,
Calif.). All mutations were confirmed by sequence analysis
using
a Taq DyeDeoxy Terminator Cycle Sequencing kit (ABI).
Detection of CEA-related glycoproteins in transfected BHK-21
cells by immunoblot analysis and flow cytometry.
To determine
whether the recombinant chimeric cDNAs were producing glycoproteins
with the appropriate molecular weights and immunoreactivities, protein
extracts of transfected cells were analyzed. BHK-21 cells were infected
with vaccinia virus encoding the T7 RNA polymerase (vTF7-3) at a
multiplicity of infection of 10 (23). At 3 h
postinfection, the cells were transfected with the cDNAs encoding MHVR,
the chimeric recombinant or mutated glycoproteins, or empty plasmid in
serum-free medium. At 24 h posttransfection, the cells were lysed
with 0.3 ml of radioimmunoprecipitation assay buffer (0.1 M NaCl, 0.001 M EDTA [pH 7.4], 0.1% Nonidet P-40, 0.1% deoxycholate, 1%
phenylmethylsulfonyl fluoride, 1% aprotinin). Thirty to forty
microliters of the extract was mixed with sample treatment mix
(53), boiled for 3 to 5 min, and separated by
electrophoresis on sodium dodecyl sulfate-8 or 10% polyacrylamide gels. The proteins were transferred to nitrocellulose, which was blocked with 5% bovine serum albumin in B3 buffer (0.15 M NaCl, 0.001 M EDTA, 0.05 M Tris base, 0.05 M Tris-HCl, 0.05% Tween 20, 0.1%
bovine serum albumin) and then probed with a 1:200 dilution of the
polyclonal anti-MHVR antibody 655 or a 1:50 dilution of MAb CC1
followed by rabbit anti-mouse MAb. Proteins were detected with
125I-labeled staphylococcal protein A (New England Nuclear,
New Bedford, Mass.) as previously described (38).
Flow cytometry was also used to confirm the expression of recombinant
glycoproteins on the surface of transfected cells and
to determine
whether the glycoproteins could be recognized by
MAb CC1. BHK-21 cells
were transfected with recombinant cDNAs
cloned into pcDNA3 or empty
plasmid as described above. At 48
h posttransfection, the cells
were trypsinized, and the abilities
of receptor glycoproteins on the
plasma membrane to bind MAb CC1
were determined by incubation of the
cells with the MAb or an
IgG
1 MAb to an irrelevant antigen
followed by R-phycoerythrin-conjugated
affinity-purified anti-mouse
IgG. Bound antibodies were detected
in a fluorescence-activated cell
sorter (FACS). Controls included
cells without primary or secondary
antibodies and cells incubated
only with R-phycoerythrin.
Assays for virus receptor activity and MAb CC1 receptor
blockade.
To determine if the recombinant chimeric and mutant
glycoproteins could serve as functional receptors for MHV-A59, the
glycoproteins were transiently expressed in BHK-21 cells as previously
described (17, 18, 20, 21). Briefly, cells grown on glass
coverslips were transfected with plasmids containing the cDNAs
subcloned into pcDNA3 (InVitrogen) or the empty plasmid, using
LipofectAMINE (Life Technologies, Gaithersburg, Md.) according to the
manufacturer's recommendations. Thirty-five hours posttransfection,
the cells were incubated for 1 h with MHV-A59 at a multiplicity of
infection of 1. At 16 h after virus inoculation, the cells were
fixed with cold acetone. Viral antigens in the cytoplasm were detected
with a 1:50 dilution of polyclonal convalescent mouse anti-MHV serum followed by a 1:50 dilution of rhodamine-labeled goat anti-mouse IgG
and visualized in a Zeiss microscope. For recombinant molecules that
showed virus receptor activity in this assay, the ability of MAb CC1 to
block MHV-A59 infection was examined. Transfected cells were treated
for 1 h with a 1:5 dilution of MAb CC1 hybridoma supernatant or a
control antibody of the same isotype directed against an unrelated
antigen and then inoculated with virus in the presence of MAb CC1.
Virus receptor activity was then assayed as indicated above. To confirm
expression of the recombinant glycoproteins at the plasma membrane,
transiently transfected BHK-21 cells were fixed with 2%
paraformaldehyde 48 to 72 h posttransfection, incubated with
BHK-21 cell preadsorbed polyclonal antireceptor antibody 655 or normal
rabbit serum followed by rhodamine-labeled goat anti-rabbit serum, and
visualized in a Zeiss microscope (20).
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RESULTS |
Identification of residues in the N-terminal domain of MHVR
important for MHV-A59 receptor activity.
We previously
demonstrated that the N-terminal Ig-like domain of MHVR binds MHV-A59
and is essential for virus infection (17, 19). When
expressed at high levels in a transient transfection assay,
Bgp1b also can serve as a functional receptor for MHV-A59,
but this glycoprotein is not recognized by MHV-A59 in a solid-phase
binding assay (9) and is not recognized by anti-MHVR MAb CC1
(18, 52). The N-terminal domain of Cea10 fused to the
second, third, fourth, transmembrane, and cytoplasmic domains of MHVR
cannot serve as a functional receptor for the virus when expressed in MHV-resistant BHK cells (32). To identify the regions of the MHVR N-terminal domain that are necessary for virus receptor activity, the abilities of MHVR/Bgp1b and MHVR/Cea10 N-terminal
domain chimeras to serve as functional receptors for MHV-A59 were
examined. Each of the N-terminal chimeras, shown schematically in Fig.
2, was followed by the second, third, fourth, transmembrane, and cytoplasmic domains of MHVR. cDNAs encoding
the parental or chimeric glycoproteins in the expression vector pcDNA3
were transfected into MHV-resistant BHK-21 cells. Immunolabeling of
transfected cells with anti-MHVR antibody 655 confirmed that each of
the chimeric glycoproteins was expressed on the plasma membrane.
Transfected cells were inoculated with MHV-A59 as described above.
Constructs were scored as follows: +, positive (several cells
expressing viral antigens were detected in every 60× field); +/
,
weakly positive (5 to 50 cells expressing viral antigens were detected
on the entire coverslip); or , negative (fewer than 5 labeled
cells were detected on the coverslip). Representative immunofluorescence data are shown in Fig.
3.
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FIG. 2.
Functions associated with the N-terminal domain
recombinant chimeric anchored glycoproteins. All chimeras also
contained the second, third, fourth, transmembrane, and cytoplasmic
domains of MHVR (not shown). Unshaded regions represent MHVR sequences,
black regions represent Cea10 sequences, and gray regions represent
Bgp1b sequences. Selected amino acid positions are
indicated above. Receptor activity and MAb CC1 receptor blockade
activity were determined by immunofluorescence as described in
Materials and Methods. MAb CC1 binding was determined by immunoblot
assay of cell lysates following infection with vaccinia virus vTF7-3
and transfection of recombinant plasmid. ND, not done.
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FIG. 3.
Detection of MHV antigens or chimeric glycoproteins in
hamster cells transfected with plasmid containing the cDNA of MHVR,
Cea10, or representative MHVR/Cea10 chimeras. BHK-21 cells grown on
glass coverslips were transfected with recombinant MHVR cDNA in which
the N-terminal domain consisted of Cea10 (A and D), MHVR (B and E), or
MHVR1-52/Cea1053-108 (C and F). Following
transfection, cells in panels A, B, C, E, and F were inoculated with
MHV-A59, incubated for 16 h, and fixed in cold acetone. Cells in
panel E and F were pretreated with MAb CC1. Viral antigens in the
cytoplasm were detected with anti-MHV serum and rhodamine-labeled goat
anti-mouse IgG. Cells in panel D were transfected, and surface
expression of the transfected molecule was confirmed by
immunofluorescence with the anti-MHVR polyclonal antibody 655.
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Analysis of the receptor activities of the MHVR/Cea10 chimeric
glycoproteins showed that every construct that served as a
receptor for
MHV-A59 contained amino acids 34 to 52 of MHVR (Fig.
2). For instance,
one construct contained amino acids 1 to 52
of MHVR
(MHVR
1-52/Cea10
53-108), while a second
construct
contained amino acids 34 to 108 of MHVR
(Cea10
1-33/MHVR
34-108).
Both of these
chimeras displayed receptor activity. In contrast,
the construct
containing amino acids 1 to 52 of Cea10 showed no
receptor activity.
Surprisingly, a chimeric glycoprotein in which
the N-terminal domain
contained only amino acids 34 to 70 of MHVR
(Cea10
1-33,71-108/MHVR
34-70) did not exhibit
any MHV-A59 receptor activity. This finding demonstrates that
while
amino acids 34 to 52 of MHVR are essential determinants
of MHV-A59
receptor activity, additional MHVR sequences, either
from amino acids 1 to 33 or from amino acids 71 to 108, also affect
MHV-A59 receptor
activity.
To further determine which amino acids were important for MHV-A59
receptor activity, a series of point mutations was generated
by
site-directed mutagenesis. As shown in Table
1, amino acids
in the N-terminal domain
of MHVR were changed to alanine residues
(I
66I
67/AA) or amino acids similar to those of
Cea10
(L
26A
27L
28A
30A
32/QTRVY,
D
42K
43/HN, I
66L
74/TF),
a rat biliary glycoprotein (E
65/V, V
85/A,
T
91E
93/FQ, T
98/I), or a human
biliary glycoprotein (R
96R
97/VP)
in an effort
to abrogate receptor activity. None of these introduced
mutations had
any effect on receptor activity. A construct which
contained an
R
64-to-S mutation and deletion of amino acids 55
to 58 and
65 to 71, however, exhibited no receptor activity. When
the
S
64 mutation was reverted to R in this construct, weak but
detectable receptor activity was restored. Modeling studies suggest
that R
64 is involved in formation of an intramolecular salt
bridge
(see Fig.
7) that probably is required for correct folding of
the glycoprotein.
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TABLE 1.
Effects of point mutations in MHVR on MHV-A59 receptor
activity, MAb CC1 receptor blockade activity, and MAb CC1
binding activitya
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In a second set of recombinants, mutations were introduced to change
individual amino acids in Cea10 to the corresponding
MHVR amino acids
in an effort to generate a functional receptor
molecule (Table
2). Because the chimeric glycoprotein
studies
described above indicated that amino acids 34 to 52 of MHVR
were
critical determinants of MHV-A59 receptor activity, we
concentrated
on these residues. The construct containing amino acids 1 to 70
of Cea10 and 71 to 108 of MHVR, which exhibited no receptor
activity,
was used as the parental construct for these mutagenesis
studies
(Fig.
2). When the amino acids
S
38G
39G
41 were mutated to TTI in
Cea10
1-70/MHVR
71-108, weak receptor activity
was observed
(Table
2). When the amino acid changes
S
38G
39 to TT or G
41 to
I were
introduced into the Cea10
1-70/MHVR
71-108
chimera,
however, no receptor activity was detected (Table
2). In
addition,
when the mutations
S
38G
39G
41 to TTI were introduced
into a construct
containing the entire N-terminal domain of Cea10, no
receptor
activity was observed (Table
2). These data show that amino
acids
38 to 41 of MHVR are important determinants of MHV-A59 receptor
activity when in the presence of amino acids 71 to 108 of MHVR
but not
amino acids 71 to 108 of Cea10.
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TABLE 2.
Effects of point mutations in the N-terminal domain on
MHV-A59 receptor activity and MAb CC1
binding activitya
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Introduction of a
KpnI restriction enzyme site into the MHVR
and Cea10 cDNAs resulted in a K
35-to-Q amino acid change in
both
proteins. This change did not alter the receptor activity of MHVR,
Cea10, or any of the chimeric recombinant glycoproteins (data
not
shown). Introduction of the
ClaI restriction enzyme site
into
the cDNAs of MHVR and Cea10 resulted in
S
52N
53M
54F
56 to IDRK
changes
in MHVR and N
53R
54K
56 to
DMF changes in Cea10. These amino acid
changes also did not alter the
receptor activities of either parental
construct (Fig.
4). When these amino acid substitutions
were introduced
into certain chimeric glycoproteins, however, their
receptor activities
were affected. The chimeric glycoprotein containing
amino acids
1 to 33 of Cea10 and 34 to 108 of MHVR exhibited weak
MHV-A59
receptor activity (Fig.
2). When the amino acids
S
52N
53M
54F
56 were
mutated to IDRK in this chimera, however, MHV-A59 receptor
activity was
abrogated (Fig.
4). Conversely, although the chimeric
glycoprotein
containing Cea10 amino acids 34 to 70 in an MHVR
background showed no
receptor activity (Fig.
2), changing
N
53R
54K
56 to DMF in this construct
restored weak MHV-A59 receptor activity
and MAb CC1 binding activity
(Fig.
4). These results strongly
support the conclusions that amino
acids 34 to 70 are critical
determinants of MHV-A59 receptor activity
and MAb CC1 binding
and that additional sequences within the N-terminal
domain outside
this region also affect receptor activity.
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FIG. 4.
Functions associated with the N-terminal recombinant
chimeric anchored glycoproteins with and without ClaI
restriction enzyme sites. All chimeras also contained the second,
third, fourth, transmembrane, and cytoplasmic domains of MHVR (not
shown). Unshaded regions represent MHVR sequences, and black regions
represent Cea10 sequences. Mutated amino acids are indicated. Receptor
activity and MAb CC1 receptor blockade activity were determined by
immunofluorescence as described in Materials and Methods. MAb CC1
binding was determined by immunoblot assay of cell lysates following
infection with vaccinia virus vTF7-3 and transfection of recombinant
plasmid. ND, not done.
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Role of MHVR constant domains in receptor activity.
Previous
studies showed that a naturally occurring anchored two-domain splice
variant of MHVR containing domains 1 and 4 (MHVR[1,4]) and a
recombinant anchored two-domain variant of MHVR containing domains 1 and 2 (MHVR[1,2]) both can serve as functional receptors for MHV-A59
(18, 21). Because our analysis of the recombinant chimeric
glycoproteins indicated that multiple regions within the N-terminal
domain of MHVR can influence receptor activity, we also examined the
effects of MHVR constant regions on receptor activity. As demonstrated
previously (18, 21), MHVR[1,4] functioned as a viral
receptor. MHVR[1,2], on the other hand, exhibited only weak MHV-A59
receptor activity in this assay (Fig. 5).
In light of this result, we constructed several MHVR/Bgp1b
N-terminal chimeras in which the recombinant N-terminal domains replaced the N-terminal domains of MHVR[1,4] or MHVR[1,2]. These chimeric glycoproteins were tested for MHV-A59 receptor activity and
MAb CC1 binding and receptor blockade activities (Fig. 5). N-terminal
domain chimeras that functioned as virus receptors when linked to the
full-length MHVR also functioned as receptors when linked to
MHVR[1,4]. In the context of MHVR[1,2], however, the N-terminal
chimera Bgp1b1-70/MHVR71-108 did
not serve as a functional receptor and the chimera
MHVR1-70/Bgp1b71-108 functioned
only weakly as a receptor for MHV-A59 (Fig. 5). These data show that
the constant regions of MHVR also can influence receptor activity and
suggest that optimal virus receptor activity requires the presence of
domain 4.
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FIG. 5.
Functions associated with recombinant chimeric anchored
glycoproteins containing various constant domains. All chimeras also
contained the transmembrane and cytoplasmic domains of MHVR (not
shown). Domains are numbered (1 = N-terminal domain). The arrow
indicates approximate location of amino acid 70 in the N-terminal
domain. Unshaded regions represent MHVR sequences, and gray regions
represent Bgp1b sequences. Receptor activity and MAb CC1
receptor blockade activity were determined by immunofluorescence as
described in Materials and Methods. MAb CC1 binding was determined by
immunoblot assay of cell lysates following infection with vaccinia
virus vTF7-3 and transfection of recombinant plasmid. ND, not done.
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Analysis of antireceptor MAb CC1 binding domains.
The
anti-MHVR MAb CC1 has been shown to protect cells expressing MHVR from
infection by MHV-A59 (50, 51). To identify amino acids
in the N-terminal domain of MHVR required for MAb CC1 binding activity,
the ability of MAb CC1 to block infection by MHV-A59 of cells
expressing receptor-positive recombinant chimeric glycoproteins was
examined. In this receptor blockade assay, MAb CC1 did not block
infection of cells expressing the chimeric glycoproteins MHVR1-70/Cea1071-108,
MHVR1-52/Cea1053-108, or
Cea101-33/MHVR34-108 (Fig. 2). FACS
analysis of cells expressing these chimeric glycoproteins confirmed
that MAb CC1 did not recognize the chimeric glycoproteins on the
surface of these cells (data not shown), but all chimeric glycoproteins were expressed on the cell surface, as evidenced by surface labeling with the polyclonal antibody 655. While MAb CC1 did not block infection
of cells expressing the chimeric glycoprotein
MHVR1-70/Cea1071-108, it did block
infection of cells expressing
MHVR1-70/Bgp1b71-108. Cells
expressing Bgp1b1-70/MHVR71-108,
however, were not blocked by MAb-CC1 (Fig. 2). These data suggest that
amino acids 1 to 70 of MHVR are critical for MAb CC1 binding activity.
The context of these residues, however, also affects the antibody
binding.
To determine if MAb CC1 could bind to the mutated recombinant
glycoproteins in an immunoblot assay, cell lysates from vaccinia
virus-infected, transfected cells were electrophoresed on
polyacrylamide
gels and transferred to nitrocellulose, and proteins
were detected
in a standard immunoblot assay. Representative results
are shown
in Fig.
6. None of the
MHVR/Cea10 chimeric glycoproteins was recognized
by MAb CC1. The
antireceptor polyclonal antibody 655, on the other
hand, detected all
chimeric proteins in this assay (Fig.
6). Among
MHVR/Bgp1
b
chimeras, MAb CC1 recognized the chimeric glycoprotein containing
amino
acids 1 to 70 of MHVR
(MHVR
1-70/Bgp1
b71-108) but not
the chimera containing the amino acids 1
to 70 of Bgp1
b
(Bgp1
b1-70/MHVR
71-108). These
results confirm the importance
of amino acids 1 to 70 of MHVR in MAb
CC1 binding.
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|
FIG. 6.
Recognition of MHVR, Bgp1b, Cea10, or
representative chimeric glycoproteins by anti-MHVR antibodies. Cell
lysates from BHK-21 cells infected with vaccinia virus vTF7-3 and
transfected with cDNA encoding MHVR, Bgp1b, Cea10, or
recombinant glycoproteins were separated by electrophoresis on sodium
dodecyl sulfate-8 or 10% polyacrylamide gels, transferred to
nitrocellulose, and incubated with either anti-MHVR MAb CC1 (A) or
rabbit polyclonal anti-MHVR antibody 655 (B). Bound antibodies were
detected by incubation of immunoblots with
125I-staphylococcal protein A. Sizes are indicated in
kilodaltons. R, amino acids from MHVR; C, amino acids from Cea10;
1b, amino acids from Bgp1b.
|
|
To further analyze the binding characteristics of MAb CC1, the ability
of this antibody to bind to the various point mutants
in an immunoblot
assay was determined. None of the recombinant
glycoproteins in which
Cea10 amino acids were changed to corresponding
MHVR amino acids gained
MAb CC1 binding activity (Table
2). We
also examined the ability of MAb
CC1 to bind to glycoproteins
in which MHVR residues were changed to
alanines or corresponding
residues of Cea10, a rat biliary
glycoprotein, or a human biliary
glycoprotein. As shown in Table
1,
most constructs in which one
or a few MHVR amino acids were altered
maintained MAb CC1 binding.
In two constructs
(D
42K
43 to HN and
L
26A
27L
28A
30A
32
to QTRVY),
however, MAb CC1 binding was eliminated, thereby
demonstrating
the importance of amino acids 26 to 32, 42, and 43 in MAb
CC1
binding.
| |
DISCUSSION |
Previous studies of MHV pathogenesis have shown that infection can
lead to a variety of diseases (4, 49) and that the outcome
is dependent both on the strain of virus and the genetic makeup of the
host organism (1, 3, 5, 6, 15, 16, 25, 28, 29, 31, 43, 45,
50). Several reports have shown that, at least in cell culture
assays where recombinant glycoproteins are expressed at high levels,
multiple murine and human biliary glycoprotein-like molecules can serve
as functional receptors for MHV-A59 (10, 11, 18, 38, 54,
55), and recent studies indicate that differences in binding
affinity between the receptor and virus may determine the receptor
effectiveness (39, 51). It is therefore possible that the
various syndromes associated with MHV infection may, at least to some
degree, be determined by molecular aspects of the receptor molecule.
To identify the amino acid residues of the MHVR glycoprotein necessary
for receptor activity, we constructed a series of chimeric and mutated
recombinant glycoproteins and analyzed the receptor activities and MAb
binding properties of these molecules. All recombinant constructs were
derived from MHVR, the principal MHV-A59 receptor molecule, which is
also referred to as Bgp1a or C-CAM (20, 38, 52,
53), Bgp1b, an allelic variant derived from
MHV-resistant SJL/J mice that exhibits receptor activity in cell
culture assays (18), and Cea10, a closely related murine
glycoprotein that exhibits no receptor activity (32).
Analysis of the chimeric recombinant glycoproteins shows that all
chimeric molecules possessing receptor activity contain amino acids 34 to 52 of MHVR, indicating the critical importance of these residues.
Similar conclusions were reached by Rao et al., who showed that amino
acids 38 to 43 of MHVR are critical for MHV binding (41). It
is important to note, however, that these amino acids of MHVR are not
sufficient for receptor activity. Our results show that a glycoprotein
containing amino acids 34 to 70 of MHVR in a background of Cea10 does
not serve as a functional receptor. Clearly, some amino acids between 1 and 33 or 71 and 108 of MHVR are required in conjunction with amino
acids 34 to 52. We hypothesize that these additional amino acids are
necessary to ensure the correct tertiary structure of the N-terminal
domain and that structural differences between the N domains of MHVR
and Cea10 explain the necessity for these additional MHVR residues.
Mutational analysis of the chimeric recombinant glycoproteins
confirmed the importance of amino acids 34 to 52 and showed that amino
acids 52 to 56 also are important for receptor activity. The
chimeric glycoprotein Cea101-70/MHVR71-108
exhibited no MHV-A59 receptor activity. When amino acids
S38 G39 G41 were converted in this
glycoprotein to the corresponding MHVR amino acids (TTI), the resulting
chimeric glycoprotein exhibited weak but detectable receptor activity,
thereby confirming the critical importance of this region of the
molecule for MHV-A59 receptor activity. Furthermore, alteration of the
amino acids 52, 53, 54, and 56 resulting from introduction of a
restriction enzyme site into the cDNAs of MHVR and Cea10 also affected
the receptor activities of certain chimeric glycoproteins. Our results
show that simply converting these amino acids in Cea10 to the
corresponding MHVR amino acid residues did not convert the N-terminal
domain of Cea10 into that of a functional receptor. If these amino
acids were changed in a chimeric glycoprotein that contained additional
MHVR N-terminal regions, however, receptor activity was regained.
Molecular modeling studies suggest that residues R64 and
D82 form a salt bridge in the N-terminal domain of the Bgp1
molecule. The two residues involved in the formation of this
intramolecular salt bridge are conserved in mouse, rat, and human
biliary glycoproteins. Mutational analysis of amino acid
R64 confirms the importance of the tertiary structure of
this molecule in receptor activity. An MHVR construct containing an
R64-to-S mutation and deletion of residues 55 to 58 and 65 to 71 showed no virus receptor activity. When R64 was
reintroduced into this deletion construct, weak but detectable receptor
activity was restored.
Interestingly, these studies also showed that the constant domains of
MHVR influence receptor activity. MHVR[1,2], which lacks the two
C-terminal constant domains (domains 3 and 4), and N-terminal chimeras
constructed with this molecule did not function as effective receptors
for MHV-A59. In light of these findings, one could argue that the
additional constant domains are required simply to project the
virus-binding, N-terminal domain away from the cell surface, thereby
permitting the virus unimpeded access to the receptor. As shown
previously (18), though, and confirmed in this report, MHVR[1,4] functions quite well as a receptor and presumably extends from the cell surface a distance equivalent to MHVR[1,2].
Alternatively, one could argue that domain 4 but not domain 2 is
necessary to ensure the correct conformation of the receptor-binding
site. Previous analyses of the N-terminal domain (17, 19),
however, make this scenario unlikely. Rather, we postulate that
MHVR[1,2] is deficient in some, as yet undefined, postbinding event
that is required for infection.
Two allelic variants of Bgp1, MHVR and Bgp1b, have been
isolated from MHV-susceptible BALB/c and MHV-resistant SJL/J mice, respectively, and these isoforms differ noticeably in their abilities to serve as functional MHV receptors (18). A sequence
comparison of the N-terminal domains of these Bgp1 allelic variants
shows that the region identified as important for receptor activity also represents a highly variable region (18). While the
amino acid sequences of the N-terminal domains of these two
glycoproteins are identical from positions 1 to 37, 15 amino acid
differences exist in the 22 residues from amino acid 38 to 60. This
extensive difference in the presumptive virus-binding site provides a
molecular explanation for the observed differences in receptor activity demonstrated by these two Bgp1 isoforms in vivo. The cellular function
of these molecules is unknown, although related glycoproteins have been
shown to function in vitro as intercellular adhesion molecules
(12). Recent evidence suggests that this adhesion function
in the rat C-CAM molecule is mediated by amino acids 63 to 67 of the
mature protein (42). It is interesting that the domain
associated with this biological function differs from the putative
virus receptor site.
Our results show that binding of the antireceptor MAb CC1 to MHVR is
very dependent on the tertiary structure of this glycoprotein. In
contrast to the results obtained in the receptor activity assays, no
CC1 antibody binding was detected to any of the MHVR/Cea10 recombinant
glycoproteins in immunoblot, immunofluorescence, or FACS analysis, and
MAb CC1 was unable to protect cells expressing MHVR/Cea10 chimeric
recombinant glycoproteins from MHV-A59 infection. Analysis of
MHVR/Bgp1b chimeric glycoproteins indicates that the
MAb-CC1 binding site is within the first 70 amino acids of MHVR.
Mutational analysis of MHVR confirms this finding. When the mutations
L26A27L28A30A32 to QTRVY or D42K43 to HN were introduced into
MHVR, antibody binding was eliminated, indicating that these residues
or changes in the tertiary structure of the molecule resulting from
changing these residues must be critical to MAb CC1 binding. These
amino acids are in very close linear proximity to the amino acid
residues identified as most important for receptor activity, suggesting that the binding sites of the virus and MAb may overlap. Such overlapping binding sites would explain the ability of MAb CC1 to
protect cells expressing MHVR from infection. These findings also
provide a molecular explanation for the previous observations that
Bgp1b and Bgp2 can serve as functional receptors for
MHV-A59 in in vitro assays but are not recognized by MAb CC1 (18,
38).
The murine glycoprotein Bgp1 has been identified as a member of the Ig
superfamily (7, 20, 52, 53). Several other members of this
family, including intercellular adhesion molecule 1, Pvr, and CD4, have
been identified as receptors for viruses (receptors for rhinovirus,
poliovirus, and human immunodeficiency virus, respectively) (14,
24, 27, 33, 35, 36, 44, 47). Initial mapping studies demonstrated
for each of these pathogens that the virus recognizes the
amino-terminal Ig-like domain of the receptor (17, 19, 21, 30, 34,
36, 44). For Pvr, CD4, and Bgp1, the amino-terminal domain
represents a V-like Ig domain. More precise mapping studies of Pvr and
CD4 suggest the importance of residues along the putative C'-C"-D edge
of these two molecules in receptor activity (2, 8, 13, 37).
Molecular modeling studies predict that this region represents a rather
large, exposed face and also corresponds to the complementarity
determining region 2. This finding has lead to speculation that the
receptor-virus interaction may mimic at least some aspects of the
antibody-antigen interaction (40). Our studies of Bgp1 show
that residues in the putative C-C' region of this glycoprotein are
critical for receptor activity (Fig. 7).
In fact, we constructed several point mutants in which single amino
acids in the C"-D region of MHVR were altered. These changes resulted
in no change in receptor activity. Based on our model of the structure
of MHVR, it is interesting to speculate that the residues critical for
receptor activity exist in a relatively sheltered location and that the
MHV-Bgp1 interaction may not mirror the human immunodeficiency
virus-CD4 or poliovirus-Pvr interactions.
View larger version (44K):
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|
FIG. 7.
Structural model of the N-terminal domain of MHVR.
Structure was determined based on sequence similarities between the
N-terminal domains of MHVR and CD4. Beta sheets are indicated by wide
ribbons and labeled. Numbers indicate amino acid positions. The amino
acid region critical for MHV-A59 receptor activity is in black. A
putative salt bridge between residues R64 and
D82 is indicated.
|
|
Our results have identified a small region of the MHVR glycoprotein
critical for receptor activity. A more complete understanding of the
MHV-Bgp1 interaction, however, will require an examination of the
regions of the MHV spike glycoprotein involved in binding to the
receptor. In initial experiments, Suzuki and Taguchi concluded that
multiple, dissociated regions of the spike are involved in binding,
suggesting that spike binding to the receptor is conformationally dependent (46). A three-dimensional structure of the spike
alone or in conjunction with MHVR may provide insight into the regions of contact between these two moieties. Such detailed information could
be useful in the development of antiviral agents that specifically interfere with this binding event. Finally, such detailed molecular information may provide insight into how slight variations in the
receptor structure and viral attachment protein affect receptor activity, thereby influencing the pathogenesis of mammalian viruses.
| |
ACKNOWLEDGMENTS |
We are grateful to Alexis Basile and Jin Gao for excellent
technical assistance and to David Wentworth, Bruce Zelus, Dianna Blau,
and Dina Tresnan for critical reviews of the manuscript. The molecular
model for the N terminal domain of MHVR was kindly provided by Stephen
Harrison (Harvard University).
This research was supported by Uniformed Services University of the
Health Sciences grant C074ET, NIH grants AI26075 and AI25231, and
Medical Research Council of Canada grant 12036. D.R.W. was supported by
NIAID fellowship AI08879.
| |
FOOTNOTES |
*
Corresponding author. Present address: Department of
Microbiology, Campus Box B-175, University of Colorado Health Sciences Center, Denver, CO 80262. Phone: (303) 315-7329. Fax: (303) 315-6785. E-mail: kathryn.holmes{at}uchsc.edu.
Present address: Laboratory of Hepatitis Research, Food and Drug
Administration, Bethesda, MD 20892.
| |
REFERENCES |
| 1.
|
Arnheiter, H.,
T. Baechi, and O. Haller.
1982.
Adult mouse hepatocytes in primary monolayer culture express genetic resistance to mouse hepatitis virus type 3.
J. Immunol.
129:1275-1281[Medline].
|
| 2.
|
Arthos, J.,
K. C. Deen,
M. A. Chaikin,
J. A. Fornwald,
G. Sathe,
Q. J. Sattentau,
P. R. Clapham,
R. A. Weiss,
J. S. McDougal,
C. Pietropaolo,
R. Axel,
A. Truneh,
P. J. Maddon, and R. W. Sweet.
1989.
Identification of the residues in human CD4 critical for the binding of HIV.
Cell
57:469-481[Medline].
|
| 3.
|
Bang, F. B., and A. Warwick.
1960.
Mouse macrophages as host cells for the mouse hepatitis virus and the genetic basis of their susceptibility.
Proc. Natl. Acad. Sci. USA
46:1065-1075[Free Full Text].
|
| 4.
|
Barthold, S. W.
1986.
Mouse hepatitis virus: biology and epizootiology, p. 571-601. In
P. N. Bhatt, R. O. Jacoby, H. C. Morse III, and A. E. New (ed.), Viral and mycoplasmal infections of laboratory rodents. Effects on biomedical research.
Academic Press, Orlando, Fla.
|
| 5.
|
Barthold, S. W.,
D. S. Beck, and A. L. Smith.
1986.
Mouse hepatitis virus nasoencephalopathy is dependent upon virus strain and host genotype.
Arch. Virol.
91:247-256[Medline].
|
| 6.
|
Barthold, S. W., and A. L. Smith.
1984.
Mouse hepatitis virus strain-related patterns of tissue tropism in suckling mice.
Arch. Virol.
81:103-112[Medline].
|
| 7.
|
Beauchemin, N.,
C. Turbide,
J. Q. Huang,
S. Benchimol,
S. Jothy,
K. Shirota,
A. Fuks, and C. P. Stanners.
1989.
Studies on the function of carcinoembryonic antigen, p. 49-64. In
A. Yachi, and J. E. Shively (ed.), The carcinoembryonic antigen gene family.
Elsevier, Amsterdam, The Netherlands.
|
| 8.
|
Bernhardt, G.,
J. Harber,
A. Zibert,
M. DeCrombrugghe, and E. Wimmer.
1994.
The poliovirus receptor: identification of domains and amino acid residues critical for virus binding.
Virology
203:344-356[Medline].
|
| 9.
|
Boyle, J. F.,
G. G. Weismiller, and K. V. Holmes.
1987.
Genetic resistance to mouse hepatitis virus correlates with absence of virus-binding activity on target tissues.
J. Virol.
61:185-189[Abstract/Free Full Text].
|
| 10.
|
Chen, D. S.,
M. Asanaka,
F. S. Chen,
J. E. Shively, and M. M. C. Lai.
1997.
Human carcinoembryonic antigen and biliary glycoprotein can serve as mouse hepatitis virus receptors.
J. Virol.
71:1688-1691[Abstract].
|
| 11.
|
Chen, D. S.,
M. Asanaka,
K. Yokomori,
F.-I. Wang,
S. B. Hwang,
H.-P. Li, and M. M. C. Lai.
1995.
A pregnancy-specific glycoprotein is expressed in the brain and serves as a receptor for mouse hepatitis virus.
Proc. Natl. Acad. Sci. USA
92:12095-12099[Abstract/Free Full Text].
|
| 12.
|
Cheung, P. H.,
N. L. Thompson,
K. Earley,
O. Culic,
D. Hixson, and S.-H. Lin.
1993.
Cell-CAM105 isoforms with different adhesion functions are coexpressed in adult rat tissues and during liver development.
J. Biol. Chem.
268:6139-6146[Abstract/Free Full Text].
|
| 13.
|
Clayton, L. K.,
R. E. Hussey,
R. Steinbrich,
H. Ramachandran,
Y. Husain, and E. L. Reinherz.
1988.
Substitution of murine for human CD4 residues identifies amino acids critical for HIV-gp120 binding.
Nature
335:363-366[Medline].
|
| 14.
|
Dalgleish, A. G.,
P. C. L. Beverley,
P. R. Clapham,
D. H. Crawford,
M. F. Greaves, and R. A. Weiss.
1984.
The CD4 (T4) antigen is an essential component of the receptor for the AIDS retrovirus.
Nature (London)
312:763[Medline].
|
| 15.
|
Dindzans, V. J.,
E. Skamene, and G. A. Levy.
1986.
Susceptibility/resistance to mouse hepatitis virus strain 3 and macrophage procoagulant activity are genetically linked and controlled by two non-H2-linked genes.
J. Immunol.
137:2355-2360[Abstract].
|
| 16.
|
Dupuy, J. M.,
C. Dupuy, and D. Decarie.
1984.
Genetically determined resistance to mouse hepatitis virus strain 3 is expressed in hematopoietic donor cells in radiation chimeras.
J. Immunol.
133:1609-1613[Abstract].
|
| 17.
|
Dveksler, G. S.,
A. A. Basile,
C. B. Cardellichio, and K. V. Holmes.
1995.
Mouse hepatitis virus receptor activities of an MHVR/mph chimera and MHVR mutants lacking N-linked glycosylation of the N-terminal domain.
J. Virol.
69:543-546[Abstract].
|
| 18.
|
Dveksler, G. S.,
C. W. Dieffenbach,
C. B. Cardellichio,
K. McCuaig,
M. N. Pensiero,
G.-S. Jiang,
N. Beauchemin, and K. V. Holmes.
1993.
Several members of the mouse carcinoembryonic antigen-related glycoprotein family are functional receptors for the coronavirus mouse hepatitis virus-A59.
J. Virol.
67:1-8[Abstract/Free Full Text].
|
| 19.
|
Dveksler, G. S.,
S. E. Gagneten,
C. A. Scanga,
C. B. Cardellichio, and K. V. Holmes.
1996.
Expression of recombinant anchorless N-terminal domain of MHVR makes hamster or human cells susceptible to MHV infection.
J. Virol.
70:4142-4145[Abstract].
|
| 20.
|
Dveksler, G. S.,
M. N. Pensiero,
C. B. Cardellichio,
R. K. Williams,
G.-S. Jiang,
K. V. Holmes, and C. W. Dieffenbach.
1991.
Cloning of the mouse hepatitis virus (MHV) receptor: expression in human and hamster cell lines confers susceptibility to MHV.
J. Virol.
65:6881-6891[Abstract/Free Full Text].
|
| 21.
|
Dveksler, G. S.,
M. N. Pensiero,
C. W. Dieffenbach,
C. B. Cardellichio,
A. A. Basile,
P. E. Elia, and K. V. Holmes.
1993.
Mouse coronavirus MHV-A59 and blocking anti-receptor monoclonal antibody bind to the N-terminal domain of cellular receptor MHVR.
Proc. Natl. Acad. Sci. USA
90:1716-1720[Abstract/Free Full Text].
|
| 22.
|
Frana, M. F.,
J. N. Benke,
L. S. Sturman, and K. V. Holmes.
1985.
Proteolytic cleavage of the E2 glycoprotein of murine coronaviruses: Host-dependent differences in proteolytic cleavage and cell fusion.
J. Virol.
56:912-920[Abstract/Free Full Text].
|
| 23.
|
Fuerst, T. R.,
E. G. Niles,
W. F. Studier, and B. Moss.
1986.
Eukaryotic transient-expression system based on recombinant vaccinia virus that synthesizes bacteriophage T7 RNA polymerase.
Proc. Natl. Acad. Sci. USA
83:8122-8128[Abstract/Free Full Text].
|
| 24.
|
Greve, J. M.,
G. Davis,
A. M. Meyer,
C. P. Forte,
S. C. Yost,
C. W. Marlor,
M. E. Kamarick, and A. McClelland.
1989.
The major human rhinovirus receptor is ICAM-1.
Cell
56:839-847[Medline].
|
| 25.
|
Hirano, N.,
T. Murakami,
F. Taguchi,
K. Fujiwara, and M. Matumoto.
1981.
Comparison of mouse hepatitis virus strains for pathogenicity in weanling mice infected by various routes.
Arch. Virol.
70:69-73[Medline].
|
| 26.
|
Keck, U.,
P. Nédellec,
N. Beauchemin,
J. Thompson, and W. Zimmermann.
1995.
The CEA10 gene encodes a secreted member of the murine carcinoembryonic antigen family and is expressed in the placenta, gastrointestinal tract and bone marrow.
Eur. J. Biochem.
229:455-464[Medline].
|
| 27.
|
Klatzman, D.,
E. Champagne,
S. Chamaret,
J. Gruest,
D. Guetard,
T. Hercend,
J. C. Gluckman, and L. Montagnier.
1984.
T-lymphocyte T4 molecule behaves as the receptor for human retrovirus LAV.
Nature (London)
312:767-768[Medline].
|
| 28.
|
Knobler, R. L.,
D. S. Linthicum, and M. Cohn.
1985.
Host genetic regulation of acute MHV-4 viral encephalomyelitis and acute experimental autoimmune encephalomyelitis in (BALB/cKe × SJL/J) recombinant-inbred mice.
J. Neuroimmunol.
8:15-28[Medline].
|
| 29.
|
Lamontagne, L. M., and J. M. Dupuy.
1984.
Natural resistance of mice to mouse hepatitis virus type 3 infection is expressed in embryonic fibroblast cells.
J. Gen. Virol.
65:1165-1171[Abstract/Free Full Text].
|
| 30.
|
Landau, N. R.,
M. Warton, and D. R. Littman.
1988.
The envelope glycoprotein of the human immunodeficiency virus binds to the immunoglobulin-like domain of CD4.
Nature (London)
334:159-162[Medline].
|
| 31.
|
Le Prevost, C.,
E. Levy-Leblond,
J. L. Virelizier, and J. M. Dupuy.
1975.
Immunopathology of mouse hepatitis virus type 3 infection. Role of humoral and cell-mediated immunity in resistance mechanisms.
J. Immunol.
114:221-225[Abstract/Free Full Text].
|
| 32.
|
Lu, J.-H.
1995.
.
Ph.D. thesis.
Uniformed Services University of the Health Sciences, Bethesda, Md.
|
| 33.
|
Maddon, P. J.,
A. G. Dalgleish,
J. S. McDougal,
P. R. Clapham,
R. A. Weiss, and R. Axel.
1986.
The T4 gene encodes the AIDS virus receptor and is expressed in the immune system and the brain.
Cell
47:333-348[Medline].
|
| 34.
|
McClelland, A.,
J. DeBear,
S. Connolly Yost,
A. M. Meyer,
C. W. Marlor, and J. M. Greve.
1991.
Identification of monoclonal antibody epitopes and critical residues for rhinovirus binding in domain 1 of intercellular adhesion molecule 1.
Proc. Natl. Acad. Sci. USA
88:7993-7997[Abstract/Free Full Text].
|
| 35.
|
McDougal, J. S.,
A. Mawle,
S. P. Cort,
J. K. A. Nicholson,
D. Cross,
J. A. Schleppler-Campbell,
D. Hicks, and J. Sligh.
1985.
Cellular tropism of the human retrovirus HTLV/LAV. I. Role of T cell activation and expression of the T4 antigen.
J. Immunol.
135:3151-3162[Abstract].
|
| 36.
|
Mendelson, C. L.,
E. Wimmer, and V. R. Racaniello.
1989.
Cellular receptor for poliovirus: molecular cloning, nucleotide sequence, and expression of a new member of the immunoglobulin superfamily.
Cell
56:855-865[Medline].
|
| 37.
|
Moebius, U.,
L. K. Clayton,
S. Abraham,
S. C. Harrison, and E. L. Reinherz.
1992.
The human immunodeficiency virus gp120 binding site on CD4: delineation by quantitative equilibrium and kinetic studies of mutants in conjunction with a high-resolution CD4 atomic structure.
J. Exp. Med.
176:507-517[Abstract/Free Full Text].
|
| 38.
|
Nédellec, P.,
G. S. Dveksler,
E. Daniels,
C. Turbide,
B. Chow,
A. A. Basile,
K. V. Holmes, and N. Beauchemin.
1994.
Bgp2, a new member of the carcinoembryonic antigen-related gene family, encodes an alternative receptor for mouse hepatitis viruses.
J. Virol.
68:4525-4537[Abstract/Free Full Text].
|
| 39.
|
Ohtsuka, N.,
Y. K. Yamada, and F. Taguchi.
1996.
Differences in virus-binding activity of two distinct receptor proteins for mouse-hepatitis virus.
J. Gen. Virol.
77:1683-1692[Abstract/Free Full Text].
|
| 40.
|
Peterson, A., and B. Seed.
1988.
Genetic analysis of monoclonal antibody and HIV binding sites on the human lymphocyte antigen CD4.
Cell
54:65-72[Medline].
|
| 41.
|
Rao, P. V.,
S. Kumari, and T. M. Gallagher.
1997.
Identification of a contiguous 6-residue determinant in the MHV receptor that controls the level of virion binding to cells.
Virology
229:336-348[Medline].
|
| 42.
|
Sippel, C. J.,
T. Shen, and D. H. Perlmutter.
1996.
Site-directed mutagenesis within an ectoplasmic ATPase consensus sequence abrogates the cell aggregating properties of the rat liver canalicular bile acid transporter/ecto-ATPase/cell CAM 105 and carcinoembryonic antigen.
J. Biol. Chem.
271:33095-33104[Abstract/Free Full Text].
|
| 43.
|
Smith, M. S.,
R. E. Click, and P. G. Plagemann.
1984.
Control of mouse hepatitis virus replication in macrophages by a recessive gene on chromosome 7.
J. Immunol.
133:428-432[Abstract].
|
| 44.
|
Staunton, D. E.,
V. J. Merluzzi,
R. Rothlein,
R. Barton,
S. D. Marlin, and T. A. Springer.
1989.
A cell adhesion molecule, ICAM-1, is the major surface receptor for rhinoviruses.
Cell
56:849-853[Medline].
|
| 45.
|
Stohlman, S. A., and J. A. Frelinger.
1978.
Resistance to fatal central nervous system disease by mouse hepatitis virus, strain JHM. I. Genetic analysis.
Immunogenetics
6:277-281.
|
| 46.
|
Suzuki, H., and F. Taguchi.
1996.
Analysis of the receptor-binding site of murine coronavirus spike protein.
J. Virol.
70:2632-2636[Abstract].
|
| 47.
|
Tomassini, J. E.,
D. Graham,
C. M. DeWitt,
D. W. Lineberger,
J. A. Rodkey, and R. J. Colonno.
1989.
CDNA cloning reveals that the major group rhinovirus receptor on HeLa cells is intercellular adhesion molecule 1.
Proc. Natl. Acad. Sci. USA
86:4907-4911[Abstract/Free Full Text].
|
| 48.
|
Vallejo, A. N.,
R. J. Pogulis, and L. R. Pease.
1995.
Mutagenesis and synthesis of novel recombinant genes using PCR, p. 603-612. In
C. W. Dieffenbach, and G. S. Dveksler (ed.), PCR primer. A laboratory manual.
Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
|
| 49.
|
Wege, H.,
S. Siddell, and V. Ter Meulen.
1982.
The biology and pathogenesis of coronaviruses.
Curr. Top. Microbiol. Immunol.
99:165-200[Medline].
|
| 50.
|
Weiser, W.,
I. Vellisto, and F. B. Bang.
1976.
Congenic strains of mice susceptible and resistant to mouse hepatitis virus.
Proc. Soc. Exp. Biol. Med.
152:499-502[Medline].
|
| 51.
| Wessner, D. R., B. Zelus, and K. V. Holmes. Unpublished data.
|
| 52.
|
Williams, R. K.,
G.-S. Jiang, and K. V. Holmes.
1991.
Receptor for mouse hepatitis virus is a member of the carcinoembryonic antigen family of glycoproteins.
Proc. Natl. Acad. Sci. USA
88:5533-5536[Abstract/Free Full Text].
|
| 53.
|
Williams, R. K.,
G.-S. Jiang,
S. W. Snyder,
M. F. Frana, and K. V. Holmes.
1990.
Purification of the 110-kilodalton glycoprotein receptor for mouse hepatitis virus (MHV)-A59 from mouse liver and identification of a nonfunctional homologous protein in MHV-resistant SJL/J mice.
J. Virol.
64:3817-3823[Abstract/Free Full Text].
|
| 54.
|
Yokomori, K., and M. M. C. Lai.
1992.
Mouse hepatitis virus utilizes two carcinoembryonic antigens as alternative receptors.
J. Virol.
66:6194-6199[Abstract/Free Full Text].
|
| 55.
|
Yokomori, K., and M. M. C. Lai.
1992.
The receptor for mouse hepatitis virus in the resistant mouse strain SJL is functional: implications for the requirement of a second factor for viral infection.
J. Virol.
66:6931-6938[Abstract/Free Full Text].
|
J Virol, March 1998, p. 1941-1948, Vol. 72, No. 3
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
