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Journal of Virology, November 2001, p. 11185-11195, Vol. 75, No. 22
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.22.11185-11195.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Structural Features of Nectin-2 (HveB) Required
for Herpes Simplex Virus Entry
Wanda M.
Martinez and
Patricia G.
Spear*
Department of Microbiology-Immunology,
Northwestern University Medical School, Chicago, Illinois 60611
Received 14 June 2001/Accepted 8 August 2001
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ABSTRACT |
One step in the process of herpes simplex virus (HSV) entry into
cells is the binding of viral glycoprotein D (gD) to a
cellular receptor. Human nectin-2 (also known as HveB and Prr2), a
member of the immunoglobulin (Ig) superfamily, serves as a gD receptor for the entry of HSV-2, variant forms of HSV-1 that have amino acid
substitutions at position 25 or 27 of gD (for example, HSV-1/Rid), and
porcine pseudorabies virus (PRV). The gD binding region of nectin-2 is
believed to be localized to the N-terminal variable-like (V) Ig domain.
In order to identify specific amino acid sequences in nectin-2 that are
important for HSV entry activity, chimeric molecules were
constructed by exchange of sequences between human nectin-2 and its
mouse homolog, mouse nectin-2, which mediates entry of PRV but not
HSV-1 or HSV-2. The nectin-2 chimeric molecules were expressed in
Chinese hamster ovary cells, which normally lack a gD receptor, and
tested for cell surface expression and viral entry activity. As
expected, chimeric molecules containing the V domain of human nectin-2
exhibited HSV entry activity. Replacement of either of two small
regions in the V domain of mouse nectin-2 with amino acids from the
equivalent positions in human nectin-2 (amino acids 75 to 81 or 89)
transferred HSV-1/Rid entry activity to mouse nectin-2. The
resulting chimeras also exhibited enhanced HSV-2 entry activity and
gained the ability to mediate wild-type HSV-1 entry. Replacement of
amino acid 89 of human nectin-2 with the corresponding mouse amino acid
(M89F) eliminated HSV entry activity. These results identify two
different amino acid sequences, predicted to lie adjacent to the C' and
C" beta-strands of the V domain, that are critical for HSV entry
activity. This region is homologous to the human immunodeficiency virus
binding region of CD4 and to the poliovirus binding region of CD155.
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INTRODUCTION |
The entry of herpes simplex virus (HSV) into cells
is a multistep process that requires the interaction of several viral
glycoproteins with various cell surface receptors. Initial
attachment occurs via the binding of viral glycoprotein C
(gC) or glycoprotein B (gB) to cell surface heparan
sulfate. Subsequently, glycoprotein D (gD) interacts with
one of its several cellular receptors. This somehow triggers fusion of
the viral and cellular membranes, a step that requires
glycoprotein H (gH), glycoprotein L (gL), gB, gD, a cellular gD receptor, and possibly additional cellular molecules (reviewed in references 40 and 41). Other
members of the alphaherpesvirus family, such as porcine pseudorabies
virus (PRV) and bovine herpesvirus-1 (BHV-1), encode homologous sets of
viral glycoproteins and enter cells through a very similar
mechanism. These animal herpesviruses are able to utilize some of the
human receptors for entry, which partly explains their ability to
infect cultured human cells (41).
Two of the four gD receptors identified to date are nectin-1
(44), previously named HveC (13), HIgR
(8), and Prr1 (22), and nectin-2, previously
named HveB (45) and Prr2 (10). The mouse
homologs of these human receptors have considerable sequence identity
with their human counterparts, 95% for nectin-1 and 72% for nectin-2,
and also exhibit viral entry activity (25, 38, 39). Both
the mouse and human forms of nectin-1 can serve as entry receptors for
HSV-1, HSV-2, PRV, and BHV-1 (8, 13, 25, 26, 38). On the
other hand, the mouse and human forms of nectin-2 have a more limited
entry activity and different specificities. Mouse nectin-2 is an entry
receptor for PRV but not BHV-1 or HSV strains (39),
whereas human nectin-2 can mediate the entry of PRV and variant
forms of HSV-1 that have amino acid substitutions at position 25 or 27 of gD (21, 45). HSV-1 strains expressing gDs with the Q27P
or Q27R amino acid substitution have been designated Rid variants
(9). Human nectin-2 can also serve as a weak receptor for
HSV-2 entry but has very little entry activity for wild-type HSV-1
strains (21, 45).
Nectin-1 and nectin-2 belong to a subgroup of the immunoglobulin (Ig)
superfamily, based on structural and sequence similarities. Other
members of this subgroup include nectin-3 (34, 36) and the poliovirus receptor (CD155) (24). Nectin-3 has no
reported viral entry activity, but CD155 is able to mediate entry of
PRV and BHV-1 (13). Each of these proteins can be
expressed as multiple isoforms that are secreted or membrane bound due
to the use of different C-terminal exons (6, 16, 20, 36,
41). All members of this Ig subfamily contain three homologous
Ig domains, an N-terminal variable-like (V) domain and two
constant-like (C2) domains. The membrane-bound forms have the most
efficient viral entry activity, apparently independent of the sequences
of the transmembrane region or cytoplasmic tail (8, 13,
21). A secreted form of nectin-1 was reported to bind to cells
and to have detectable HSV entry activity (20).
The cellular role of the nectins includes participation in
cell-to-cell adhesion. These proteins localize to cadherin-based adherens junctions in polarized epithelium or to cell junctions in
nonpolarized cells and link neighboring cells through
trans-homophilic or heterophilic interactions (36, 43,
44). Certain isoforms of the nectins containing specific
carboxy-terminal sequences can associate with the actin cytoskeleton
through interactions with afadin, an F-actin binding protein (15,
23, 36). The binding of nectin to afadin is important for
localization of the nectins to cadherin-based junctions (15, 23,
44). Although binding of nectin-1 to afadin is not necessary for
HSV entry (8, 13, 35), this interaction does facilitate
the efficient cell-to-cell spread of HSV infection (35).
Since nectin-1 and nectin-2 are probably coexpressed in a variety of
cell types, they may serve redundant roles in certain cell types.
However, mutations that abolish expression of full-length nectin-1 in
humans result in autosomal recessive cleft lip or palate ectodermal
dysplasia syndrome (42). Knockout of the nectin-2 gene in
mice resulted in male sterility through defects in spermatogenesis,
without obvious effects on females (5).
Various lines of evidence suggest that the interaction of HSV with
nectin-1 or nectin-2 occurs through the V domain. Soluble nectin-1
consisting of only the V domain blocks the entry of HSV into
nectin-1-expressing cells and binds soluble gD (7, 19). Similar results were observed with a truncated nectin-2 protein containing only the V domain when tested with the HSV-1 variant U21 and
soluble U21 gD (21). Also, a nectin-1 protein deleted for
the two C2-like domains can mediate HSV entry, albeit inefficiently (7). Epitope mapping of anti-nectin-1 antibodies that can
inhibit gD binding and HSV entry suggests that amino acids (a.a.) 80 to 104 of the V domain of nectin-1 are critical for the gD interaction (17).
The aim of this study was to identify specific regions and amino acids
within the V domain of nectin-2 that are important for HSV entry. We
chose to study nectin-2 to take advantage of the difference in entry
specificity of the human and murine homologs. A chimeric approach was
used to identify human nectin-2 sequences that are able to confer HSV
entry activity on mouse nectin-2 and therefore are critical for viral
entry activity. Various sets of nectin-2 chimeras were constructed by
replacing regions of mouse nectin-2 with the corresponding amino acids
of human nectin-2. The chimeric proteins were tested for ability to
mediate entry of several alphaherpesviruses, including wild-type HSV-1,
HSV-1/Rid1, HSV-2, PRV, and BHV-1.
As expected, the V domain of human nectin-2 was shown to contain the
critical determinants for HSV entry. Two short regions (a.a. 75 to 81 and a.a. 89) within the V domain of human nectin-2 were identified that
could independently convert mouse nectin-2 into an entry receptor for
HSV-1/Rid1. The resulting chimeras also exhibited HSV-1 and improved
HSV-2 entry activity, neither characteristic of the parental molecules.
A human nectin-2 molecule containing the substitution M89F lost HSV but
not PRV entry activity. Thus, we have identified two regions and
specific amino acid residues within the V domain of nectin-2 that are
critical for HSV entry activity. These amino acid residues map to one
side of the V domain within loops adjacent to the C' and C"
beta-strands. This region is homologous to that of CD4 and CD155 that
is critical for human immunodeficiency virus (HIV) and poliovirus
entry, respectively. This region is also adjacent to the homologous
region in nectin-1 that contains epitopes for monoclonal antibodies
(MAbs) that can inhibit gD binding. In light of the homology between
nectin-1 and -2, these studies will aid in the identification and
characterization of specific sequences in nectin-1 that are important
for viral entry.
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MATERIALS AND METHODS |
Cells and viruses.
CHO-K1 cells were provided by J. Esko
(University of California, San Diego). 
-Galactosidase (-gal)
reporter viruses used were wild-type HSV-1 (strain KOS) and HSV-1/Rid1,
described previously as KOS/tk12 and KOS-Rid1/tk12, respectively
(45); gH-negative PRV(Kaplan) (3), provided
by T. Mettenleiter (Federal Research Center for Virus Diseases of
Animals, Insel Reims, Germany); and BHV-1(Cooper)TK-bgal+v4a
(27), provided by L. Bello (University of Pennsylvania).
The reporter virus HSV-2(333)gJ
, engineered to contain a
cytomegalovirus-lacZ cassette in place of part of the
glycoprotein J (gJ) gene, will be described in detail
elsewhere (C. Rowe and P. G. Spear, unpublished results). PRV was
propagated and titered on gH-expressing Vero SW78 cells
(3), and BHV-1 was propagated and titered on MDBK cells.
All other viruses were propagated and titered on Vero cells.
Plasmids.
Plasmid pMW20, containing the human nectin-2 open
reading frame (ORF) (GenBank AF058448) in pcDNA3, has been described previously (45). This plasmid was used for the expression
of human nectin-2 in all assays. Plasmid Mph-pcDNA3, containing the mouse nectin-2 ORF, was provided by D. Shukla (University of Missouri). To generate this plasmid, primers
5'-CTGAAGCTTCCCATGGCCCGGGCCGCAGTC and
5'-GTCTCTAGAGTAGGGTCACACGTAAACTGC were used to amplify mouse nectin-2 coding sequences from a 15.5-day-old embryonic mouse (C57BL/6J) cDNA library (Gibco-BRL). The amplified segment was digested
with HindIII and XbaI and cloned into pcDNA3
(D. Shukla and P. G. Spear, unpublished results). The coding
sequence was identical to that described before (GenBank M12197)
(32).
(i) Plasmids expressing chimeric or mutated receptors.
All
sequences were first cloned into pUC19 (New England Biolabs) for
mutagenesis and then cloned into pcDNA3.1 (Invitrogen) for mammalian
expression. Site-directed mutagenesis was performed according to the
manufacturer's instructions using a PCR-based system (QuikChange
site-directed mutagenesis kit; Stratagene).
(ii) Plasmids expressing Ch 1 to Ch 5.
Plasmid pWM31
contains the mouse nectin-2 ORF altered by the introduction of a
SacII restriction site between the V and C2 domains
(5'-AACGGTACCCGCCGCGGGGTGACCTGG) and an EcoRV
site between the C2-C2 domains
(5'-CCCTCCAGAAGTATCGATATCCGGCTATGATGAC). Upon sequencing, a
nucleotide change was detected in this plasmid which resulted in an
amino acid substitution (R463W) in the fifth amino acid from the
carboxyl-terminal end of mouse nectin-2. The nectin-2 protein expressed
from pWM31 is indistinguishable from that expressed from Mph-pcDNA3 in
viral entry assays (data not shown). pWM31 was used in all experiments
as the wild-type mouse nectin-2 expression plasmid. pWM33 contains the
ORF of human nectin-2 (SacI fragment of pMW20) in pUC19
altered by the addition of a SacII site between domains V
and C2 (5'-GGTCCGTCCGCGGGATGACCTGGCTC) and an
EcoRV site between domains C2 and C2
(5'-CCTCCTGAAGTGTCGATATCCGGCTATGAT). Plasmid pWM39 (Ch 1)
contains the ectodomain of human nectin-2 (SrfI-BlpI fragment of pWM33) fused to the
transmembrane (TM) and cytoplasmic domains of mouse nectin-2
(BlpI-SrfI fragment of pWM31). pWM41 (Ch 2)
contains the V and first C2 domain of human nectin-2
(SrfI-EcoRV fragment of pWM39) followed by the C2
domain, TM, and cytoplasmic sequences of mouse nectin-2
(EcoRV-SrfI fragment of pWM31). pWM38 (Ch 3)
contains the V domain of human nectin-2
(SrfI-SacII of pWM33) followed by mouse nectin-2
sequences (SacII-SrfI fragment of pWM31). pWM36
(Ch 4) contains the two C2 domains of human nectin-2
(SacII-BlpI fragment of pWM28, a plasmid similar
to pWM33) ligated between the V domain and TM sequences of mouse
nectin-2 (BlpI-SacII fragment of pWM31). pWM20 (Ch 5) contains the ectodomain of mouse nectin-2
(HindIII-BlpI fragment from Mph-pcDNA3) fused
to the TM and cytoplasmic domains of human nectin-2
(BlpI-HindIII fragment of pMW20).
(iii) Plasmids expressing Ch 7 to Ch 20, F84 mutants, and M89
mutants.
Plasmids were constructed by performing site-directed
mutagenesis on pWM29, which contains the mouse nectin-2 ORF
(SacI fragment of pWM33) in pUC19. For the M89 mutants,
site-directed mutagenesis was performed on pWM68, which contains the
ORF of human nectin-2 (BamHI fragment of pMW20) in pUC19.
Mutated plasmids were sequenced to ensure that there were no unintended
mutations and the mutagenized coding region was cloned into the
HindIII site or BamHI site (for human
nectin-2 mutants) of pcDNA3.1 for mammalian expression. The nectin-2
molecules are encoded by the following plasmids: Ch 6, pWM61; Ch 7, pWM62; Ch 8, pWM63; Ch 9, pWM64; Ch 10, pWM65; Ch 11, pWM66; Ch 12, pWM75; Ch 13, pWM74; Ch 14, pWM77; Ch 15, pWM78; Ch 16, pWM71; Ch 17, pWM70; Ch 18, pWM72; Ch 19, pWM79; Ch 20, pWM76; F84A, pWM87; F84I,
pWM89; F84T, pWM88; F84K, pWM85; F84E, pWM86; F84Y, pWM84; M89I,
pWM100; and M89F, pWM101.
CELISA for detection of proteins on cell surfaces.
A cell
enzyme-linked immunosorbent assay (CELISA) was performed as described
previously (11, 12). Briefly, transfections were performed
on subconfluent CHO-K1 cell monolayers using Lipofectamine (Gibco-BRL).
Each well of a six-well plate received 1.5 µg of plasmid, 5 µl of
Lipofectamine, and Opti-MEM (Gibco-BRL) in 1 ml. Twenty-four hours
later, cells were replated into 96-well dishes. The next day, cells
were incubated with PBS-BSA (phosphate-buffered saline [PBS] plus 0.5 mM MgCl2, 1 mM CaCl2, and
3% bovine serum albumin [BSA]). This solution was also used for all
washes and for antibody dilutions. After 30 min, the appropriate
primary antibody was added to cells. Antibodies used included
anti-human nectin-2 R146 (45), provided by G. Cohen and R. Eisenberg (University of Pennsylvania), anti-mouse nectin-2 6B3
[
-mouse nectin-2 (V)], and anti-mouse nectin-2 18C12 [-mouse
nectin-2 (C2)] (1), provided by A. Nomoto (University of
Tokyo). Cells were washed four times and fixed using 2%
formaldehyde-0.2% glutaraldehyde in PBS. Then, cells were incubated
for 30 min with biotin-conjugated secondary antibody (1:500 dilution)
(Sigma), washed as before, and incubated with Amdex
streptavidin-conjugated horseradish peroxidase at 1:20,000 dilution
(Amersham) for 30 more min. Cells were then washed and reacted with
substrate solution containing 3,3',5,5'-tetramethylbenzidine (BioFX).
At various times after substrate addition, plates were read at 370 nm.
Alternatively, the reaction was stopped by the addition of stopping
solution (BioFX), and plates were read at 410 nm.
Virus entry assays.
Virus entry assays were performed as
previously described (30). Briefly, CHO-K1 cells were
transfected as described above and replated into 96-well plates after
24 h. Cells were then exposed to serial dilutions of
-gal-expressing virus diluted in PBS plus 0.1% glucose and 1%
heat-inactivated serum. After 6 h, cells were washed, incubated
with the -gal substrate ONPG
(o-nitrophenyl--D-galactopyranoside) and analyzed as described previously (30).
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RESULTS |
Critical determinants for HSV entry map to the V domain of human
nectin-2.
To generate the first set of human-mouse nectin-2
chimeric molecules, identical restriction enzyme sites were engineered
between the V-C2 and C2-C2 domains of the cloned human and mouse
nectin-2 genes by site-directed mutagenesis. These sites were used,
together with existing shared enzyme sites, to exchange the V, first
C2, or second C2 domain gene segments between the human and mouse nectin-2 genes in different combinations. Five different chimeric molecules were constructed (Fig. 1).
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FIG. 1.
Nectin-2 chimeric molecules and cell surface expression.
A schematic representation of human, mouse, and chimeric nectin-2
molecules is shown. Human nectin-2 sequences are represented by black
lines, and mouse nectin-2 by gray lines. Empty boxes correspond to the
proposed signal peptides, and the transmembrane region (TM) is marked
by a vertical line. Ig-like domains (V, C2, and C2) are drawn as loops,
connected by the predicted disulfide linkage. The name of each molecule
is shown to the left of the drawing. To determine cell surface
expression of the various nectin-2 molecules, CHO-K1 cells were
transfected with plasmids expressing human or mouse nectin-2 or
chimeric molecules or with control plasmid. Forty-eight hours later
cells were exposed to the appropriate primary antibody and fixed.
Antibody binding was detected with a biotinylated secondary antibody,
followed by streptavidin-horseradish peroxidase. Peroxidase activity
was used as a measure of antibody binding. Values shown are the means
and standard deviations of quadruplicate determinations. Data for each
molecule are shown directly to its right. Antibodies used were
polyclonal rabbit anti-human nectin-2 antibody (-human nectin-2) and
monoclonal anti-mouse nectin-2 antibodies recognizing an epitope in the
V domain or second C2 domain.
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To determine whether the chimeric molecules retained proper
conformation and were expressed on the cell surface, Chinese hamster
ovary cells (CHO-K1) were transfected with plasmids expressing
the
wild-type nectin-2 molecules or chimeras or with control plasmid
and
tested, by CELISA, for the binding of anti-human or anti-mouse
nectin-2
antibodies (Fig.
1). The antibodies used were a polyclonal
anti-human
nectin-2 antibody and two monoclonal anti-mouse nectin-2
antibodies
that recognize the mouse nectin-2 V domain and second
C2 domain,
respectively. Results shown in Fig.
1 demonstrate that
the polyclonal
anti-human nectin-2 antibodies bound, at nearly
equivalent
levels, to all chimeras containing some portion of
the ectodomain
of human nectin-2. The monoclonal anti-mouse nectin-2
antibodies
detected, at similar levels, cell surface expression
of all chimeric
molecules containing the mouse nectin-2 V and
C2 domains. These results
indicate that all chimeric molecules
were expressed on the cell surface
as efficiently as the parental
molecules and retained at least some
antigenic
determinants.
To determine which chimeric molecules were able to mediate HSV entry,
viral entry assays were performed. CHO-K1 cells, normally
resistant to
the entry of HSV, were transfected with plasmids
expressing wild-type
human or mouse nectin-2 or the chimeric molecules
or with control
plasmid and then exposed to serial dilutions of
reporter viruses
HSV-1/Rid1 (an HSV-1 variant expressing gD with
the amino acid
substitution Q27P), HSV-2, and PRV. These reporter
viruses contain a
lacZ cassette in the viral genome and express
-gal upon
entry into cells.
-Gal activity was used as a measure
of viral
entry. Results from a representative experiment are shown
in Fig.
2. Wild-type human and mouse nectin-2 and all the
chimeras
were functional for PRV entry, which confirms cell surface
expression
and retention of functional activity by the chimeric
molecules.
Only chimeric molecules that contained the V domain of human
nectin-2
(Ch 1, Ch 2, and Ch 3) were able to mediate entry of HSV-2 or
HSV-1/Rid1 at efficiencies similar to that of wild-type human
nectin-2.
A very low level of entry activity was also observed
with human
nectin-2 and Ch 1, Ch 2, and Ch 3 for wild-type HSV-1.
Conversely,
chimeric molecules containing the V domain of mouse
nectin-2 (Ch 4 and
Ch 5) behaved similarly to wild-type mouse
nectin-2 and were not able
to mediate HSV entry. Exchange of the
other domains (first C2, second
C2, or TM-cytoplasmic) did not
significantly affect the entry ability
of the molecules, which
was determined solely by the V domain present.
We noted, however,
that Ch 3 was reproducibly more efficient than human
nectin-2
at mediating HSV-2 entry. These experiments indicate that the
V domain of human nectin-2 is sufficient to convert mouse nectin-2
into
a functional HSV entry receptor and support data by others
(
21) indicating that the V domain of human nectin-2
contains
critical determinants for HSV entry into cells.
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FIG. 2.
Alphaherpesvirus entry activities of wild-type and
chimeric nectin-2 molecules. CHO-K1 cells transfected with plasmids
expressing human nectin-2, mouse nectin-2, or chimeric molecules or
with control plasmid were replated onto 96 wells and exposed to serial
dilutions of reporter viruses (HSV-1/Rid1, PRV, HSV-1, and HSV-2) for
6 h. Infected cells were then washed, and -gal substrate was
added. -Gal activity was used as a measure of viral entry. Values
shown are the means and standard deviations of triplicate
determinations. Similar results were obtained in two other
experiments.
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Identification of amino acids within V domain of human nectin-2
that can confer HSV entry activity on mouse nectin-2.
To identify
amino acid residues within the V domain of human nectin-2 required for
HSV entry activity, new chimeric molecules were constructed in which
single or multiple amino acids in the V domain of mouse nectin-2 were
replaced with the corresponding residues from human nectin-2, as
explained below. HSV entry activity of all chimeras was determined, in
viral entry assays, by exposing transfected CHO-K1 cells to serial
dilutions of reporter alphaherpesviruses HSV-1, HSV-1/Rid1, HSV-2, PRV,
and BHV-1 and measuring -gal activity 6 h after infection. The
chimeric molecules were also tested for cell surface expression, in a
CELISA, by measuring the binding of anti-mouse nectin-2 (C2) antibody
to CHO-K1 cells transfected with the various molecules.
(i) V domain chimeras.
Alignment of sequences between the two
cysteines of the V domain of human and mouse nectin-2 identified
discrete regions of divergence between these molecules (Fig.
3A). Six new chimeric molecules were constructed in
which these regions in mouse nectin-2 were replaced by the
corresponding sequences from human nectin-2 using site-directed
mutagenesis. Note that Ch 11 has both of the substitutions made
individually for Ch 7 and Ch 9. As shown in Fig. 3B, the anti-mouse
nectin-2 (C2) antibody bound to CHO-K1 cells expressing mouse nectin-2
and all the chimeric molecules, indicating that the chimeras were
expressed on the cell surface. The finding that reduced levels of
antibody bound to cells expressing Ch 8 and Ch 10 was reproducible and
suggests that these chimeras were not expressed or transported to the
cell surface as efficiently as wild-type mouse nectin-2 or that the
substitutions in the V domain somehow altered the conformation of the
membrane-proximal C2 domain, which seems unlikely.
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FIG. 3.
Alignment of human and mouse nectin-2 sequences in the V
domain and cell surface expression of V domain chimeric molecules. (A)
The sequence between the two cysteines of the V domain of mouse
nectin-2 is aligned above the corresponding sequence of human nectin-2.
Amino acids are numbered from the initial methionine. Gray shading
indicates identity between the sequences. New chimeric molecules were
constructed by replacing the underlined mouse nectin-2 sequences with
the sequences at equivalent positions in human nectin-2 and given the
names shown below the human sequence. Ch 11 has both of the
substitutions shown for Ch 7 and Ch 9. The amino acids exchanged in Ch
7 and Ch 9 are referred to in the text and later figures as regions A
and B, respectively. (B) Cell surface expression of wild-type and V
domain chimeric molecules. CHO-K1 cells were transfected with plasmids
expressing human nectin-2, mouse nectin-2, or chimeric molecules or
with control plasmid and 48 h later tested for the binding of
anti-mouse nectin-2 (C2) antibody as explained for Fig. 1. Values shown
are the means and standard deviations of triplicate determinations. The
same transfected cell populations were used to obtain the results shown
in panel B and in Fig. 4.
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Results of a representative experiment to test the viral entry activity
of these chimeric molecules are shown in Fig.
4. All
wild-type and chimeric molecules were able to mediate entry of
PRV
despite the apparently reduced levels of Ch 8 and Ch 10, confirming
their cell surface expression and retention of some functional
activity. Ch 6, 8, and 10 behaved like mouse nectin-2 and were
not able
to mediate HSV entry. However, Ch 7, 9, and 11 gained
the ability to
mediate entry of HSV-1/Rid1 to levels similar to
that of human
nectin-2. These chimeras were also able to mediate
HSV-2 entry but much
more efficiently than did human nectin-2.
Since the chimeric molecules
exhibited enhanced HSV-2 entry activity,
we tested whether the chimeras
could mediate entry of other alphaherpesviruses
(HSV-1 and BHV-1).
Chimeras 7, 9, and 11 were able to mediate
entry of wild-type
HSV-1 into cells much more efficiently than
human nectin-2. None of the
molecules exhibited BHV-1 entry activity
(data not shown). The results
from these experiments show that
two regions from human nectin-2,
regions A (a.a. 75 to 81) and
B (a.a. 88 to 92) (Fig.
3A), could
independently or jointly transfer
HSV-1/Rid1 entry activity to mouse
nectin-2. The resulting chimeras
also exhibited enhanced
HSV-1 and HSV-2 entry activity compared
to wild-type human
nectin-2.
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FIG. 4.
Alphaherpesvirus entry activities of V domain nectin-2
chimeric molecules. CHO-K1 cells transfected with plasmids expressing
human nectin-2, mouse nectin-2, or V domain chimeric molecules or with
control plasmid were infected with reporter alphaherpesviruses
(HSV-1/Rid1, PRV, HSV-1, and HSV-2) as described for Fig. 2. Values
shown are the means and standard deviations of triplicate
determinations. Similar results were obtained in two other
experiments.
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(ii) Single amino acid substitutions.
To determine whether
specific amino acids within region A or B of human nectin-2 could
transfer HSV entry activity to mouse nectin-2, new chimeric molecules
were constructed in which one or a few amino acids in these regions in
mouse nectin-2 were replaced with the corresponding amino acids from
human nectin-2. The amino acid sequences of regions A and B of the new
chimeras and the wild-type nectin-2 molecules are shown in Fig.
5A.
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FIG. 5.
Amino acid sequences of regions A and B in nectin-2
chimeras Ch 12 to Ch 20 and cell surface expression. (A) The amino acid
sequences of regions A and B in nectin-2 chimeric molecules are shown
between the mouse nectin-2 (lowercase letters) and human nectin-2
(uppercase letters and underlined) sequences. The name given to each
chimera is shown to the left of the sequence. (B) Cell surface
expression of region A and B nectin-2 chimeric molecules. CHO-K1 cells
were transfected with plasmids encoding human nectin-2, mouse nectin-2,
or region A or B nectin-2 chimeric molecules and tested for the binding
of anti-mouse nectin-2 (C2) antibody as described for Fig. 1. Values
are the means and standard deviations of quadruplicate
determinations.
|
|
All the region A and B chimeras were expressed on the cell surface, as
shown by CELISA using the anti-nectin-2 (C2) antibody
(Fig.
5B). All
the chimeras were also able to mediate entry of
PRV, although with
different efficiencies, which confirms cell
surface expression and
retention of some functional entry activity
for the chimeric molecules
(Fig.
6 and
7).
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FIG. 6.
Alphaherpesvirus entry activities of region A nectin-2
chimeric molecules. CHO-K1 cells were transfected with plasmids
expressing wild-type and region A chimeric molecules, Ch 7, or control
plasmid. Forty-eight hours later, cells were exposed to serial
dilutions of reporter alphaherpesviruses (HSV-1/Rid1, PRV, HSV-1, or
HSV-2) as described for Fig. 2. -Gal activity was used as a measure
of virus entry. The means and standard deviations of triplicate
determinations are shown for a representative experiment. The assays
were repeated three times with similar results.
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|
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FIG. 7.
Alphaherpesvirus entry activities of region B nectin-2
chimeric molecules. CHO-K1 cells were transfected with plasmids
expressing wild-type and region B chimeric molecules, Ch 9, or control
plasmid. Forty-eight hours later, cells were exposed to serial
dilutions of reporter alphaherpesviruses (HSV-1/Rid1, PRV, HSV-1, or
HSV-2) as described for Fig. 2. -Gal activity was used as a measure
of virus entry. The means and standard deviations of triplicate
determinations are shown for a representative experiment. Similar
results were obtained in two other experiments.
|
|
A representative experiment for the viral entry assays using region A
chimeras is shown in Fig.
6. Ch 7, which contains the
entire region A
of human nectin-2 (Fig.
3A), was included for
comparison. All of the
region A chimeric molecules were able to
mediate entry of HSV-1/Rid1,
but not as efficiently as did human
nectin-2 (Fig.
6). These chimeras
also gained the ability to mediate
entry of HSV-2 to levels similar to,
or greater than that of human
nectin-2. Only Ch 15 exhibited wild-type
HSV-1 entry activity
to a level approaching that of Ch 7. These results
show that substitutions
in region A have different effects on entry of
the four alphaherpesviruses
tested. None of the substitutions affected
PRV entry activity.
Any of the substitutions in region A resulted in
acquisition of
HSV-1/Rid1 entry activity but not to the levels observed
with
wild-type human nectin-2. For HSV-2, any of the substitutions
in
region A is enough for acquisition of entry activity; the more
region A
amino acids derived from human nectin-2, the more enhanced
the entry
activity. For wild-type HSV-1, at least the three amino
acids
substituted in Ch 15 are required for significant levels
of entry
activity.
A representative experiment for the viral entry assays using region B
chimeras is shown in Fig.
7. Ch 9, which contains the
entire region B
of human nectin-2 (Fig.
3A), was included for
comparison. All chimeric
molecules that contained a Met instead
of Phe at position 84 (Ch 17, Ch
19, and Ch 20) gained the ability
to mediate entry of HSV-1/Rid1 and
had enhanced entry activity
for HSV-1 and HSV-2. Ch 19, containing
substitution of two amino
acids (S83K and F84M) exhibited the highest
levels of entry activity
for all three HSV strains tested. Other
substitutions in this
region (Ch 16 and Ch 18) did not confer HSV entry
activity on
mouse nectin-2. Interestingly, the single amino acid
substitution
at position 84 (F84M) actually reduced PRV entry activity
(Ch
17).
Effect of various substitutions in position 84 of mouse nectin-2 on
alphaherpesvirus entry.
Ch 17, which contains the F84M mutation,
was functional for HSV entry. The Phe at that position in mouse
nectin-2 may cause steric hindrance (or a different conformational
structure in that area) to prevent HSV entry. Alternatively, a Met, as
present in human nectin-2, may be specifically required for entry
activity. To determine the effect on HSV entry of other amino acid
substitutions in position 84 of mouse nectin-2, we constructed mouse
nectin-2 molecules containing different amino acid residues in that
position (Fig. 8). All mouse nectin-2 mutants were
expressed on the cell surface at levels similar to mouse nectin-2, as
detected by the binding of the anti-mouse nectin-2 (C2) antibody to
transfected CHO-K1 cells (Fig. 8A).
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FIG. 8.
Cell surface expression and alphaherpesvirus entry
activities of mouse nectin-2 mutants containing amino acid
substitutions at position 84. (A) Six mouse nectin-2 mutants were
constructed in which the amino acid at position 84 was replaced with
another amino acid (Ala, Ile, Thr, Lys, Glu, or Tyr) and given the name
of the substitution as shown on the x axis. To assess
cell surface expression, CHO-K1 cells transfected with plasmids
expressing the mouse nectin-2 position 84 mutants, wild-type mouse
nectin-2, or control plasmid were tested for the binding of anti-mouse
nectin-2 (C2) antibody as described for Fig. 1. Results shown are the
means and standard deviations of triplicate determinations. (B) CHO-K1
cells transfected as above were infected with reporter
alphaherpesviruses (HSV-1/Rid1, PRV, HSV-1, and HSV-2) as described for
Fig. 2. The means and standard deviations of triplicate determinations
are shown for a representative experiment. The assays were repeated
twice with similar results.
|
|
The mutant mouse nectin-2 molecules were tested for viral entry
activity, and a representative experiment is shown in Fig.
8B. In
addition to Ch 17 (F84M), mutants containing either an
Ile (F84I) or an
Ala (F84A) gained the ability to mediate entry
of HSV-1, HSV-1/Rid1,
and HSV-2. The activity of F84I was very
similar to that of Ch 17 (F84M), indicating that an Ile can substitute
very well for Met in that
position to allow HSV entry. F84T exhibited
a somewhat reduced but
detectable entry activity for HSV-1/Rid1
and HSV-2. Mutants having a
charged residue (F84K and F84E) or
an aromatic amino acid (F84Y) were
inactive for viral entry. Some
mutants exhibited significantly reduced
ability to mediate PRV
entry (F84E, F84T, F84K, and
F84A).
Altering the Met at position 89 of human nectin-2 influences HSV
entry activity.
Because changing the Phe at position 84 of mouse
nectin-2 to Met or Ile confers HSV entry activity, we tested the effect
of substituting the Met at the equivalent position (a.a. 89) in human nectin-2 with other amino acids. Human nectin-2 mutants were
constructed in which the Met at position 89 was replaced by a Phe, as
in mouse nectin-2, or by Ile (Fig. 9). We hypothesized
that the M89F mutation would eliminate human nectin-2 HSV entry
activity. Also, because the F84I substitution in mouse nectin-2
conferred HSV entry activity, the M89I mutation should not affect the
ability of human nectin-2 to mediate HSV entry.
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FIG. 9.
Cell surface expression and alphaherpesvirus entry
activities of human nectin-2 mutants containing amino acid
substitutions at position 89. (A) Two human nectin-2 mutants were
constructed in which the amino acid at position 89 was exchanged for an
Ile or a Phe, as shown on the y axis. To assess cell
surface expression, CHO-K1 cells transfected with plasmids expressing
wild-type human nectin-2, M89I, M89F, or control plasmid were tested
for the binding of anti-human nectin-2 antibody, as described for Fig.
1. Results shown are the means and standard deviations of triplicate
determinations. (B) Alphaherpesvirus entry activities of wild-type
human nectin-2 and position 89 mutants. CHO-K1 cells were transfected
as above and 48 h later exposed to serial dilutions of reporter
alphaherpesviruses (HSV-1/Rid1, PRV, HSV-1, and HSV-2) as described for
Fig. 2. Results shown are the means and standard deviations of
triplicate determinations. The assays were repeated three times with
similar results.
|
|
The human nectin-2 mutants were tested for cell surface expression
using the polyclonal anti-human nectin-2 antibody. As shown
in Fig.
9A,
the mutants were detected at the cell surface at levels
similar to
wild-type human nectin-2. When tested for viral entry
activity (Fig.
9B), all molecules were able to mediate PRV entry.
However, the M89F
mutant lost the ability to mediate entry of
HSV-1/Rid1, HSV-1, and
HSV-2. As hypothesized, substitution of
an Ile in this position (M89I)
did not affect HSV-1/Rid1 entry.
Interestingly, the M89I mutant
exhibited enhanced HSV-1 and HSV-2
entry activity. Thus, replacing the
Met at position 89 with Phe
alters the herpesvirus entry activity of
human nectin-2, eliminating
HSV but not PRV entry activity, yielding an
activity profile similar
to that of mouse nectin-2. An Ile in the
equivalent position is
associated with enhanced HSV-1 and HSV-2 entry
activity, as when
an Ile is present in mouse nectin-2. Clearly the
particular amino
acid at position 84 in mouse nectin-2 or 89 in human
nectin-2
is crucial for the ability of these cell surface molecules to
mediate HSV and PRV
entry.
| |
DISCUSSION |
In this study our goal was to identify structural differences
between human and mouse forms of nectin-2 that accounted for ability of
the human form but not the mouse form to mediate HSV entry. Our results
confirmed the previous finding that determinants for HSV entry reside
in the N-terminal V-like Ig domain of human nectin-2 (21).
More importantly, they demonstrated that the particular amino acid
residues present in two small regions of the V domain determined
whether either mouse or human nectin-2 could serve as an HSV entry
receptor. Moreover, we found that changes in amino acid sequence in
these regions had different effects on the ability of several
alphaherpesviruses tested to utilize these receptors. This indicates
that the various forms of alphaherpesvirus gD must differ in their
interactions with each of the various wild-type and mutated forms of
nectin-2.
The exchange of Ig domains between human and mouse forms of nectin-2
gave straightforward results. All chimeras with the V domain of human
nectin-2 had the entry activities characteristic of human nectin-2, and
all chimeras with the V domain of mouse nectin-2 had the more
restricted entry activity characteristic of mouse nectin-2. This
confirms that the V domain contains the critical determinants for HSV
entry (21). The only anomaly was the reproducible
enhancement of entry activity for HSV-2 when the V domain of human
nectin-2 was fused to the remainder of the mouse nectin-2 molecule (Ch
3 in Fig. 2). Possibly, the C2 domains of mouse nectin-2 provide a
better scaffold for presentation of the human V domain to HSV-2 than do
the C2 domains of human nectin-2.
When short stretches of mouse sequence within the V domain were
replaced with human sequences from equivalent positions, replacements in two of the five regions of divergence tested gave remarkable results. Replacements within regions A or B or both (Fig. 3 to 7)
conferred ability to mediate entry of HSV-1/Rid1 and also conferred ability to mediate entry of HSV-1 and HSV-2 much more efficiently than
is characteristic of human nectin-2. Further dissection of region A
revealed that replacement of mouse amino acids GTV with human amino
acids HQN (Ch 15) was almost as effective as substituting with APANHQN
(the entire sequence of human nectin-2 present at this position) (Ch
7). Further dissection of region B revealed that all mouse chimeras
having Met at position 84 (as in human nectin-2 in the equivalent
position) had acquired HSV-1/Rid1 entry and also new entry activities,
whereas all those that retained the Phe at position 84 had acquired
no new entry activities, irrespective of other changes made in this
region. The optimal replacement in region B, even better than replacing
the entire region, was the substitution of mouse amino acids SF at
positions 83 and 84 with the human amino acids KM from the equivalent
positions 88 and 89.
Replacement of amino acids in region A or B of mouse nectin-2 with
human nectin-2 sequences conferred normal (for HSV-1/Rid1) or enhanced
(HSV-1 and HSV-2) entry activities. However, the replacement of one
amino acid in region B of human nectin-2 with the corresponding mouse
amino acid (M89F) eliminated all HSV entry activities, even though
region A was unchanged. Thus, the presence of a Phe at position 89 in
the context of the human V domain or at position 84 in the context of
the mouse V domain is associated, in both cases, with absence of any
HSV entry activity. The presence of a Phe at position 84 in the context
of a mouse V domain containing human sequences in region A is
associated with HSV entry activity. Whether the presence of a Phe at
position 84 in mouse nectin-2 permits HSV entry activity depends on the
sequence in region A. It might be possible to alter human nectin-2 so
that presence of a Phe at position 89 would also permit HSV entry activity.
The amino acid present at position 84 in the mouse V domain or at
position 89 in the human V domain is clearly critical for entry of all
the viruses tested, but the particular amino acid preferred at this
position for optimal entry activity is different for PRV and the HSV
strains. The only molecules that exhibited reduced entry activity for
PRV were Ch 9 (which has the entire region B replaced with human
sequences) and various mouse nectin-2 mutants containing substitutions
in position 84 in region B, including F84M (Ch 7). For PRV entry, the
preferred amino acid at position 84 was Phe, at least for mouse
nectin-2. The results obtained with the HSV strains provide a clear
contrast. Phe at position 84 in mouse (wild-type mouse nectin-2) or 89 in human (M89F) was associated with absence of HSV entry activity,
suggesting that PRV and HSV strains respond differently to the presence
of Phe at this position. The substitutions F84M and F84I in mouse
nectin-2 conferred entry activity for HSV-1/Rid1 to levels similar to
that observed for human nectin-2. The same substitutions conferred enhanced entry activity for wild-type HSV-1 and HSV-2, highlighting differences in entry requirements for HSV-1/Rid and wild-type HSV-1 and
HSV-2. Also, the M89I substitution in human nectin-2 was without effect
on HSV-1/Rid1 entry, whereas the M89F substitution eliminated this
entry activity. As expected, the M89F substitution also eliminated the
entry activity observed for wild-type HSV-1 and HSV-2, but
surprisingly, the M89I substitution enhanced entry activity for both
wild-type HSV-1 and HSV-2. Assuming that these variations in sequence
of the nectin-2 V domain influence gD binding, the gDs encoded by PRV
and HSV-1/Rid1 must each differ from those encoded by HSV-1 and HSV-2
in their interactions with each form of nectin-2 tested. The
differences observed between HSV-1 and HSV-2 entry seem to be
principally quantitative and not qualitative.
Although the direct binding of alphaherpesvirus gDs to nectin-1 and
other entry receptors has been observed (7, 12, 18, 19, 25, 38,
46), it has been difficult to detect the binding of gD to
nectin-2. A previous report demonstrated by ELISA the weak binding of
the variant form of gD U21 (amino acid substitution at position 25) to
soluble forms of human nectin-2 (21). We were able to
detect low levels of binding of a soluble form of HSV-1/Rid1 gD to
cells expressing a variant form of mouse nectin-2 with high entry
activity (Ch 19), but not to wild-type human nectin-2 or some of the
other active chimeras. The failure to detect HSV gD binding to human
nectin-2 is probably due to low affinity of the interaction.
Alterations made here, resulting in chimeric molecules with enhanced
entry activity, may also enhance the affinity of gD-nectin-2
interactions enough to begin to detect binding of soluble gD to cells
or binding of gD to receptor by ELISA. Other methods will have to be
devised to obtain quantitative comparisons of the gD-receptor
interactions, in order to determine whether the apparent affinity of
the interaction correlates with entry activity of the parental and
chimeric receptors described here.
Alignment of mouse and human nectin-2 sequences with that of CD155
allowed us to make rough predictions about the location of the amino
acids in regions A and B relative to the beta-strands that form the V
domain (Fig. 10). Loop regions between the
beta-strands, specifically B-C, C-C', C'-C", C"-D, and D-E loops,
showed the most variability in sequence among the molecules. Region A
appears to localize to an area encompassing the C-C' loop and region B to the C'-C" loop. The C'-C" region is predicted to be exposed and
available for interactions with virus, and in fact, equivalent regions
of other members of the Ig superfamily have been shown to be contact
points for viruses. Studies on CD155 have identified the C'-C"-D region
as an important component of the binding site for poliovirus.
Specifically, amino acids localized to the C'-C" loop are crucial for
viral binding to receptor (4, 31). Substitution of a
single amino acid to a bulkier residue (Q55F), in the position equivalent to the Met in region B of human nectin-2, abolished poliovirus binding (31). The region in CD4 encompassing
the C'-C"-D beta-strands and intervening loops has been identified as
the binding site for HIV (2, 29). Transfer of this region of human CD4 to the rat homolog can confer HIV entry activity on the
hybrid molecule (37). In addition, substitutions of
amino acids in the C'-C" loop affect virus binding
(33). Thus, it seems that the equivalent region of the V
domains of different Ig molecules can be utilized by several viruses
for binding to the cell surface and for entry.
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FIG. 10.
Alignment of nectin-2, nectin-1, and poliovirus
receptor (CD155) V domain sequences. The sequence of the V domain of
CD155 (24) was aligned with the corresponding sequences of
mouse and human nectin-2 and human nectin-1. The proposed location of
the beta-strands of CD155 (14) is indicated above the
CD155 sequences. Gray shading represents identity in amino acid of at
least three of the molecules. Regions A and B of human nectin-2 are
underlined. The proposed epitopes for MAbs that inhibit gD binding to
nectin-1 are underlined (17).
|
|
Because nectin-2 is believed to be a gD receptor, as are all the other
HSV entry receptors, regions A and B in human nectin-2 could form part
or all of the contact site with gD or could otherwise influence the
conformation of the contact site. In a recent study of human nectin-1,
three monoclonal antibodies were shown to inhibit the binding of gD to
nectin-1. The epitopes of two of these antibodies were mapped using
overlapping peptides (17). These epitopes were localized
to sequences homologous to region B in nectin-2 and extending
downstream to the D-E loop (Fig. 10). Taken together, these results
suggest that the region in nectin-2 including the C' and C"
beta-strands and surrounding loops is the site to which HSV gD binds.
It has been shown that soluble forms of HSV-1 gD can inhibit cell
adhesion mediated by nectin-1 (35), suggesting that the interface for trans-homophilic interactions between nectin-1
ectodomains may overlap with the gD-binding domain. We have preliminary
evidence, however, that the M89F mutation in human nectin-2 has little
or no effect on trans-homophilic interactions between
nectin-2 ectodomains despite the absence of HSV entry activity. A
mutation at position 136 in mouse nectin-2 was reported to abolish the
trans-homophilic interaction (28). Work is
in progress to assess the effects of an equivalent mutation in human
nectin-2 and other mutations on both alphaherpesvirus entry and
trans-homophilic interactions.
Because of the homology between nectin-1 and nectin-2, the information
obtained in this study on nectin-2 will facilitate identification of
the regions in nectin-1 that are critical for alphaherpesvirus entry
activity. Also, the nectin-2 chimeras and mutants generated in this
study will be useful for high-resolution structural studies designed to
determine how the variations in primary sequence influence
three-dimensional structure, interactions with various forms of
alphaherpesvirus gD, and entry activity.
| |
ACKNOWLEDGMENTS |
We thank N. Susmarski and M. L. Parish for excellent
technical assistance and C. Rowe, G. Cohen, R. Eisenberg, and A. Nomoto for reagents.
This work was supported by Public Health Service grants R37 AI36293 and
U19 AI31494 from the National Institute for Allergy and Infectious
Diseases. W.M.M. was supported by Public Health Service fellowship F31
GM 19765.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology-Immunology, Northwestern University Medical School, 320 E. Superior St., Mailcode S213, Chicago, IL 60611. Phone: (312) 503-8230. Fax: (312) 503-1339. E-mail: p-spear{at}northwestern.edu.
| |
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Journal of Virology, November 2001, p. 11185-11195, Vol. 75, No. 22
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.22.11185-11195.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
