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Previous Article | Next Article 
Journal of Virology, February 2000, p. 1267-1274, Vol. 74, No. 3
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Nectin2
(PRR2 or HveB) and Nectin2
Are
Low-Efficiency Mediators for Entry of Herpes Simplex Virus Mutants
Carrying the Leu25Pro Substitution in Glycoprotein D
Marc
Lopez,1
Francesca
Cocchi,2
Laura
Menotti,2
Elisa
Avitabile,2
Patrice
Dubreuil,1 and
Gabriella
Campadelli-Fiume2,*
Institute of Cancerology and Immunology,
INSERM U119, Marseille, France,1 and
Department of Experimental Pathology, University of Bologna,
Bologna, Italy2
Received 8 October 1999/Accepted 6 November 1999
 |
ABSTRACT |
The receptors for entry of herpes simplex viruses 1 and 2 (HSV-1
and -2), widely expressed in human cell lines, are members of a subset
of the immunoglobulin superfamily exemplified by herpesvirus entry
mediator C (HveC) and the herpesvirus immunoglobulin-like receptor
(HIgR). This report focuses on two members of this subset, herpesvirus
entry mediator B (HveB), recently designated nectin2/PRR2
, and its
splice variant isoform, nectin2/PRR2
. Nectin2 and - share the
ectodomain but differ in the transmembrane and cytoplasmic regions.
HveB was reported to enable entry of HSV-1 carrying mutations in
glycoprotein D (gD) and of HSV-2, but not of wild-type (wt) HSV-1. We
report that (i) both nectin2 and - served as receptors for the
entry of HSV-1 mutant viruses HSV-1(U10) and -(U21) and AP7r that carry the Leu25Pro substitution in gD but not for
HSV-1 mutants U30 and R5000 that carry the Ser140 or Ala185
substitution in gD. All of these mutants were able to overcome the
block to entry mediated by expression of wt gD. (ii) Infection of cells expressing nectin2 or - required exposure to multiplicities of
infection about 100-fold higher than those required to infect cells
expressing HveC or HIgR. (iii) gD from HSV-1(U21) bound in vitro
soluble forms of nectin2. The association was weaker than that to the
soluble form of HveC/HIgR. Binding of wt HSV-1 gD to soluble nectin2
was not detectable. (iv) A major region of nectin2 functional in virus
entry mapped to the V domain, located at the N terminus.
| |
INTRODUCTION |
The process of herpes simplex virus
(HSV) entry into cells begins with low-affinity attachment to heparan
sulfate glycosaminoglycans (30). This interaction greatly
enhances virus entry, as infectivity is reduced in cells devoid of
glycosaminoglycans (3). Human herpesvirus mediator A (HveA),
a novel member of the tumor necrosis factor receptor family, was the
first cellular mediator shown to be required for HSV entry into human
cells (25). Antibodies to HveA blocked HSV infectivity in
cells transfected with the mediator or in T lymphocytes but not
universally in the cell lines currently used in HSV studies. The narrow
distribution and usage of HveA, together with its activity restricted
only to some HSV strains, led to the further search for cellular
proteins necessary for HSV entry into human cells. Recently, the
members of a cluster of the immunoglobulin (Ig) superfamily were
identified as the HSV receptors widely expressed in human cell lines
like HEp-2, HeLa, and human fibroblasts (8, 13). The cluster
includes three major groups of human proteins, each of which has known splice variant isoforms. For all of the members, six conserved cysteines define the same basic structure made of one V and two C2
domains (11, 21). They are (i) HveC, previously known as PRR1, for poliovirus receptor-related 1 (13, 21), and its splice variant isoform HIgR, for herpesvirus Ig-like receptor (8); (ii) two molecules originally designated PRR2 and
-, also splice variant isoforms (11), the former
redesignated HveB (32); and (iii) the poliovirus receptor
(23), also designated CD155 or herpesvirus entry mediator D
(HveD) (13), of which four isoforms are known. HveC and HIgR
share the ectodomain and differ in the transmembrane and cytoplasmic
regions but cannot be differentiated with respect to their function as
mediators of HSV entry (8). They enable entry of all of the
HSV type 1 (HSV-1) and HSV-2 strains tested, as well as of bovine
herpesvirus 1 (BHV-1) and porcine pseudorabies virus (PRV) (8,
13). The V domain contains the major functional region in HSV-1
entry and interacts physically with glycoprotein D (gD) (7,
19), the envelope glycoprotein known to mediate HSV entry into
cells by interaction with the receptor (8, 18).
In contrast to HveC and HIgR, HveB/PRR2 was reported to mediate the
entry of a restricted number of HSV strains, namely, HSV-1-rid1, -rid2,
and ANG and HSV-2 (32), while its murine homologue mediates
the entry of PRV (29). Human PRR2 and PRR2, two
isoforms with the same ectodomain and different transmembrane and
cytoplasmic regions (11), are homophilic adhesion molecules expressed specifically at interendothelial junctions (20).
Recently, they were found to be recruited to adherens junctions via
afadin through PDZ domains and were renamed nectin2/PRR2
(31). We note that for a cellular protein with viral
receptor activity, it is an established procedure to maintain the name
based on the cellular function (thus, for example, the receptors or
coreceptors for human immunodeficiency virus and adenoviruses maintain
the designation CD4, chemokine receptors 5 and 4, or integrins).
According to this rule, PRR2/HveB and PRR2 are designated
nectin2 and - below.
Cells which express wild-type (wt) HSV-1 gD (wtgD1)
constitutively are resistant to infection with wt HSV-1 (5,
16). The block to infection is overcome by spontaneous
gD-unrestricted mutants selected for the ability to enter cells
expressing HSV-1 gD, namely, HSV-1(U10), -(U21), -(U30), -rid1, and
-rid2 (4, 6, 9), as well as by a mutant resistant to
monoclonal antibody (MAb) AP7 (AP7r virus) (24);
by R5000 (27), a virus able to infect resistant clones of
thymidine kinase-deficient baby hamster kidney (BHKtk
)
cells, or by the ANG strain (9). The amino acid
substitutions in gD that enable these viruses to overcome the block to
infection mediated by HSV-1 gD (wtgD1) map at three
specific loci, amino acids 25 (U10, U21, AP7r virus, and
ANG), 27 (rid1, rid2, and ANG), 140 (R5000), and 185 (U21 and U30). The
phenomenon of restriction to infection mediated by expression of
wtgD1 predicted that constitutive expression of
wtgD1 sequesters the major receptor normally employed by
the wt virus for entry into cells but allows entry of the HSV-1
gD-unrestricted mutants through one or more secondary receptors and
that the interaction between secondary receptors and mutant forms of gD
would be at low affinity (4, 5).
The objective of the present study was to determine whether both
isoforms of nectin2, and , mediate entry of HSV mutants, to
identify the mutations in gD-unrestricted mutants that enable nectin2/PRR2 to serve as a receptor for these viruses, to locate the
region of nectin2 functional in virus entry, and to determine if mutant
gD interacts physically with nectin2. So far, it has been reported that
wtgD1 binds to HveC and to HveA with high affinity and that
mutant gD from strain rid1 binds both HveC and HveA with even higher
affinity (18); binding of mutant gD to HveB has not been investigated.
We report that (i) both isoforms of nectin2, and , enabled entry
of some HSV-1 mutants and recombinants carrying the L25P substitution
in gD but not other substitutions, (ii) a major functional region for
entry was located in the V domain positioned at the N terminus, (iii)
nectin2/PRR2 and - were much less efficient at mediating entry of
the unrestricted mutant HSV-1(U21) than were HveC and HIgR, and (iv) gD
from HSV-1(U21) (gDU21) interacted physically with the
soluble form of nectin2. The association was weaker than that of gD
from the wt virus to soluble HveC/HIgR.
| |
MATERIALS AND METHODS |
Cells and viruses.
All cells were grown in Dulbecco's
modified Eagle medium supplemented with 5% fetal calf serum. J1.1-2
cells were previously described (8). HSV-1(F), HSV-2(G),
HSV-1(MP), Sc-16, KOS, HFEM, and BHV-1 were also previously described
(12, 14, 15, 17, 28, 33), as were HSV-1(U21), (U10), and
(U30), their marker transfer and marker rescue recombinants (4,
6). The mutants resistant to MAbs AP7, AP12, LP2, LP14, R5000,
and R5001 have been described earlier (24, 27). Viruses were
grown and titrated by plaque assay in Vero cells. Virus infectivity in
nectin2 cells was detected by immunostaining or 
-galactosidase
(-gal) expression, by reading the optical density (OD) at 405 nm
(25), or by light microscopy observation of
-gal-expressing cells.
Construction of cells expressing nectin2 and -.
Cells
expressing nectin2 and - were obtained by transfection of pLX2S
or pLX2L containing full-length nectin2 or nectin2 cDNAs from
TF-1 cells cloned in the pLXSN vector (20). Stable transformants of J1.1-2 cells expressing nectin2 or - were
obtained by G418 neomycin selection, staining with MAb R2.477, and
enrichment by cell sorting in a Becton Dickinson Vantage cell sorter,
according to nectin2 expression. For construction of nectin2 and
- cells harboring 27p-LacZ, pCEP27p-LacZ was generated as
follows. The lacZ gene was removed from pON832 (gift of E. Mocarski, Stanford University) by BamHI digestion and cloned
into the BamHI site downstream of the HSV-1 27 promoter
in pRB3053, generating pRB3053LacZ. The cassette containing the 27
promoter-lacZ fusion was cloned into pCEP4 (Invitrogen)
devoid of the SalI cassette, containing the cytomegalovirus
promoter, the multicloning site, and the simian virus 40 polyadenylation signal. Stable transformants of nectin2 or -
cells harboring pCEP27p-LacZ were derived by hygromycin (250 µg/ml) selection.
Antibodies.
MAbs R2.477 and R2.525 were submitted to the VI
International Workshop on Human Leukocyte Differentiation Antigen
(22). MAb BC12 was purchased from Diaclone. MAb R1.302,
directed to HIgR/PRR1, was previously described (22). MAb
LP1 to -TIF and MAb 1240 to BHV-1 gB were gifts from T. Minson
(Cambridge University) and M. Ackermann (University of Zurich),
respectively. Rabbit polyclonal antiserum to gM was previously
described (2). Purified mouse IgGs, goat polyclonal sera
against the Fc fragment of human IgG, and alkaline
phosphatase-conjugated anti-mouse and anti-rabbit antibodies were from
Sigma. Biotinylated anti-mouse and anti-rabbit secondary antibodies
(ABC kit) were from Vector Laboratories.
Construction, production, and purification of soluble forms of
nectin2.
The entire extracellular domain of nectin2 (amino acids 1 to 347) was amplified by PCR with primers SBPRR2.5 (AATT TAGA TATC ATGG
CCCG GGCC GCTG CCCT C) and SPRR2.3n (TTAT ACTT GCGG CCGC TCGG ACAA AGAT
GACC TGCG C) as previously described (20). The V domain of
nectin2 (amino acids 1 to 160) was amplified with primers SBPRR2.5 and
CFLR2V (GTTG CGGC CGCT ATGA CTCT GAGC CAGG TCAT C). The PCR products
were cloned in frame with the Fc fragment of the human IgG1 sequence by
using the Cos Fc Link vector (SmithKline Beecham Pharmaceuticals, King
of Prussia, Pa.) to produce Fc-tagged soluble forms, designated VCC2-Fc
and V2-Fc, respectively. For production, transfections of COS-1 cells
were carried out with Fugene 6 (Boehringer Mannheim). The proteins were
purified on Affigel protein A. The purity and quality of the proteins
were monitored by gel electrophoresis, followed by silver staining (Bio-Rad), as previously described (20). The production of
VCC1-Fc, V1-Fc, and CTLA4-Fc was previously described (7).
ELISA.
A sandwich enzyme-linked immunosorbent assay (ELISA)
for the soluble forms of nectin2/PRR2 was performed with 96-well trays coated with an antibody against the human Fc fragment (Sigma) at 10 µg/ml. After saturation of wells with bovine serum albumin, 109 M VCC2-Fc or V2-Fc was reacted with biotinylated MAbs
R2.477, R2.525, BC12, and R1.302 (2.5 µg/ml), followed by
streptavidin-peroxidase and One Step ABTS (Pierce). gD1 and
gDU21 were purified from HSV-1(F)- or HSV-1(U21)-infected
BHK cells, and purification was monitored by silver staining. Membranes
were obtained from the microsomal fraction of cytoplasm, solubilized in
1% Nonidet P-40 in 20 mM Tris-HCl buffer, and 150 mM NaCl, and
protease inhibitors and purified by affinity chromatography to MAb #30
to gD (4) immobilized to Affigel. This resulted in
purification practically to homogeneity (see the insert in Fig. 6).
Microwell plates were coated with 16 nM gD1 or
gDU21 in 100 µl of bicarbonate buffer (15 mM
Na2CO3, 35 mM NaHCO3, 0.02%
NaN3, pH 9.5) at 4°C overnight and then reacted with the
indicated concentrations of the soluble forms of VCC1-Fc, V1-Fc,
VCC2-Fc, and V2-Fc diluted in 1% bovine serum albumin-2% NaCl in
phosphate-buffered saline. The negative control consisted of CTLA4-Fc.
Binding was detected by incubation with anti-human Ig coupled to
peroxidase (1:6,000) for 45 min at 37°C, followed by incubation with
o-phenylenediamine (Sigma) at 0.5 mg/ml in 2.5 mM citric
acid-5 mM Na2HPO4-0.009%
H2O2, blocking with
H2SO4 1:6 in H2O, and reading of
the OD at 490 nm.
Immunostaining and FACS analysis.
For immunostaining, cells
were fixed with ethanol and reacted with a rabbit polyclonal antibody
to gM (1:2,000), MAb LP1 to -TIF (1:1,500), or MAb 1240 to BHV-1 gB
(undiluted hybridoma culture medium), followed by appropriate
biotinylated or nonbiotinylated secondary antibodies.
Fluorescence-activated cell sorter (FACS) analysis was performed as
previously described (22) with a FACScan flow cytometer.
Infectivity blocking assays.
For assays of infectivity
blocking by MAbs R2.525, BC12, and R2.477, cells grown in 96- or
48-well trays were preincubated with the indicated amounts of purified
IgGs from the indicated antibodies in Dulbecco's modified Eagle medium
supplemented with heat-inactivated fetal bovine serum for 2 h at
37°C. HSV-1(U21) (50 PFU/cell) was added, and the mixture was
incubated for a further 90 min at 37°C. The viral inoculum was
removed, and the cells were rinsed twice, overlaid with medium
containing the same concentration of antibodies that was present during
the preabsorption, and incubated for 16 h at 37°C. Infection was
monitored by immunostaining of cells with rabbit polyclonal anti-gM
antibodies for HSV-1 strains in nectin2- and --expressing cells
or by -gal activity measurement in nectin2- and --expressing
cells carrying 27p-LacZ. OD was read in a Bio-Rad ELISA reader.
Triplicates were run for each antibody concentration. Data reported are
averages of at least two experiments. A 100% value represent the value
obtained with infected cells not exposed to antibodies.
| |
RESULTS |
gD-unrestricted mutants HSV-1(U10) and -(U21), but not HSV-1(U30),
infect cell lines expressing both isoforms of nectin2, and
.
In order to construct cell lines expressing nectin2 and
-, J1.1-2 cells, a derivative of BHKtk cells resistant
to infection with all of the HSV-1 and -2 strains tested,
including gD-unrestricted mutants HSV-1(U21), -(U10), and -(U30),
were transfected with pLX2S or pLX2L, containing the full-length
nectin2 and - cDNAs from TF-1 cells, respectively. Neomycin-resistant cells were selected and enriched by cell sorting following staining with MAb R2.477. The extents of expression of
nectin2 and - were similar, as detected by FACS analysis (data
not shown).
In the first series of experiments, we ascertained whether both
isoforms of nectin2, and , can serve as receptors for
HSV-1(U10), -(U21), and -(U30) mutants. We found that HSV-1(U10) and
-(U21) were able to infect cells expressing nectin2 or - [Fig.
1, data shown for HSV-1(U21)].
Surprisingly, HSV-1(U30) did not infect nectin2- or --expressing
cells (Fig. 2), despite the fact that, like HSV-1(U10) and -(U21), it was selected for its ability to overcome
the resistance to infection of cells expressing wtgD1. HSV-1(U30) can employ HveC and HIgR as primary receptors
(8).
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FIG. 1.
Infection of nectin2 (first and third rows) and
nectin2 (second row)-expressing cells with HSV-1(U21) at 100, 30, and 10 PFU/cell and with HSV-2(G) at 100 and 10 PFU/cell. Uninfected
nectin2-expressing cells, bottom right panel. Infection was detected
by immunostaining with polyclonal antibodies to gM or MAb LP1 to
-TIF.
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FIG. 2.
Infection of nectin2-expressing cells with HSV-1(U10)
and -(U21) and exposure to HSV-1(U30) and R5000 at 30 PFU/cell.
Infection was detected by immunostaining with polyclonal antibodies to
gM.
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We noticed a striking difference in the multiplicity of infection (MOI)
required to enter nectin2- and --expressing cells compared to
that required to enter HveC- or HIgR-expressing cells. Thus, an MOI of
10 PFU/cell resulted in infection of only a small minority of
nectin2-expressing cells. When the MOI was increased to 30 and 100 PFU/cell, the number of infected cells increased but remained much
below 100% (Fig. 1). This was true for both nectin2- and
--expressing cells. We note that HIgR-expressing cells can be
infected at 100% efficiency with MOIs as low as 3 to 5 PFU/cell
(8). Infection of nectin2- and --expressing cells
therefore requires about 2 log higher MOIs than infection of HIgR
cells. Nectin2 and - are cell adhesion molecules that act through
homophilic interaction (1, 20). In order to check if the
high MOI required to enter nectin2- and --expressing cells was
due to low receptor availability, we infected monolayers of 70%
confluent and fully confluent cells in parallel and scored the numbers
of infected cells. Subconfluent or confluent cultures expressed very
similar amounts of nectin2, as detected by FACS analysis (data not
shown). No difference was observed between the amounts of infected
cells (data not shown), indicating that homophilic interaction, when
present, did not result in subtraction of receptors for the incoming
virus. Altogether, the results show that not all of the gD-unrestricted
mutants, selected for the ability to overcome the block to infection
mediated by wtgD1, were able to infect cells expressing
nectin2 or -. The finding that both isoforms, and ,
mediated entry of HSV-1(U21) and -(U10) suggested that the ectodomain
of the molecules carries the major functional domain and that
differences in the transmembrane and cytoplasmic tails are not crucial
for this activity. Nectin2- or --expressing cells were infected
at much lower efficiency than HveC- or HIgR-expressing cells.
It was reported that expression of HveB (nectin2) in CHO cells,
which are partially susceptible to HSV-2 entry, augments infection with
HSV-2(G) by about twofold, suggesting that it can serve as a mediator
of HSV-2 entry (32). J1.1-2 cells are highly resistant to
HSV-2 infection (8) and therefore represent a suitable
system with which to address the issue of whether nectin2 may function
as a mediator of HSV-2 entry. We found that expression of nectin2 or
- in J1.1-2 conferred some degree of susceptibility to HSV-2 but
with very low efficiency, inasmuch as infection at 100 PFU/cell
resulted in a number of infected cells much lower than that observed
with HSV-1(U21) (Fig. 1). Due to the very low efficiency of HSV-2 entry
into nectin2 cells, HSV-2 was not investigated further.
Several strains of HSV-1, KOS, Sc16, MP, and HFEM, as well as BHV-1,
had almost no ability to enter nectin2-expressing cells, in agreement
with previous data (32).
Nectin2- and --expressing cells were almost undistinguishable in
all assays, and subsequent results were obtained with both cell lines
but are shown mainly for one cell line only.
Nectin2 enables entry of gD mutants carrying the L25P substitution,
a mutation that enables mutant viruses to overcome the block to entry
into cells expressing wt HSV-1 gD.
HSV-1(U10) gD carries the L25P
amino acid substitution. HSV-1(U21) gD carries both the L25P and A185T
amino acid substitutions. These viruses also carry other mutations
outside of the gD gene (4). In order to ascertain if the
ability of HSV-1(U21) and -(U10) to infect nectin2-expressing cells is
dependent on the mutations present in gD and not on mutations present
outside of the gD gene, nectin2 cells were infected with recombinants
RFU21 and RFU10, which were created by marker transfer of the mutant gDs from HSV-1(U21) and HSV-1(U10) into HSV-1(F) and with the marker
rescue viruses RsU21 and RsU10, which were created by rescue of mutant
gD in HSV-1(U21) or HSV-1(U10) with wtgD1. The mutant virus
AP7r, which carries the L25P substitution was included in
this assay. Infection (100 and 30 PFU/cell) was monitored by
immunostaining of infected cells with rabbit polyclonal antibodies to
gM. Representative examples are shown in Fig. 2. The results,
summarized in Table 1 as positive or
negative, demonstrate that the recombinants of HSV-1(U10) and -(U21)
viruses were, indeed, able to infect nectin2 cells and that the
AP7r virus was also able to infect nectin2 cells, while the
marker rescue viruses RsU21 and RsU10 did not infect nectin2- and
--expressing cells. There was no detectable difference in the number
of cells infected with HSV-1(U10) or -(U21) (Fig. 2), indicating that
the ability of HSV-1(U21) to employ nectin2 was not dependent on the additional A185T substitution in gD. The results demonstrate that nectin2 serves as a specific receptor for gD mutants carrying the L25P
substitution and not for the mutant carrying the A185T substitution and
that the A185T substitution does not alter the effect of the L25P
substitution. Previously, no recombinant was used in studies in which
the rid1, rid2, and ANG strains were shown to infect HveB-expressing
CHO cells (32) to unambiguously ascribe the observed
phenotype to the mutations in gD. This is relevant in view of the fact
that HSV-1(U21) was reported to carry mutations that allow infection of
gD-expressing cells also outside the gD gene (4) and also
that mutations in gK can partially overcome the gD-mediated restriction
to infection (26).
We next tested whether nectin2 can serve as a receptor for mutants
carrying other substitutions in gD. R5000 and its recombinant R5001
carry a substitution at Ser140 (27). The mutants selected for resistance to MAbs LP14, AP12, and LP2 carry substitutions at amino
acids 16, 129, and 216 (24). The results shown in part in
Fig. 2 and summarized in Table 1 show that nectin2 could not serve as a
receptor for any of these mutants, despite the fact that R5000 and
R5001 can infect cells expressing wt HSV-1 gD. We conclude on the basis
of the mutants tested that nectin2 can serve as a receptor for gD
carrying the L25P substitution. This mutation coincides with one of the
mutations which enable HSV-1 to overcome the block to infection
mediated by HSV-1 gD. Nectin2 cannot serve as a receptor for viruses
carrying mutations in gD at residues 16, 129, 140, 185, and 216. Mutation at residue 185 does not affect the ability to employ nectin2
conferred by the L25P substitution. We note that, relative to HSV-1 gD,
HSV-2 gD, which could employ nectin2, although with very low
efficiency, is not mutated at amino acid 25 or at amino acid 27, where
the substitutions of HSV-1-rid1, -rid2, and ANG are located. However, it carries substitutions nearby, at amino acids 21 and 35 (10), which might account for the weak ability of nectin2 to
serve as a receptor for HSV-2.
As no difference was observed between HSV-1(U10) and HSV-1(U21) in the
ability to employ nectin2 as a receptor and as the A185T mutation,
alone, or in combination, had no additional effect on entry conferred
by the L25P substitution, the subsequent studies were performed with
HSV-1(U21).
MAbs R2.525 and BC12, but not R2.477, inhibit entry of
HSV-1(U21).
Three MAbs to nectin2 and - were assayed for the
ability to block the entry of HSV-1(U21). They are MAbs R2.525 and
R2.477, derived previously in one of our laboratories (22),
and BC12 (Diaclone). In order to quantify virus entry, derivatives of
nectin2 and - cells containing the lacZ gene under the
control of the 27 promoter (27p-LacZ) were constructed.
Nectin2 and - cells, whether carrying 27p-LacZ or not, were
incubated with increasing concentrations of MAbs for 2 h at 37°C
prior to infection with HSV-1(U21). Cells were fixed 16 h later,
and virus infection was monitored by immunoperoxidase staining with a
polyclonal antibody to gM or by assay of -gal activity. The results
in Fig. 3A and B show that MAbs R2.525
and BC12 inhibited HSV-1(U21) entry in a dose-dependent fashion.
Inhibition was about 90% at 20 µg/ml. By contrast, MAb R2.477 did
not inhibit virion infectivity (data are shown for nectin2). These
results suggest that MAbs R2.525 and BC12, but not R2.477, bind or
affect the nectin2 site functional in HSV-1(U21) entry.
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FIG. 3.
Block of HSV-1(U21) entry by MAbs to nectin2. (A)
Nectin2-expressing cells were preincubated with MAb R2.525, BC12, or
R2.477 to nectin2 or mouse IgGs (0.16 mg/ml) and then infected with
HSV-1(U21). Infection was monitored by immunostaining 16 h later.
(B) Nectin2-expressing cells carrying 27p-LacZ were preincubated
with the indicated concentrations of R2.525, BC12, and R2.477
antibodies or mouse IgGs and then infected with HSV-1(U21). Infection
was quantitated as -gal activity. A value of 100% represents the
value obtained with infected cells not exposed to antibodies.
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MAbs R2.525 and BC12, but not R2.477, bind the V domain of
nectin2.
In order to define the location of the nectin2 epitopes
recognized by the three antibodies tested above, soluble forms of nectin2 consisting of the entire ectodomain or of the single V domain,
designated VCC2-Fc and V2-Fc, were constructed by cloning the domains
of interest in the Cos Fc Link vector. The recombinant proteins,
VCC2-Fc and V2-Fc, were purified by affinity chromatography to Affigel
protein A from the extracellular medium of COS-1-transfected cells. The
binding of MAbs R2.525, BC12, and R2.477 to VCC2-Fc and V2-Fc was
determined in a sandwich ELISA. Microwells were first coated with
anti-human antibodies and thereafter with VCC2-Fc and V2-Fc and then
reacted with MAbs R2.525, BC12, and R2.477. Figure
4 shows that all of the MAbs bound
VCC2-Fc, which contains the full-length ectodomain. Interestingly, MAbs
R2.525 and BC12 had high levels of binding activity to V2-Fc, which
contains the single V domain whereas MAb R2.477 did not bind V2-Fc.
This demonstrates that the epitope recognized by the first two
antibodies is located in the V domain, whereas the epitope recognized
by MAb R2.477 appears to be located outside of the V domain but within
the ectodomain.
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FIG. 4.
ELISA binding of MAbs R2.525, R2.477, and BC12, directed
to nectin2, with soluble forms of nectin2 containing the entire
ectodomain (VCC2-Fc) or the single V domain (V2-Fc).
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Soluble forms of nectin2 containing the single V domain block
HSV-1(U21) infectivity.
The above results show that two MAbs which
inhibit HSV-1(U21) infectivity recognize epitopes located in the V
domain, whereas a MAb which does not block virus infectivity does not
bind the V domain. This provides evidence that a major nectin2 site
functional for HSV-1(U21) entry resides in the V domain. To confirm
these data, we tested whether V2-Fc, the soluble form of nectin2
containing the single V domain, competed with the cell-bound
full-length receptor and blocked HSV-1(U21) entry. The inhibition assay
was performed with nectin2 and --expressing cells and with the
respective cells carrying 27p-LacZ. The results in Fig.
5A and B show that V2-Fc inhibited virus
infectivity in a dose-dependent manner. Inhibition was complete at 200 nM (the data shown are for nectin2 cells). The results confirm that
a major nectin2 region functional in HSV-1(U21) entry is located in the
V domain. This feature is similar to that observed with HIgR and HveC
and HSV-1 (7, 19).
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|
FIG. 5.
Entry of HSV-1(U21) into nectin2-expressing cells is
competitively blocked by a soluble form of nectin2 carrying the single
V domain (V2-Fc). (A) HSV-1(U21) (100 PFU/cell) was preincubated with
V2-Fc (200 nM) or CTLA4-Fc and then allowed to adsorb to
nectin2-expressing cells. Infection was monitored by
immunoperoxidase staining. (B) Aliquots of HSV-1(U21) were preincubated
with V2-Fc or CTLA4-Fc and then allowed to adsorb to
nectin2-expressing cells carrying 27p-LacZ. Infection was
quantified as -gal activity. Each point represents the average of
triplicate assays. A value of 100% indicates the OD measured in
virus-infected cultures treated with no antibody.
|
|
gD from HSV-1(U21) interacts physically with soluble forms of
nectin2.
In the final series of experiments, we wanted to
ascertain whether a soluble form of nectin2 interacts physically with
gD from HSV-1(U21) (gDU21) and whether the binding site
resides in the V domain. Previously, binding of gD from the rid1 mutant
with HveB was not reported. gDU21 and wtgD1,
each purified to homogeneity from lysates of HSV-1(F)- or
HSV-1(U21)-infected cells by affinity chromatography (Fig.
6), were immobilized on microtiter wells and then reacted with increasing concentrations of the soluble forms of
HIgR or nectin2, designated VCC1-Fc, V1-Fc, VCC2-Fc, and V2-Fc,
respectively. Binding was detected by reactivity of anti-human Fc
antibodies. The results in Fig. 6 indicate that both wtgD1
and gDU21 bound to VCC1-Fc and V1-Fc with very similar patterns. gDU21 bound VCC2-Fc and V2-Fc. The association
was weaker than that to VCC1-Fc and V1-Fc. wtgD1 did not
bind VCC2-Fc in the concentration range tested. It was reported that gD
from HSV-1-rid1 and ANG had a somewhat higher affinity to HveC than
wtgD1 (18); we have not observed a similar
increase. We note that gDrid1 is mutated at amino acid 27, whereas gDU21 is mutated at amino acids 25 and 185. Determination of whether the slight changes in association to HveC or
HIgR correlate with the different mutations was beyond the scope of the
present investigation. Two major conclusions can be drawn from these
results. First, a physical interaction occurs between nectin2 and
gDU21. Second, the association between soluble nectin2 and
gDU21 is weaker than that between wtgD1 or gDU21 and a soluble form of HveC or HIgR.
View larger version (30K):
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|
FIG. 6.
In vitro binding of gDU21 and
wtgD1 to soluble forms of HveC/HIgR (VCC1-Fc and V1-Fc) or
nectin2 (VCC2-Fc and V2-Fc) receptors or to CTLA4-Fc as a negative
control. Affinity-purified gDU21 or wtgD1 was
immobilized on microwells and then reacted with increasing
concentrations of the indicated proteins. Binding was detected with
anti-human IgG-peroxidase. The insert in the top left corner represents
silver staining of affinity-purified gD from HSV-1(F)-infected (F) or
HSV-1(U21)-infected (U21) cells. The lower band represents the
monomeric form (m), and the upper band represents the dimeric form (d),
of gD.
|
|
| |
DISCUSSION |
Substitutions at or near residue 25 confer on gD the ability to
employ nectin2 as a receptor.
Of the mutants tested in this study,
nectin2 could serve as a receptor only for viruses carrying the
substitution at amino acid 25. Surprisingly, the mutants HSV-1(U30) and
R5000, carrying gD substitutions at amino acids 185 (U30) and 140 (R5000) that enabled entry into cells expressing wt HSV-1 gD, were not
able to utilize nectin2, suggesting that these viruses are able to employ still another, as yet unknown, secondary receptor. The results
presented earlier (32) suggested an involvement also of
amino acid 27. Current results demonstrate that mutant gD interacts physically with soluble forms of nectin2. Remarkably, the mutations at
residues 25 and 27 do not greatly affect the ability of HSV-1 gD to
interact with HveC or HIgR. This interaction has been finely mapped and
involves two gD regions, recognized by group Ia and Ib MAbs to gD,
located between amino acids 216 and 234 and 222 and 252, respectively
(18). It can be concluded that a domain of gD that enables
viral entry via nectin2 is located at or near amino acid 25. The
substitutions at residue 25, and possibly 27, appear to confer on gD,
which in the wt form seems to be unable to interact with nectin2, some
degree of ability to interact with nectin2 while not grossly altering
its ability to interact with HveC/HIgR. That HveC and HIgR can tolerate
a number of substitutions in gD is indirectly supported by the
observation that HveC and HIgR can mediate the entry also of HSV-2,
BHV-1, and PRV (8, 13) and of HSV-1 mutants resistant to
MAbs LP2, LP14, and AP12. The data suggest that the interaction of
mutant gD from HSV-1(U21) with nectin2 involves a domain not involved
in the interaction between wt HSV-1 gD and the ectodomain of HveC/HIgR.
Nectin2 and - represent low-efficiency receptors for
HSV-1(U21).
Evidence for the conclusion that nectin2 and -
are low-efficiency HSV-1(U21) receptors rests on the observation that
an MOI about 100-fold higher was required for HSV-1(U21) to infect cells expressing the nectin2 receptor than to infect cells expressing HveC/HIgR. Our results suggest that homophilic interaction of nectin2
in confluent cultures did not represent a limiting factor in the
availability of the nectin2 receptor for the infecting virus, since the
yield of infected cells did not change when confluent or subconfluent
cell cultures were infected. Nectin2 interacted physically with mutant
gD from HSV-1(U21). Interestingly, the association between
gDU21 and soluble nectin2 was weaker than that between
wtgD1 or gDU21 and soluble HIgR. The weaker
association is in keeping with the ability of nectin2 to serve as
low-efficiency receptor for HSV-1(U21). The failure to detect an
association between wtgD1 and soluble nectin2 is in keeping
with the inability of nectin2 to serve as a receptor for HSV-1(F)
(32).
A major region of nectin2 functional in the entry of HSV-1 mutants
is located in the V domain of the molecule.
Both isoforms of
nectin2, and , were able to mediate the entry of HSV-1(U21). The
two isoforms share the ectodomain and differ in the transmembrane and
cytoplasmic regions. This finding provided the first evidence that the
major region of nectin2 functional in HSV entry is located in the
ectodomain of the molecule. The functional region was further located
to the V domain on the basis of two lines of evidence. First, two MAbs
that blocked the entry of virions recognized an epitope located in the
V domain. Conversely, a MAb that did not block virion infectivity
recognized an epitope located outside of the V domain. Second, a
soluble form of the receptor, consisting of the V domain fused to the
Fc portion of human IgG could compete with the cell-bound full-length
receptor and reduce virion infectivity. In this respect, nectin2 does
not differ from HIgR and HveC, whose major region functional in HSV-1 entry resides in the V domain (7, 19), and does not even differ from the poliovirus receptor, whose functional region also resides in the V domain. The extent of divergence between the V domains
of HveC/HIgR and nectin2 is 67.1% at the amino acid level. This
divergence modulates the binding of two forms of gD differing at
residue 25. While HveC and HIgR bind gD from both wt HSV-1 and the
HSV-1(U21) and -rid1 mutant strains with high affinity, nectin2 binds
gD from HSV-1(U21) with low efficiency but does not appear to bind gD
from wt HSV-1 at all.
| |
ACKNOWLEDGMENTS |
We thank E. Mocarski (Stanford University), T. Minson (Cambridge
University), and M. Ackermann (University of Zurich) for the gifts of
plasmid pON832, MAb LP1, and the MAb to BHV-1 gB, respectively.
The studies at the University of Bologna were aided by Progetto
Finalizzatto Biotecnologie, by Telethon, and by grants from the
Ministry of Education and Research, ex60% and ex40%. The studies at
the INSERM U119, Marseille, were aided by INSERM, the Association pour
la Recherche Contre le Cancer (ARC), and the Ligue Nationale Francaise
Contre le Cancer (LNFCC).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Dipartimento di
Patologia Sperimentale, Sezione di Microbiologia e Virologia, Via San Giacomo, 12, 40126 Bologna, Italy. Phone: 39 051 2094733/34. Fax: 39 051 2094747. E-mail: campadel{at}kaiser.alma.unibo.it.
| |
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Journal of Virology, February 2000, p. 1267-1274, Vol. 74, No. 3
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Abstract
Introduction
