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Journal of Virology, December 1999, p. 9879-9890, Vol. 73, No. 12
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
The Major Neutralizing Antigenic Site on Herpes
Simplex Virus Glycoprotein D Overlaps a Receptor-Binding
Domain
J. Charles
Whitbeck,1,2,3,*
Martin I.
Muggeridge,1,2,
Ann H.
Rux,1,2,3
Wangfang
Hou,1,2
Claude
Krummenacher,1,2
Huan
Lou,1,2
Albert
van Geelen,1,
Roselyn
J.
Eisenberg,2,3 and
Gary H.
Cohen1,2
School of Dental
Medicine,1 Center for Oral Health
Research,2 and School of Veterinary
Medicine,3 University of Pennsylvania,
Philadelphia, Pennsylvania 19104
Received 28 May 1999/Accepted 24 August 1999
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ABSTRACT |
Herpes simplex virus (HSV) entry is dependent on the interaction of
virion glycoprotein D (gD) with one of several cellular receptors. We
previously showed that gD binds specifically to two structurally
dissimilar receptors, HveA and HveC. We have continued our studies by
using (i) a panel of baculovirus-produced gD molecules with various
C-terminal truncations and (ii) a series of gD mutants with
nonoverlapping 3-amino-acid deletions between residues 222 and 254. Binding of the potent neutralizing monoclonal antibody (MAb) DL11
(group Ib) was unaffected in forms of gD containing residues 1 to 250 but was greatly diminished in molecules truncated at residue 240 or
234. Both receptor binding and blocking of HSV infection were also
affected by these C-terminal truncations. gD-1(234t) bound weakly to
both HveA and HveC as determined by enzyme-linked immunosorbent assay
(ELISA) and failed to block infection. Interestingly, gD-1(240t) bound
well to both receptors but blocked infection poorly, indicating that
receptor binding as measured by ELISA is not the only gD function
required for blocking. Optical biosensor studies showed that while
gD-1(240t) bound HveC with an affinity similar to that of gD-1(306t),
the rates of complex formation and dissociation were significantly faster than for gD-1(306t). Complementation analysis showed that any
3-amino-acid deletion between residues 222 and 251 of gD resulted in a
nonfunctional protein. Among this set of proteins, three had lost DL11
reactivity (those with deletions between residues 222 and 230). One of
these proteins (deletion 222-224) was expressed as a soluble form in
the baculovirus system. This protein did not react with DL11, bound to
both HveA and HveC poorly as shown by ELISA, and failed to block HSV
infection. Since this protein was bound by several other MAbs that
recognize discontinuous epitopes, we conclude that residues 222 to 224 are critical for gD function. We propose that the potent
virus-neutralizing activity of DL11 (and other group Ib MAbs) likely
reflects an overlap between its epitope and a receptor-binding domain
of gD.
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INTRODUCTION |
The herpes simplex virus (HSV)
genome codes for at least 11 glycoproteins, most of which are
detectable in the virion envelope (50). Infection of
susceptible cells is initiated by the attachment of virions, via
glycoprotein C (gC) and/or gB, to cell surface heparan sulfate
proteoglycans (21, 22, 59). This is followed by the
interaction of gD with a cellular receptor. Then, pH independent fusion
occurs between the virus envelope and the host cell plasma membrane
(58); gB, gD, and the gH-gL complex have all been implicated in this step (50, 52).
Recently, expression cloning was used to identify several human genes
whose products convert the normally nonpermissive Chinese hamster ovary
cells into cells that are permissive for HSV type 1 (HSV-1) and HSV-2
entry (9, 19, 40, 53). These mediators of HSV entry are
known as HveA, HveB, and HveC. HveA is a member of the tumor necrosis
factor receptor superfamily of proteins (40) and interacts
with both lymphotoxin 
and LIGHT (38). HveB (also called
PRR2) and HveC (also called PRR1) are closely related members of the
immunoglobulin superfamily of proteins (36.1% amino acid sequence
identity within the predicted extracellular domains) which share 53.2 and 33.9% amino acid sequence identities, respectively, with the
poliovirus receptor extracellular domain (14, 19, 37, 53).
The normal cellular functions of these proteins remain unknown,
although recent data suggest that the murine homolog of HveB may be a
cell-cell adhesion molecule (1). A splice variant of HveC,
called HIgR, can also mediate HSV infection of nonpermissive cells
(9). Soluble forms of gD have been shown to bind directly to
soluble forms of HveA, HveC, and HIgR but not to HveB (8, 9, 31,
54, 55). In addition, antibodies to the receptors have been shown
to block infection by HSV (9, 40, 53). Thus, it is clear
that HSV can utilize several different and structurally unrelated cell
surface proteins as receptors and that two of these receptors bind
directly to HSV gD.
Two approaches were used in previous studies to try to define the
relationship between gD structure and function: (i) examination of the
properties of a panel of monoclonal antibodies (MAbs) to gD (11,
12, 23, 41, 43) and (ii) examination of the properties of a panel
of gD mutants (7, 17, 42). First, the antigenic site I of gD
was defined by seven MAbs, all of which possess potent
virus-neutralizing activity in the absence of complement (41). Although all group I MAbs block the binding of other
group I antibodies to gD, further subdivision of these MAbs into groups Ia and Ib was done on the basis of studies with truncated and other
mutant forms of gD. Two group Ia MAbs, HD1 and LP2 (11), bind to gD truncated at amino acid residue 233, whereas DL11 and four
other group Ib antibodies do not (11, 43). More recently, we
showed that, whereas DL11 blocks the binding of soluble HveA or HveC to
HSV virions, HD1 blocks the binding of HveC but not of HveA to HSV
(31, 44). On the other hand, MAbs in group VII blocked the
binding of HveA but not of HveC to HSV (31, 44). Taken
together, these results suggest that the binding of gD to each of these
receptors involves both a common region as well as unique portions of
the gD molecule. Furthermore, information about the location of
epitopes within antigenic sites I and VII has provided important clues
as to the portions of gD involved in the binding of each receptor. For
example, since group VII MAbs recognize a continuous epitope within
amino acids 11 to 19 (10, 26), it is likely that residues
near the amino terminus of gD are important for its interaction with
HveA. In support of this hypothesis, a mutant form of gD with a change
at amino acid 27 fails to bind to HveA but still interacts with HveC
(31, 54). Not surprisingly, viruses with this change in gD
are unable to utilize HveA as an entry receptor (40).
Using gD mutants and complementation analysis, we previously identified
four distinct regions within the gD primary structure that are
important for HSV infection which were designated functional regions I
through IV (7). Several observations can be made regarding
the relationship between antigenic site Ib (discussed above) and
functional regions II and III. First, all of the linker insertions
within functional region II abolished or greatly diminished binding by
the group Ib MAb, DL11. Second, functional region II (residues 125 to
161) encompasses residues previously shown to affect the binding of
certain group Ib antibodies (residues 132 and 140). Third, functional
region III (residues 225 to 246) includes residues known to be required
for group Ib antibody binding. These observations taken together
suggest that functional regions II and III may be closely positioned
within the folded (tertiary) structure of gD and may, together, form a
functional domain.
Here we address the contribution of gD residues between 222 and 275 to
the formation of both antigenic site Ib and a functional (receptor-binding) domain. To accomplish this, we constructed two sets
of HSV-1 gD mutants. The first group is a nested set of C-terminal
truncations consisting of molecules truncated at residues 234, 240, 250, 260, 285, and 306. The second set of constructs is a panel of 11 gD mutants containing adjacent, nonoverlapping, 3-amino-acid deletions
within functional region III. Our results support our hypothesis that
there is an overlap between antigenic site Ib and a domain involved in
binding to the HSV receptors, HveA and HveC.
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MATERIALS AND METHODS |
Cells and virus.
HeLa and Vero cells were obtained from the
ATCC and grown in Dulbecco modified Eagle medium (DMEM; Gibco)
supplemented with 5% fetal bovine serum (FBS). Sf9 (Spodoptera
frugiperda) cells (GIBCO BRL) were grown in Sf900II medium (GIBCO
BRL). The HSV1(KOS) recombinant, hrR3 (20), in
which the lacZ gene, under the control of the ICP6 promoter,
has been inserted into the ICP6 locus, was propagated in D14 cells as
described by Goldstein and Weller (20) and titers were
determined on Vero cells. COS-1 cells were grown in DMEM supplemented
with 5% FBS. VD60 cells were grown in DMEM containing 5% FBS and 1 mM
histidinol (35). The isolation and propagation of the
gD-null virus, F-gD
, has been described previously (35).
The HSV-1 strain KOS was used where indicated.
Construction of baculovirus recombinants expressing truncated
forms of gD.
The strategy employed in the construction of a
baculovirus recombinant expressing gD-1(306t) has been described in
detail elsewhere (49). The construction of bac-gD-1(285t)
and bac-gD-1(234t) has also been described (47). Briefly,
PCR primers were synthesized in order to amplify and modify the gD
ectodomain coding region for cloning into the pVT-Bac transfer vector
plasmid and expression in a recombinant baculovirus. The upstream
primer, 5'-TTTTGGATCCCAAATATGCCTTGGCGGATG-3', hybridized to the noncoding strand of the gD open reading frame (ORF) immediately beyond the predicted signal sequence coding region
and incorporated a BamHI restriction enzyme cleavage site (underlined). Three different downstream primers were used separately with the upstream primer to generate ORFs coding for gD truncated after
residue 260, 250, or 240. The downstream primer used to amplify the PCR
fragment for gD-1(260t) cloning and expression was
5'-GGCGAATTCAGTGGTGGTGGTGGTGGTGGGTCTCGGACAGCTCCGGGGGCAG-3' and incorporated an EcoRI restriction enzyme cleavage
site (underlined). The downstream primer used to amplify the PCR
fragment for gD-1(250t) cloning and expression was
5'-GGCGAATTCAGTGGTGGTGGTGGTGGTGGCTCGTGTATGGGGCCTT-3' and incorporated an EcoRI restriction enzyme cleavage
site (underlined). The downstream primer used to generate the PCR
fragment for gD-1(240t) cloning and expression was
5'-GGCGAATTCAGTGGTGGTGGTGGTGGTGCCCGGCGATCTTCAAGCTGTATA-3' and incorporated an EcoRI restriction enzyme cleavage
site (underlined). The primer used to generate the PCR fragment for
gD-1(
222-224, 306t) cloning and expression was
5'-TTTTCTGCAGTTAATGATGATGATGATGATGGTAAGGCGTCGCGG-3' and incorporated a PstI restriction enzyme cleavage
site (underlined). The PCR-amplified DNA fragments coded for gD lacking
its natural signal sequence so that the melittin signal sequence, coded
for by pVT-Bac, would replace the missing gD signal sequence. The downstream PCR primers were also designed to append six histidine codons prior to the termination codon to allow for purification of the
recombinant proteins by nickel agarose chromatography. The
PCR-amplified products were then digested with BamHI and
either EcoRI or PstI and cloned into pVT-Bac
which had been digested with the same enzymes. Once cloned into
pVT-Bac, the resulting plasmid constructs were cotransfected with
baculovirus DNA (Baculogold; Pharmingen) into Sf9 cells growing in
monolayer culture. After 4 days, the culture supernatant (containing
recombinant progeny virus) was replated onto Sf9 cell monolayers under
Grace's insect cell medium containing 1% agarose. Recombinant virus
plaques were picked, amplified, and screened for the expression of
secreted gD by sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (SDS-PAGE) and immunoblot analysis of the culture
medium from Sf9 cells infected with recombinant virus picks. Virus
clones expressing gD were plaque purified two times, and protein
expression from individual virus clones was verified at each stage by
SDS-PAGE and immunoblot analysis. The plaque-purified baculovirus
recombinant selected for routine use in production of gD-1 truncated at
residue 260 was named bac-gD-1(260t). The soluble protein produced by bac-gD-1(260t) is referred to as gD-1(260t). The nomenclature for the
250 and 240 truncations followed the same pattern. These designations
indicate that the secreted gD produced is truncated after the indicated
amino acid residue of the predicted mature (signal sequence removed)
protein (in this numbering system, the initiator methionine residue of
gD occurs at position 
25).
Production and purification of recombinant baculovirus-produced
proteins.
Production and purification of gD-1(306t), gD-1(285t),
gD-1(234t), HveA(200t), and HveC(346t) have been described (31,
47, 49, 54, 56). Production and purification of gD-1(260t), gD-1(250t), gD-1(240t), and gD-1(222-224, 306t) were carried out as
described previously for HveA(200t) [also called HVEM(200t) (54)].
ELISA.
Soluble receptor proteins HveA(200t) or HveC(346t) in
phosphate-buffered saline (PBS) were bound to 96-well enzyme-linked immunosorbent assay (ELISA) plates for 3 h at room temperature. The plates were washed three times with PBS-0.2% Tween 20 and incubated in blocking solution (PBS, 5% nonfat milk, 0.2% Tween 20)
for 30 min at 25°C. Plates were then washed three times with PBS-0.2% Tween 20 and incubated with truncated forms of gD at various
concentrations in blocking solution for 16 h at 4°C. Plates were
then washed three times with PBS-0.2% Tween 20 and incubated for 30 min with R7 (a rabbit polyclonal antiserum against gD) diluted 1 to
1,000 in blocking solution. After three washes with PBS-0.2% Tween
20, the plates were incubated in horseradish peroxidase-conjugated goat
anti-rabbit antibody (Boehringer Mannheim) diluted 1/1,000 in blocking
solution. Plates were washed three times with PBS-0.2% Tween 20 and
then once with 20 mM sodium citrate (pH 4.5). After removal of the
citrate buffer, ABTS substrate solution (Moss, Inc.) was added, and the
absorbance at 405 nm in individual wells was read by using a
Perkin-Elmer HTS 7000 Bio-Assay Reader. Finally, absorbance was plotted
against the concentration of gD used.
Antibodies.
R7 is a rabbit polyclonal antiserum raised
against native, full-length gD-2 isolated from virus-infected cells
(26). R69 is a rabbit polyclonal antiserum raised against
denatured, full-length gB-1 isolated from virus-infected cells
(16). 1D3 is a group VII MAb recognizing gD residues 11 to
19 (13, 18). DL6 is a group II MAb recognizing residues 272 to 279 (15, 26). MAbs HD1 (group Ia), DL11 (group Ib), D2
(group Ib), DL2 (group VI), and ABD (group III) recognize discontinuous
epitopes (11, 23, 41, 46, 48).
Blocking of HSV-1 entry into mammalian cells with soluble
proteins.
The blocking of HSV entry into cells with soluble gD was
carried out as described previously (27) and as modified by
Nicola et al. (45).
SDS-PAGE.
Purified glycoproteins were separated by SDS-PAGE
under "native" (0.1% SDS, no reducing agent, no boiling
[11]) or denaturing (samples boiled 10 min in 2.5%
SDS-350 mM -mercaptoethanol) conditions in precast Tris-glycine
gels (Novex). After SDS-PAGE, separated proteins were stained with
silver nitrate (Pharmacia) or transferred to nitrocellulose, probed
with antibodies, and visualized by enhanced chemiluminescence (Amersham).
Construction of gD-1 3-amino-acid deletion series.
Oligonucleotide-directed mutagenesis was carried out by using the
method of Zoller and Smith (60), as modified by Kunkel et
al. (33, 34), to generate the series of plasmid constructs expressing gD containing sequential, nonoverlapping 3-amino-acid deletions spanning residues 222 through 254. The template for mutagenesis was an M13mp18 construct containing the gD-1 (Patton) ORF
(cloned into the unique HindIII site) which was excised
from plasmid pRE4 (12) by HindIII digestion.
The specific mutagenic primers used were as follows: 222-224,
5'-TGGTTCTCGGGGGGCAGCATC-3'; 225-227,
5'-ACGGTGCGCTGGATGAAGCGGGGC-3'; 228-230,
5'-GTATACGGCGACGTTCTCGGGGAT-3'; 231-233,
5'-CTTCAAGCTGTAGGTGCGCTGGTT-3'; 234-236,
5'-CCCGGCGATCTTTACGGCGACGGT-3'; 237-239,
5'-CCCGTGCCACCCCAAGCTGTATAC-3'; 240-242,
5'-GGCCTTGGGCCCGGCGATCTTCAAGC-3'; 243-245,
5'-CGTGTATGGGGCGTGCCACCCGGC-3'; 246-248,
5'-CAGGGTGCTCGTCTTGGGCCCGTGC-3'; 249-251,
5'-TCCGGGGGCAGCAGGTATGGGGCCTT-3'; 252-254,
5'-GGACAGCTCCGGGGTGCTCGTGTAT-3'.
After mutagenesis, the gD ORFs were excised (HindIII)
from M13 replicative-form DNA and transferred into the mammalian
expression plasmid, pRSVnt-EPA (5). Plasmids containing the
gD ORF in the desired orientation were sequenced by using the
method of Chen and Seeburg (6) to confirm the presence of
the anticipated mutations (nine nucleotide deletions) within the gD ORF.
Antigenic analysis of mutants.
Transfection of COS cells and
the subsequent preparation of cytoplasmic extracts were performed as
previously described (12, 41).
Immunoperoxidase staining.
This procedure, which was
performed as previously described (43), is a modification of
that of Holland et al. (24) and Kousoulas et al.
(30). Surface staining of transfected cells was studied with
unfixed cells; for detection of intracellular antigens, the cells were
fixed with 5% methanol in PBS before incubation with the MAbs.
Complementation assay.
The assay was performed essentially
as previously described (43), except that COS cells were
used instead of Vero cells. Briefly, cells were transfected with
DNA-calcium phosphate precipitates for 16 h at 37°C and then
washed and incubated in DMEM-5% FBS for 8 h at 37°C. Each dish
of cells was subsequently infected at room temperature with
106 PFU of F-gD virus, followed by the addition of 5 ml
of DMEM-5% FBS and incubation for 1 h at 37°C. The medium was
then removed, and extracellular virus was inactivated by incubating the
monolayer for 1 min in glycine-saline (pH 3.0) (4, 25).
After 18 h in DMEM-5% FBS at 37°C, the medium was removed and
stored at 70°C for subsequent determination of the virus titers.
The cells were lysed by freeze-thawing and sonication with a Microson
cell disruptor. Nuclei were then pelleted by low-speed centrifugation,
and the supernatant was stored at 70°C for subsequent determination
of the virus titers. Both intracellular and extracellular virus titers were determined on VD60 cells. Transfection with salmon sperm DNA was
used as the negative control. One hundred percent complementation is
defined as the titer obtained after transfection with plasmid pRE4,
which expresses wild-type gD (12). Complementation with a
mutant is then defined by the following formula: % complementation = 100 × (titer with mutant plasmid titer with carrier DNA)/(titer with pRE4 titer with carrier DNA).
Optical biosensor experiments.
Biosensor experiments were
carried out on a Biacore X optical biosensor (Biacore AB) at 25°C as
previously described (32, 47). Biosensor data were analyzed
by using a global fitting routine with BIAevaluation software,
version 3.0 (2). Model curve fitting was carried out by
using a 1:1 Langmuir interaction with drifting baseline. This models
the simple interaction between ligand (L) and receptor (R) as follows:
L + R 
LR. The rate of association (kon)
was measured from the forward reaction, and koff
was measured from the reverse reaction. For gD-1(234t), a maximum
koff was estimated as previously described
(47) by using the equation
ln(R0/Rn) = koff(tn t0), where R0 is the response at time zero (t0) of dissociation and
Rn is the response at time n
(tn) (29). Scatchard analyses of the
gD-1(234t)-receptor complexes were performed as previously described
(47).
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RESULTS |
C-terminal truncations.
Krummenacher et al. (31)
and Rux et al. (47) showed that, compared to gD truncated at
residue 306 [gD-1(306t)], molecules truncated at residues 285 [gD-1(285t)] and 275 [gD-1(275t)] exhibited enhanced receptor
binding. In contrast, a form consisting of residues 1 to 234 [gD-1(234t)] exhibited greatly diminished receptor binding. gD-1(234t) was shown to retain much of the native structure of the
full-length molecule in that most MAbs recognizing discontinuous epitopes of gD reacted with gD-1(234t) (47). One exception
was that the group Ib MAb, DL11, bound poorly to gD-1(234t). Since gD-1(234t) lacks a significant portion of functional region III (7) (residues 225 to 246), we reasoned that the diminished receptor binding of gD-1(234t) was consistent with the idea that functional region III is directly involved in receptor binding. To
define more precisely the C-terminal gD residues required for receptor
binding as well as for the binding of MAb DL11, we expressed three
additional forms of gD in the baculovirus system. These gD molecules
were truncated after residues 260 [gD-1(260t)], 250 [gD-1(250t)], and 240 [gD-1(240t)]. Stick diagrams of these, as well as other recombinant baculovirus products, are shown in Fig. 1A. Each truncated form of gD was
constructed such that six histidine residues were present at the C
terminus to allow for purification by nickel chromatography. The gD
truncation mutants were purified by immunoaffinity chromatography
[gD-1(306t) and gD-1(285t)] or by nickel chromatography (all
other forms of gD). To assess the purity of the recombinant proteins,
similar amounts were loaded onto an SDS-10% polyacrylamide gel,
electrophoresed, and stained with silver nitrate. All of the proteins
were purified to near homogeneity and were of the expected sizes (Fig.
1B). Western blot analysis with the group VII MAb 1D3 (Fig. 1C)
confirmed that all of these purified proteins retained the correct
N terminus of gD (Fig. 1A).
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FIG. 1.
Recombinant baculovirus-produced proteins. (A) Stick
diagrams of full-length HSV gD and the truncated forms used in this
study (produced in recombinant baculovirus-infected cells). Functional
regions I to IV as defined by Chiang et al. (7) are shown as
shaded regions. The positions of linear epitopes for group II and group
VII are indicated. The positions of consensus sites for
N-glycosylation are marked by balloons. The disulfide bond
pattern for the six cysteine residues located in the extracellular
domain of gD (36) is shown on the full-length gD stick
diagram. (B) Silver-stained SDS-polyacrylamide gel (10%) showing the
purified recombinant baculovirus-produced proteins used in this study.
Lane 1, gD-1(306t); lane 2, gD-1(285t); lane 3, gD-1(260t);
lane 4, gD-1(250t); lane 5, gD-1(240t); lane 6, gD-1(234t);
lane 7, gD-1(222-224, 306t). (C) Western blot of the purified
proteins shown in panel B probed with MAb 1D3 (group VII).
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Antigenic analysis of C-terminal gD truncations.
To assess the
antigenic structure of the recombinant gD molecules, the proteins were
separated on nondenaturing ("native") SDS-polyacrylamide gels, and
blots were probed with various MAbs. The blot shown in Fig.
2A was reacted with the group II MAb DL6, which recognizes a linear epitope (residues 272 to 279) (26) (Fig. 1A). The expected pattern of reactivity with DL6 was observed in
that proteins smaller than gD-1(285t) were not reactive. The blots
shown in Fig. 2B to D were reacted with MAbs DL2, ABD, and HD1, each of
which recognizes a separate discontinuous epitope on gD. All of the
truncated proteins reacted similarly with these MAbs, indicating that
the native structure of gD was not grossly altered by the truncations.
The blots shown in Fig. 2E and F were reacted with two group Ib MAbs,
DL11 and D2. Although DL11 bound strongly to gD-1(306t),
gD-1(285t), gD-1(260t), and gD-1(250t), it bound weakly to
gD-1(240t) and gD-1(234t). In previous studies, we showed that
DL11 competed with soluble HveA and HveC for binding to gD in HSV
virions, suggesting that it binds within or near a region of gD
involved in receptor interaction (31, 44). According to the
data presented in Fig. 2E, gD residues immediately upstream of 250 contribute to the DL11 epitope. MAb D2, like DL11, bound weakly to
gD-1(240t) and gD-1(234t) but also exhibited reduced reactivity
with gD-1(250t) when compared with molecules truncated after
residues 260, 285, and 306. These results confirm and extend previous
work mapping residues critical to the formation of antigenic site Ib
(11, 12, 41-43).
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FIG. 2.
Antigenic analysis of baculovirus-produced gD truncation
mutants. Purified proteins were separated by "native" SDS-PAGE,
transferred to nitrocellulose, and probed with gD-specific MAbs. Lane
1, gD-1(306t); lane 2, gD-1(285t); lane 3, gD-1(260t); lane
4, gD-1(250t); lane 5, gD-1(240t); lane 6, gD-1(234t). (A)
Blot probed with DL6 (group II MAb). (B) Blot probed with DL2 (group VI
MAb). (C) Blot probed with ABD (group III MAb). (D) Blot probed with
HD1 (group Ia MAb). (E) Blot probed with DL11 (group Ib MAb). (F) Blot
probed with D2 (group Ib MAb).
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ELISA.
Previous studies showed that, compared to
gD-1(306t), molecules truncated after residues 285 and 275 bound to
HveA and HveC with increased affinity, while a molecule truncated after
residue 234 bound with reduced affinity (31, 47). To assess
the effect of the C-terminal truncations on receptor interaction, we
analyzed their binding to truncated forms of HveA [HVEM(200t)] and
[HveC (HveC(346t)] by ELISA (Fig. 3).
Figure 3A shows the binding of truncated forms of gD to HveA, while
Fig. 3B shows their binding to HveC. As previously reported (31,
47), gD-1(285t) bound to both HveA and HveC, as seen by
ELISA, ca. 100-fold better than did gD-1(306t). gD-1(260t) and
gD-1(250t) bound to both receptors as well as gD-1(285t).
However, gD-1(240t) bound to both receptors about as well as
gD-1(306t), whereas the binding of gD-1(234t) was nearly
undetectable. We conclude from these observations that gD residues
between positions 234 and 240 are critical for receptor binding and
that residues between positions 240 and 250 may also be involved (since
the receptor-binding activity of gD-1(240t), though not eliminated,
is reduced relative to larger forms of gD). It is of interest to note
that gD-1(240t), which showed diminished reactivity with the MAb
DL11, still bound to both receptors.
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FIG. 3.
Analysis of gD truncation mutants for receptor binding
by ELISA. The wells of an ELISA plate were coated with an excess of
HveA(200t) or HveC(346t) and incubated with increasing concentrations
(shown on the x axis) of gD truncation mutants. Bound gD was
detected by incubating sample wells with a rabbit antiserum raised
against gD (R7), followed by peroxidase-conjugated goat anti-rabbit
antibody and then peroxidase substrate. (A) Binding to HveA(200t). (B)
Binding to HveC(346t). Symbols:  , gD-1(306t);  ,
gD-1(285t);  , gD-1(260t);  , gD-1(250t);  ,
gD-1(240t);  , gD-1(234t).
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Biosensor analysis of gDt binding to HveA and HveC.
Previously, we used optical biosensor technology to show that the
increased affinity of gD-1(285t) for both HveA and HveC relative to
gD-1(306t) resulted almost exclusively from a faster rate of
complex formation (47). In contrast, gD-1(234t)
exhibited a faster rate of complex dissociation
(koff) with HveA compared to gD-1(306t),
suggesting that some gD residues involved in HveA binding had been
removed. Here we found that the binding kinetics and affinities of
gD-1(285t), gD-1(260t), and gD-1(250t) for both receptors
were quite similar (Table 1). In each
case, the higher affinity was due primarily to a faster rate of complex
formation (kon). gD-1(240t) exhibited
binding kinetics and an affinity similar to gD-1(306t) in its
interaction with HveA, consistent with its similar binding properties
as determined by ELISA. Although gD-1(240t) exhibited an overall
affinity for HveC similar to that of gD-1(306t), the
kon was 10-fold faster and the
koff was 4-fold faster than gD-1(306t).
Thus, in contrast to the ELISA results, the optical biosensor enabled
us to distinguish the binding of gD-1(306t) versus gD-1(240t)
to HveC. As observed previously (47), gD-1(234t) bound
to HveAt, but the data failed to fit a 1:1 Langmuir binding model. A
similar result was obtained when gD-1(234t) binding to HveC was
examined. Because of this, the binding kinetics for gD-1(234t) could not be analyzed by using the global fitting routine of the instrument software. Instead, maximum koff
values were estimated by plotting
ln(R0/Rn) versus time for the
initial part of the dissociation phase. For both HveA and HveC, the
maximum koff for gD-1(234t) was
approximately 10-fold faster than for gD-1(306t). Finally,
equilibrium dissociation constants (KD) for
gD-1(234t) binding to HveA and HveC were calculated from data
collected under conditions of binding equilibrium by using Scatchard
analysis. For gD-1(234t) binding to HveA this calculation yielded a
KD approximately sixfold lower than
gD-1(306t), while for binding to HveC the KD was nearly identical to that of gD-1(306t).
Blocking of virus entry by soluble forms of gD.
Soluble gD
blocks HSV entry into susceptible cells, presumably by binding to and
occupying cell surface receptors (28, 45). We tested the
abilities of truncated gD to block infection of HeLa and Vero cells
(Fig. 4A and B). gD-1(285t),
gD-1(260t), and gD-1(250t) blocked HSV infection at similar
concentrations (50% inhibition occurred between 1 and 10 nM) and were
more potent than gD-1(306t) (50% inhibition occurred between 100 and 200 nM). These results were consistent with the ELISA and biosensor
data showing that gD-1(285t), gD-1(260t), and gD-1(250t)
bound to both HveA and HveC with greatly increased affinities relative
to gD-1(306t). Similarly, the weak ability of gD-1(234t) to
block HSV infection is consistent with its diminished capacity to bind
HveA or HveC relative to gD-1(306t) (at least by ELISA).
Surprisingly, gD-1(240t) blocked HSV infection much less
effectively than gD-1(306t) (50% inhibition occurred at
approximately 5 µM). This result was unexpected because both the
ELISA and biosensor data indicated that this protein bound to both
receptor molecules with an affinity similar to gD-1(306t). We have
repeated these experiments several times with similar results. These
data suggest that gD-1(240t) may lack a portion of a gD functional
domain.
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FIG. 4.
Analysis of gD truncation mutants for blocking of HSV
entry. Cells in 96-well tissue culture plates were incubated with
increasing concentrations (shown on the x axis) of various
forms of gD prior to infection with HSV-1(KOS) carrying a
-galactosidase reporter gene (hrR3). At 5 h
postinfection, cells were lysed and assayed for -galactosidase
activity. (A) HeLa cells. (B) Vero cells. Symbols: , gD-1(306t);
, gD-1(285t); , gD-1(260t); , gD-1(250t); ,
gD-1(240t); , gD-1(234t);  , BSA.
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Antigenic structure of 3-amino-acid deletion mutants.
In order
to characterize further the region of gD encompassing functional region
III, as well as the residues involved in group Ib MAb binding, we used
site-directed mutagenesis to generate a series of plasmids encoding
full-length gD with nonoverlapping 3-amino-acid deletions spanning
amino acid residues 222 through 254 (Fig.
5). COS cells were transfected separately
with plasmids expressing each of the gD mutants. With the exception of
the 240-242 deletion mutant, all of the mutated proteins were
transported to the surface of transfected cells, as detected by
immunoperoxidase staining (data not shown). Cytoplasmic extracts were
then prepared from COS cells 40 h after transfection. As
controls, plasmids pRE4, which expresses wild-type gD-1, and pWW17,
which expresses the 234-244 deletion mutant (12),
were included. To quantitate relative gD expression, equal volumes of
each extract were electrophoresed on a denaturing polyacrylamide gel,
followed by transfer to nitrocellulose and probing with MAb DL6
(26). Based on this result, the volumes of extract loaded on
subsequent gels were normalized so as to give approximately equal
signals with DL6 (Fig. 6A). No protein could be detected for mutant 240-242, even after repetition of the
mutagenesis, so it was omitted from further analysis. Each extract was
then electrophoresed on a native polyacrylamide gel with no comb, and
strips of nitrocellulose were cut from the resulting Western blot and
probed with various MAbs (Fig. 6B to D). MAbs HD1 (panel B) and ABD
(panel C), which recognize discontinuous epitopes in antigenic sites Ia
and III, respectively (41-43), bound to all of the mutant
proteins. The binding of DL11 (panel D) was eliminated by deletion of
residues 222 to 224, 225 to 227, and 228 to 230 (lanes 1 to 3, respectively), suggesting that residues 222 to 230 contribute to
antigenic site Ib.
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FIG. 5.
Complementation analysis of 3-amino-acid deletion
mutants of HSV-1 gD. The predicted amino acid sequence for residues 220 to 255 of HSV-1(KOS) gD is shown at the top left (numbering is
based on the assignment of residue number 1 to the lysine at the N
terminus of the signal-peptidase-processed molecule, which is the 26th
residue of the primary translation product). HSV-2(strain 333) has two
amino acid changes relative to gD from the KOS strain in this region of
the protein, V L at residue 233 and AP at residue 246. Below the
wild-type sequence, the corresponding sequences of the 3-amino-acid
deletion mutants are shown. The level of complementation of a gD-null
virus is shown for each construct in the column at the right and is
expressed as a percentage of that achieved with the wild-type construct
(the mutant lacking residues 240 to 242 was never detected in
transfected cells [see text]).
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FIG. 6.
Antigenic analysis of HSV-1 gD 3-amino-acid deletion
mutants. Replicate cultures of COS cells were transfected separately
with plasmid constructs expressing wild-type gD, gD lacking residues
234 to 244, and each of the 3-amino-acid deletion mutants. Detergent
extracts were prepared from transfected cells after 40 h,
subjected to SDS-PAGE, and transferred to nitrocellulose (Western
blot). Blots were then probed with MAbs against HSV gD. (A) Blot probed
with DL6. (B) Blot probed with ABD. (C) Blot probed with HD1. (D) Blot
probed with DL11. Lane 1, gD-1(222-224); lane 2, gD-1(225-227); lane 3, gD-1(228-230); lane 4, gD-1(231-233); lane 5, gD-1(234-236); lane 6, gD-1(237-239); lane 7, gD-1(243-245); lane 8, gD-1(246-248); lane 9, gD-1(249-251); lane 10, gD-1(252-254); lane 11, gD-1(234-244); lane 12, wild-type gD-1.
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Activity of deletion mutants in a complementation assay.
Each
mutant was tested for its ability to complement the production of
infectious F-gD virus in COS cells by using quantities of plasmid
DNA that result in similar numbers of gD-expressing cells.
F-gD lacks a gD gene and produces infectious virus only when
functional gD protein is provided in trans (35).
With the exception of 252-254, none of the mutants was able to
complement F-gD, as found previously for the 234-244 mutant
(42) (Fig. 5). To address the possibility that lack of
complementation was due to failure of the mutated proteins to be
incorporated into virions, extracellular complemented F-gD virus was
centrifuged through a 10% sucrose cushion at 84,000 × g for 2 h at 4°C. The pellet was solubilized in denaturing
SDS-PAGE sample buffer, electrophoresed on a 7.5% polyacrylamide gel,
Western blotted, and probed with polyclonal antibodies against gD and
gB (Fig. 7). Although each of the mutant
proteins was detected in virions, the 225-227 and 243-245
proteins were incorporated inefficiently and may explain their
complementation-negative phenotype. Taken together, these results suggest that a region encompassing at least residues 222 to 251 is required for gD function.
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FIG. 7.
Detection of gD in F-gD virus complemented with the
3-amino-acid gD deletion mutants. Extracellular, F-gD virus which
had been complemented separately with each of the 3-amino-acid deletion
mutants was prepared as described in the text and analyzed by SDS-PAGE
followed by Western blotting. The resulting blot was probed with a
mixture of two polyclonal antibodies, R7 (raised against gD) and R69
(raised against gB). Lane 1, virus complemented with
gD-1(222-224); lane 2, virus complemented with
gD-1(225-227); lane 3, virus complemented with
gD-1(228-230); lane 4, virus complemented with
gD-1(231-233); lane 5, virus complemented with
gD-1(234-236); lane 6, virus complemented with
gD-1(237-239); lane 7, virus complemented with
gD-1(243-245); lane 8, virus complemented with
gD-1(246-248); lane 9, virus complemented with
gD-1(249-251); lane 10, virus complemented with
gD-1(252-254); lane 11, cells transfected with salmon sperm
DNA; lane 12, virus complemented with wild-type gD-1.
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Expression of gD-1(222-224) and gD-1(231-233) as
soluble forms in the baculovirus system.
In order to examine the
receptor-binding properties of a subset of the 3-amino-acid gD deletion
mutants, we constructed two baculovirus recombinants expressing gD-1
truncated after residue 306 and lacking residues 222 to 224 (DL11
negative) or residues 231 to 233 (DL11 positive). While both proteins
were detected in recombinant baculovirus-infected insect cells, only
the 222-224 protein [gD-1(222-224, 306t)] was secreted.
The baculovirus-produced gD-1(222-224, 306t) was purified by
nickel-agarose chromatography (Fig. 1), and its reactivity with a panel
of MAbs was analyzed by native Western blot (Fig.
8). As anticipated from the data shown in
Fig. 5, this mutant form of gD reacted with MAbs ABD and HD1. The
deletion mutant also reacted as well as gD-1(306t) with MAbs DL6
and DL2, further validating its structural integrity. In contrast,
gD-1(222-224, 306t) failed to react with either of two group Ib
MAbs tested, DL11 and D2. These results were consistent with the
antigenic properties of the full-length form of this protein expressed
in mammalian cells (see Fig. 6).
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FIG. 8.
Antigenic analysis of gD-1(222-224, 306t)
produced in recombinant-baculovirus-infected cells. Purified proteins
were separated by SDS-PAGE, transferred to nitrocellulose, and probed
with the gD-specific MAbs indicated below each panel. Lane 1, gD-1(306t); lane 2, gD-1(222-224, 306t). The gD-1(306t)
bands shown in each panel correspond to those shown in Fig. 2A to F.
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gD-1(222-224, 306t) binds poorly to HveA and HveC and fails
to block HSV infection.
To assess the receptor-binding properties
of gD-1(222-224, 306t), we examined its ability to bind to
HveA(200t) and to HveC(346t) by ELISA. As shown in Fig.
9A, the binding of gD-1(222-224,
306t) to HveA(200t) was barely detectable, even at concentrations as high as 6 µM. The binding to HveC(346t) was diminished by ca. 10-fold
relative to that of gD-1(306t). Consistent with its reduced binding
to both HveA and HveC, gD-1(222-224, 306t) failed to block
virus infection of HeLa or Vero cells (Fig.
10). The failure of
gD-1(222-224, 306t) to bind well to either of two known HSV receptors most likely explains the inability of the full-length form of
this protein to block virus infection or to complement the infectivity
of a gD-null virus.
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FIG. 9.
Analysis of gD-1(222-224, 306t) for receptor
binding by ELISA. The wells of an ELISA plate were coated with an
excess of HveA(200t) or HveC(346t) and incubated with increasing
concentrations (shown on the x axis) of gD-1(306t),
gD-1(250t), or gD-1(222-224, 306t). Bound gD was detected
by incubating sample wells with a rabbit antiserum raised against gD
(R7), followed by peroxidase-conjugated goat anti-rabbit antibody and
then peroxidase substrate. (A) Binding to HveA(200t). (B) Binding to
HveC(346t). Symbols: , gD-1(306t); , gD-1(250t);  ,
gD-1(222-224, 306t).
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FIG. 10.
Analysis of gD-1(222-224, 306t) for blocking of
HSV entry. Cells in 96-well tissue culture plates were incubated with
increasing concentrations (shown on the x axis) of
gD-1(306t), gD-1(250t), or gD-1(222-224, 306t) prior to
infection with HSV-1(KOS) carrying a -galactosidase reporter
gene (hrR3). At 5 h postinfection, cells were lysed and
assayed for -galactosidase activity. (A) HeLa cells. (B) Vero cells.
Symbols: , gD-1(306t); , gD-1(250t); ,
gD-1(222-224, 306t); , bovine serum albumin.
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DISCUSSION |
During the past decade, numerous studies have examined how the
structure of HSV gD relates to its function. Some studies focused on a
discontinuous antigenic site which was bound by several type-common, complement-independent neutralizing MAbs (antigenic site I). On the
basis of additional characteristics, group I MAbs were subdivided into
subgroups Ia and Ib (41). For example, the group Ia MAb, HD1, binds to gD truncated at amino acid residue 233, whereas the group
Ib antibodies, such as DL11, do not. Separate studies demonstrated the
involvement of residues upstream of 233 in antigenic site Ib as well
(39, 43). Single-amino-acid changes were identified which
allowed gD to function during virus replication while conferring resistance to neutralization by certain group I antibodies.
Specifically, two group Ib antibodies failed to neutralize a virus
expressing gD with a Ser-to-Asn change at residue 140, and a third
group Ib antibody failed to neutralize a virus expressing gD with a Gln-to-Leu change at residue 132 (Fig.
11).
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FIG. 11.
Stick diagram of HSV gD showing features relevant to
this study. The amino- and carboxy-terminal ends of the gD ectodomain
are indicated by H2N and COOH, respectively. Cysteine
residues are denoted by C, and the disulfide bond pattern
(36) is indicated by dashed lines. Functional regions I to
IV as defined by Chiang et al. (7) are shaded in gray. The
positions of individual residues relevant to the present study are
marked by a dot and labeled with the residue number.
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Evidence of an overlap between antigenic site Ib and a putative
functional region of gD was provided by Muggeridge et al. (42), who examined seven gD mutants containing N-terminal,
internal, or C-terminal amino acid deletions for their ability to
complement a gD-null virus. gD lacking residues 234 to 244 was
expressed on the surface of transfected cells and, although not
globally altered in structure, failed to rescue the infectivity of a
gD-null virus. Interestingly, this mutant protein failed to react with DL11, suggesting that antigenic site Ib, as well as a functional region
of gD, was disrupted by this 11-amino-acid deletion. In a similar
study, Feenstra et al. (17) found that deletion of residues
231 to 235 resulted in a protein which also failed to complement a
gD-null virus but retained reactivity with DL11. More recently, Nicola
et al. (44) showed that DL11 blocked the interaction of
soluble HveA with gD or with HSV virions, and Krummenacher et al.
(31) showed that DL11 blocked the interaction of soluble HveC with HSV virions. Finally, gD truncated at residue 234 was bound
by DL11 weakly and bound HveA with a markedly lower affinity (KD) than molecules truncated at residue 275, 285, or 306 (47).
Linker-scanning mutational analysis of HSV gD (7) identified
four distinct functional regions within the gD primary structure wherein linker insertions did not cause global structural alterations but greatly diminished or eliminated the protein's ability to complement the infectivity of a gD-null virus (shaded areas designated I through IV in Fig. 11). This study also revealed a relationship between antigenic site Ib and regions II and III. First, linker insertions within region II abolished or greatly diminished binding by
DL11. Second, region II (residues 125 to 161) encompasses residues previously shown to affect the binding of group Ib antibodies (residues
132 and 140; see Fig. 11). Third, region III (residues 225 to 246)
includes residues required for group Ib antibody binding. These
observations suggest that regions II and III may be closely positioned
within the folded structure of gD and may, together, form a functional
(receptor-binding) domain.
In the present study we addressed the contribution of gD residues
between 222 and 275 to the formation of both antigenic site Ib as well
as a receptor-binding domain. We constructed three baculovirus
recombinants expressing gD truncated after residues 240, 250, and 260 and analyzed them along with previously described gD truncations (after
residues 234, 285, and 306) for antigenic structure, receptor binding,
and virus-blocking activity. All of the truncated proteins
were bound by several MAbs recognizing discontinuous epitopes. In
contrast, reactivity with DL11 was not exhibited by all of the
truncation mutants. Although gD-1(250t) reacted strongly with DL11,
gD-1(240t) and gD-1(234t) had significantly diminished
reactivity. Thus, we conclude that the C-terminal limit for full DL11
binding occurs between residues 240 and 250.
Analysis of the C-terminal truncation mutants for receptor binding
revealed a pattern somewhat similar to that seen for DL11 binding.
Using the activity of gD-1(306t) as a reference point, gD-1(285t), gD-1(260t), and gD-1(250t) exhibited enhanced
binding to both HveAt and HveCt (Fig. 11), a property previously
demonstrated for gD-1(285t) and gD-1(275t) (31, 47).
The higher affinity of gD-1(285t) and gD-1(275t) for HveA was
shown by optical biosensor studies to result from a faster
kon. Here we found that gD-1(260t) and
gD-1(250t) bound to both HveA and HveC with kinetics and
KD values very similar to those of
gD-1(285t). The calculated KD values for the
interactions of gD-1(240t) with HveA and HveC were quite similar to
those for gD-1(306t). Interestingly, the kon and koff values obtained for the interaction of
gD-1(240t) with HveC were significantly faster than those obtained
for gD-1(306t). From these experiments it is clear that the loss of
high-affinity receptor binding by gD is first evident in
gD-1(240t), the same truncation point at which full DL11 reactivity
is lost. The shorter truncation, gD-1(234t), exhibited an
approximately 10-fold faster koff for both HveA
and HveC relative to gD-1(306t), perhaps due to deletion of gD
residues which stabilize the complexes (Fig. 11).
The ability of soluble gD to bind receptor molecules should
theoretically correspond to its ability to block HSV infection of cells
bearing those receptors. In the case of both HeLa and Vero cells, the
blocking activities of all but one of the proteins closely matched
their receptor-binding properties as seen by ELISA. Interestingly,
gD-1(240t), which bound both HveA and HveC with a
KD very similar to gD-1(306t), was much less
effective in blocking HSV infection than gD-1(306t). Perhaps the
membrane-bound forms of HveA and HveC recognize gD somewhat differently
than the truncated forms used in the ELISA and biosensor studies. This
result might also suggest that there is yet another receptor in HeLa
and Vero cells to which gD-1(240t) binds with lower affinity than
gD-1(306t). This explanation seems unlikely, at least for HeLa
cells, since Cocchi et al. (8) showed that a MAb to HIgR
(HveC) effectively blocks HSV infection of this cell line.
Alternatively, the difference in blocking ability between
gD-1(306t) and gD-1(240t) may reflect the different rates of
gD-HveC complex formation and or dissociation observed in the optical
biosensor studies discussed above.
The observation that gD-1(234t) bound HveA, albeit in an unstable
manner, indicated that at least some receptor-binding residues were
present upstream of 234. To extend our analysis of the group Ib epitope
and functional region III, we generated a panel of plasmid constructs
expressing full-length HSV-1 gD with sequential, nonoverlapping,
3-amino-acid deletions extending from residue 222 through residue 254. The altered gD molecules expressed in transiently transfected cells
were first analyzed for function by using a complementation assay. Only
one of the 3-amino-acid gD deletion mutants (252-254) complemented
the infectivity of a gD-null virus, confirming the conclusions of
Chiang et al. (7). All forms of gD retained the folded
structure necessary for reactivity with group III and group Ia MAbs,
and each was detected on the surface of transfected cells. However, gD
lacking residues 222 to 224, 225 to 227, or 228 to 230 failed to react
with DL11, indicating that even small deletions in this region of gD
disrupt antigenic site Ib. Earlier results, examined in connection with
data presented here, suggest that gD residues 222 through 230 are
critical for proper formation of the DL11 epitope, whereas residues
between positions 231 and 250 may be important for proper presentation of the DL11 epitope but are not directly involved in antibody binding.
To examine the receptor-binding properties of some of the 3-amino-acid
deletion mutants, we cloned and expressed two of these proteins
(222-224 and 231-233) as truncated forms in the baculovirus system. Although both of these molecules were detected in
recombinant-baculovirus-infected cells, only gD-1(222-224,
306t) could be purified from the culture medium. gD-1(222-224,
306t) reacted with several MAbs (but not DL11, as expected), bound
weakly to HveA and HveC, and failed to block HSV infection of mammalian
cells. This result showed that gD-1(222-224) is nonfunctional
due, at least in part, to its greatly diminished binding to cellular
receptors. Once again, these data support the concept of an overlap
between a receptor-binding domain of gD and the DL11 epitope.
Antibodies directed to viral proteins can neutralize virus infectivity
by binding to and occupying the site on a virion protein which
interacts with a cellular receptor during virus attachment and entry.
This mechanism of neutralization by certain MAbs has been demonstrated
for several different viruses, including influenza virus (3,
51). Whether DL11 (and other group Ib MAbs) neutralizes HSV
infectivity by occupying part of its receptor binding domain has yet to
be conclusively demonstrated. The data presented here and in previous
publications are clearly consistent with this interpretation, although
it is formally possible that the receptor-binding site on gD is
spatially distinct from the group Ib antigenic site. To address this
and other questions, we are currently attempting to determine the
crystal structure of gD alone, as well as gD complexed with each of its
two known receptors or complexed with the DL11 MAb.
| |
ACKNOWLEDGMENTS |
This investigation was supported by Public Health Service grants
AI-18289 to G.H.C. and R.J.E. from the National Institute of Allergy
and Infectious Diseases and grants NS-30606 and NS-36731 to R.J.E. and
G.H.C. from the National Institute of Neurologic Diseases and Stroke.
C.K. was supported by a fellowship (823A-053464) from the Swiss
National Science Foundation.
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FOOTNOTES |
*
Corresponding author. Mailing address: 212 Levy Bldg.,
School of Dental Medicine, University of Pennsylvania, Philadelphia, PA
19104. Phone: (215) 898-6553. Fax: (215) 898-8385. E-mail: whitbeck{at}biochem.dental.upenn.edu.
Present address: Department of Microbiology and Immunology,
Louisiana State University School of Medicine, Shreveport, LA 71130.
Present address: Department of Microbiology, University of Nevada
at Reno, Reno, NV 89557.
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Journal of Virology, December 1999, p. 9879-9890, Vol. 73, No. 12
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Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
