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Previous Article | Next Article 
Journal of Virology, September 1998, p. 7341-7348, Vol. 72, No. 9
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Infectivity of a Pseudorabies Virus Mutant Lacking
Attachment Glycoproteins C and D
Axel
Karger,
Jerg
Schmidt, and
Thomas C.
Mettenleiter*
Institute of Molecular and Cellular Virology,
Friedrich-Loeffler-Institutes, Federal Research Centre for Virus
Diseases of Animals, D-17498 Insel Riems, Germany
Received 2 March 1998/Accepted 9 June 1998
 |
ABSTRACT |
Initiation of herpesvirus infection requires attachment of virions
to the host cell followed by fusion of virion envelope and cellular
cytoplasmic membrane during penetration. In several alphaherpesviruses,
glycoprotein C (gC) is the primary attachment protein, interacting with
cell-surface heparan sulfate proteoglycans. Secondary binding is
mediated by gD, which, normally, is also required for penetration.
Recently, we described the isolation of a gD-negative infectious
pseudorabies virus (PrV) mutant, PrV gD
Pass (J. Schmidt,
B. G. Klupp, A. Karger, and T. C. Mettenleiter, J. Virol. 71:17-24, 1997). In PrV gD Pass, attachment and
penetration occur in the absence of gD. To assess the
importance of specific attachment for infectivity of PrV
gD Pass, the gene encoding gC was deleted, resulting in
mutant PrV gCD Pass. Deletion of both known
attachment proteins reduced specific infectivity compared to
wild-type PrV by more than 10,000-fold. Surprisingly, the
virus mutant still retained significant infectivity and could
be propagated on normal noncomplementing cells, indicating the presence
of another receptor-binding virion protein. Selection of bovine kidney
(MDBK) cells resistant to infection by PrV gCD Pass
resulted in the isolation of a cell clone, designated NB, which was
susceptible to infection by wild-type PrV but refractory to infection
by either PrV gCD Pass or PrV gD Pass, a
defect which could partially be overcome by polyethylene glycol
(PEG)-induced membrane fusion. However, even after PEG-induced infection plaque formation of PrV gCD Pass or PrV
gD Pass did not ensue in NB cells. Also, phenotypic gD
complementation of PrV gCD Pass or PrV gD
Pass rescued the defect in infection of NB cells but did not restore
plaque formation. Glycosaminoglycan analyses of MDBK and NB cells
yielded identical results, and NB cells were normally susceptible to
infection by other alphaherpesviruses as well as vesicular
stomatitis virus. Infectious center assays after PEG-induced infection of NB cells with PrV gD Pass on MDBK cells
indicated efficient exit of virions from infected NB cells. Together,
our data suggest the presence of another receptor and
receptor-binding virion protein which can mediate PrV entry and
cell-to-cell spread in MDBK cells.
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INTRODUCTION |
Attachment of herpesviruses to
target cells is mediated by viral glycoproteins which are embedded in
the virion envelope and interact with cellular surface components
acting as virus receptors. The best-characterized herpesvirus-cell
interaction is the binding of glycoprotein gp350/220 of the
gammaherpesvirus Epstein-Barr virus to the B-lymphocyte surface protein
CD21, also designated complement receptor 2 (28). Among the
alphaherpesviruses, initial interaction between the virion and the
target cell involves binding of glycoprotein C (gC) to cell-surface
glycosaminoglycans, in particular, heparan sulfate, as components of
proteoglycans. This heparan sulfate interaction has been observed for
herpes simplex virus type 1 (HSV-1) and HSV-2 (7, 41, 48),
pseudorabies virus (PrV) (23, 36),
varicella-zoster virus (50), and bovine herpesvirus 1 (BHV-1) (20, 29). In addition, the gammaherpesvirus bovine
herpesvirus 4 (BHV-4) (45) and the betaherpesviruses human
cytomegalovirus (HCMV) (2) and human herpesvirus 7 (40) have been reported to interact with heparan sulfate
proteoglycans during attachment.
Receptor-binding activity has also been shown for gD of HSV-1, PrV, and
BHV-1. Soluble HSV-1 gD binds to a saturable number of receptors on the
surface of target cells (9), and gD of HSV-1, PrV, and BHV-1
is required for a secondary, stable binding which is no longer
sensitive to competition by exogenous heparin (11, 22).
Recently, a member of the tumor necrosis factor receptor family,
designated herpesvirus entry mediator (HVEM), has been identified which
functions in entry of HSV-1 into partially resistant chinese hamster
ovary (CHO) cells (27). The viral ligand for HVEM is
gD (47). Whereas gC is not required for
productive replication of HSV-1, PrV, or BHV-1 and is, therefore,
regarded as nonessential, the presence of gD is necessary for
replication of wild-type strains of these viruses (24, 42).
Thus, in the absence of gC, attachment could be mediated by gD.
Moreover, for HSV-1 it has been shown that heparan sulfate-binding of
gC virions is mediated by the essential gB
(8). This indicates that gC-negative HSV-1 is still able to
infect cells via a heparan sulfate-dependent pathway. In contrast, gC
represents the only PrV virion glycoprotein capable of
interacting productively with cell surface heparan sulfate for
mediating infection (12). Neither PrV gB nor heterologous
BHV-1 gB exhibits heparan sulfate-binding activity in gC-negative PrV
virions (14). Therefore, for PrV only two virion proteins
have been reported to play a role in attachment, gC and gD.
Evidence for the capability to bind to cellular surface proteins has
also been reported for gH of HCMV (13) and gB of BHV-1 (19, 46). However, neither of the postulated receptors has been characterized.
In wild-type PrV, gD is required for penetration but not for direct
cell-to-cell spread (30, 32) which allowed copassaging of
gD PrV-infected cells with noninfected cells. Using this
approach, we recently isolated an infectious gD-negative PrV mutant,
PrV gD Pass (37). Similar results have also
been obtained for BHV-1 (39). Infectivity of PrV
gD Pass is not dependent on the presence of gD, and viral
titers of PrV gD Pass reach up to 107 PFU/ml.
We were interested in analyzing the importance of the other attachment
protein, gC, for infectivity of PrV gD Pass. We report
here the construction of a mutant of PrV gD Pass with a
deletion of gC and its characterization in cell culture. We also
isolated an MDBK cell clone which is specifically refractory to
infection by the infectious gD PrV mutants due to a
defect in entry.
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MATERIALS AND METHODS |
Viruses and cells.
Virus mutants were derived from the
wild-type PrV strain Kaplan (PrV-Ka) (10). The
gG gD PrV mutants 133 (PrV-gD) (32) and PrV gD Pass
(37) have been described previously. Both mutants carry a
gG-
-galactosidase expression cassette at the gG locus
(25) as does PrV-1112 (25), which replicates like
wild-type PrV. PrV-gC, a deletion mutant lacking most of
the gC gene and the 3' end of the upstream UL43 gene, has been
described previously (12). BHV-1 was obtained from G. Keil,
vesicular stomatitis virus (VSV) was obtained from H. Schirrmeier, and
equine herpesvirus 1 (EHV-1) was obtained from N. Osterrieder (all from
the Federal Research Centre for Virus Diseases of Animals, Insel Riems,
Germany). The HSV-1 strain KOS was obtained from P. Spear, Northwestern
University, Chicago, Ill. Viruses were propagated on porcine (PSEK),
bovine (MDBK), or African green monkey kidney (Vero) cells. For
detection of -galactosidase activity, monolayers were fixed and
overlaid with staining solution containing
5-bromo-4-chloro-3-indolyl--D-galactopyranoside (X-Gal)
(34). Phenotypic gD complementation of gD-negative viruses was achieved by propagation of the respective virus mutant on PrV
gD-expressing cells (32).
Southern blot hybridization.
Southern blotting was performed
by standard procedures (33) using 32P-labelled
hybridization probes.
Virus purification and immunoblot.
Monoclonal antibodies
(MAbs) against gB, gC, gD, and gH (15) were used. Proteins
of sucrose gradient-purified virions (16) were analyzed by
Western blotting (43) after electrophoresis in sodium
dodecyl sulfate-10% polyacrylamide gels (17) under reducing conditions. Specific infectivities of virion preparations were
determined by calculating particle numbers in preparations of
gradient-purified virions obtained from supernatants of infected cells,
based on their DNA content (37). Virion preparations were
routinely assayed by electron microscopy for purity and presence of
enveloped virions.
Glycosaminoglycan differentiation.
Analysis of
glycosaminoglycan composition was performed according to a protocol by
Yamagata et al. (49) as modified by Gressner et al.
(5). Briefly, Na2
35SO4-labelled proteoglycans were extracted
from cell cultures, and glycosaminoglycans were purified by
ion-exchange chromatography after digestion of the protein moiety.
Distribution of heparan sulfate and chondroitin sulfate was determined
by digestion with heparinase-heparitinase or chondroitinase ABC and
quantitated by measuring radioactivity in reaction products.
Titration and infectious-center assay.
To determine virus
titers, MDBK cells were infected with serial dilutions of virus
suspensions and incubated at 37°C for 1 h. Thereafter, the
inoculum was removed and cells were overlaid with semisolid
methylcellulose medium. Cells were stained with crystal violet, by
immunostaining (for HSV-1), or by X-Gal overlay after 2 or 3 days of
incubation at 37°C. Plaques or infected single cells were then
quantitated. For infectious-center assays, two wells of a six-well
tissue culture dish were inoculated with an appropriate virus dilution
containing between 200 and 500 PFU. Since NB cells are normally not
susceptible to PrV gD Pass and PrV gCD
Pass, they were infected with undiluted stock solutions of these viruses. After incubation at 37°C for 1 h, polyethylene glycol (PEG) fusion was performed in one well, as described below, and control
cells were treated with cell culture medium instead of PEG.
Extracellular virus was then inactivated by treatment with citrate
buffer (CBS) (40 mM citric acid-sodium citrate [pH 3.0], 10 mM KCl,
135 mM NaCl) for 1 min. Cells were washed with phosphate-buffered saline, trypsinized, resuspended in medium, and coseeded with MDBK
cells in a 10-cm-diameter culture dish. Cells were stained with X-Gal
after 2 days, and plaques were counted.
PEG-induced fusion.
For PEG fusion experiments
(35) cells were inoculated with the respective virus
suspension and incubated at 37°C for 1 h. The inoculum was then
removed, and cells were washed with phosphate-buffered saline and
overlaid for 30 s with PEG50 (50% PEG 6000 in modified Eagle
medium [MEM]). PEG was removed by consecutive washes with a 1:2 and
1:4 dilution in MEM of PEG50, followed by three washes in MEM
supplemented with 5% fetal calf serum. Cells were further incubated
for 2 days at 37°C prior to X-Gal staining.
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RESULTS |
Isolation and characterization of PrV gCD Pass.
To isolate a gC variant of PrV gD Pass, DNA
of purified PrV gD Pass virions was cotransfected into
Vero cells with plasmid TN90/3 (38) in which most of the gC
gene and the 3' end of the UL43 gene has been deleted. Virus progeny
was enriched for gC-negative viruses by complement-mediated
neutralization with an anti-gC MAb. Surviving viruses were plated onto
Vero cells, and five plaques were randomly picked. Southern blot
analysis showed that all five plaques contained the desired deletion in
the gC gene. One isolate, designated PrV gCD Pass, was
further tested. As shown in Fig. 1, after
agarose gel electrophoresis (Fig. 1A) of BamHI-digested DNA
of PrV-Ka (Fig. 1, lanes 1), PrV-gC (Fig. 1, lanes 2),
PrV gD Pass (Fig. 1, lanes 3), and PrV gCD
Pass (Fig. 1, lanes 4), hybridization with a gC gene-specific probe
(Fig. 1B) yielded the expected signals in the gC+ viruses
whereas it failed to hybridize to DNA of the gC viruses.
Moreover, BamHI fragment 2 containing the gC gene shifted to
the size of BamHI fragment 3 (Fig. 1A, lanes 2 and 4) due to the introduction of the ca. 1.4-kbp deletion. Hybridization with a
gD-specific probe was also performed (Fig. 1C). All gD+
viruses showed the expected signals, whereas the gD
viruses did not exhibit specific reactivity.
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FIG. 1.
Genotypic characterization of PrV gCD
Pass. Virion DNA was isolated from PrV-Ka (lanes 1),
PrV-gC (lanes 2), PrV gD Pass (lanes 3),
and PrV gCD Pass (lanes 4) and cleaved with
BamHI, and resulting fragments were separated in a 0.8%
agarose gel by electrophoresis. (A) Ethidium bromide-stained gel. After
transfer to nylon filters, hybridization was performed with probes
specific for the gC gene (B) or the gD gene (C). Positions of
BamHI fragments of PrV-Ka DNA are indicated on the left.
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As an additional test, Western blotting was performed on lysates of
purified virions of PrV-Ka (Fig. 2, lanes
1), PrV-gC (Fig. 2, lanes 2), PrV gD Pass
(Fig. 2, lanes 3), and PrV gCD Pass (Fig. 2, lanes 4).
Whereas all virion preparations showed the presence of gB and gH, gC
was detected in only the PrV-Ka and PrV gD Pass virion
preparations, and gD was present in only PrV-Ka and PrV-gC. Specific infectivity of PrV gCD
Pass as determined on MDBK cells was approx. 800-fold lower than that
of PrV gD Pass (1.2 × 107 particles/PFU
for PrV gCD Pass versus 1.5 × 104
particles/PFU for PrV gD Pass). In contrast, specific
infectivity of PrV-gC was reduced only ca. 50-fold
compared to PrV-Ka (1.1 × 104 particles/PFU for
PrV-gC versus 2.3 × 102 particles/PFU
for PrV-Ka). This indicates a stronger dependence for infection on the
presence of gC in PrV gD Pass than that in wild-type
PrV-Ka, presumably due to the absence of the other known attachment
protein, gD, in PrV gD Pass. In summary, these data show
that PrV gCD Pass simultaneously lacks gC and gD.
Deletion of both known attachment proteins strongly impairs virus
infectivity. However, since PrV gCD Pass was isolated and
could be propagated on normal cells, these results imply that at least
one additional PrV virion protein functions in mediating attachment of
this virus mutant.
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FIG. 2.
Protein profile of mutant PrV. Virions of wild-type PrV
(lanes 1), PrV-gC (lanes 2), PrV gD Pass
(lanes 3), and PrV gCD Pass (lanes 4) were lysed, and
proteins were separated by acrylamide gel electrophoresis. After
transfer to nitrocellulose membranes, the filters were probed with MAbs
specific for gB, gC, gD, and gH ( gB, gC, gD, and gH,
respectively). Bound antibody was visualized after incubation
with peroxidase-conjugated secondary antibody by enhanced
chemiluminescence recorded on X-ray film. The anti-gB antibody
recognizes the uncleaved precursor as well as one of the two
proteolytic cleavage products.
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Selection of an MDBK cell clone resistant to infection by PrV
gCD Pass.
MDBK-derived cell clones resistant to
infection by PrV gCD Pass were selected by a procedure
adapted from Tufaro et al. (44). Approximately 4 × 107 cells at 80% confluency in a 162-cm2
tissue culture flask were mutagenized by treatment with methylethyl sulfonic acid for 18 h. Cells were cultivated for 24 h at
37°C and split 1:4. Three days later, the resulting four tissue
culture flasks were infected with PrV gCD Pass at a
multiplicity of infection of 0.01. Cell cultures were washed three
times a day with MEM-10% FCS for the following 7 days. Thereafter,
fresh medium was added and cells were incubated at 37°C for 14 days.
Colonies of surviving cells were trypsinized and cloned by limiting
dilution in 96-well plates. Single-cell clones were grown with
conditioned medium for the next 7 to 14 days, followed by further
propagation in standard MEM. Individual cell clones were tested for
plating efficiencies of PrV-1112, PrV-gC, PrV
gD Pass, and PrV gCD Pass in comparison to
MDBK cells. Mutant cell clones showing reductions in titer were
recloned, and individual clones were judged as free from input PrV
gCD Pass when all of the following tests were negative:
(i) indirect immunofluorescence using a polyspecific anti-PrV goat
hyperimmune serum; (ii) plating of supernatants from the cell clones on
porcine kidney (PK) and MDBK cells and staining with crystal violet and X-Gal after 2 days; (iii) cocultivation of resistant cell clones with
PK and MDBK cells for 4 days and staining with crystal violet and
X-Gal; and (iv) PCR for a 377-bp fragment of the UL51 gene (18), which reliably allows the detection of a single
infected cell in 104 noninfected cells. One cell clone,
designated NB, which exhibited the strongest reduction in plating
efficiency of PrV gD Pass and PrV gCD Pass
was selected for further experiments.
NB cells are not susceptible to infection by gD
passaged virus mutants.
To test susceptibility of NB cells for
infection, wild-type-like PrV-1112, phenotypically gD-complemented
unpassaged PrV gD, PrV gD Pass, and PrV
gCD Pass were titrated on MDBK and NB cells. Results are
shown in Fig. 3A. Whereas wild-type PrV
and phenotypically gD-complemented PrV-gD produced
plaques on both cell lines with similar efficiencies, PrV
gD Pass and PrV gCD Pass induced plaque
formation only on MDBK cells but not on NB cells. Titers on MDBK cells
were ca. 107 PFU/ml for PrV gD Pass and ca.
104 PFU/ml for PrV gCD Pass. It is especially
noteworthy that even after infection of NB cells with undiluted stocks
of either virus, which corresponds to a multiplicity of infection of 10 for PrV gD Pass and 0.1 for PrV gCD Pass,
no plaques were observed. After careful visual examination only few
blue-staining single infected cells could be detected, which amounted
to ca. 200 for PrV gD Pass and <20 for PrV
gCD Pass. Phenotypic gD complementation of PrV
gD Pass and PrV gCD Pass restored
infectivity on NB cells and led to an ~10-fold increase in
infectivity on MDBK cells (Fig. 3B). However, plaque formation still
did not ensue in NB cells.
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FIG. 3.
Plating efficiency of mutant PrV on MDBK and NB cells.
Titers of wild-type-like PrV-1112, phenotypically gD-complemented PrV
gD (gD+ PrV-gD), PrV
gD Pass, and PrV gCD Pass were determined
on MDBK cells (white bars) or NB cells (black bars) by plaque assay and
X-Gal staining (A). (B) Plating efficiencies of PrV-1112, PrV
gD Pass, and PrV gCD Pass on MDBK and NB
cells after propagation on a PrV gD-expressing cell line. Average
values and standard variations (error bars) of three independent
experiments are shown. This corresponds to PFU on MDBK cells and to
infected single cells after infection of NB cells with PrV
gD Pass and PrV gCD Pass. These virus
mutants do not form plaques on NB cells irrespective of phenotypic gD
complementation.
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To determine the ability of other viruses to form plaques on NB cells,
MDBK and NB cells were infected with PrV, HSV-1, BHV-1, EHV-1, and VSV.
As shown in Fig. 4, all viruses
induced similar numbers of plaques on either cell line, and no defect
in infection of NB cells was observed. Titers for EHV-1 are low on both
cells since EHV-1 does not grow well on bovine cells. Together these data indicate that NB cells exhibit a striking restriction in infection
which is specific for the infectious gD mutants.
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FIG. 4.
Plating efficiencies of different viruses on MDBK and NB
cells. Alphaherpesviruses PrV-1112, HSV-1, BHV-1, and EHV-1 as well as
the rhabdovirus VSV were titrated on MDBK and NB cells by plaque assay.
Average titers and standard variations (error bars) of three
independent experiments are shown.
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gD infectious PrV is unable to enter NB cells.
To assay whether the restriction in infectivity of the passaged
gD-negative virus mutants on NB cells occurs at the level of entry,
MDBK and NB cells were inoculated with PrV gD Pass and
PrV gCD Pass, and membrane fusion was experimentally
induced by PEG. PEG-mediated fusion enhanced the number of infected NB
cells by ca. 200-fold and 1,000-fold, respectively (Fig.
5 and 6).
In contrast, titers on MDBK cells were not affected by PEG treatment.
Thus, at least part of the restriction appears due to a defect in entry of the gD infectious PrV mutants. However, even after
PEG-induced entry of the infectious gD virus mutants,
only single blue-staining infected NB cells were observed (Fig. 5).
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FIG. 5.
Infectivity of mutant PrV on MDBK and NB cells. MDBK and
NB cells in six-well tissue culture plates were infected with 1 ml of a
PrV-1112 stock diluted 1/106 or with 1 ml of a PrV
gD Pass stock diluted 1/106 (MDBK cells) or
1/10 (NB cells). Both stock solutions contained 107 PFU of
the respective virus per ml as determined on MDBK cells. Two days after
infection cells were stained with X-Gal. In this experiment, no plaques
or single infected cells were observed after infection of NB cells with
PrV gD Pass. After PEG-induced fusion (+ PEG) the amount
of infected single cells increased but plaque formation did not
ensue.
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FIG. 6.
PEG-induced infectivity of PrV on MDBK and NB cells.
MDBK (white bars) and NB cells (black bars) were infected with serial
dilutions of PrV-1112, PrV-gC, PrV gD Pass,
and PrV gCD Pass. After X-Gal staining, infectious titers
were determined by counting either plaques (for PrV-1112 and
PrV-gC on both cell lines and for PrV gD
Pass and PrV gCD Pass on MDBK cells) or single infected
cells (for PrV gD Pass and PrV gCD Pass on
NB cells). Relative infectivities and standard variations (error bars)
compared to control plates which were not treated with PEG are
indicated.
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NB cells do not differ from MDBK cells in glycosaminoglycan
composition.
Infection of target cells by PrV is initiated by
interaction of gC with cell-surface heparan sulfate. To examine whether
the entry defect of gD infectious PrV mutants in NB
cells is associated with a difference in glycosaminoglycans,
radiolabelled proteoglycans were extracted, protein
moieties were digested with papain, and the amount of heparan
sulfate and chondroitin sulfate was determined after digestion with
heparinase-heparitinase or chondroitinase. No significant differences
in the amount of total radiolabelled material were detected between
MDBK and NB cells (ca. 106 cpm in 105 cells).
In both cell lines, ~50% of radioactively labelled material was
sensitive to digestion with heparinase-heparitinase and ~30% was
digested with chondroitinase (21). Thus, NB cells exhibit no
gross defect in glycosaminoglycan synthesis, indicating that the
primary receptor for PrV is present in comparable amounts in both cell
lines. This is further demonstrated by a comparable inhibition of
plaque formation by exogenous heparin of gC+ PrV-1112 and
insensitivity of gC PrV toward heparin inhibition on both
cell lines (Fig. 7).
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FIG. 7.
Heparin inhibition. PrV-1112 and PrV-gC
were titrated on MDBK and NB cells in the presence (black bars) and
absence (white bars) of heparin (50 µg/ml). The addition of heparin
reduced titers of gC+ PrV-1112 on both cell lines to a
similar extent, whereas PrV-gC was not affected by the
presence of heparin on either cell line. Average values and standard
variations (error bars) of three independent experiments are shown.
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Egress of gD infectious PrV from NB cells is not
impaired.
NB cells are refractory to entry of gD
infectious PrV. After PEG-induced fusion the number of infected cells
increased but plaque formation did not ensue. To analyze whether this
phenotype reflects an additional egress defect, NB cells were infected
with PrV gD Pass and PrV gCD Pass by PEG
fusion. One parallel well was then overlaid with methylcellulose medium
and stained with X-Gal after 2 days. Cells from the other well were
trypsinized and reseeded with susceptible MDBK cells. Monolayers were
then also stained with X-Gal after 2 days. As shown in Table
1, the number of infected single cells in
the NB monolayer and the number of plaques formed in the infectious center assay correlated quite well, which indicates that virus is
released from infected NB cells and is able to enter neighboring susceptible MDBK cells.
| |
DISCUSSION |
Initiation of infection by herpesviruses requires interaction
between virion glycoproteins and cellular receptors. For
alphaherpesviruses, several virion envelope constituents have been
implicated in receptor binding. gC of HSV-1, PrV, and BHV-1 binds to
cell surface heparan sulfate, resulting in an initial interaction which
is sensitive to competition with exogenous heparin (7, 23,
29). This first binding converts into a more stable attachment
via gD (11, 22). In addition, HSV-1 virion gB has also been
shown to mediate attachment by interaction with heparan sulfate
(8). Thus, three receptor binding proteins have been
identified in HSV-1. In contrast, in PrV virion gB does not
productively interact with heparan sulfate (12), and only gC
and gD of PrV are thought to interact with cellular receptors (11,
23). The isolation of a PrV mutant which is infectious even in
the absence of gC and gD indicates that another virion component(s)
must also have or be able to acquire receptor binding activity. These
studies were possible due to the isolation of a PrV mutant, PrV
gD Pass, which by copassaging of infected with
noninfected cells, acquired the ability to replicate productively in
the absence of gD (37). This was surprising since gD had
hitherto been regarded as a glycoprotein which is required
for infectious entry of PrV (30, 32). Interestingly, PrV gD
is not necessary for direct cell-to-cell spread, a prerequisite for the
copassaging experiment (30, 32).
Deletion of gC from wild-type PrV reduced specific infectivity by
~50-fold (12). In contrast, deletion of gC from PrV
gD Pass reduced specific infectivity by ~800-fold,
demonstrating a higher degree of dependence on gC-heparan sulfate
interaction in the gD virions than in gD+
virions. This further supports our previous data indicating that in the
absence of gC, attachment of virions to target cells is mainly mediated
by gD (12). Obviously, in the absence of gD, primary
gC-dependent attachment becomes of paramount importance for the virus
to bind to its target cell. Thus, the presence of either gC or gD is
necessary for efficient initial virus-cell contact.
However, since even virions lacking both gC and gD are able to infect
target cells, though with a strikingly reduced efficiency, an
additional or alternative virion protein-cell receptor interaction has
to be postulated, if it is assumed that nonspecific binding of virions
to target cells does not occur. gB and the gH/gL complex have been
shown to be required for entry of virus into target cells and direct
viral cell-to-cell spread (1, 30-32). We hypothesize that
in the absence of gC and gD, one of these proteins might provide the
relatively inefficient attachment function in PrV gCD
Pass. Both, gB and gH of other herpesviruses, i.e., BHV-1 and HCMV,
respectively, have been postulated to bind to proteinaceous cell
surface receptors (13, 19, 46).
Recently, expression cloning has been successfully used to identify a
cell surface protein, HVEM (27), which belongs to the tumor
necrosis factor alpha receptor family and is able to mediate HSV-1
infection of CHO cells by binding to virion gD (47). A basic
requirement for this approach is the availability of cells with a
restriction of virus infection at the level of entry. Unfortunately, PrV exhibits a very wide host range in vitro. Therefore, we selected for mutant cell clones which are specifically resistant to infection by
PrV. Infection with a gC virus mutant should avoid
selection for cells exhibiting defects in proteoglycan biosynthesis, as
has been observed before (6, 26). In addition, selection
with infectious gD PrV was used to gain evidence for the
presence of novel receptors which do not interact with either gC or gD.
The NB cells described here exhibit a block in entry of PrV
gD Pass and PrV gCD Pass as indicated by
PEG fusion experiments. In contrast, these cells are fully permissive
for several other PrV glycoprotein mutants (e.g.,
PrV-gM [3] and PrV-gE
[25] [data not shown]), as well as for other
alphaherpesviruses and VSV. Thus, the defect in NB cells is specific
for entry of gD infectious PrV mutants, which
indicates that it affects a cellular component which is critical
for infectivity of these particular mutants. The NB cell phenotype also
further supports our hypothesis that gD infectious PrV
mutants use an additional, or alternative, receptor for entry
(37).
As regards relevance of our findings for the entry pathway of wild-type
PrV, there are several scenarios to consider. First, gD
infectious PrV mutants may have acquired during the passaging process a novel receptor binding activity which is not present in
wild-type PrV virions. This would be indicative of an experimentally induced alteration in use of cell surface receptors. Second,
gD infectious PrV mutants may be dependent on the use of
a receptor which is not critical for wild-type virus infection due to
the presence of other virion-cell interactive proteins. The presence of
receptors which act "downstream" from the gC and gD interactions presumably by binding to either gH/L or gB has been postulated (4). It is conceivable that in the absence of gC and gD, any other receptor-binding activity gains importance, especially when involved in mediating penetration. From our data it is evident that
gD infectious PrV mutants are defective in entry into NB
cells despite the propensity, at least for PrV gD Pass,
to efficiently bind to these cells via gC (data not shown). Thus, we
hypothesize that the defect in NB cells abolishes function of a
"fusion receptor" which is essential for penetration of
gD mutant viruses. In this context it is important to
note that both passaged virus mutants are still efficiently neutralized by antibodies against gH and gL, indicating that these two proteins are
relevant for entry of wild-type and mutant viruses (data not shown).
Infectivity of wild-type PrV and several other PrV
glycoprotein mutants is not impaired on NB cells, which
could be interpreted as if the phenotype of NB cells is irrelevant for
the entry process of these viruses. However, it is conceivable that
there is redundancy in receptor binding by wild-type PrV, as already
shown by continued attachment of virions lacking gC or gD to target
cells. Thus, the entry pathway requiring the function defective in NB
cells may be bypassed by wild-type PrV but not by gD
infectious PrV mutants. Phenotypic complementation of passaged gD-negative PrV mutants by propagation on gD-expressing cells quantitatively restored infectivity of these mutants on NB cells, showing that in the presence of gD, these virus mutants enter cells via
the normal pathway. However, as expected, phenotypically gD-complemented gD-negative passaged virus mutants were still not able
to form plaques in NB cells.
Especially striking is the prominent phenotype of NB cells as
regards susceptibility to infection compared to parental MDBK cells. Infectivity of PrV gD Pass on NB cells is reduced
ca. 105-fold, which effectively means that these cells are
not permissive for PrV gD Pass infection. A similarly
striking reduction was observed for PrV gCD Pass. Thus,
NB cells represent a cell clone with a specific entry defect for PrV at
a magnitude which, presumably, allows expression screening for
receptors as used by Montgomery et al. (27). It is important
to note that infectivity of other alphaherpesviruses as well as the
nonrelated rhabdovirus VSV is not inhibited in NB cells, further
providing specificity of the phenotypic alteration.
Our data also indicate that egress from NB cells of gD
infectious PrV mutants occurs as shown by infectious-center assay. However, plaque formation in NB cells does not ensue even after PEG-induced infection. Thus, it appears as if the defect in plaque formation is correlated with the defect in entry and does not reflect a
simultaneous impairment of egress. This highlights the relationship
between entry and direct cell-to-cell spread and yields evidence that
similar cellular functions are involved in both processes.
Interestingly, after infection with gD-complemented PrV-gD, plaques did form on NB cells; i.e., cell-to-cell
spread on NB cells can occur in the absence of gD. Presumably, the
mutation(s) leading to gD-independent infectivity of PrV
gD Pass at the same time abolished a function which
is necessary for gD-independent cell-to-cell spread in NB cells.
Whether these two phenotypes are consequences of the same mutational
event remains to be determined.
Deletion of both known attachment proteins of PrV, gC and gD,
drastically reduces infectivity of PrV, although it does not completely
abolish it. Most importantly, PrV gCD Pass can be
propagated on normal cells without the danger of inadvertent rescue of
either mutation. The isolation of PrV gCD Pass now allows
new approaches to specifically alter the host range of PrV.
Incorporation of heterologous attachment proteins into PrV
gCD Pass virions could favor attachment to alternative
target cells, which is especially intriguing in light of the use of
herpesviruses for gene therapy. Experiments to analyze the potential of
our gCD infectious PrV mutant in this context are under
way.
| |
ACKNOWLEDGMENTS |
This study was supported by a grant from the Deutsche
Forschungsgemeinschaft (Me 854/4-1).
We thank B. Bettin for expert technical assistance.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institute of
Molecular and Cellular Virology, Friedrich-Loeffler-Institutes, Federal Research Centre for Virus Diseases of Animals, D-17498 Insel Riems, Germany. Phone: 49-38351-7102. Fax: 49-38351-7151. E-mail:
Thomas.C.Mettenleiter{at}rie.bfav.de.
| |
REFERENCES |
| 1.
|
Babic, N.,
B. G. Klupp,
B. Makoschey,
A. Karger, and A. Flamand.
1996.
Glycoprotein gH of pseudorabies virus is essential for penetration and propagation in cell culture and in the nervous system of mice.
J. Gen. Virol.
77:2277-2285[Abstract/Free Full Text].
|
| 2.
|
Compton, T.,
D. L. Nowlin, and N. R. Cooper.
1993.
Initiation of human cytomegalovirus infection requires initial interaction with cell surface heparan sulfate.
Virology
193:834-841[Medline].
|
| 3.
|
Dijkstra, J.,
V. Gerdts,
B. G. Klupp, and T. C. Mettenleiter.
1997.
Deletion of glycoprotein gM of pseudorabies virus results in attenuation for the natural host.
J. Gen. Virol.
78:2147-2151[Abstract].
|
| 4.
|
Fuller, A. O., and W.-C. Lee.
1992.
Herpes simplex virus type 1 entry through a cascade of virus-cell interactions requires different roles of gD and gH in penetration.
J. Virol.
66:5002-5012[Abstract/Free Full Text].
|
| 5.
|
Gressner, A. M.,
H. Pazen, and H. Greiling.
1977.
The biosynthesis of glycosaminoglycans in normal rat liver and in response to experimental hepatic injury.
Hoppe-Seyler's Z. Physiol. Chem.
358:825-833[Medline].
|
| 6.
|
Gruenheid, S.,
L. Gatzke,
H. Meadows, and F. Tufaro.
1993.
Herpes simplex virus infection and propagation in a mouse L cell mutant lacking heparan sulfate proteoglycans.
J. Virol.
67:93-100[Abstract/Free Full Text].
|
| 7.
|
Herold, B. C.,
D. WuDunn,
N. Soltys, and P. G. Spear.
1991.
Glycoprotein C of herpes simplex virus type 1 plays a principal role in the adsorption of virus to cells and in infectivity.
J. Virol.
65:1090-1098[Abstract/Free Full Text].
|
| 8.
|
Herold, B. C.,
R. J. Visalli,
N. Susmarski,
C. Brandt, and P. G. Spear.
1994.
Glycoprotein C-independent binding of herpes simplex virus to cells requires cell surface heparan sulphate and glycoprotein B.
J. Gen. Virol.
75:1211-1222[Abstract/Free Full Text].
|
| 9.
|
Johnson, D. C.,
R. L. Burke, and T. Gregory.
1990.
Soluble forms of herpes simplex virus glycoprotein D bind to a limited number of cell surface receptors and inhibit virus entry into cells.
J. Virol.
64:2569-2576[Abstract/Free Full Text].
|
| 10.
|
Kaplan, A. S., and A. Vatter.
1959.
A comparison of herpes simplex and pseudorabies viruses.
Virology
13:78-92.
|
| 11.
|
Karger, A., and T. C. Mettenleiter.
1993.
Glycoproteins gIII and gp50 play dominant roles in the biphasic attachment of pseudorabies virus.
Virology
194:654-664[Medline].
|
| 12.
|
Karger, A.,
A. Saalmüller,
F. Tufaro,
B. W. Banfield, and T. C. Mettenleiter.
1995.
Cell surface proteoglycans are not essential for infection by pseudorabies virus.
J. Virol.
69:3482-3489[Abstract].
|
| 13.
|
Keay, S.,
T. C. Merigan, and L. Rasmussen.
1989.
Identification of cell surface receptors for the 86-kilodalton glycoprotein of human cytomegalovirus.
Proc. Natl. Acad. Sci. USA
86:10100-10103[Abstract/Free Full Text].
|
| 14.
|
Klupp, B. G.,
A. Karger, and T. C. Mettenleiter.
1997.
Bovine herpesvirus 1 glycoprotein B does not productively interact with cell surface heparan sulfate in a pseudorabies virion background.
J. Virol.
71:4838-4841[Abstract].
|
| 15.
|
Klupp, B. G.,
W. Fuchs,
E. Weiland, and T. C. Mettenleiter.
1997.
Pseudorabies virus glycoprotein L is necessary for virus infectivity but dispensable for virion localization of glycoprotein H.
J. Virol.
71:7687-7695[Abstract].
|
| 16.
|
Kopp, A., and T. C. Mettenleiter.
1992.
Stable rescue of a glycoprotein gII deletion mutant of pseudorabies virus by glycoprotein gI of bovine herpesvirus 1.
J. Virol.
66:2754-2762[Abstract/Free Full Text].
|
| 17.
|
Laemmli, U. K.
1970.
Cleavage of structural proteins during the assembly of the head of bacteriophage T4.
Nature (London)
227:680-685[Medline].
|
| 18.
|
Lenk, M.,
N. Visser, and T. C. Mettenleiter.
1997.
The pseudorabies virus UL51 gene product is a 30-kilodalton virion component.
J. Virol.
71:5635-5638[Abstract].
|
| 19.
|
Li, Y.,
S. van Drunen Littel-van den Hurk,
L. A. Babiuk, and X. Liang.
1995.
Characterization of cell-binding properties of bovine herpesvirus 1 glycoproteins B, C, and D: identification of a dual cell-binding function of gB.
J. Virol.
69:4758-4768[Abstract].
|
| 20.
|
Liang, X.,
L. A. Babiuk, and T. Zamb.
1993.
Mapping of heparin-binding structures on bovine herpesvirus 1 and pseudorabies virus gIII glycoproteins.
Virology
194:233-243[Medline].
|
| 21.
|
Linker, A., and P. Hovingh.
1972.
Heparinase and heparitinase from flavobacteria.
Methods Enzymol.
28:902-911.
|
| 22.
|
McClain, D. S., and A. O. Fuller.
1994.
Cell-specific kinetics and efficiency of herpes simplex virus type 1 entry are determined by two distinct phases of attachment.
Virology
198:690-702[Medline].
|
| 23.
|
Mettenleiter, T. C.,
L. Zsak,
F. Zuckermann,
N. Sugg,
H. Kern, and T. Ben-Porat.
1990.
Interaction of glycoprotein gIII with a cellular heparinlike substance mediates adsorption of pseudorabies virus.
J. Virol.
64:278-286[Abstract/Free Full Text].
|
| 24.
|
Mettenleiter, T. C.
1994.
Initiation and spread of -herpesvirus infections.
Trends Microbiol.
2:2-4[Medline].
|
| 25.
|
Mettenleiter, T. C., and I. Rauh.
1990.
A glycoprotein gX--galactosidase fusion gene as insertional marker for rapid identification of pseudorabies virus mutants.
J. Virol. Methods
30:55-66[Medline].
|
| 26.
| Mettenleiter, T. C., B. G. Klupp, and A. Karger. Unpublished results.
|
| 27.
|
Montgomery, R. I.,
M. S. Warner,
B. J. Lum, and P. G. Spear.
1996.
Herpes simplex virus-1 entry into cells mediated by a novel member of the TNF/NGF receptor family.
Cell
87:427-436[Medline].
|
| 28.
|
Nemerow, G.,
R. Wolfert,
M. McNaughton, and N. R. Cooper.
1985.
Identification and characterization of the Epstein-Barr virus receptor on human B lymphocytes and its relationship to the C3d complement receptor (CR2).
J. Virol.
55:347-351[Abstract/Free Full Text].
|
| 29.
|
Okazaki, K.,
T. Matsuzaki,
Y. Sugahara,
J. Okadad,
M. Hasebe,
Y. Iwamura,
M. Ohnishi,
T. Kanno,
M. Shimizu,
E. Honda, and Y. Kono.
1991.
BHV-1 adsorption is mediated by the interaction of glycoprotein gIII with heparin-like moiety on the cell surface.
Virology
181:666-670[Medline].
|
| 30.
|
Peeters, B.,
N. de Wind,
M. Hooisma,
F. Wagenaar,
A. Gielkens, and R. Moormann.
1992.
Pseudorabies virus envelope glycoproteins gp50 and gII are essential for virus penetration, but only gII is involved in membrane fusion.
J. Virol.
66:894-905[Abstract/Free Full Text].
|
| 31.
|
Peeters, B.,
N. deWind,
R. Broer,
A. Gielkens, and R. Moormann.
1992.
Glycoprotein H of pseudorabies virus is essential for entry and cell-to-cell spread of the virus.
J. Virol.
66:3888-3892[Abstract/Free Full Text].
|
| 32.
|
Rauh, I., and T. C. Mettenleiter.
1991.
Pseudorabies virus glycoproteins gII and gp50 are essential for virus penetration.
J. Virol.
65:5348-5356[Abstract/Free Full Text].
|
| 33.
|
Sambrook, J.,
E. F. Fritsch, and T. Maniatis.
1989.
Molecular cloning: a laboratory manual, 2nd ed.
Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
|
| 34.
|
Sanes, J. R.,
J. L. R. Rubenstein, and J. F. Nicolas.
1986.
Use of a recombinant retrovirus to study post-implantation cell lineage in mouse embryos.
EMBO J.
5:3313-3142[Medline].
|
| 35.
|
Sarmiento, M.,
M. Haffey, and P. G. Spear.
1979.
Membrane proteins specified by herpes simplex viruses. III. Role of glycoprotein VP7 in virion infectivity.
J. Virol.
29:1149-1158[Abstract/Free Full Text].
|
| 36.
|
Sawitzky, D.,
H. Hampl, and K.-O. Habermehl.
1990.
Comparison of heparin-sensitive attachment of pseudorabies virus (PRV) and herpes simplex virus type 1 and identification of heparin-binding PRV glycoproteins.
J. Gen. Virol.
71:1221-1225[Abstract/Free Full Text].
|
| 37.
|
Schmidt, J.,
B. G. Klupp,
A. Karger, and T. C. Mettenleiter.
1997.
Adaptability in herpesviruses: glycoprotein D-independent infectivity of pseudorabies virus.
J. Virol.
71:17-24[Abstract].
|
| 38.
|
Schreurs, C.,
T. C. Mettenleiter,
F. Zuckermann,
N. Sugg, and T. Ben-Porat.
1988.
Glycoprotein gIII of pseudorabies virus is multifunctional.
J. Virol.
62:2251-2257[Abstract/Free Full Text].
|
| 39.
|
Schröder, C.,
G. Linde,
F. Fehler, and G. M. Keil.
1997.
From essential to beneficial: glycoprotein D loses importance for replication of bovine herpesvirus 1 in cell culture.
J. Virol.
71:25-33[Abstract].
|
| 40.
|
Secchiero, P.,
D. Sun,
A. L. de Vico,
R. W. Crowley,
M. S. Reitz,
G. Hauli,
P. Lusso, and R. C. Gallo.
1997.
Role of the extracellular domain of human herpesvirus 7 glycoprotein B in virus binding to cell surface heparan sulfate proteoglycans.
J. Virol.
71:4571-4580[Abstract].
|
| 41.
|
Shieh, M.-T.,
D. WuDunn,
R. I. Montgomery,
J. D. Esko, and P. G. Spear.
1992.
Cell surface receptors for herpes simplex virus are heparan sulfate proteoglycans.
J. Cell Biol.
116:1273-1281[Abstract/Free Full Text].
|
| 42.
|
Spear, P. G.
1993.
Entry of alphaherpesviruses into cells.
Semin. Virol.
4:167-180.
|
| 43.
|
Towbin, H.,
T. Staehelin, and J. Gordon.
1979.
Electrophoretic transfer of proteins from polyacrylamide gels to nitrocellulose sheets: procedure and some applications.
Proc. Natl. Acad. Sci. USA
76:4350-4354[Abstract/Free Full Text].
|
| 44.
|
Tufaro, F.,
M. D. Snider, and S. L. McKnight.
1987.
Identification and characterization of a mouse cell mutant defective in the intracellular transport of glycoproteins.
J. Cell Biol.
105:647-657[Abstract/Free Full Text].
|
| 45.
|
Vanderplasschen, A.,
M. Bublot,
J. Dubuisson,
P.-P. Pastoret, and E. Thiry.
1993.
Attachment of the gammaherpesvirus bovine herpesvirus 4 is mediated by the interaction of gp8 glycoprotein with heparinlike moieties on the cell surface.
Virology
196:232-240[Medline].
|
| 46.
|
Varthakavi, V., and H. C. Minocha.
1996.
Identification of a 56kDa putative bovine herpesvirus 1 cellular receptor by anti-idiotype antibodies.
J. Gen. Virol.
77:1875-1882[Abstract/Free Full Text].
|
| 47.
|
Whitbeck, J. C.,
C. Peng,
H. Lou,
R. Xu,
S. H. Willis,
M. Ponce de Leon,
T. Peng,
A. V. Nicola,
R. I. Montgomery,
M. S. Warner,
A. M. Soulika,
L. A. Spruce,
W. T. Moore,
J. D. Lambris,
P. G. Spear,
G. H. Cohen, and R. J. Eisenberg.
1997.
Glycoprotein D of herpes simplex virus (HSV) binds directly to HVEM, a member of the tumor necrosis factor receptor superfamily and a mediator of HSV entry.
J. Virol.
71:6083-6093[Abstract].
|
| 48.
|
WuDunn, D., and P. G. Spear.
1989.
Initial interaction of herpes simplex virus with cells is binding to heparan sulfate.
J. Virol.
63:52-58[Abstract/Free Full Text].
|
| 49.
|
Yamagata, T.,
H. Saito,
O. Habuchi, and S. Suzuki.
1968.
Purification and properties of bacterial chondroitinases and chondrosulfatases.
J. Biol. Chem.
243:1523-1535[Abstract/Free Full Text].
|
| 50.
|
Zhu, Z.,
M. D. Gershon,
R. Ambron,
C. Gable, and A. A. Gershon.
1995.
Infection of cells by varicella zoster virus: inhibition of viral entry by mannose-6-phosphate and heparin.
Proc. Natl. Acad. Sci. USA
92:3546-3550[Abstract/Free Full Text].
|
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Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
