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J Virol, February 1998, p. 1577-1585, Vol. 72, No. 2
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
A27L Protein Mediates Vaccinia Virus Interaction
with Cell Surface Heparan Sulfate
Che-Sheng
Chung,1
Jye-Chian
Hsiao,1,2
Yuan-Shau
Chang,1,2 and
Wen
Chang1,*
Institute of Molecular Biology, Academia
Sinica, Nankang,1 and
Institute of Cell
and Molecular Biology, Taipei Medical
College,2 Taipei, Taiwan, Republic of China
Received 5 September 1997/Accepted 30 October 1997
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ABSTRACT |
Vaccinia virus has a wide host range and infects mammalian cells of
many different species. This suggests that the cell surface receptors
for vaccinia virus are ubiquitously expressed and highly conserved.
Alternatively, different receptors are used for vaccinia virus
infection of different cell types. Here we report that vaccinia virus
binds to heparan sulfate, a glycosaminoglycan (GAG) side chain of cell
surface proteoglycans, during virus infection. Soluble heparin
specifically inhibits vaccinia virus binding to cells, whereas other
GAGs such as condroitin sulfate or dermantan sulfate have no effect.
Heparin also blocks infections by cowpox virus, rabbitpox virus, myxoma
virus, and Shope fibroma virus, suggesting that cell surface heparan
sulfate could be a general mediator of the entry of poxviruses. The
biochemical nature of the heparin-blocking effect was investigated.
Heparin analogs that have acetyl groups instead of sulfate groups also
abolish the inhibitory effect, suggesting that the negative charges on
GAGs are important for virus infection. Furthermore, BSC40 cells
treated with sodium chlorate to produce undersulfated GAGs are more
refractory to vaccinia virus infection. Taken together, the data
support the notion that cell surface heparan sulfate is important for
vaccinia virus infection. Using heparin-Sepharose beads, we showed that vaccinia virus virions bind to heparin in vitro. In addition, we
demonstrated that the recombinant A27L gene product binds to the
heparin beads in vitro. This recombinant protein was further shown to
bind to cells, and such interaction could be specifically inhibited by
soluble heparin. All the data together indicated that A27L protein
could be an attachment protein that mediates vaccinia virus binding to
cell surface heparan sulfate during viral infection.
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INTRODUCTION |
Cell entry is the first step in the
invasion of host cells by pathogens. Viruses have evolved strategies to
recognize and discriminate their target host cells by binding to cell
surface proteins, which may vary among tissue types. Identifying the
receptors is essential for us to understand the biology of the virus.
Receptor-mediated viral binding is shared by many viruses; however, the
nature of the binding among different viruses appears diverse (16,
50). Some viruses require a single component for entry. For
example, influenza virus binds to the terminal carbohydrate side chain sialic acids on cells, leading to endocytosis of virions
(50). Poliovirus binds to an immunoglobulin-like protein,
PVR, on the cell surface, resulting in rapid uncoating of virus
particles inside cells (11, 22, 29, 35-37). Other viruses
such as human immunodeficiency virus and herpesvirus require
coreceptors to complete the cell entry process. HIV binds to CD4 on T
cells, and subsequent interaction with a member of the chemokine
receptor family, CCR-5 or CXCR-4, leads to membrane fusion (7, 10, 27, 40). Herpes simplex virus binds to cell surface
glycosaminoglycan (GAGs) side chains (mainly heparan sulfate) of
proteoglycans, and penetration requires a tumor necrosis factor
receptor-like molecule, HVEM, to facilitate membrane fusion (2,
15, 31, 43, 45-47, 51).
Vaccinia virus belongs to the poxvirus family and infects many cells of
different origins. Vaccinia virus produces two forms of infectious
particles: intracellular mature virus (IMV) and extracellular enveloped
virus (EEV). The membrane of IMV was thought to be derived from the
intermediate compartment, whereas the EEV form of virions was derived
from the trans-Golgi network (9, 44). Different
structures of these particles suggested that they may infect cells by
different routes; however, until now, no receptor for poxvirus has been
demonstrated. We have previously isolated monoclonal antibody (MAb) B2,
which recognizes a putative receptor on cells and blocks IMV virions of
vaccinia virus binding to cells (4). B2 does not block EEV
infection, indicating that different cellular receptors exist for IMV
and EEV entry (48). B2 blocked vaccinia virus infection in
all the susceptible cells we tested, but its efficiency varies among
different cell lines and such partial inhibition suggested to us that
other mediators for vaccinia virus may also exist.
GAGs are complex structures present on a variety of cells, with
different carbohydrate moieties linked to core proteins through serine
residues (17). Most cell types express GAGs such as
condroitin sulfate, dermantan sulfate, or heparan sulfate to different
extents. The chemical structures of GAGs have been well characterized
with repeating disaccharides of a hexuronic acid and an
N-acetylhexosamine sulfate modified with carboxylate and
sulfate monoester groups (26). Due to these modifications on
sugar side chains, cell surface GAGs are highly negatively charged. The
biological roles of GAGs are quite diverse, ranging from cell
attachment and migration, compressive resilience of cartilage, and
control of fibrinogenesis to cell signaling (41). GAGs are
also shown to be mediators of virus infections. Herpesviruses and the
type O foot-and-mouth disease virus bind to cell surface heparan
sulfate during infection (20, 43, 45, 46).
In this study, we explored the role of GAGs, particularly cell surface
heparan sulfate and its related homolog heparin, in vaccinia virus
infection. Our results suggested that vaccinia virus binds to heparan
sulfate on cells. Not only vaccinia virus but also other poxviruses
such as cowpox virus, rabbitpox virus, Shope fibroma virus and myxoma
virus also bind to heparan sulfate as well. Furthermore, sulfate groups
on GAGs contributed to the negative charges which are required for
vaccinia virus infection.
We also investigated candidate virion membrane proteins on IMV that
could mediate virus interaction with heparan sulfate. Our data
suggested that A27L protein binds to cell surface heparan sulfate.
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MATERIALS AND METHODS |
Reagents and viruses.
Soluble heparin, chondroitin sulfate,
and dermatan sulfate were purchased from Sigma Inc. A chemically
modified heparin kit, containing completely desulfated N-acetylated
heparin (CDSNAc-heparin, Na salt), completely desulfated N-sulfated
heparin (CDSNS-heparin, Na salt), and N-desulfated N-acetylated heparin
(NDSNAc-heparin, Na salt), was purchased from Seikagaku Corp.
Heparin-Sepharose CL-6B beads and control CL-6B beads were purchased
from Pharmacia. Wild-type vaccinia viruses (WR) were prepared as IMV
stocks in BSC40 cells. A recombinant virus, vMJ360, expressing a
lacZ gene from an early promoter was obtained from B. Moss
(6).
Virus purification.
Vaccinia virus was purified as described
previously (21). Briefly, BSC40 cells were infected with
vaccinia virus at a multiplicity of infection (MOI) of 0.05 and the
infection was allowed to proceed until a complete cytopathic effect was
observed. The cells were scraped off the plates with a rubber policeman
and centrifuged at 1,500 × g for 10 min. The cell pellets
were resuspended in cold buffer containing 10 mM Tris (pH 7.5) and 5mM
MgCl2 and homogenized with 20 strokes in a Dounce
homogenizer. The large debris and nuclei were sedimented by
centrifugation at 2,000 rpm for 10 min. The supernatant was sonicated
and loaded on top of 36% sucrose, and the viruses were pelleted by
centrifugation at 18,000 rpm for 80 min. The pelleted viruses were
resuspended, sonicated and laid on top of a 25 to 40% sucrose gradient
for centrifugation at 13,500 rpm for 40 min in a Beckman SW28 rotor.
The band composed mainly of IMV was harvested and saved at 
70°C as
stocks. The stocks contained little contamination by extracellular
enveloped viruses since plaque formation of these purified virions was
readily neutralized (greater than 95%) by antibodies recognizing
IMV-specific proteins.
Inhibition of soluble GAGs on vaccinia virus infection.
Heparin and other soluble GAGs were incubated with vaccinia virus at
4°C for 30 min, and the mixture was added to BSC40 cells at 37°C
for 30 min. The inoculum was removed, the cells were washed and
overlaid with agar, and plaque numbers were determined 3 days later.
The numbers of plaques obtained in the absence of GAGs were used as
100%. For lacZ gene expression, BSC40 cells were infected
at a MOI of 5 PFU per cell with vMJ360 (6). At 3 h postinfection (p.i.), the cells were fixed in 0.5% paraformaldehyde and analyzed for 
-galactosidase (-gal) activity by
5-bromo-4-chloro-3-indolyl--D-galactopyranoside (X-Gal)
staining.
To investigate the inhibition of GAGs on virus binding, BSC40 cells
were infected with vaccinia virus at a MOI of 10 PFU per cell with or
without GAGs (50 µg/ml) at 4°C for 30 min. The cells were washed
thoroughly with cold phosphate-buffered saline (PBS), lysed with sodium
dodecyl sulfate (SDS)-containing sample buffer, and loaded on an
SDS-polyacrylamide gel electrophoresis (PAGE) gel (10% polyacrylamide)
for Western blot analysis with a serum against vaccinia virus virions
as described previously (4).
Inhibition of sulfation of GAGs by sodium chlorate.
All
chlorate experiments were done as described previously with minor
modifications (47). In brief, BSC40 cells were seeded in
sulfate-free Joklik modified minimal essential medium (Gibco-Bethesda Research Laboratories) supplemented with 1.8 mM CaCl2, 10 mM sodium chlorate, and 8% fetal bovine serum previously dialyzed
against PBS. In control experiments 0.8 mM sodium sulfate was also
added to the above chlorate-containing medium (sulfate-reconstituted medium) to reverse the in vivo sulfation block in cells. After 2 days,
the cells were infected with a recombinant vMJ360 at a MOI of 5 PFU per
cell and fixed at 3 h p.i. for -gal activity determination with
X-Gal. Alternatively, chlorate-treated cells were infected with
vaccinia virus at 4°C for 30 min, washed in PBS, and lysed in
SDS-containing sample buffer for Western blot analysis.
Heparin binding assays.
Heparin-Sepharose CL-6B beads or
control Sepharose beads were swollen in PBS-0.5% Nonidet P-40-0.5%
sodium deoxycholate at 4°C overnight and washed in PBS as described
previously (19). The washed beads were blocked for 1 h
at 4°C with PBS containing 1% bovine serum albumin, and vaccinia
virions (4,000 PFU) were added. The mixture was incubated at 4°C for
1 h, and the unbound virions were collected from the supernatant
after a brief centrifugation. The virus titers in the supernatant were
determined by plaque assays in BSC40 cells.
For determination of protein binding to heparin beads, 10 µg of
purified recombinant A27L or A4L proteins was incubated in PBS-Nonidet
P-40-sodium deoxycholate buffer with 200 µl of heparin beads (50%
vol/vol) at 4°C for 1 h and the supernatant was collected after
a brief centrifugation as described previously (19). The pellets were then washed with the same buffer three times. Both the
supernatant and the pellet were resuspended in protein sample buffer
containing 5% 2-mercaptoethanol, and the same proportion of each
(1/15) was loaded onto a SDS-PAGE gel (15% polyacrylamide) and
transferred for Western blot analysis with a MAb against T7 tag
sequences (1:5,000) (Novagen), as suggested by the manufacturer.
Protein expression and purification.
For expression of the
soluble recombinant A27L protein truncated before the transmembrane
region, two primers were made for PCR amplification. The 5' primer
(5'-AAAGGATCCTCTACAAAGGCTGCTAAA) and the 3' primer
(5'-AAAAAGCTTATTTTCCAACCTAAATAG) were used with viral DNA
template in a PCR amplification with a program of 94°C for 1 min,
42°C for 1.5 min, and 72°C for 1.5 min for 25 cycles. The amplified
DNA fragment contained sequences corresponding to A27L amino acids 21 to 84. The DNA fragment was digested with BamHI and
HindIII and cloned into pET21a (Novagen). The resulting plasmid expressed the A27L ectodomain with a T7 tag peptide at the N
terminus for easy identification and hexahistidine sequences at the C
terminus for purification with a nickel column.
For A4L, the 5' primer (5'-TATGAATTCATGGACTTCTTTAACAAG) and
the 3' primer (5'-TATAAGCTTCTTTTGGAATCGTTCAAA) were used
with
vaccinia virus DNA template, and the amplified DNA fragment
contained
sequences encoding the entire amino acids (1 to 841) of the
A4L
open reading frame. The DNA fragment was digested with
EcoRI and
HindIII and cloned into pET21a
(Novagen).
For protein expression, the bacterial cultures were transformed with
individual plasmids as described above and the cultures
were induced
with 0.2 mM isopropyl-
-
D-thiogalactopyranoside (IPTG)
for 1 h at 37°C and harvested. The bacterial pellets were
sonicated,
and the supernatant recovered after centrifugation was
loaded
onto a nickel column as suggested in the pET system manual
(Novagen).
The column was washed, and the bound protein was eluted with
0.3M
imidazole and dialyzed against PBS at 4°C overnight before use.
Biotinylation of A27L protein and cell binding assays.
Biotinylation of A27L protein was performed with an ECL biotinylation
system purchased from Amersham Life Science, Inc. In brief, 2 mg of
purified A27L protein was mixed with 40 µl of the biotinylation
reagent N-hydroxysuccinamide ester in 40 mM bicarbonate buffer (pH 8.6) at room temperature for 1 h as suggested by the manufacturer. The biotinylated mixture was then loaded on a 9-ml Sephadex G-25 column previously equilibrated with PBS. Biotinylated A27L protein was collected in fractions 4 to 6, and the extent of
biotinylation was confirmed by spectrophotometry and by Western blot
analysis with horseradish peroxidase-conjugated streptavidin.
For cell binding assays, BSC40 cells (2 × 10
4 per
well) were incubated with biotinylated A27L protein (0.2 µg/µl)
alone or
with GAGs (50 µg/ml) in a volume of 50 µl in a 96-well
plate at
4°C for 30 min. The cells were subsequently washed with cold
PBS,
and phycoerythrin-conjugated streptavidin (1:100) was added for
another 30 min at 4°C. The cells were washed three more times
with
cold PBS, and images were photographed under a Nikon fluorescence
microscope with a Nikon G-2A filter (wavelength, 510 to 560 nm)
connected to a Kodak photoMicroGraphy Digitize-Integrate system
(MGDS
system). All images were analyzed by the FreePlus Editing
program or
Adobe Photoshop.
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RESULTS |
Vaccinia virus binds to cell surface heparan sulfate during viral
infection.
The three most abundant GAGs on plasma membrane
proteoglycans of mammalian cells are heparan sulfate, chondroitin
sulfate, and dermantan sulfate (24). Heparin, on the other
hand, is found only in secretary granules of mast cells
(26). Technically, soluble heparin is often used as an
effective competitor for heparan sulfate on cells. To investigate the
effects of cell surface GAGs on vaccinia virus binding, we incubated
various soluble GAGs with viruses during infection and determined the
inhibitory effects of each GAG in vaccinia virus plaque formation (Fig.
1A). At 1 µg/ml, heparin blocks 35% of
the vaccinia virus plaque formation. Heparin blocked vaccinia virus
better at higher concentrations (2 to 5 µg/ml) and reached a maximum
of 60% inhibition at 5 to 10 µg/ml. Other GAGs such as condroitin
sulfate and dermatan sulfate did not show any significant inhibition.
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FIG. 1.
(A) Soluble heparin blocks vaccinia virus infection of
cells. BSC40 cells were infected with vaccinia virus in the presence of
different GAGs (heparin [HP], chondroitin sulfate [CS], and
dermatan sulfate [DS]) at various concentrations (0, 1, 2, 5, and 10 µg/ml) for 60 min at 37°C. The cells were then washed with PBS and
overlaid with agar for plaque assays. The numbers of plaques obtained
from infection without GAGs, within the range of 100 to 150 plaques,
were used as 100%. The data were obtained from an average of four
plates. (B). Heparin blocks vaccinia virus binding to cells. BSC40
cells were infected with vaccinia virus at a MOI of 10 PFU per cell in
the presence of different GAGs (50 µg/ml), as shown above the lanes,
at 4°C for 30 min, washed with PBS, and lysed in gel sample buffer
containing 5% 2-mercaptoethanol. The samples were separated by
SDS-PAGE (10% polyacrylamide) and transferred for Western blot
analysis with an antiserum (1:100) previously raised against purified
virions. The arrow indicates the position of a viral 35-kDa protein
encoded by the D8L gene. (C). Heparin analogs fail to block vaccinia
virus infection. BSC40 cells were infected with vaccinia virus in the
presence of heparin or its analogs CDSNAc-heparin, CDSNS-heparin, or
NDSNAc-heparin as described in Materials and Methods. The cells were
washed with PBS and overlaid with agar, and plaque numbers were
determined after 3 days. The number of plaques obtained from infection
without GAGs was used as 100%.
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We then determined the mechanism of heparin inhibition of vaccinia
virus infection. BSC40 cells were infected with vaccinia
virus at 4°C
for 30 min, and cell-associated virions were determined
by Western blot
analysis (Fig.
1B). With a serum against purified
virions, several
viral proteins were specifically detected in
virus-infected cells. The
intensity of these bands was greatly
reduced when heparin was incubated
with cells during infection.
Again, condroitin sulfate and dermatan
sulfate had little effect
on virus binding to cells. The data indicated
that heparin specifically
blocked vaccinia virus binding to mammalian
cells during infection.
Negative charges contributed by sulfation of heparan sulfate on
cells are required for vaccinia virus infection.
Heparan sulfate
and heparin contain a number of N-sulfate groups in place of
N-acetyl groups and contain L-iduronic acid in place of some glucuronic acid residues with some of the former sulfated
in the 2 position. Generally heparin has a higher proportion of
N-sulfate and L-iduronic acid than does heparan
sulfate (26). To address the chemical structure responsible
for heparin competition, we obtained different heparin analogs that
contain reduced sulfate contents by chemical modifications.
NDSNAc-heparin and CDSNS-heparin contains less sulfate (4.5 to 8% sulfate), and CDSNAc-heparin is completely desulfated (less than
1.5% sulfate). Removing any sulfate from heparin dramatically reduces
its inhibitory effect on vaccinia virus infection (Fig. 1C). This
therefore suggested that the charge density contributed by sulfate is
important for virus interaction with cell surface heparan sulfate. This
result is similar to what has been reported for herpes simplex virus and pseudorabies virus (18).
We then sought to deplete sulfate from cell surface GAGs with sodium
chlorate to determine if sulfate moieties are indeed
required for
vaccinia virus infection. BSC40 cells plated in sulfate-free
medium
continued to grow with a normal morphology indistinguishable
from the
controlled cells in sulfate-reconstituted medium (Fig.
2A and D). This is expected since,
without exogenous sulfate source,
metabolism of methionine and cysteine
could still be used as the
endogenous source of sulfation in vivo
(
32). In addition, these
cells grown in sulfate-free medium
could be infected by vaccinia
virus to similar extents to the
controlled cells when
lacZ expression
from a viral early
promoter was monitored (Fig.
2B and E). The
addition of 10 mM sodium
chlorate sulfate-free medium blocked
the activities of cellular
ATP-sulfurylase and sulfate adenyltransferase
and reduced sulfate
incorporation into GAGs by up to 96% (
1,
14,
23). At the
same time, chlorate treatment significantly
inhibited virus infection
(Fig.
2C). It therefore provided direct
evidence that sulfation of cell
surface GAGs is required for vaccinia
virus infection. We could still
detect 5 to 10% blue cells, suggesting
either that chlorate blockage
is leaky or that vaccinia virus
could use alternative means of cell
entry in the absence of sulfation.
Nevertheless, desulfation of GAGs by
chlorate treatment had a
profound effect on vaccinia virus infection.
Such chlorate inhibition
could be reversed by the addition of exogenous
sodium sulfate
to chlorate-containing medium (
47).
Consistently, reconstitution
of the normal sulfation state in vivo also
rendered cells susceptible
to virus infection again (Fig.
2F). These
data, taken together,
demonstrated that the sulfate moieties on heparan
sulfate are
involved in vaccinia virus entry.
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FIG. 2.
Undersulfation of GAGs by chlorate treatment blocks
vaccinia virus binding. BSC40 cells were seeded in sulfate-free medium
(A to C) or sulfate-reconstituted medium (D to F). In addition, 10 mM
sodium chlorate was added to BSC cells in panels C and F to block
sulfation in vivo. After 2 days, BSC cells were infected with vMJ360 at
a MOI of 5 PFU per cell and fixed at 3 h p.i. for -gal activity
with X-Gal. (G) BSC40 cells were prepared as described above, infected
with vaccinia virus at 4°C for 30 min, washed, and lysed immediately
for Western blot analysis with an antiserum against a viral D8L
protein, as marked by an arrow.
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To demonstrate the mechanism of chlorate treatment on virus entry, we
pretreated cells with chlorate and infected them with
vaccinia virus at
4°C for 30 min. These cells were washed and
lysed for Western blot
analysis with an antiserum against a viral
D8L protein. As shown in
Fig.
2G, the amount of cell-associated
viruses was greatly reduced when
chlorate was added to sulfate-free
medium. When exogenous sulfate was
added, virus binding to cells
was increased. The data correlated with
-gal staining in Fig.
2A to F and therefore provided direct evidence
that undersulfation
of cell surface GAGs by chlorate treatment resulted
in reduction
of vaccinia virus binding to cells.
Other poxviruses also bind to cell surface GAGs during
infection.
We then investigated if other poxviruses also adopt a
similar strategy for cell entry process. BSC40 cells were infected with cowpox virus, rabbitpox virus, Shope fibroma virus, or myxoma virus in
the presence of heparin, as described in the legend to Fig. 1. Plaque
numbers for each virus were determined (Fig.
3A). Heparin blocked vaccinia virus and
cowpox virus to a similar extent, around 55 to 60%. It inhibited
rabbitpox virus better, at 78%. Furthermore, it blocked most plaque
formation by Shope fibroma virus and myxoma virus, reaching more than
80% inhibition. Therefore, the data indicated that heparin could act
as a general inhibitor of poxvirus infections.
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FIG. 3.
(A) Heparin blocks infections by other poxviruses. BSC40
cells were infected with Shope fibroma virus (SFV), myxoma virus (MXV),
rabbitpox virus (RPV), cowpox virus (CPX), and vaccinia virus (VV) in
the presence of heparin at various concentrations as shown at the
bottom of the figure, and plaque numbers were determined as described
in the legend to Fig. 1A. (B) MAb B2 blocked various poxvirus
infections differently from the blocking effect of heparin. BSC40 cells
were infected with different poxviruses in the presence of heparin (10 µg/ml) or hybridoma culture supernatant containing B2, and the plaque
numbers were determined as described in the legend to Fig. 1A.
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Previously, we isolated MAb B2, which binds to cells and blocks
vaccinia virus infection (
4). Similar to heparin, B2 also
interferes with vaccinia virus binding to cells. However, we have
shown
that cells treated with trypsin or pronase lost their reactivity
to B2,
suggesting that B2 recognizes a protein on the cell surface
(
4). Since heparin also blocked vaccinia virus binding to
cells,
we were curious to test if B2 cross-reacts with GAGs structures
on cells. One simple experiment was to test whether the blocking
effect
of B2 on different poxviruses was identical to the blocking
effect of
heparin. We performed parallel experiments to compare
MAb B2 with
heparin for their inhibitory effects on these four
poxviruses. Both
inhibitors were present in excess to ensure that
maximum effect would
be achieved. As shown in Fig.
3B, the sensitivities
of these poxviruses
to MAb B2 could be divided into two categories.
Vaccinia virus, cowpox
virus, and rabbitpox virus were sensitive
to MAb B2 treatment,
resulting in 95, 80, and 88% inhibition,
respectively. On the other
hand, infections of Shope fibroma virus
and myxoma virus were resistant
to B2, with less than 10% inhibition.
At the same time, heparin
blocked all five poxviruses. The spectrum
of virus sensitivity to
heparin did not correlate with B2, suggesting
that heparin and B2
compete for two different constituents on
cells for virus binding
during infection and that not all poxviruses
infect cells through
identical routes.
Recombinant A27L protein binds to heparin beads in vitro.
To
investigate the biochemical nature of vaccinia virus binding to GAGs,
we used heparin-Sepharose beads to determine if virions indeed bind to
heparin. Purified vaccinia virus virions were incubated with
heparin-conjugated beads at 4°C for 1 h, the unbound viruses were collected, and the virus titers were determined. As shown in
Figure 4, about 10% of the input virions
bound to the control Sepharose beads whereas an average of 50% of the
input virions bound to the heparin-Sepharose beads.
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FIG. 4.
Vaccinia virus virions bind to the heparin-Sepharose
beads in vitro. Different amounts of purified vaccinia virus virions,
as indicated at the bottom of the figure, were incubated with
heparin-Sepharose beads at 4°C for 60 min as described in Materials
and Methods. The unbound virions were collected in the supernatant, and
the titers were determined. The data shown on the y axis
were obtained by the following formula % Bound = [1-(PFUsupernatant/PFUinput)] × 100.
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To search for a candidate viral protein responsible for GAGs
interaction, we overexpressed vaccinia virus candidate proteins
in a
prokaryotic system to obtain large quantities. For example,
both
recombinant A27L and A4L proteins were tagged with 6-histidine
at the C
termini and purified with a nickel column. Both recombinant
proteins
were stained with Coomassie blue to check for their purity
(Fig.
5A, lanes 1 and 2). Also, Western blot
analysis was performed
to confirm the presence of T7-tagged peptide
sequences at the
N termini of these recombinant proteins (lanes 3 and
4). Subsequently,
these purified proteins were incubated with control
Sepharose
beads or heparin-Sepharose beads at 4°C for 30 min, and
after
the beads were washed the amount of proteins retained in the
beads
was determined by Western blot analysis. Neither protein bound
to
the control beads (Fig.
5B, lanes 4 and 9), and the proteins
were
collected in the supernatant (lanes 5 and 10). At the same
time, A27L
protein specifically bound to the heparin-Sepharose
beads (lane 2)
whereas A4L did not (lane 7).
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FIG. 5.
(A) Purification of the recombinant A27L and A4L
proteins. Both A27L (lanes 1 and 3) and A4L (lanes 2 and 4) recombinant
proteins were expressed in BL21(DE3) as described in Materials and
Methods and purified through a nickel column. The left panel is an
SDS-PAGE gel stained with Coomassie brilliant blue, and the right panel
is a Western blot probed with a MAb against a T7 tag (1:5,000) at the N
terminus of these recombinant proteins. (B) Recombinant A27L protein
binds to a heparin beads in vitro. Purified A27L (lanes 1 to 5) or A4L
(lanes 6 to 10) protein was incubated with heparin-Sepharose beads
(lanes 2, 3, 7, and 8) or control Sepharose beads (lanes 4, 5, 9, and
10) at 4°C for 60 min, and the supernatant was collected. The beads
were washed three times, and the volumes of the bound (lanes 2, 4, 7, and 9) or supernatant (lanes 3, 5, 8, and 10) samples were adjusted so
that equal proportions of each sample were loaded on a 15%
polyacrylamide gel for SDS-PAGE. Purified A27L and A4L proteins are
shown as controls in lane 1 and 6, respectively. The gel was
transferred for Western blot analysis with a MAb against a T7 tag
(1:5,000) at the N terminus of these recombinant proteins.
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Recombinant A27L protein binds to heparan sulfate on cells.
The binding of A27L protein to heparin in vitro indicated that A27L
protein may play an important role in vaccinia virus entry. We examined
the interaction of soluble recombinant A27L protein with live BSC40
cells to determine the specificity of its binding to cells. Monolayers
of BSC40 cells were incubated with biotinylated A27L protein at 4°C,
and the bound A27L protein was detected by phycoerythrin-conjugated
streptavidin by immunofluorescence. BSC40 cells incubated with
streptavidin alone showed very low background staining (Fig.
6A). Binding of A27L protein to cells was
seen as intense homogeneous staining on the cell surface (Fig. 6B). Binding of A27L recombinant protein to cells was greatly diminished in
the presence of soluble heparin, except that some small speckles were
observed (Fig. 6C). In contrast, A27L protein that had been incubated
with condrointin sulfate (Fig. 6D) or dermatan sulfate (Fig. 6E) bound
to cells in a pattern indistinguishable from that observed with A27L
protein alone.
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|
FIG. 6.
Recombinant A27L protein binds to the cell surface. Live
BSC40 cells were incubated at 4°C for 30 min with PBS (A and F) or
biotinylated A27L protein alone (B and G) or A27L protein previously
mixed with heparin (C and H), condrointin sulfate (D and I), or
dermatan sulfate (E and J) as described in Materials and Methods. The
cells were washed three times and phycoerythrin-conjugated streptavidin
was added for another 30-min incubation. After being washed, the cells
were observed with a fluorescence microscope (A to E) or reverse-phase
light microscope (F to J). All the images were analyzed as described in
Materials and Methods.
|
|
| |
DISCUSSION |
Poxviruses are known to infect a variety of different cell types
both in vitro and in vivo (34). Vaccinia virus, as the prototype orthopoxvirus, has been shown to infect multiple organs in
the hosts. The nature of such a wide host range is not understood, and
no receptor for vaccinia virus has been reported. In this study, we
show that vaccinia virus binds to cell surface heparan sulfate during
infection. The evidence came from several experiments. First, soluble
heparin specifically competed with cells for virus binding. In
addition, undersulfation of cell surface heparan sulfate by
chlorate treatment reduced cell susceptibility to virus infection. Furthermore, purified vaccinia virus virions bound directly to the
heparin-Sepharose column. Since heparan sulfate proteoglycans are found
in the extracellular matrix and on the surface of most adherent
mammalian cells, it would be advantageous for viruses to adopt such an
interaction during infections (24). Indeed, results from
four other poxviruses we tested also suggested a similar role of
heparan sulfate for poxvirus entry. The nature of the virus-heparan
sulfate interaction was governed mainly by the charge density
contributed by different extents of sulfation on sugar moieties.
However, undersulfated heparin sulfate produced in the presence of
chlorate was reported to contain a reduced level of iduronic acids
(23). Therefore, sugar structures of heparan sulfate may
also specify vaccinia virus-cell interactions. We did notice that the
dependence of vaccinia virus on heparan sulfate may not be as tight as
that of herpesvirus, since the extent of inhibition by soluble heparin
was never complete. Besides BSC40 cells, heparin could also block
vaccinia virus infection of RK13 and HeLa cells to similar extents. We
cannot completely rule out an involvement of other GAGs which may play
a role for vaccinia virus but have escaped detection.
Cell surface heparan sulfate has been reported to play a role in the
invasion of several pathogens into mammalian cells; these pathogens
include bacteria such as Chlamydia trachomatis and
Neisseria gonorrhoeae, the intracellular parasite
Leishmania, and viruses such as herpesviruses and type O
foot-and-mouth disease virus (20, 28, 46, 49, 52). The
abundance and ubiquitous distribution of proteoglycans on various cells
may justify a role as common attachment sites for different pathogens
through a relatively nonspecific charge interaction. Since the entry
process often has multiple stages, subsequent steps after such initial
interactions may have been diversified according to the unique
structure of individual pathogens. For example, herpesvirus binding to
heparan sulfate is followed by membrane fusion between viruses and
cells. Such a fusion factor, HVEM, was recently isolated and shown to be specific for herpes simplex virus type 1 (31). Vaccinia
virus was also shown to enter cells via plasma membrane fusion
(8). Thus, in principle, a different fusion factor may exist
for vaccinia virus. Since we found that MAb B2 blocked vaccinia virus
infection differently from soluble heparin, it is possible that B2
reacts with a surface molecule which plays some roles in the fusion
event. Experiments to address these issues are in progress.
Heparan sulfate-virus interaction could induce conformational
rearrangements that may enhance or optimize subsequent fusion events.
In herpes simplex virus, such process is mediated by multiple viral
proteins on virions. Herpes simplex virus virion binding to heparan
sulfate is mediated by two viral proteins, gC and gB. Overexpression of
gB in cells results in cell fusion after low-pH treatment (3,
42). Other viral membrane proteins such as gD, gH, and gL are
also known to be required for cell fusion, although they do not
directly bind to heparan sulfate (42).
For vaccinia virus, our results suggested that one viral membrane
protein, A27L, could mediate virus attachment to heparan sulfate
moieties on cells. A27L protein was previously reported to bind to
cells, but the nature of the binding was not explored (25).
We showed that recombinant A27L protein bound to heparin in vitro. In
addition, purified A27L protein bound to cells, and this interaction
could be specifically blocked by soluble heparin. These data revealed a
molecular basis to explain the functions of A27L protein in the
virus-host interaction. Similar to gB in HSV, A27L protein was
previously reported to be an envelope protein on the surface of IMV and
was required for cell fusion triggered by low-pH treatment (38,
39). Deletion of the N-terminal region of A27L protein eliminated
its fusion activity, and many neutralizing MAbs recognize an epitope
located near the N-terminus of A27L protein (13, 30). It is
interesting that a cluster of positively charged amino acids are also
located within the N-terminal region. These arginine and lysine
residues, in principle, could be the GAG-binding domain of A27L
protein. In future, it will be worthwhile to generate site-specific
mutations of A27L proteins and to determine the relationship between
the heparin binding activity of A27L protein and its fusion activity.
Natural mutations of A27L gene in vaccinia virus were found in
persistently infected cells (5, 33). Mutations of A27L protein resulted in viable mutant viruses with a small-plaque phenotype
(5, 12). It could mean that A27L mutant viruses enter cells
via surface molecules distinct from heparan sulfate. Alternatively,
other viral membrane proteins may substitute for the heparin-binding
functions of A27L protein in these A27L mutant viruses. These two
possibilities are not mutually exclusive and will be worth studying in
the future.
Vaccinia virus has two forms of infectious particles, IMV and EEV.
These viruses are composed of distinct membrane structures, and hence
the entry of individual forms must be different from others. Our
present study focuses on IMV entry, and any new information may help us
understand its roles in virus spread within hosts. Studying the
molecular mechanisms of virus entry may also help explain why multiple
forms of poxviruses have evolved. Our study of GAG-vaccinia virus
interaction is only the beginning of an attempt to dissect vaccinia
virus entry pathways. More experiments are needed to further understand
the molecular events that facilitate vaccinia virus entry processes.
| |
ACKNOWLEDGMENTS |
We thank Chi-Long Lin for computer assistance. We also thank
Douglas Platt for carefully reviewing the manuscript.
This work is supported by research grants from the National Science
Council (grant NSC 86-2316-B-001-016) and from Academia Sinica.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institute of
Molecular Biology, Academia Sinica, Narkay, Taipei, Taiwan 11529, Republic of China. Phone: 886-2-789-9230. Fax: 886-2-782-6085. E-mail: mbwen{at}ccvax.sinica.edu.tw.
| |
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Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
