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Previous Article | Next Article 
Journal of Virology, September 1998, p. 7357-7366, Vol. 72, No. 9
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Adaptation of Sindbis Virus to BHK Cells Selects
for Use of Heparan Sulfate as an Attachment Receptor
William B.
Klimstra,*
Kate D.
Ryman, and
Robert E.
Johnston
Department of Microbiology and Immunology,
School of Medicine, University of North Carolina at Chapel Hill,
Chapel Hill, North Carolina
Received 6 April 1998/Accepted 12 June 1998
 |
ABSTRACT |
Attachment of Sindbis virus to the cell surface glycosaminoglycan
heparan sulfate (HS) and the selection of this phenotype by cell
culture adaptation were investigated. Virus (TR339) was derived from a
cDNA clone representing the consensus sequence of strain AR339 (K. L. McKnight, D. A. Simpson, S. C. Lin, T. A. Knott,
J. M. Polo, D. F. Pence, D. B. Johannsen, H. W. Heidner, N. L. Davis, and R. E. Johnston, J. Virol.
70:1981-1989, 1996) and from mutant clones containing either
one or two dominant cell culture adaptations in the E2 structural
glycoprotein (Arg instead of Ser at E2 position 1 [designated TRSB])
or this mutation plus Arg for Ser at E2 114 [designated TRSB-R114]).
The consensus virus, TR339, bound to baby hamster kidney (BHK) cells
very poorly. The mutation in TRSB increased binding 10- to 50-fold, and
the additional mutation in TRSB-R114 increased binding 3- to 5-fold
over TRSB. The magnitude of binding was positively correlated with the
degree of cell culture adaptation and with attenuation of these viruses in neonatal mice. HS was identified as the attachment receptor for the
mutant viruses by the following experimental results. (i) Low
concentrations of soluble heparin inhibited plaque formation on and
binding of mutant viruses to BHK cells by >95%. In contrast, TR339
showed minimal inhibition at high concentrations. (ii) Binding and
infectivity of TRSB-R114 was sensitive to digestion of cell surface HS
with heparinase III, and TRSB was sensitive to both heparinase I and
heparinase III. TR339 infectivity was only slightly affected by either
digestion. (iii) Radiolabeled TRSB and TRSB-R114 attached efficiently
to heparin-agarose beads in binding assays, while TR339 showed
virtually no binding. (iv) Binding and infectivity of TRSB and
TRSB-R114, but not TR339, were greatly reduced on Chinese hamster ovary
cells deficient in HS specifically or all glycosaminoglycans. (v)
High-multiplicity-of-infection passage of TR339 on BHK cell cultures
resulted in rapid coselection of high-affinity binding to BHK cells and
attachment to heparin-agarose beads. Sequencing of the passaged virus
population revealed a mutation from Glu to Lys at E2 70, a mutation
common to many laboratory strains of Sindbis virus. These results
suggest that TR339, the most virulent virus tested, attaches to cells
through a low-affinity, primarily HS-independent mechanism. Adaptive
mutations, selected during cell culture growth of Sindbis virus,
enhance binding and infectivity by allowing the virus to attach by an
alternative mechanism that is dependent on the presence of cell surface
HS.
| |
INTRODUCTION |
Alphaviruses have a broad host range
in nature, replicating in mammalian, avian, arthropod, and amphibian
species, and are capable of infecting a wide variety of cultured cells
(60, 61). Because of their broad host range, it has been
suggested that alphaviruses use a ubiquitously expressed molecule for
attachment to cells (27, 60). Attachment is thought to be
mediated primarily by the virus E2 structural glycoprotein (reviewed in
reference 61). Attached Sindbis virus is uniformly
distributed over fixed cell surfaces, occupying 104 to
105 receptor sites (similar to results with Semliki Forest
virus [SFV] [21]), and treatment of attached virus
with high-ionic-strength buffer results in the elution of most bound
virus (5, 50). These results suggest that a charge
interaction might play a significant role in alphavirus attachment.
Indeed, several studies have suggested that sulfated polyanions, such
as cell surface glycosaminoglycans (GAGs), are involved in binding of
alphaviruses to cells. Schleupner et al. (57) implicated
polyanionic polysaccharide in inactivation of a small-plaque variant of
Sindbis virus. Symington and Schlesinger (63) found that
pretreatment of mouse plasmacytoma cells with heparin resulted in a
large increase in Sindbis virus binding. Mastromarino et al.
(39) were able to partially compete Sindbis virus
infectivity with soluble heparin and several other sulfated polyanions
and diminish infectivity by digestion of cell surface heparan sulfate
(HS) with heparinase, suggesting that a sulfated molecule may be a
component of the receptor site. Polyanionic compounds which block human
immunodeficiency virus (HIV) attachment also inhibit infectivity of
alphaviruses including SFV and Sindbis virus (58).
Although a single cellular receptor has not been unambiguously
identified for any alphavirus (27, 46; reviewed in
reference 60), studies using methods such as
chemical cross-linking (37), copurification of
virus-receptor complexes (16), enzymatic inactivation of
cellular receptors (59, 69), analysis of anti-idiotype antibodies (69, 71), and analysis of antireceptor antibodies (36, 70) have indicated that attachment is mediated through virus interaction with a cell surface protein. However, putative receptors of different molecular weights have been identified in
different laboratories and with different cell types (16, 36, 37,
69-71). Given the number of different cell surface structures
shown to interact with alphaviruses, several investigators have
suggested that multiple receptors may exist, in some instances on the
same cell type (59, 69, 70). A significant complicating factor is that single amino acid differences in the structural glycoproteins of different strains may profoundly affect virus attachment-entry processes. As few studies have compared attachment differences between different alphavirus strains on a single cell type,
it is possible that differences observed in attachment-entry mechanisms
may result, at least in part, from the use of different Sindbis virus
laboratory strains.
Adaptation of Sindbis virus to growth in tissue culture or in animals
has generated virus mutants that can be used to evaluate strain-specific differences in receptor usage. Single amino acid changes in the E2 glycoprotein coordinately alter virus
attachment-entry of cultured cells and pathogenesis in vivo. Mutations
from Ser to Arg at E2 position 114 (11), Glu to Lys at E2 70 (40, 54), and Gln to His at E2 55 (67) have been
associated with rapid penetration of BHK cells. The mutations selected
in vitro (E2 Lys 70 and E2 Arg 114) are attenuating in neonatal mice
(11, 40, 66), while the in vivo-selected E2 His 55 mutation
enhances virulence in older mice (68). A correlation between
in vitro selection for mutations of certain E2 residues with rapid
penetration of BHK cells and attenuation of virulence in vivo also has
been shown for other alphaviruses: S.A.AR86 (54), Venezuelan
equine encephalitis virus (VEE) (13), and SFV
(22). However, it remains unknown whether penetration
mutants use the same attachment-entry mechanism as the parental strains
from which they were derived. Also, the effects of preexisting cell
culture-adaptive mutations in parental strains used as genetic
background for mutant selections have not been evaluated. Together,
alphavirus receptor-entry and mutant selection studies have indicated
that while a protein receptor likely plays an important role in the
infection process, charge interactions, perhaps with GAG molecules, may
also contribute to alphavirus attachment.
We have investigated strain-specific differences in Sindbis virus
attachment in a comparative study of virus generated from cDNA clones
of a Sindbis virus AR339 ancestral consensus sequence (TR339) and two
cell culture-adapted mutants. The cloned consensus sequence eliminates
several cell culture-adaptive mutations present in sequenced laboratory
strains of AR339 (40). In our studies, virus differing from
the consensus sequence by either one or two dominant adaptive mutations
exhibited greatly increased binding to BHK cells that was dependent
upon the presence of cell surface HS. Binding of TR339 was only
slightly dependent upon HS. The HS-dependent phenotype could be
selected rapidly upon passage of TR339 in BHK cells and was correlated
with attenuation of virus disease in neonatal mice.
(Portions of this work were presented at the 1997 meeting of the
American Society for Virology.)
| |
MATERIALS AND METHODS |
Cell culture.
Baby hamster kidney (BHK-21) (ATCC CCL-10),
Swiss 3T3 (ATCC CCL-92), L929 (ATCC CCL-1), and Neuro-2A (ATCC CCL-131)
cells were maintained in alpha minimal essential medium supplemented with 10% donor calf serum, 10% tryptose phosphate broth, 0.29 mg of
L-glutamine per ml, 100 U of penicillin per ml, and 0.05 mg
of streptomycin per ml. Chinese hamster ovary (CHO-K1) (ATCC CRL-61)
and CHO mutant (psgA-745 [ATCC CRL-2242] and pgsD-677 [ATCC
CRL-2244]) cells were maintained in Ham's F-12 medium supplemented with 10% fetal bovine serum. Primary mouse and chicken embryo fibroblast (MEF and CEF, respectively) cultures were prepared by
homogenization of 12- to 15-day (MEF) or 9- to 10-day (CEF) gestation
embryos followed by incubation in trypsin for cell dissociation. Dissociated homogenates were then strained to remove remaining tissue,
concentrated through centrifugation, and plated. Cells were grown to
confluence and either used directly in assays or used after one
passage. Primary cells were maintained in Dulbecco minimal essential
medium-F-12 supplemented with 10% fetal bovine serum, 100 U of
penicillin per ml, 0.05 mg of streptomycin per ml, and 0.05 mg of
gentamicin per ml. All cell culture reagents were obtained from Gibco.
Viruses.
All viruses were generated from cDNA clones. The
construction of pTRSB, pE2S1, and pTRSB-R114 (the "p" prefix
designates the plasmid form of the clone) have been described
previously (24, 40, 65). pToto 1101 (51), pToto
50 (51), pTE5'2J (23), and pTE3'2J
(23) were kindly provided by Charles Rice, Washington University, St. Louis, Mo. pTR339 was constructed in the background of
pE2S1 by introducing the consensus nsP3 Arg 528 through exchange of an
SpeI-to-HpaI fragment from pTE5'2J and exchange
of a BssHII-to-XhoI fragment from a pToto 1101 clone previously mutagenized to return E1 237 to the consensus sequence
residue (E1 Ala 237). Virus stocks were generated by in vitro
transcription of linearized plasmid DNA followed by electroporation
into BHK cells. To minimize introduction of cell culture-adaptive
mutations, supernatants from electroporated cultures were clarified by
centrifugation and used directly as viral stocks. Stocks were titered
by plaque assay on BHK cells.
RP.
Replicon particles (RP), similar to those described by
Bredenbeek et al. (6), which contained a Sindbis virus
genome with the structural protein genes replaced by the gene for green
fluorescent protein (GFP) were constructed, with this genome packaged
by using various viral E2 glycoproteins. Replicon helper constructs
expressing the capsid and glycoprotein genes but lacking most
nonstructural protein sequences and RNA packaging signals were
constructed from plasmids pTRSB, pE2S1, pTR339, and pTRSB-R114 by
digestion with SmaI and HpaI, followed by
religation (removing nucleotides 767 to 6991 of the viral genome).
GFP-expressing replicon genomes were constructed by introducing the
mut2 GFP gene (kindly provided by Stanley Falkow, Stanford
University) into the Sindbis virus double 26S promoter vectors pTE5'2J
and pTE3'2J. The AatII-to-HpaI restriction
fragment of pTE5'2JGFP was then introduced into pTRSB. This construct
contains a second copy of the 26S subgenomic promoter and the GFP gene
upstream of the authentic 26S promoter but is otherwise isogenic with
pTRSB (pTRSB5'GFP). The BsiWI-to-XhoI fragment of
pTE3'2JGFP was likewise introduced into pTRSB, creating a downstream
double promoter vector (pTRSB3'GFP) with the second 26S promoter and
GFP gene just downstream of the E1 gene. The E1 237 coding difference
between pTE3'2J and pTRSB was corrected by restriction fragment
exchange. PCR primers then were designed to amplify the GFP gene and
surrounding sequences from the downstream GFP vector, preserving the
XhoI site and nontranslated region at the 3' end of the
virus genome and introducing an XbaI site at the 5' end of
the GFP gene. The XbaI-to-XhoI fragment of
pTRSB5'GFP was removed (deleting all of the structural genes) and
replaced with the PCR fragment, thereby generating a replicon genome
that would produce nonstructural proteins and drive GFP expression in
infected cells from the 26S viral promoter. RP stocks were generated by
electroporation of BHK cells with a mixture of GFP replicon and
structural protein helper RNAs. Replicon stocks were titered by
fluorescent center assay on BHK cells. All genetic manipulations
described in this and other sections were confirmed by DNA sequencing.
Fluorescent center assay.
RP were diluted to a concentration
of 100 to 200 BHK infectious units per 50 µl in virus diluent-binding
buffer (VB) (phosphate-buffered saline, 1% donor calf serum). Cells
were seeded in 12- or 24-well plates and infected in 50 µl of VB for
60 min at 37°C. Monolayers were washed twice with VB and incubated in
growth medium for 8 to 12 h postinfection. Growth medium was then
removed and monolayers were fixed with 2% paraformaldehyde. Individual
infected cells expressing GFP were visualized on an Olympus
fluorescence microscope with a fluorescein isothiocyanate filter block.
Plaque reduction assays.
Virus was diluted to ~100 BHK PFU
per 200 µl in VB. Cells were infected in 12-well or
60-mm2 plates for 60 min at 37°C. Depending upon the
experiment, plates were either washed two times with 1 ml of VB prior
to overlay or were overlaid directly with an 0.5% immunodiffusion
agarose-growth medium solution. After 24 h, plates were stained
with neutral red and plaques were enumerated. For competition
experiments with heparin, dextran sulfate, chondroitin sulfate A
(CS-A), chondroitin sulfate B (CS-B), or bovine serum albumin (BSA)
(all obtained from Sigma), competitor was added to the diluted virus 30 min prior to infection and the mixture was incubated on ice. For
heparinase I, heparinase III, and chondroitinase ABC (all obtained from
Sigma) digestions, cell monolayers were incubated with the enzyme for 1 h at 37°C, followed by two washes with VB prior to infection.
Virulence of viruses in mice.
Neonatal (12- to 24-h-old)
CD-1 (Charles River) mice were infected subcutaneously with 1,000 BHK
PFU of each virus in 50 µl of VB. Virus doses were confirmed by
plaque assay of the inoculum on BHK cells. Mice were observed at 12- or
24-h intervals to determine average survival times (AST) and percent
mortality.
Virus purification.
Radiolabeled virus was prepared by
infection of BHK cells with stock virus as described previously
(26) with the following modifications. Virus-infected
monolayers were incubated in medium containing 10 µCi of
[35S]methionine (Amersham) per ml. Clarified virus
preparations were purified on discontinuous 20 to 60% (wt/wt) sucrose
gradients in TNE (0.05 M Tris-HCl [pH 7.2], 0.1 M NaCl, 0.001 M EDTA)
buffer, followed by continuous 20 to 60% sucrose gradients. For final concentration, virus was pelleted through 20% sucrose and resuspended in VB. BHK-specific infectivity (PFU per count per minute [cpm]) was
calculated for each radiolabeled virus preparation by plaque assay on
BHK cells.
Virus attachment assay.
Due to high background binding of
some virus mutants to the surfaces of tissue culture plates, cells were
dissociated from plates with enzyme-free cell dissociation buffer
(Gibco) and binding assays were conducted in suspension. Cells were
washed three times with VB prior to reaction with virus. Fifty
microliters of cells (~106) were added to Eppendorf tubes
followed by 50 µl of purified virus (ranging from 5 × 104 to 1 × 105 cpm, equivalent to
~5 × 109 to ~1 × 1010 particles
per reaction), each diluted in VB. Mixtures were incubated at 4°C for
60 min with gentle agitation. Cells then were washed three times with 1 ml of VB, and pellets were resuspended in 100 µl of 0.6% Nonidet
P-40 in TNE. Radioactivity associated with cells was enumerated by
scintillation counting of 50 µl of the suspension. Control reactions
with no added cells were performed for each binding experiment, and cpm
adherent to reaction tubes were subtracted from total cpm bound.
Binding reactions were performed in duplicate or triplicate, and all
experiments were repeated at least twice. For heparin competition
assays, heparin was added to diluted virus 30 min prior to mixing with
cells and incubated at 4°C. For binding to heparin-agarose beads and
BSA-agarose beads (Sigma), 1 ml of beads was washed with VB three
times, followed by resuspension in 1 ml of VB. Fifty microliters of
beads was then added to 50 µl of diluted virus exactly as in the cell
binding assays. Incubation, washes, resuspension, and enumeration of
bead-associated radioactivity also were exactly as with cell binding
assays. For GAG precursor addition experiments with psgA-745 cells,
monolayers (pgsD-745 and CHO-K1) were incubated for 48 h in
complete medium supplemented with 1 mM
p-nitrophenyl-
-D-galactoxylopyranoside (Sigma) followed by processing for binding assays as described above.
BHK-passaged virus.
BHK cell monolayers were infected with
TR339 at a multiplicity of infection of ~1, followed by incubation at
37°C for ~20 h. Supernatants were harvested and clarified as with
viral stocks and then titered and used for infection of a new BHK
monolayer. This was repeated until five passages had been achieved. For
radiolabeling of BHK-passaged virus, clarified supernatants of passage
2 virus were used to infect BHK cell monolayers followed by processing, as described above. This resulted in production of radiolabeled virus
particles with a passage level equivalent to passage 3. Virus genome
RNA was harvested directly from the third BHK cell passage supernatant
by extraction with RNAzol (Bio 101), followed by isopropanol
precipitation. RNA was then subjected to reverse transcriptase PCR with
E2 and E1 glycoprotein-specific primers on a Perkin-Elmer Cetus
thermocycler. The cDNA was then amplified by PCR with the same primer
sets. Amplified cDNA was sequenced at the University of North Carolina
at Chapel Hill Automated DNA Sequencing Facility on a model 373A DNA
sequencer (Applied Biosystems) with the Taq DyeDeoxy
Terminator Cycle Sequencing Kit (Applied Biosystems).
| |
RESULTS |
A cDNA clone (designated pTR339) of the ancestral Sindbis virus
AR339 sequence (40) has been constructed. This sequence differs from the clone of our biological laboratory strain of AR339
(pTRSB) at three coding positions: nsP3 528, E2 1, and E1 72 (Table
1). The biological isolate which was the
source for pTRSB was derived by single-step selection for growth in BHK
cells (40). An Arg-for-Ser substitution at E2 114, conferring rapid penetration of BHK cells in comparison with TRSB and
significantly attenuating virulence, was selected in the TRSB
background and incorporated into pTRSB to give pTRSB-R114
(11, 65). We have used TR339, TRSB, and TRSB-R114 in
mouse virulence, cell binding, and infectivity assays to determine if
adaptation to BHK cells is correlated with altered cell attachment and
changes in virulence for neonatal mice.
Virulence of viruses for neonatal mice.
Twelve- to 24-h-old
CD-1 mice were inoculated subcutaneously with each virus and monitored
for mortality at 12-h intervals (Fig. 1).
Infection with TR339 resulted in 100% mortality, with an AST of
1.8 ± 0.34 (mean ± standard deviation) days. TRSB infection also resulted in 100% mortality, but the AST was extended
significantly (3.2 ± 0.46 days [two-tailed Student's
t test with unequal variance; P, <0.001]).
TRSB-R114 caused only ~50% mortality, with a considerably extended
survival time (7.9 ± 2.5 days). These data indicate that strains
which diverge at only one or two amino acids from the AR339 consensus
sequence can exhibit significant attenuation of disease in neonatal
mice.
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FIG. 1.
Survival of neonatal CD-1 mice infected with TR339
(solid line; n, 30; AST, 1.8 ± 0.34 days), TRSB
(evenly dashed line; n, 30; AST, 3.2 ± 0.46 days), or
TRSB-R114 (unevenly dashed line; n, 25; AST, 7.9 ± 2.5 days). Mice were inoculated subcutaneously with 1,000 BHK PFU of virus
in 50 µl of diluent.
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Virus binding to and infectivity for BHK cells.
BHK cell
binding assays revealed a dramatic difference in attachment
efficiencies of TR339 and the cell culture-adapted mutants (Fig.
2). In multiple experiments, only 0.05 to
0.5% of added TR339 bound to BHK cells, while the bound proportion of
added TRSB and TRSB-R114 increased to 5 to 10% and 20 to 30%,
respectively. These results suggest a strong correlation between BHK
cell-adaptive mutations and attachment efficiency and an inverse
correlation with virulence in mice. We have also found this correlation
with other AR339 strains (33). For TR339, the percent cpm
bound was much lower than previously reported for AR339 laboratory
strains (59, 67, 69, 70). Preliminary assays indicated that
the binding of TR339 and TRSB to BHK cells was not saturable. However, TRSB-R114 exhibited saturable binding (data not shown).
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FIG. 2.
Relative binding and specific infectivity of TR339,
TRSB, and TRSB-R114 for BHK cells. For binding assay (solid bars),
105 cpm of each radiolabeled virus was added to
106 BHK cells in suspension and incubated at 4°C for 60 min. After three washes with VB, radioactivity associated with cells
was quantitated. For specific infectivity (hatched bars), radiolabeled
virus was diluted and assayed for plaque formation on BHK cell
monolayers. Specific infectivity (PFU/cpm) was then calculated for each
virus. Values are presented as percentages of values for TRSB (100%).
*, binding of TR339 was <1% of that of TRSB in this assay.
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Specific infectivity of radiolabeled virus (PFU/cpm) was closely
correlated with relative binding to BHK cells (Fig. 2). Covariation of
binding and infectivity suggests that binding measured in these assays
reflects an interaction that leads directly to infection of cells and
that the increase in infectivity of TRSB compared with TR339, and the
additional increase of TRSB-R114 compared with TRSB, results from
increased efficiency of attachment to cells. Binding reactions with
primary CEF, primary MEF, murine L929 fibroblasts, murine Swiss 3T3
fibroblasts, and murine Neuro-2A neuroblastoma cells revealed the same
patterns of binding efficiency as with BHK cells: TRSB-R114 > TRSB > TR339 (data not shown). The absolute amount of binding for
each virus varied between cell types; however, TR339 binding was never
more than 1% of added cpm.
Binding and BHK cell infectivity of a virus with Ser at E2 1, but the
TRSB residues at nsP3 528 and E1 72 (E2S1) (Table 1), were
indistinguishable from TR339 (data not shown). This demonstrates that
of the three TRSB mutations relative to the consensus sequence (Table
1), the E2 Arg 1 mutation alone accounts for the increased binding and
infectivity.
We also placed the E2 Arg 114 mutation in the E2 Ser 1 background
(E2S1-R114) (Table 1). The resultant virus exhibited >90% of the
binding efficiency of TRSB-R114 (data not shown). This suggests that
the E2 Arg 114 mutation by itself confers a very large increase in
attachment ability and that the E2 Arg 1 and E2 Arg 114 mutations can
independently increase cell binding.
Heparin competition of binding and infectivity.
As described
above, several previous Sindbis virus studies indicated that a
charge-based interaction, perhaps involving a cell surface sulfated
polysaccharide, might be important to binding. In preliminary assays,
we found that the binding and infectivity of TR339 were insensitive to
ionic strength, whereas TRSB and TRSB-R114 binding and infectivity were
significantly reduced by NaCl concentrations above 175 mM (data not
shown). This indicated that alteration of cell surface charge could
affect the binding of BHK cell-adapted Sindbis virus strains.
We next evaluated the ability of the sulfated polysaccharide heparin to
block plaque formation by these viruses (Fig.
3A). Virus derived from pToto 50 (cDNA
clone of Sindbis virus strain HRsp [51])
also was included to evaluate the effects of heparin on the infectivity
of an extensively passaged AR339 strain. Heparin is commonly used as an
analog of cellular HS in receptor-ligand interaction assays, since
ligand interactions with heparin and analogous HS structures have
little qualitative difference (31). TR339 showed only
limited (~25%) competition at heparin concentrations ranging from
<50 µg/ml to >10 mg/ml. In sharp contrast, soluble heparin
effectively competed infectivity of TRSB and TRSB-R114 at low
concentrations (50% plaque reduction endpoints of 1.1 and 3.3 µg/ml,
respectively [Fig. 3A]). Plaque formation by Toto 50 also was >95%
competed; however, the 50% plaque reduction endpoint was at a 5- to
10-fold-higher heparin concentration than for TRSB and TRSB-R114. In
control competition experiments, BSA slightly increased plaque numbers
with increasing concentrations, while the GAG molecule CS-A had no
detectable effect on infectivity of any of the viruses. CS-B (dermatan
sulfate), which is structurally similar to HS, and dextran sulfate, a
highly sulfated molecule similar to heparin, inhibited virus plaque
formation only at high concentrations (>1 mg/ml [data not shown]).
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FIG. 3.
Soluble heparin competition of TR339, TRSB, TRSB-R114,
and Toto 50. (A) Reduction in plaque formation of TR339 (squares), TRSB
(circles), TRSB-R114 (triangles), and Toto 50 (diamonds) on BHK cell
monolayers with increasing concentrations of heparin. Viruses were
diluted to 100 to 200 PFU/200 µl and reacted with heparin for 30 min
at 4°C, followed by infection of BHK cell monolayers in the presence
of heparin. (B) Reduction in binding of TR339 (squares), TRSB
(circles), and TRSB-R114 (triangles) to BHK cells with increasing
concentrations of heparin. Viruses (105 cpm/reaction) were
reacted with heparin as described above, followed by binding assay in
the presence of heparin. Results are averages of two or three reactions
at each concentration.
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It is of interest that maximum competition of TR339 was achieved at
<50 µg of heparin per ml, with no further increase in competition
observed at 10 mg/ml. This result may indicate the presence of two
populations of virus in the TR339 stock. Production of virus stocks by
electroporation of in vitro transcripts may involve limited selection
for growth on BHK cells (see below). If electroporation efficiency is
less than 100%, then virus progeny from successfully electroporated
cells will be amplified in cells that received no viral transcripts
initially.
Binding assays showed a similar pattern, in that TRSB and TRSB-R114
were competed in binding by soluble heparin while TR339 showed
resistance similar to that exhibited for plaque formation (Fig. 3B).
However, concentrations required to inhibit binding of the viruses were
significantly greater than for plaque reduction, likely reflecting the
much higher concentration of virus used in binding assays. Consistent
with plaque formation assays, BSA increased binding slightly and CS-A
had no effect. These results indicate that the block in generating TRSB
or TRSB-R114 plaques in the presence of heparin is at the level of
attachment to cells.
Enzymatic digestion of cell surface HS.
Heparinase digestion
of cells is commonly used to examine the effect of removal of HS on
ligand binding to cell surface receptors (53). Virus
infectivity and binding were evaluated after digestion of BHK cells
with heparinase I (which digests highly sulfated heparin-like
structures on HS [15]) or heparinase III (which digests both HS and heparin [15]). Digestion of BHK
cells with increasing concentrations of either heparinase I or III
resulted in a maximum reduction of TR339 infectivity of only ~25%
regardless of the enzyme used, consistent with the heparin competition
experiments (Fig. 4). However, a
dose-dependent inhibition of TRSB plaque-forming ability was observed
with both heparinase I and heparinase III. TRSB-R114 was unaffected by
heparinase I digestion; however, this virus was nearly as sensitive as
TRSB to heparinase III.
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FIG. 4.
Effect of heparinase digestion on plaque-forming
efficiency of TR339, TRSB, and TRSB-R114 on BHK cells. (A) BHK
cell monolayers were digested with increasing concentrations of
heparinase I, followed by three rounds of washing with virus buffer and
infection with 100 to 200 PFU of TR339 (squares), TRSB (circles), or
TRSB-R114 (triangles). (B) BHK cell monolayers were digested with
increasing concentrations of heparinase III, washed, and infected as
above. Data are averages of two or three assays at each
concentration.
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Binding experiments were consistent with efficiency of plaque
formation. Binding of TRSB was sensitive to both heparinase I and
heparinase III, while TRSB-R114 was sensitive only to heparinase III
(Fig. 5). In control experiments, binding
and infectivity of all viruses were reduced significantly less (maximum
of ~30% reduction) by digestion of cells with chondroitinase ABC
(data not shown). These heparinase experiments suggest that TRSB and TRSB-R114 interact with different types of HS structures. TRSB-R114 binding may be dependent on a structural characteristic of HS or the
context of HS displayed on cell surfaces, while TRSB may bind
promiscuously to HS structures. The fact that TRSB-R114 binding is
saturable, while that of TRSB is not, also suggests that these viruses attach to different HS structures.
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FIG. 5.
Effect of heparinase digestion on binding of TRSB
(circles) and TRSB-R114 (triangles) to BHK cells. (A) BHK cell
monolayers were digested with increasing concentrations of heparinase
I, followed by three rounds of washing with VB, suspension, and use in
binding assays (5 × 104 cpm of radiolabeled virus per
reaction). (B) BHK cell monolayers were digested with increasing
concentrations of heparinase III and processed as above. Data are
averages of two or three binding reactions at each concentration. In
these assays, binding of TR339 to digested or undigested cells was not
above background cpm measured in cell-free control reactions.
|
|
Genetic alteration of cell surface GAGs.
Binding and
infectivity of viruses also were evaluated on wild-type CHO-K1 cells
and CHO mutants defective in GAG and HS synthesis. The mutant CHO cell
line pgsA-745 is deficient in xylosyltransferase (18), an
enzyme of a pathway common to all GAG biosynthesis, and hence is GAG
deficient. The mutant line pgsD-677 is deficient in
N-acetylglucosaminyl- and glucuronosyltransferase
activities (interrupting HS synthesis) and overproduces CS
(35). Due to extremely variable plaque sizes of Sindbis
virus on the different CHO cell lines, an RP-based fluorescent
infectious center assay was used to determine infectivity on these
cells. Cell monolayers were infected with RP assembled with structural
proteins of either TR339, TRSB, or TRSB-R114 and containing a defective
genome that directed the expression of GFP within infected cells. Since
structural protein genes were deleted from the RP genomes, virus spread
beyond the initially infected cells was prevented. Therefore, relative RP infectivity, determined by the TR339, TRSB, and TRSB-R114
glycoproteins in their respective envelopes, could be measured by
enumeration of single infected cells by fluorescence microscopy.
Consistent with the role of GAGs suggested by the competition and
enzymatic digestion assays, the infectivity of TRSB and TRSB-R114 RP
was greatly reduced on the GAG-deficient cells (by 90 and >95%,
respectively [Fig. 6A]). Reminiscent of
heparinase digestion of BHK cells, TR339 RP exhibited only ~30%
reduction in infection efficiency. Infectivity of mutant RP on the
HS-deficient pgsD-677 cells was greatly reduced compared to wild-type
cells but was not reduced as much as with GAG-deficient cells (Fig. 6A). However, this difference between the two cell lines appears to be
unrelated to cell binding (see below).
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FIG. 6.
Infectivity of TR339, TRSB, and TRSB-R114 GFP-expressing
RP and binding of analogous viruses to wild-type CHO-K1 cells and CHO
cell mutants deficient in all GAGs (pgsD-745) or HS (pgsD-677).
(A) Monolayers of each cell type were infected (60 min) with 100 to 200 BHK GFP-infectious units followed by three washes with VB, medium
replacement, and incubation for 8 to 12 h. Cells expressing GFP
were enumerated by fluorescence microscopy. Data are averages of four
infections of TR339 (hatched bars), TRSB (solid bars), and TRSB-R114
(cross-hatched bars). (B) Suspension binding assays (105
cpm added per reaction) were completed as described for BHK cells.
Results for TR339 (hatched bars), TRSB (solid bars), and TRSB-R114
(cross-hatched bars) are presented as percent cpm bound and
represent averages of two or three reactions.
|
|
In close correlation with infectivity, binding of TRSB and TRSB-R114 to
the GAG-deficient pgsA-745 cells was reduced by >90 and >95%,
respectively, compared with CHO-K1 cells (Fig. 6B). Binding of the
mutant viruses to the HS-deficient pgsD-677 cells was similarly
reduced; however, as indicated above, all RP were slightly more
infectious for these cells, suggesting that overproduction of CS may
increase infection efficiency at a postbinding step of virus entry. In
addition, binding to the mutant pgsD-677 cells was consistently lower
than to pgsA-745 cells, suggesting either that the pgsA-745 cells
produce a small amount of HS or that the overproduction of CS on
pgsD-677 cells inhibits virus binding. In the absence of GAGs or HS,
the amount of binding of TRSB and TRSB-R114 was reduced to the level of
TR339 binding. This indicates that interaction with HS accounts for
most, if not all, of the increased binding and infectivity of TRSB and
TRSB-R114 on normal cells relative to TR339.
The specific effect of HS-GAG deficiency on binding to pgsA-745 cells
was further shown by restoring GAG precursors to these cells. The
pgsA-745 cells cannot transfer xylose precursors to core proteins to
initiate GAG chain synthesis (18). The addition of xyloside
precursors increases production of GAGs in these cells to a level
similar to precursor-treated CHO-K1 cells and restores binding of the
HS binding-dependent basic fibroblast growth factor (17).
However, GAGs produced under these conditions are not covalently
attached to core proteins and may adhere to cell surfaces as free GAG
chains (49). Incubation of pgsA-745 cells in 1 mM p-nitrophenyl--D-galactoxylopyranoside for
48 h resulted in the restoration of TRSB binding to >90% of TRSB
binding to similarly treated CHO-K1 cells. However, TRSB-R114 binding
was restored only to ~20% of TRSB-R114 binding to similarly treated
CHO-K1 cells (data not shown). This result, in combination with the
heparinase digestion and binding saturation studies, suggests that TRSB
binds promiscuously to HS molecules on cell surfaces. In contrast, the majority of TRSB-R114 binding may be dependent on a subset of HS,
perhaps requiring attachment of these molecules to proteoglycan core
proteins. Separate control experiments demonstrated that, like BHK
cells, binding and infectivity of TRSB and TRSB-R114 (but not TR339) on
wild-type CHO-K1 cells were efficiently competed with soluble heparin.
In addition, CHO-K1 cells showed reductions in binding and infectivity
similar to BHK cells after digestion with heparinases (data not shown).
Direct virus binding to an HS analog.
To determine whether
TRSB and TRSB-R114 bind directly to HS structures, heparin-agarose and
BSA-agarose beads were used as cell surrogates in suspension binding
assays. Results shown in Table 2
demonstrate that both mutant viruses bound efficiently to
heparin-agarose beads, while TR339 did not. In contrast to cell binding
assays, the beads bound ~70% of TRSB and TRSB-R114 radioactivity added. The actual binding in these assays may have been
even greater, since there was some unavoidable loss of beads during
wash steps. None of the viruses bound appreciably to BSA-agarose beads
(Table 2), and binding of TRSB and TRSB-R114 to the heparin-agarose beads could be competed with soluble heparin but not soluble BSA or
CS-A (data not shown). These results taken together strongly indicate
that attachment to heparin-agarose beads results from a specific
virus-heparin interaction. The E2S1-R114 virus (Table 1) also attached
efficiently to heparin-agarose beads (Table 2), suggesting that the E2
Arg 114 mutation defines a separate locus (compared with E2 1) capable
of independently mediating HS attachment.
Passage of TR339 in BHK cells coselects for increased cell binding
and heparin interaction.
Mutation to efficient HS attachment is
the result of active selection pressure during Sindbis virus adaptation
to BHK cell growth. As with the other experiments reported here, the
TR339 stock (passage 0) consisted of culture fluids from cells
electroporated with in vitro transcripts of a full-length cDNA clone.
TR339 was passaged five times in BHK cells, followed by assay of the
attachment phenotype of virus obtained from each passage. Figure
7A shows increasing virus titer and
susceptibility to competition with soluble heparin (200 µg/ml) for
virus from passages 1 through 5. Between passage 1 and passage 3, virus
titer increased ~100-fold, concomitant with an increase in
susceptibility to heparin competition of from ~20 to >80%. No
further increase in either phenotype was noted after passage 3. For
this reason, virus equivalent to passage 3 was used for subsequent
analysis. Radiolabeled virus binding assays indicated that one
consequence of the adaptation of TR339 to BHK cells was a large
increase in binding to and specific infectivity for BHK cells (Fig.
7B). In fact, binding and infectivity of the passage 3 virus was
significantly greater than TRSB and similar to TRSB-R114 (Fig. 2 and
7B). The passage 3 virus also attached efficiently to heparin-agarose
beads, indicating that heparin binding and cell binding were covariant
phenotypes (Fig. 7C). The E1 and E2 glycoproteins of the passage 3 virus population were sequenced, and a single coding change from Glu to
Lys at E2 70 was found. This mutation was observed previously in our laboratory during BHK cell passage experiments (40, 54). It also is a constituent of most Sindbis virus AR339 laboratory strains, including Toto 50, which is effectively competed by soluble heparin. Similar to the effect of E2 Arg 114, E2 Lys 70 confers rapid
penetration of BHK cells when introduced into the TRSB (E2 Arg 1)
background and significantly attenuates virulence in neonatal mice
(40).
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FIG. 7.
Changes in titer, heparin competition, BHK cell binding,
and heparin-agarose bead binding phenotypes of TR339 after passage in
BHK cells. (A) BHK cell monolayers were infected at a multiplicity of
infection of 1 followed by incubation for 20 h, harvesting of
supernatants, and infection of new monolayers. This cycle was repeated
for a total of five passages. Hatched bars (left y axis)
indicate BHK cell titers for each of the five passages. The solid line
(right y axis) indicates change in inhibition of BHK cell
plaque-forming efficiency due to competition with soluble heparin (200 µg/ml). (B) Increases in BHK cell binding (solid bars) and specific
infectivity (hatched bars) of virus derived from the third passage,
compared to TR339 stock virus. (C) Increase in heparin-agarose bead
binding (solid bars) but not BSA-agarose bead binding (hatched bars) of
third-passage virus, compared to TR339 stock virus. *, binding of
either virus to BSA-agarose beads was <1% of added cpm.
|
|
| |
DISCUSSION |
HS as a Sindbis virus attachment receptor.
HS can serve as an
attachment receptor for Sindbis virus but contributes significantly to
binding and infection only by cell culture-adapted strains. While
infection with the AR339 consensus sequence virus, TR339, was
predominantly HS independent, four other cell culture-adapted strains,
each with mutations in the E2 gene, attached to cells through an
HS-dependent mechanism. These findings suggest that Sindbis virus
rapidly mutates to utilize HS during cell culture adaptation and that
binding to cell surface HS plays little or no role in interactions
between natural Sindbis virus isolates and cells in vivo. Our AR339
laboratory strain, TRSB, acquired a mutation conferring HS attachment
(Ser to Arg at E2 1) during single-step BHK cell adaptation prior to
cDNA cloning (40). Attachment of TRSB was significantly
increased relative to TR339 and was sensitive to both heparinase I and
heparinase III but was not saturable. When TRSB was subjected to
selection for rapid penetration of BHK cells, an additional mutation
conferring HS attachment arose at E2 114 (Ser to Arg [11,
47]). Attachment of this virus showed high affinity, was
saturable, and was sensitive only to heparinase III. The effect of E2
Arg 1 was independent of the residue at E1 72, as shown in control
binding and heparin competition experiments using E2S1 (Table 1).
Additionally, passage of TR339 in BHK cells selected for a Glu-to-Lys
mutation at E2 70 that conferred high-affinity attachment to BHK cells
and to heparin-agarose beads.
While it has been known for some time that herpesviruses, including
herpes simplex virus (73), human cytomegalovirus
(10), bovine herpesvirus (45), and pseudorabies
virus (41), attach to HS during in vitro infection, it has
only recently become apparent that a number of other viruses can use
this molecule for cell attachment. Recent publications have implicated
HS in the in vitro attachment of type O foot-and-mouth disease virus
(FMDV) (29, 55), HIV (48, 52), respiratory
syncytial virus (34), porcine reproductive and respiratory
syndrome virus (30), equine arteritis virus (1),
Dengue virus (8), adeno-associated virus (62), and vaccinia virus (9).
In the herpes simplex virus system, a protein that can mediate entry,
but not attachment, has been identified (43). This suggests
that utilization of GAG molecules in virus infection can result in a
two-step entry process in which interaction with the GAG molecule
increases the concentration of the virus ligand in the vicinity of its
entry receptor, thereby enhancing the overall efficiency of infection.
That this model may be generally applicable is supported by the studies
of Wickham et al. (72), who found that an HS binding
sequence introduced into the tip of the adenovirus fiber protein
greatly increased infectivity of the virus for cell types that did not
express a high-affinity receptor. Our data do not clearly indicate
whether infection of HS-dependent Sindbis virus occurs in one or
several steps. It is clear that all of the viruses tested maintained a
low level of infectivity for cells lacking HS. This suggests that
infection can proceed without efficient binding and may reflect the
presence of an additional receptor(s).
Our results closely parallel those of Sa-Carvalho et al.
(55) with type O FMDV. In their studies, passage in culture
was associated with changes to positive amino acids at several
positions in the capsid protein and acquisition of heparin-HS
attachment. The coselection for rapid penetration of BHK cells,
mutation in E2, and ability to attach to HS analogs also has been
documented for VEE in our laboratory (2). Thus, adaptation
to HS attachment may represent a common cell culture-adaptive mechanism
among alphaviruses. Our results and those of Sa-Carvalho et al. may
suggest further that adaptation to HS binding in cultured cells could
occur in multiple virus families. Therefore, studies of both virus
attachment to cultured cells and virus pathogenesis in vivo could be
compromised by the presence of such adaptive mutations embedded in the
genetic background of "wild-type" laboratory strains or cloned
viruses derived from them.
The relationship of our results to previous studies that have
identified different proteins as putative attachment receptors for
Sindbis virus on different cells (e.g., references 16,
37, and 69-71) is not clear. Cell surface
chains of HS are generally attached to proteoglycan core proteins
(31). Moreover, HS exhibits structural heterogeneity between
cell types and is presented in different contexts on different cell
types (e.g., through attachment to different core proteins or in
different protein-proteoglycan-GAG complexes [4, 28,
31]). The heterogeneous expression of HS and GAG chains on
different cell types raises the possibility for virus interaction with
different HS-protein structures on different cells and that
cell-type-specific GAG or proteoglycan core protein expression could
regulate virus binding (3, 56). It is unknown whether any of
the putative Sindbis virus receptor proteins are full-time or
facultative proteoglycans or whether any of these are intimately
complexed with proteoglycan-HS chains on cell surfaces. However, a
major conclusion from the results presented here is that single amino
acid differences between AR339 strains can dramatically alter cell
interaction properties. Therefore, it is quite possible that
unidentified structural glycoprotein differences between Sindbis virus
laboratory strains account for the conflicting results from different
laboratories.
Domains involved in HS attachment.
As defined by attachment to
BHK cells and heparin-agarose beads, mutation to a positive charge at
E2 1, E2 70, or E2 114 can independently increase attachment affinity,
suggesting that these mutations may define three HS interaction domains
on the glycoprotein spike. Most protein-GAG binding is mediated by
electrostatic interaction between clusters of basic amino acids
arranged in a three-dimensional array on the ligand and a concentrated
negative charge on the sulfated polysaccharide chain (reviewed in
reference 31). In an analysis similar to that
undertaken by Flynn and Ryan with pseudorabies virus protein gC
(20), we have scanned the PE2 and E1 glycoproteins for
sequences that conform to the XBBXBX and XBBBXXBBX (B, basic; X, any
amino acid) heparin interaction consensus motifs identified by Cardin
and Weintraub (7). The activity of these consensus sequences
is not dependent upon orientation (20). While no close
matches were found in E1, three close matches were found in PE2 (Fig.
8).
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FIG. 8.
Identification of heparin interaction consensus
sequences (from reference 7) in the PE2
glycoprotein. Matches (XBBXBX or XBXBBX) are indicated in boldface type
within the glycoprotein sequence (residue numbers of the amino-terminal
consensus match residues are in boldface type below the sequence). E2
1, E2 70, and E2 114 mutations are indicated in boldface type above the
glycoprotein sequence. The site of furin protease cleavage of PE2 is
indicated by the arrow. Sequence matches adjacent to the transmembrane
domain have not been included.
|
|
One exact match comprised the XBXBBX furin protease cleavage site of
PE2 (14, 42; reviewed in reference
32), which is immediately adjacent to the E2 Arg 1 mutation present in both TRSB and TRSB-R114. Heidner et al.
(25) have shown that substitution of Arg, Ile, Val, or Asn
for Ser at E2 1 reduces PE2 cleavage efficiency, resulting in mature
virus particles that contain various amounts of PE2 and its associated
furin cleavage-heparin binding site. Appropriate mutagenesis
experiments are currently in progress to test the hypothesis that BHK
cell binding is increased as a function of PE2-furin cleavage site
content in virions. Interestingly, the portion of the HIV V3 loop
thought to interact with HS (52) contains a cluster of
positively charged amino acid residues comprising an occult furin
protease cleavage site that has been proposed to be cleaved during HIV
entry of cells (44).
The positively charged mutations at E2 70 and E2 114 were not part of,
or adjacent to, heparin interaction sequences. Positive charge
mutations in the E2 glycoprotein could increase HS binding (i) by
participating in conformationally determined HS binding sites similar
to those proposed for type O strains of FMDV (55); (ii) by
decreasing the efficiency of PE2 cleavage during virus maturation,
thereby increasing the virion content of uncleaved PE2 containing the
heparin interaction consensus motif; or (iii) by altering the
conformation of virus glycoprotein spikes, resulting in exposure of
preexisting HS interaction motifs.
In contrast to TRSB, the majority of binding of TRSB-R114 (mediated by
E2 Arg 114) involves interaction with a specific HS structure, as shown
by binding saturation, xyloside precursor reconstitution, and
heparinase digestion experiments. This is consistent with studies
indicating that protein-HS interactions can show significant HS
sequence and sulfation specificity (e.g., references
19 and 38). Further study will be
required to elucidate specific HS structures involved in interaction
with different Sindbis virus mutants.
Previous studies had indicated that virus attachment to cells was not
increased by the E2 Arg 114 mutation (47). Our results may
differ from those for two reasons. First, the criterion for attachment
in assays conducted by Olmsted et al. involved resistance to removal by
washing of plaque-forming virus bound to cell monolayers, as opposed to
the binding of radiolabeled virus particles to cell suspensions, as
reported here. We have found that while these viruses exhibit large
differences in the amount of virus that attaches to cells, once virus
particles are attached they appear to be equally resistant to
dislodging by washing (data not shown). Secondly, viruses in the
previous assays were purified on potassium tartrate gradients. We have
found that this purification technique reduces the infectivity and
binding of TRSB-R114 preparations severalfold, perhaps due to the
detrimental effects of high ionic strength on virus particles. This
phenomenon also has been observed with a VEE E2 glycoprotein mutant
(12).
Relationship of HS attachment to neonatal mouse virulence.
Perhaps most interesting is that the primarily HS-independent
interaction of TR339 with cells is not saturable and is barely measurable in a variety of cell binding assays. This result is independent of cell type or temperature, is obtained when binding assays are done with cell suspensions or monolayers, and is consistent in both positive and subtractive binding assays (data not shown). Nevertheless, TR339 is the most virulent of the tested viruses in vivo
(these studies; also references 33 and
65), suggesting that a weak, primarily
HS-independent attachment may represent an important component of
alphavirus entry in nature. TR339, TRSB, and TRSB-R114 exhibit
indistinguishable tissue tropisms in neonatal mice, differing only by
rate and extent of spread (33, 65). Therefore, the
high-affinity attachment of Sindbis virus laboratory strains, as
typically measured in in vitro binding assays, may simply be a
consequence of adaptation to cultured cells and does not determine
tissue tropism in neonatal mice. However, this assertion is tempered by
the possibility that virus attachment in the context of an intact
organismal host may be very different from that measured in cell
binding assays. For instance, in a number of virus systems, particles
may require activation by host factors for full infectivity in
vivo (reviewed in reference 32).
In separate studies (33, 65), it has been shown that
attenuation of TRSB and TRSB-R114 coincides with lower virus titers in
sera and brains of infected mice. Therefore, we suggest that the HS
attachment phenotype results in a general reduction in virus
replication competence in vivo. A similar hypothesis was recently
proposed by Sa-Carvalho et al. for FMDV (55), where tissue
culture-adapted type O strains that had acquired the ability to attach
to HS were greatly reduced in animal virulence. GAGs, and specifically
HS molecules, comprise ubiquitous cell surface structures and also are
abundant components of extracellular matrices and basal laminae
(reviewed in references 4, 28, 31, and 64). Consequently, it is possible that HS attachment
results in virus binding to unproductive receptor structures in vivo. In addition, HS attachment may affect virus replication competence by
interfering with virus particle release from cells. We have observed
that virus particle production from individual infected BHK cells is
inversely correlated with HS attachment efficiency (data not shown). We
are currently investigating whether a combination of inappropriate
receptor targeting and reduced particle release may determine neonatal
mouse virulence of Sindbis viruses that have adapted to attach to HS.
| |
ACKNOWLEDGMENTS |
We thank Peter Mason for several stimulating discussions. We also
thank Nancy Davis for critical reading of the manuscript. Cherice
Connor, Michael Hawley, and Travis Knott provided excellent technical
assistance.
This work was supported by Public Health Service-NIH grant AI22186.
W.B.K. was supported by an NIH Predoctoral Traineeship (T32 AI07419)
and by the U.S. Army Research Office (DAAH04-95-1-0224).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology and Immunology, University of North Carolina at Chapel
Hill, School of Medicine, Chapel Hill, NC 27599-7290. Phone: (919)
966-4026. Fax: (919) 962-8103. E-mail: wklimstr{at}med.unc.edu.
| |
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Abstract
Introduction
