![[Feedback]](/icons/banner/feedbackACT.gif)
![[For Subscribers]](/icons/banner/subscriberACT.gif)
![[Archive]](/icons/banner/archiveACT.gif)
![[Search]](/icons/banner/searchACT.gif)
![[Contents]](/icons/banner/tocACT.gif)
Previous Article | Next Article 
Journal of Virology, August 1999, p. 6370-6379, Vol. 73, No. 8
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
The CC-Chemokine RANTES Increases the Attachment of
Human Immunodeficiency Virus Type 1 to Target Cells via
Glycosaminoglycans and Also Activates a Signal Transduction Pathway
That Enhances Viral Infectivity
Alexandra
Trkola,1,*
Cynthia
Gordon,1,2
Jamie
Matthews,1
Elizabeth
Maxwell,1
Tom
Ketas,1
Lloyd
Czaplewski,3
Amanda E. I.
Proudfoot,4 and
John
P.
Moore1,5
The Aaron Diamond AIDS Research
Center,1 The Rockefeller
University,5 and Department of
Pathology, New York University School of
Medicine,2 New York, New York; British
Biotech Pharmaceuticals Ltd., Oxford, United
Kingdom3; and Serono Pharmaceutical
Research Institute, Geneva, Switzerland4
Received 2 March 1999/Accepted 28 April 1999
 |
ABSTRACT |
We have studied the mechanisms by which the CC-chemokine RANTES can
enhance the infectivities of human immunodeficiency virus type 1 (HIV-1) and other enveloped viruses, when present at concentrations in
excess of 500 ng/ml in vitro. Understanding the underlying mechanisms
might throw light on fundamental processes of viral infection, in
particular for HIV-1. Our principal findings are twofold: firstly, that
oligomers of RANTES can cross-link enveloped viruses, including HIV-1,
to cells via glycosaminoglycans (GAGs) present on the membranes of both
virions and cells; secondly, that oligomers of RANTES interact with
cell-surface GAGs to transduce a herbimycin A-sensitive signal which,
over a period of several hours, renders the cells more permissive to
infection by several viruses, including HIV-1. The enhancement
mechanisms require that RANTES oligomerize either in solution or
following binding to GAGs, since no viral infectivity enhancement is
observed with a mutant form of the RANTES molecule that contains a
single-amino-acid change (glutamic acid to serine at position 66) which
abrogates oligomerization.
| |
INTRODUCTION |
Infection of target cells by human
immunodeficiency virus type 1 (HIV-1) is mediated by interactions of
the viral envelope glycoproteins with CD4 and a coreceptor
(32). Among the latter, the CC-chemokine receptor CCR5 and
the CXC-chemokine receptor CXCR4 are the most physiologically important
(8, 27, 56). The cognate chemokines can influence HIV-1
infection in several ways in vitro, the most commonly observed being
inhibition of virus entry because of competition between the virus and
the chemokine for binding sites on the same receptor (5, 17, 22,
29, 64, 66, 80, 84, 85, 94). Receptor down-regulation in response
to chemokine binding and signaling can also interfere with virus entry
by reducing the density of available coreceptors on the cell surface
(2, 4, 51). However, CC-chemokines have also been reported
to enhance HIV-1 infection of various cells in vitro (26, 36, 45,
58, 78).
Previously, we showed that the CC-chemokine RANTES could enhance HIV-1
infection of target cells in a manner that was independent of CD4 and
any known coreceptor and even independent of the route of virus entry
(36). Other CC-chemokines, such as macrophage-inhibitory protein (MIP)-1
and MIP-1
, did not have this effect
(36). The extent of infectivity enhancement caused by RANTES
was significant: in excess of 100-fold under some conditions. Two
components of the enhancement mechanism were noted: one was apparent
when the target cells were preincubated for several hours with RANTES
prior to the addition of virus, and the other was evident when RANTES was added simultaneously with the virus (36). Here, we
further analyze how RANTES can increase viral infectivity. We conclude that a major mechanism of infectivity enhancement is caused by the
cross-linking of virions to the cell surface by oligomers of RANTES.
These oligomers form after binding to glycosaminoglycans (GAGs), such
as heparan sulfate, on both the virion and cell membranes. Of note is
the fact that RANTES variants that do not oligomerize do not enhance
viral infectivity (24). A second mechanism of viral
infectivity enhancement arises from the prolonged interaction of RANTES
oligomers with cell surface GAGs, which activates a herbimycin
A-sensitive, tyrosine-kinase-dependent signal transduction pathway.
| |
MATERIALS AND METHODS |
Cells.
HeLa-CD4 cells were provided by David Kabat
(47). They were maintained in Dulbecco's minimal essential
medium containing 10% fetal calf serum (FCS), glutamine, and
antibiotics and split twice a week. Chinese hamster ovary (CHO)-K1
cells, heparan sulfate-mutant CHO cells (psgD-677 cells), and
chondroitin sulfate-mutant CHO cells (psgA-745 cells) were all obtained
from the American Type Culture Collection (Rockville, Md.) (30,
31, 49). These lines were maintained in F12K nutrient mixture
(Kaighn's modification) supplemented with 10% FCS.
Chemokines.
Human MIP-1 was purchased from R&D Systems
Inc. (Minneapolis, Minn.). Recombinant human RANTES was produced in the
bacterial host Escherichia coli as previously described
(75). AOP-RANTES was derived from RANTES, as reported
elsewhere (80). Rat RANTES was purchased from Peprotech
Inc., Rockville, N.J. RANTES(3-68) was made by total peptide synthesis
and provided by RMF DICTAGENE, Epalinges, Switzerland. The RANTES(3-68)
molecule has the wild-type RANTES sequence but lacks the two N-terminal
amino acids, serine and proline (65, 74). Its N-terminal
sequence is therefore YSSDTPP... . The mutated, nonaggregating
RANTES molecule, BB-10520 RANTES, was made at British Biotechnology
Ltd. (Oxford, United Kingdom) (24). It has the wild-type
RANTES sequence except for a single-amino-acid change: glutamic acid to
serine at residue 66 (E66>S). The RANTES E66>S gene was expressed and
secreted from the yeast Pichia pastoris at high yield. The
purified protein, designated BB-10520 RANTES, had undergone truncation
of the two N-terminal amino acids so that its N-terminal sequence was
YSSDTPP... (24). This molecule and RANTES(3-68) are
therefore identical except for the E66>S substitution.
Viruses.
Env-pseudotyped, luciferase-expressing reporter
viruses were produced by the calcium phosphate technique (15, 23,
29). Thus, 293T cells were cotransfected with the
envelope-deficient HIV-1 NL4-3 construct, pNL-Luc, and with a pSV
vector expressing viral envelope glycoproteins (15, 23, 29).
The pNL-Luc virus carries the luciferase reporter gene; the pSV vectors
express envelope glycoproteins derived from HIV-1, amphotropic murine leukemia virus (MuLV), or vesicular stomatitis virus (VSV). The Env-pseudotyped viruses are designated HIV-1MuLV,
HIV-1VSV, HIV-1HXB2, etc., with the subscript
representing the pseudotyped env gene.
Viral infection assay with luciferase readout.
The extent of
HIV-1 entry was determined by using a single-cycle infection assay
(15, 23, 29). One day before infection, cells were seeded at
a density of 104 per well of a 96-well tissue culture plate
(HeLa-CD4) or at 5 × 104 per well of a 24-well tissue
culture plate (CHO-K1, psgD-677, and psgA-745). After 24 h, the
cells were infected with Env-pseudotyped HIV-1 (e.g.,
HIV-1MuLV) for 2 h at 37°C in the presence or
absence of chemokines in a total infection volume of 100 (HeLa-CD4) or 500 (CHO-K1, psgD-677, and psgA-745) µl. The amount of input virus was determined by measuring its HIV-1 p24 antigen content. Unbound virus was removed by washing, and fresh medium lacking chemokines was
added to the cells. Seventy-two hours postinfection, the cells were
washed once with phosphate-buffered saline (PBS) and lysed in 50 µl
of Reporter Lysis Buffer (Promega Inc.). The luciferase activity in a
mixture of 100 µl of luciferase substrate (Promega) and 30 µl of
cell lysate was measured in relative light units (RLU) with a DYNEX MLX
microplate luminometer. Statistical analyses were performed by an
unpaired Student t test (95% confidence interval; two
tailed) to estimate significance.
Cell-cell fusion assay.
In the cell-cell fusion assay, a
luciferase reporter gene is transactivated when cell-cell fusion occurs
(28, 61). The T7-luciferase system and the recombinant
vaccinia viruses were provided by Bernard Moss and Robert Doms. Two
days before a fusion experiment, the target HeLa-CD4 cells were
transfected with the T7-luciferase construct by using Lipofectin (Gibco
BRL-Life Technologies), according to the manufacturer's instructions.
The next day, 4 × 104 lipofected target cells were
seeded into each well of a 96-well plate in the presence or absence of
chemokines and then incubated for 24 h at 37°C. One day before
the experiment, the T7 RNA polymerase and Env proteins were introduced
into the effector HeLa cells by infection for 2.5 h with
recombinant vaccinia viruses at a multiplicity of infection of 10 in
Dulbecco's minimal essential medium supplemented with 2.5% FCS. The
cells were then trypsinized, washed in PBS, and incubated overnight in
medium containing rifampin (Sigma Chemicals; 100 µg/ml) at room
temperature. For the fusion experiment, the effector cells were washed
in PBS and resuspended in medium containing rifampin and cytosine
-D-arabinofuranoside (10 µM; Sigma Chemicals). The
effector cells (8 × 104), with or without chemokine,
were added to each well. Fusion took place for 2.5 h at 37°C,
and then the luciferase activity in cell lysates was determined with
the Promega system described above.
RANTES oligomerization assay.
The ability of RANTES and
RANTES derivatives to oligomerize was assayed on heparin beads as
described previously (37). Heparin-Sepharose CL-6B beads
(Pharmacia; 0.5 µg/ml) were shaken with 0.23 nM
125I-labeled RANTES or RANTES derivative (each custom
labeled by Amersham International, Little Chalfont, United Kingdom) in
the presence of increasing concentrations of unlabeled protein in 100 µl of binding buffer (50 mM HEPES, pH 7.4, containing 5 mM MgCl2, 1 mM CaCl2, 150 mM NaCl, and 0.5%
bovine serum albumin [BSA]) for 4 h at room temperature. The
beads were then washed three times with 200 µl of binding buffer
adjusted to contain 500 mM NaCl. The bound radioactivity was measured
in a MicroWallac beta counter, and the data were plotted as described
elsewhere (37).
Virus-cell adsorption assay.
The virus-cell adsorption assay
was performed as described previously (54, 88). Briefly,
sucrose gradient-purified HIV-1IIIB particles grown on H9
cells and sucrose gradient-purified control microvesicles from
uninfected H9 cells were provided by Larry Arthur (Frederick Cancer
Research and Development Center, Frederick, Md.) (9). The
two preparations were standardized for total protein content. For the
binding reactions, 1 µg of protein was added to 2 × 105 target cells. These were either from the CD4-positive,
T-lymphoid cell line A3.01 or the related CD4-negative A2.01 line
(54, 88).
For experiments in which RANTES was added to target cells
simultaneously with virions, 2 × 105 cells were
incubated for 2 h on ice with virions (or control microvesicles)
and the anti-HLA-DR antibody G46-6 (0.5 µg/ml; Pharmingen) in the
presence or absence of various concentrations of RANTES or BB-10520
RANTES. The cells were washed three times with ice-cold binding buffer
(Dulbecco's PBS containing 1% BSA and 0.1% sodium azide
[D-PBS-BSA]), and then bound particles were detected with
goat-anti-mouse-phycoerythrin secondary antibody (DAKO Diagnostics) and
quantitated by fluorescence-activated cell sorter (FACS).
For experiments in which target cells were pretreated with RANTES, the
cells (106/ml in culture medium) were incubated for 24 h at 37°C in the presence or absence of various concentrations of
RANTES or BB-10520 RANTES. After being washed in ice-cold binding
buffer, 2 × 105 cells were incubated for 2 h on
ice with virions or microvesicles and the G46-6 antibody (0.5 µg/ml).
The cells were then washed three times with binding buffer before
detection and quantitation of bound particles as described above.
Virion binding to immobilized RANTES.
Two methods were used
for virion binding. In the first, 4 × 107 magnetic
beads coated with anti-murine immunoglobulin G (Dynal Inc.) were
reacted with 5 µg of monoclonal anti-RANTES antibody (MAB-278; R&D
Systems Inc.)/ml for 30 min at 37°C. Unbound antibody was removed by
washing with D-PBS-BSA, and then the beads were incubated with 10 µg
of RANTES or BB-10520 RANTES/ml for 30 min at 37°C in the presence or
absence of chondroitin sulfate. Unbound chemokine was washed away, and
the beads were incubated with HIV-1MuLV (250 ng of HIV-1
p24 antigen per sample) for 2 h at 37°C. Unbound virus was
washed away and the beads were pelleted, resuspended, and analyzed for
their p24 antigen content.
In the second assay, 6.7 × 107 streptavidin-coated
magnetic beads (Dynal Inc.) were reacted with 5 µg of biotinylated
polyclonal anti-RANTES or anti-MIP-1 antibodies (BAF 278 and BAF
271; R&D Systems Inc.)/ml for 30 min at 37°C. The rest of the
procedure was as described above, except that the HIV-1MuLV
input was 500 ng of HIV-1 p24 antigen per sample.
| |
RESULTS |
Enhancement of viral infectivity by RANTES is dependent upon the
RANTES sequence.
We have demonstrated previously that RANTES, but
not other CC-chemokines such as MIP-1 and MIP-1, is able to
enhance viral infectivity independently of the envelope glycoproteins
and the route used by the test viruses to enter target cells
(36). To gain further insight into the underlying
mechanisms, we tested several different sequence variants of the RANTES
molecule. The origins and properties of these RANTES variants are
described in Materials and Methods. To eliminate any direct influences
of RANTES on the receptor used for virus entry, we used as a test virus
MuLV envelope glycoprotein pseudotypes of HIV-1
(HIV-1MuLV); the entry of HIV-1MuLV occurs via
a plasma membrane phosphate transporter which is not known to be a
RANTES receptor (53). As target cells, we used the HeLa-CD4
cell line, since RANTES enhances HIV-1MuLV infection of
HeLa cells just as it does HIV-1 infection via CD4 and the CCR5 or
CXCR4 coreceptors (36).
Based on our previous observations, RANTES enhancement of
HIV-1MuLV infectivity was studied in two ways
(36). The target cells were pretreated with CC-chemokines
for 24 h and then washed before the addition of virus for 2 h
in the absence of CC-chemokine (Fig. 1a);
alternatively, CC-chemokines were added to the cells for a 2-h period,
simultaneously with the viral inoculum, and then washed away (Fig. 1b).
View larger version (10K):
[in this window]
[in a new window]
|
FIG. 1.
Effect of RANTES and RANTES variants on infection with
MuLV pseudotypes. (a) CC-chemokines at the indicated concentrations
were added to HeLa-CD4 cells for 24 h and then washed from the
cells immediately before infection was initiated by the addition of
HIV-1MuLV (3.2 ng of HIV-1 p24 antigen) for 2 h. No
CC-chemokines were present during the infection period or subsequently.
(b) CC-chemokines were added during the 2-h viral infection period but
were not present before or after that time. In all experiments, unbound
virus and CC-chemokines (if present) were washed away after the
infection period and the cultures were replenished with fresh medium
without CC-chemokine. The extent of viral infection was measured by
determination of luciferase expression in quadruplicate cultures on day
3 postinfection; the data (mean ± standard deviation) are
presented as percentages of control (no chemokine = 100%). The
chemokines used were RANTES ( ), RANTES(3-68) ( ), BB-10520 RANTES
( ), and MIP-1 ( ). The untreated control values were 5,063 ± 948 RLU for both panels a and b. To test for statistical
significance, we compared the data sets obtained in the presence and
absence of CC-chemokine by the unpaired Student t test (95%
confidence interval; two-tailed P values). Treatment of the
cells for 24 h with 10, 5, and 1 µg of RANTES/ml (a) caused a
significant increase in HIV-1MuLV infection compared to the
untreated control (P < 0.0001). A significant increase
in HIV-1MuLV infection was also caused by 10 µg of
RANTES(3-68)/ml (P = 0.001) but not by MIP-1
(P = 0.299). Treatment with BB-10520 RANTES
significantly decreased HIV-1MuLV infection (P < 0.001). In the experiment shown in panel b, all four compounds
significantly increased HIV-1MuLV infection; even the
moderate increases observed with BB-10520 RANTES and MIP-1 at 10 µg/ml achieved statistical significance (P < 0.001
and P = 0.011, respectively).
|
|
As was found previously, RANTES but not MIP-1 substantially enhanced
HIV-1MuLV infectivity in a dose-dependent manner, whether it was added to the target cells 24 h prior to the virus (Fig. 1a)
or simultaneously with the virus (Fig. 1b) (36).
Significant, but somewhat reduced, infectivity enhancements were also
observed with RANTES(3-68), a variant of RANTES that is N-terminally
truncated by two residues (Fig. 1). In contrast, BB-10520 RANTES, which differs from the conventional RANTES molecule at only a single position
(E66>S) and by a two-residue truncation at the N terminus (24), caused a modest decrease in HIV-1MuLV
infectivity when added to the cells 24 h prior to the virus (Fig.
1a). Furthermore, BB-10520 RANTES stimulated only a very slight
increase in infectivity when added at the highest concentration tested
(10 µg/ml) simultaneously with HIV-1MuLV (Fig. 1b).
Clearly, whether viral infectivity enhancement occurs is a function of
the RANTES sequence, which presumably affects an important structural
feature of this molecule. Of note is the fact that AOP-RANTES and rat
RANTES both behave like the wild-type human RANTES molecule in that
they also enhance viral infectivity (references 24
and 36 and data not shown). Each of these molecules,
and also RANTES(3-68), is identical to wild-type human RANTES at
residue 66, but each differs from BB-10520 RANTES at this position. The
two-residue N-terminal truncation of BB-10520 RANTES is not responsible
for its inability to enhance viral infectivity, since RANTES(3-68) has
the same truncation yet still causes infectivity enhancement (Fig. 1).
RANTES promotes virion adsorption to target cells.
The
experiments described above (Fig. 1a), taken together with our previous
findings (36), show that RANTES causes a significant increase in the infectivity of cell-free virus when it is present during the virus-cell adsorption phase of the viral life cycle. One
explanation of this would be that RANTES promotes virion binding to the
cells. To test this directly, we measured the attachment of
HIV-1IIIB to target cells (Fig.
2), using an assay developed by Mandor,
Ugolini, and colleagues (54, 88). Virions grown in cells
expressing HLA-DR (e.g., H9 cells) incorporate this protein into their
membranes on budding from the cell membrane. The virions are then added
to cells that do not express HLA-DR (e.g., A2.01 or A3.01 cells), and
bound HLA-DR (i.e., virion membrane derived) is detected by FACS, using
an anti-HLA-DR antibody. Cells that grow in suspension were used for
this assay, to avoid damage to the membrane composition of adherent
cells when they are detached for FACS analysis. By using CEM.NKR cells
that are closely related to A3.01 cells, we have confirmed that RANTES
causes viral infectivity enhancement in T cells which grow in
suspension (data not shown).
View larger version (29K):
[in this window]
[in a new window]
|
FIG. 2.
RANTES promotes virion adsorption to target cells. (a)
A3.01 cells were incubated for 2 h on ice with preparations
containing HIV-1IIIB virions (IIIB/H9 vesicles) or control
microvesicles (H9 vesicles) in the presence of the indicated
concentrations of RANTES (hatched bars) or BB-10520 RANTES (shaded
bars) or with no CC-chemokine (solid bars). (b) A3.01 cells were
treated for 24 h at 37°C with RANTES, BB-10520 RANTES, or no
CC-chemokine, as described above. IIIB/H9 vesicles or control H9
vesicles were subsequently added for 2 h on ice in the absence of
CC-chemokine. In both panels, cell-bound particles were detected by
FACS after HLA-DR monoclonal antibody staining. The values shown are
the percentages of positive cells that were gated.
|
|
Because cells produce small vesicles derived from cell membranes that
are of a size similar to that of virions, it is necessary to control
for the binding of these vesicles to target cells (9, 35).
Consequently, we used sucrose gradient-purified preparations from both
HIV-1IIIB-infected and uninfected H9 cells, designated IIIB/H9 vesicles and H9 vesicles, respectively. The former contain virions and microvesicles; the latter contain only microvesicles.
The binding of virions and microvesicles to CD4-positive A3.01 cells
was measured in the presence and absence of RANTES and BB-10520 RANTES
(Fig. 2). In one set of experiments, we mimicked what happens when
RANTES and virions are added simultaneously to target cells in
infectivity assays (Fig. 1b and 2a); in a second set, we treated the
cells for 24 h with the RANTES molecules before adding virions in
the absence of chemokine, again mimicking what happens in some
infectivity assays (Fig. 1a and 2b).
We could detect the binding to A3.01 cells of HIV-1IIIB
virions (IIIB/H9 vesicles) and, to a lesser extent, of the control microvesicles (H9 vesicles) (Fig. 2). The simultaneous addition of
RANTES (5 µg/ml) caused a substantial increase in the number of A3.01
cells to which virions or microvesicles were attached. The effect of
RANTES was greater with the virion-containing preparation than with the
microvesicles, especially at a RANTES concentration of 1 µg/ml (Fig.
2a). In contrast, BB-10520 RANTES only slightly increased the number of
cells that had virions attached and only at the highest concentration
tested (5 µg/ml). BB-10520 RANTES had no effect on microvesicle
attachment (Fig. 2a). Furthermore, when virion attachment was
quantified by measuring the median fluorescence intensity levels, as
opposed to the percentage of fluorescence-positive cells, BB-10520
RANTES caused no increase whereas the same concentration of RANTES
raised the median fluorescence intensity by 20-fold (data not shown). A
similar pattern of results was found when A3.01 cells were treated with
the CC-chemokines for 24 h before the addition of virions or
microvesicles (Fig. 2b). RANTES, but not BB-10520 RANTES, pretreatment
caused an increase in the attachment of IIIB/H9 vesicles and, to a
lesser extent, of H9 vesicles, although only at the highest
concentration tested (5 µg/ml).
Analogous experiments were performed with CD4-negative A2.01 cells. In
the absence of RANTES, no binding of either the IIIB/H9 virions or the
control H9 vesicles was detectable (data not shown). This is consistent
with previous observations that CD4 is required on the target cells for
specific, stable virus attachment in this assay (54, 88).
However, RANTES, either added simultaneously with the virions or used
to pretreat the cells, caused a large increase in the binding of both
virions and microvesicles to the A2.01 cells (data not shown). These
effects of RANTES were not mimicked by BB-10520 RANTES (data not
shown). Thus, RANTES can promote the attachment of virions and cell
membrane-derived vesicles to target cells in a CD4-independent manner.
RANTES binds to virions.
One mechanism by which RANTES could
promote virus-cell attachment would be for it to bind simultaneously to
both virions and cells, cross-linking the former to the latter. It is
well established that RANTES binds to cell surfaces via multiple
receptors, including both classical chemokine receptors (73,
92) and GAGs (10, 37, 66, 89). To test whether RANTES
can also bind to virions, we used two assays. In the first, we attached
RANTES to magnetic beads via indirectly adsorbed anti-RANTES antibodies
and then added HIV-1MuLV and determined the extent of
virion binding by measuring how much HIV-1 p24 antigen was associated
with the beads. There was significantly greater binding of virions to
RANTES-coated beads than to control beads lacking RANTES (Fig.
3a). Virion attachment to the
RANTES-coated beads was inhibited by the soluble GAG chondroitin sulfate, suggesting that the process was GAG mediated (see Fig. 6). The
BB-10520 RANTES molecule did not promote significant virion attachment
to beads (Fig. 3a), despite being able to recognize the anti-RANTES
monoclonal antibody coating the beads (data not shown). In a similar
assay, RANTES and MIP-1 were immobilized on streptavidin-coated
beads via biotinylated polyclonal antibodies. The amount of virus
captured on the beads was 20-fold greater in the presence of RANTES
than when MIP-1 was used (Fig. 3b), which is consistent with the
ability of RANTES, but neither MIP-1 nor MIP-1, to enhance viral
infectivity (36) (Fig. 1).
View larger version (17K):
[in this window]
[in a new window]
|
FIG. 3.
RANTES binds to virions. (a) RANTES was captured on
magnetic beads via an anti-murine immunoglobulin G antibody and a
murine anti-RANTES antibody (solid bars). HIV-1MuLV virions
were then reacted with the beads for 2 h in the presence or
absence of the indicated concentrations of soluble chondroitin sulfate
(CS). The use of BB-10520 RANTES is indicated by the shaded bar, and
the background binding in the absence of RANTES is represented by an
open bar. The extent of virion capture was measured by p24 antigen
determination and is expressed as the percentage of that achieved in
the presence of RANTES but absence of CS (6.5 ng/sample, defined as
100%). The data shown are from one of two to three independent
experiments. (b) Biotin-labeled antibodies to CC-chemokines were
immobilized on streptavidin-coated magnetic beads and incubated with
the appropriate CC-chemokines (solid bars, RANTES; shaded bars,
MIP-1) before the addition of HIV-1MuLV virions for
2 h. The extent of virion capture was measured by p24 antigen
determination. The data shown are from one of three independent
experiments.
|
|
RANTES forms oligomers induced by binding to GAGs.
The results
discussed above demonstrate that RANTES molecules which enhance viral
infectivity promote virion attachment to cells and also bind to
virions. In contrast, a RANTES variant (BB-10520 RANTES) that does not
enhance virus-cell attachment also does not cause virus-cell binding
and is not virion reactive. This correlation suggests that RANTES
cross-links viruses to cells by binding simultaneously to receptors
present on both the virion and cell membranes. But does a single RANTES
molecule cause cross-linking or must RANTES oligomerize? To test this,
we measured the extent to which RANTES and its variants can
oligomerize, using an assay in which the RANTES molecules that bind to
immobilized heparin, a typical GAG, are quantitated (Fig.
4).
View larger version (15K):
[in this window]
[in a new window]
|
FIG. 4.
RANTES and AOP-RANTES, but not BB-10520 RANTES,
multimerize upon binding to heparin. Radiolabeled RANTES (),
AOP-RANTES (), or BB-10520 RANTES () was incubated with
heparin-Sepharose beads in the presence of increasing amounts of the
same, unlabeled chemokine, and the amount of radiolabeled chemokine
bound to the beads was determined. The values shown are the means (± standard deviations) from five independent experiments.
|
|
RANTES and AOP-RANTES clearly form oligomers in this assay at
concentrations above 100 ng/ml, whereas BB-10520 RANTES only dimerizes
at similar concentrations (Fig. 4). The single-amino-acid change
(E66>S) introduced into the RANTES molecule to make BB-10520 RANTES
therefore prevents oligomerization, an observation also made by others
(24). The extent of the RANTES multimerization shown here is
greater than that previously described (37). This may be due
to a variation in bivalent cation concentration in the assay buffers
used in the present and earlier sets of experiments. We have noticed
that EDTA completely abolishes the oligomerization of RANTES,
indicating that the process is cation dependent (data not shown).
Qualitatively, there is a correlation between the abilities of
RANTES-based molecules to oligomerize and to enhance viral infectivity
(Fig. 1 and 4). Quantitatively, the concentration range at which RANTES
binding to immobilized heparin occurs should not be precisely compared
with what happens when RANTES binds to the cell surface, because the
efficiency of the latter varies with the cell surface GAG composition
and concentration. Overall, the results shown in Fig. 4 are consistent
with the hypothesis that RANTES oligomers attach simultaneously to both
virions and cells, cross-linking one to the other and promoting viral
infectivity by increasing the amount of cell-bound virus.
GAGs are involved in the attachment of virions to cells via
RANTES.
To what receptor(s) on virions and cells do oligomers of
RANTES bind? We reported previously that we could not identify a seven-transmembrane-spanning receptor common to all the human and
nonhuman cell lines in which RANTES enhanced viral infectivity (36). These negative findings, together with knowledge of
the RANTES concentration range over which enhancement occurred, focused our attention on cell surface GAGs. These molecules, typified by
heparan sulfate and chondroitin sulfate, are known to be low-affinity cell surface RANTES receptors (10, 37, 66). Indeed, RANTES is secreted from CD8+ cells as GAG complexes
(89).
To address the involvement of GAGs, we first used two cell lines
defective in GAG synthesis, derived by treating wild-type CHO-K1 cells
with a chemical mutagen (31, 49). These CD4-negative lines
have been used to demonstrate that GAGs are required for adhesion of
the malarial circumsporozoite protein to target cells (34).
The pgsA-745 line contains a mutation resulting in a defect in
xylosyltransferase, an enzyme that attaches xylose to a serine residue
of the core protein in the first sugar transfer reaction of GAG
synthesis (31). This cell line does not, therefore, produce any GAGs. The psgD-677 line expresses altered forms of
N-acetylglucosaminyltransferase and glucuronosyltransferase, enzymes
required for heparan sulfate polymerization. These cells specifically
lack heparan sulfate and accumulate three- to fourfold more chondroitin
sulfate than wild-type cells (49).
Because HIV-1 and HIV-1MuLV pseudotypes do not efficiently
infect CHO-K1 cells (41) (or mutants thereof), we used HIV-1 pseudotyped with the VSV envelope glycoproteins (HIV-1VSV);
RANTES enhances the infectivity of this virus just as it does HIV-1 and HIV-1MuLV (36). The enhancement of
HIV-1VSV infectivity by RANTES was significantly reduced in
simultaneous-addition experiments with both CHO-K1 cell mutants,
especially with the pgsA-745 GAG-deficient cell line (Fig.
5b). Similar, but more pronounced,
reductions in the extent of infectivity enhancement were observed when
both mutant CHO-K1 cell lines were pretreated with RANTES for 24 h before the addition of HIV-1VSV in the absence of RANTES
compared to what was observed with the wild-type CHO-K1 cells. Indeed, there was no significant enhancement of infectivity with the pgsA-745, GAG-deficient cells under these conditions (Fig. 5a).
View larger version (9K):
[in this window]
[in a new window]
|
FIG. 5.
RANTES-mediated infectivity enhancement is dependent
upon GAG expression on target cells. CHO-K1 cells (), heparan
sulfate-deficient psgD-677 cells (), or GAG-deficient psgA-745 cells
() were infected with HIV-1VSV (1.5 ng of HIV-1 p24
antigen) in the presence or absence of the indicated concentrations of
RANTES. Unbound virus was removed after a 2-h incubation, and the
cultures were replenished with fresh medium without RANTES. (a) RANTES
was added to the cells for 24 h, and then the chemokine-containing
medium was washed away immediately before the addition of virus. RANTES
was absent during the 2-h infection period and subsequently. (b) RANTES
was added during the 2-h infection period but was not present prior to
or after that time. The extent of viral infection was measured by
determination of luciferase expression in quadruplicate cultures on day
3 postinfection; the data (mean ± standard deviation) are
presented as percentages of control (no RANTES = 100%). The
untreated control values (in RLU) were as follows: (a) CHO-K1 cells,
71.4 ± 16.3; pgsD 677 cells, 19.9 ± 4.4; pgsA 745 cells,
71.8 ± 8.4; (b) CHO-K1, cells 47.4 ± 11.5; pgsD 677 cells,
22.9 ± 6.9; pgsA 745 cells, 37.8 ± 4.0.
|
|
These results implicate cell surface GAGs as mediators of
RANTES-induced viral infectivity enhancement. The most likely
explanation of the effect is that oligomers of RANTES bind to GAGs on
both the virus and cell membranes, cross-linking the two. We
investigated whether this was, in fact, the case by adding soluble GAGs
as competitors for RANTES binding to virion- or cell-associated GAGs. When HeLa-CD4 cells were treated with RANTES (5 µg/ml) in the presence or absence of soluble GAGs for 24 h prior to the addition of HIV-1MuLV, both heparan sulfate and chondroitin sulfate
caused a dose-dependent inhibition of the RANTES-mediated infectivity enhancement (Fig. 6a). In the absence of
RANTES, neither soluble GAG affected viral infectivity (Fig. 6a).
Similar results were obtained when HIV-1HXB2 (Env
pseudotype) was substituted for HIV-1MuLV (data not shown).
When RANTES and soluble GAGs were both present during the period of
virus-cell attachment and infection, the GAGs again reversed the
enhancing effect of RANTES in a dose-dependent manner (Fig. 6b).
However, the interpretation of this result is complicated by the
inhibition of viral infectivity caused by GAGs in the absence of
RANTES, a phenomenon that has been described previously (39,
63). Of note is the fact that soluble chondroitin sulfate
inhibits the attachment of HIV-1MuLV virions to
RANTES-coated magnetic beads (Fig. 3a).
View larger version (17K):
[in this window]
[in a new window]
|
FIG. 6.
RANTES-mediated infectivity enhancement is inhibited by
soluble GAGs. HeLa-CD4 cells were infected with HIV-1MuLV
as described in Materials and Methods. (a) The cells were pretreated
for 24 h with RANTES (5 µg/ml) in the presence or absence of
soluble GAGs, and then infection was initiated in the absence of both
RANTES and GAGs. (b) RANTES and GAGs were both added simultaneously
with the virus at the initiation of infection. The GAG used was heparan
sulfate ( and  ) or chondroitin sulfate ( and  ). Open
symbols, no RANTES; closed symbols, plus RANTES. The extent of viral
infection was measured by determination of luciferase expression in
quadruplicate cultures on day 3 postinfection; the data (mean ± standard deviation) are presented as percentages of control (no
RANTES = 100%). The untreated control values were (a) 27,290 ± 2,450 RLU and (b) 27,151 ± 5,468 RLU.
|
|
Effect of signal transduction inhibitors on RANTES-mediated
infectivity enhancement.
We have noted previously the correlation
between the concentrations of RANTES that enhance viral infectivity and
those that were reported by Bacon et al. to cause a large, sustained
increase in cytosolic Ca2+ concentrations in
CD4+ T cells (6, 7, 25). This increase in
intracellular Ca2+ was sensitive to the protein tyrosine
kinase inhibitor herbimycin A, whereas smaller, more transient
Ca2+ increases induced by lower concentrations of RANTES
were blocked by pertussis toxin, an inhibitor of signaling via
G-protein-coupled receptors (6, 7, 25). We therefore tested
whether the RANTES-induced enhancements of viral infectivity were
affected by herbimycin A (Fig. 7).
View larger version (10K):
[in this window]
[in a new window]
|
FIG. 7.
Effect of the tyrosine kinase inhibitor herbimycin A on
RANTES-induced infectivity enhancement. HeLa-CD4 cells were incubated
for 25 h with the indicated concentrations of herbimycin A. The
cells were then infected with HIV-1MuLV (2.5 ng of HIV-1
p24 antigen) in the presence () or absence () of 10 µg of
RANTES/ml. Unbound virus was removed after a 2-h incubation period, and
the cultures were replenished with fresh medium without RANTES. (a)
RANTES was added to the cells 24 h before the initiation of
infection (i.e., 1 h after herbimycin A was added) and then washed
away immediately before the addition of virus. Neither RANTES nor
herbimycin A was present during the 2-h infection period or thereafter.
(b) RANTES was added to the cells simultaneously with the viral
inoculum so that both RANTES and herbimycin A were present during the
2-h infection period but neither agent was present after that period.
In both experiments, the extent of viral infection was determined by
measuring luciferase expression in quadruplicate cultures on day 3 postinfection; the data are presented as percentages of control (no
chemokine = 100%). The untreated control values were (a) 183 ± 63 RLU and (b) 262 ± 53 RLU.
|
|
The enhancement of HIV-1MuLV infectivity caused by RANTES
pretreatment of HeLa-CD4 cells was inhibited by herbimycin A in a
dose-dependent manner (Fig. 7a). In the absence of RANTES, herbimycin A
had no significant effect on HIV-1MuLV infectivity (Fig.
7a). Similar results were obtained when herbimycin A was added to the target cells 48 instead of 25 h prior to infection (data not
shown). In contrast, herbimycin A pretreatment for 25 h had no
effect on the infectivity enhancement which occurred when RANTES was added to the HeLa-CD4 cells simultaneously with HIV-1MuLV
(Fig. 7b). To exclude the possibility that herbimycin A was no longer active after it had been in contact with the cells for 25 h, we repeated this experiment but with only a 1-h interval between the
addition of herbimycin A and HIV-1MuLV; the results were
identical (data not shown). Under the conditions used in both Fig. 7a
and b, the same pattern of data was obtained when HIV-1HxB2
(Env pseudotype) was substituted for HIV-1MuLV (data not
shown). Thus, the identity of the viral envelope glycoproteins which
mediate entry into the target cells does not influence the
RANTES-induced infectivity enhancement mechanisms or their sensitivity
to herbimycin A.
RANTES increases the efficiency of cell-cell fusion.
To gain
more insight into the effects of treating target cells with RANTES for
prolonged periods, we tested whether such cells were more permissive to
cell-cell fusion and not just virus-cell fusion. To do this, we used an
assay in which a luciferase reporter gene is transactivated when
cell-cell fusion occurs (28, 61). HeLa cells expressing the
envelope glycoproteins of HIV-1IIIB (HeLa-EnvIIIB cells) are the effector cells, and
luciferase-containing HeLa-CD4 cells are the targets.
RANTES, at 5 to 10 µg/ml, caused an increase in the extent of
cell-cell fusion, both when it was added to the mixed effector and
target cell population only during the fusion reaction and when it was
added to the effector cells for 24 h prior to the initiation of
cell-cell fusion (Fig. 8). In contrast,
the same concentrations of MIP-1 had little or no effect on
cell-cell fusion under these conditions (Fig. 8). Thus, whatever
changes are caused to HeLa cells by prolonged exposure to RANTES, their effect is to increase the extent of both virus-cell fusion and Env-mediated cell-cell fusion.
View larger version (23K):
[in this window]
[in a new window]
|
FIG. 8.
Effect of RANTES on HIV-1 Env-mediated cell-cell fusion.
HeLa target cells expressing the HIV-1IIIB envelope
glycoproteins were allowed to fuse with HeLa-CD4 effector cells in the
presence of the indicated concentrations of RANTES (solid bars),
MIP-1 (shaded bars), or medium (hatched bars). The designation
0 h means that the chemokine was only added to the mixed
effector-target cell population during the fusion process; the
designation 24 h indicates that the effector cells were pretreated
with the chemokine for 24 h. The values shown are representative
of those from four independent experiments.
|
|
| |
DISCUSSION |
The purpose of this study was to understand the mechanisms by
which the CC-chemokine RANTES enhances the infectivities of HIV-1 and
other enveloped viruses when present at concentrations in excess of 500 ng/ml in vitro (36). We do not argue that what we have
observed is necessarily physiologically relevant
plasma concentrations
of RANTES rarely exceed 200 ng/ml in HIV-1-infected or uninfected
people (42, 48, 52, 60)although we note that local
concentrations of RANTES in tissues are unknown but could be rather
higher than in plasma, especially at the sites of inflammation, where
RANTES performs its normal physiological functions. Neither do we
expect that plasma concentrations of exogenously administered RANTES or
its derivatives would approach the range at which viral infectivity
enhancement occurs, if and when these compounds are used
therapeutically. It should not be overlooked that concentrations of
RANTES lower than those we have studied here can inhibit the
replication of R5 HIV-1 isolates in vitro by preventing the use of the
CCR5 coreceptor by these viruses (5, 10, 22, 29, 51, 64, 80,
85).
We believe, however, that understanding how RANTES enhances viral
infectivity in vitro might throw light on the fundamental processes of
viral infection, in particular for HIV-1. The complexity of the
phenomena described here could also help explain the various, seemingly
contradictory reports that RANTES can either inhibit or enhance HIV-1
replication in primary monocytes/macrophages (1, 3, 12, 29, 44,
59, 78, 96). We have not yet studied these cells in detail, but
we and others have noted that RANTES can either inhibit or enhance the
replication of X4 and R5X4 HIV-1 isolates in primary CD4+ T
cells in a donor-dependent manner (26, 45, 58, 83, 85). We
are presently investigating this phenomenon, to see whether it is
mechanistically related to what we have observed here and previously
(36).
In the present study, our principal findings are twofold: firstly, that
oligomers of RANTES can cross-link enveloped viruses, including HIV-1,
to cells via GAGs that are present on the membranes of both virions and
cells; secondly, that oligomers of RANTES form on cell surface GAGs and
transduce a herbimycin A-sensitive signal which, over a period of
several hours, renders the cells more permissive to infection by HIV-1
or envelope pseudotypes of HIV-1. These phenomena may be relevant to
studies of several viruses, because we have observed the first process
with HIV-1, HIV-1MuLV, and HIV-1VSV and the
second with HIV-1, HIV-1MuLV, HIV-1VSV, and
influenza and vaccinia viruses (36, 83) (see above).
The observation that RANTES oligomers can cross-link virions to cells
via GAGs is consistent with previous studies emphasizing the importance
of GAGs in virus-cell binding. Mondor et al. reported that the
attachment of the TCLA strain of HIV-1Hx10 to HeLa-CD4 cells was strongly dependent on the binding of the virus to cell surface GAGs (heparans); attachment could be efficiently inhibited by
soluble heparin, dextran sulfate, or pentosan polysulfate but not by
chondroitin sulfate (54). The importance of virus-GAG interactions, mediated by envelope glycoproteins or other virion components, for HIV-1 infection of various cell lines is well characterized (62, 71, 77); indeed, the rate-limiting step in HIV-1 penetration of its target cells is attachment to the cell
surface, not the subsequent fusion reaction (68). This is
also true of many other viruses (18, 57, 72, 90), and as
with HIV-1, interactions with cell surface GAGs can be used to increase
virion infectivity. For example, GAGs play an important role in
facilitating interactions of herpes simplex virus with its fusion
receptors (55, 95) and of the following viruses with the
target cell surface: Dengue virus (16), vaccinia virus (19), foot-and-mouth disease virus (40), Sindbis
virus (46), human herpesvirus 7 (79), and
pseudorabies virus (86).
Virus-cell attachment can also be mediated by virion-associated
adhesion factors binding to cell surface counterreceptors (11, 33,
67, 76) or, as we show here, by oligomers of RANTES. The
mechanism and route by which virus-cell fusion subsequently occurs are
irrelevant. We have found that RANTES oligomers can enhance the
infectivity of VSV and MuLV Env pseudotypes of HIV-1, which enter
target cells independently of CD4 and coreceptors (36).
Similarly, the infectivities of murine influenza virus and vaccinia
virus are also enhanced by oligomerized RANTES (83). The
subsequent association of viruses with specific fusion receptors (e.g.,
of HIV-1 with CD4 and coreceptors) is still necessary for fusion and
infection to occur. But an elevated concentration of virions attached
to the cell surface increases the rate of virus-cell fusion, however
fusion is achieved and also however attachment occurs.
In addition to virus-cell attachment, GAGs play an important role in
the binding of other proteins to the cell surface. Thus, the major
surface protein of the malaria sporozoites, the circumsporozoite protein, contains a highly conserved sequence responsible for the
specific homing of malaria sporozoites to hepatocytes, the target cells
for the first stage of infection (14, 81). The conserved
sequence includes a series of positively charged amino acids whose
interaction with cell surface GAGs is required for target cell adhesion
of the sporozoite (34).
The GAG-binding region of RANTES is also positively charged and is
located close to its C terminus. Thus, Burns et al. found that lysine
and arginine residues within the C-terminal -helical region of
RANTES are critical for the interaction of this chemokine with GAGs
(10). Of note is the fact that a monoclonal antibody (4A12)
whose epitope is heavily dependent on residues in this region
interferes with the binding of RANTES to cell surface GAGs; this
process is necessary for the transduction of Ca2+ signals
and the antiviral action of low concentrations of RANTES (10). The single-residue change (glutamic acid to serine) in BB-10520 RANTES that abolishes its ability to oligomerize and cause
infectivity enhancement lies at position 66, only two amino acids away
from the C terminus and within the 4A12 epitope (10, 24).
The three-dimensional structures of chemokines clearly show that these
molecules can dimerize in a manner that is not GAG dependent. The
dimeric topology of CC-chemokines, as illustrated by RANTES
(20), differs considerably from that of CXC-chemokines, for
example, interleukin-8 (21). Furthermore, the crystal
structure of MCP-1 reveals that this CC-chemokine can also form
tetramers (50), yet MCP-1 binds to its seven-transmembrane
receptor as a monomer (70). Whether it is monomeric or
higher-order forms of RANTES that bind, at low nanomolar
concentrations, to high-affinity receptors such as CCR1 and CCR5
(6, 75, 80) remains to be determined. It should be noted
that while the E66>S mutation abrogates the ability of RANTES to form
multimers, the protein is still able to dimerize (Fig. 4)
(24). Dimerization is clearly not sufficient for a
CC-chemokine to cause viral infectivity enhancement; MIP-1 is
another molecule which dimerizes yet does not enhance infectivity
(36, 37). One difference between RANTES and MIP-1 is
that, at physiological pH, the former is cationic and the latter is
anionic (20). Yet charge cannot be the sole determinant of whether a CC-chemokine can increase viral infectivity; MCP-1 is also
cationic and oligomerizes upon binding to heparin (50), but
it does not increase HIV-1 infectivity (36, 37). Clearly, aspects of the chemistry and structure of RANTES that influence its
ability to cause viral infectivity enhancement remain to be identified.
We do not yet understand how the prolonged interactions of RANTES
oligomers with cell surface GAGs render target cells more permissive
for infection by HIV-1 and other enveloped viruses. We did, however,
note the correlation between the concentrations of RANTES that enhance
viral infectivity (36) and those found by Bacon et al. to
cause a large, sustained increase in cytosolic Ca2+
concentrations in CD4+ T cells (6, 7, 25). Since
this increase in intracellular Ca2+ was sensitive to the
protein tyrosine kinase inhibitor herbimycin A (6, 7, 25),
we tested the effect of this compound on the RANTES-induced viral
infectivity enhancement and found that the enhancement was also
herbimycin A sensitive. Dairaghi et al. suggested that intracellular
Ca2+ increases stimulated by high concentrations of RANTES
were associated with CD3 expression (25). Our experiments,
however, were all performed on CD3-negative cells, so the expression of
CD3 is not necessary for infectivity enhancement to occur.
We suggest, therefore, that the binding of RANTES oligomers to
cell-surface GAGs activates a signal transduction pathway(s) which
involves herbimycin A-sensitive tyrosine kinases. Several signaling
pathways activated by RANTES in T cells have been described (6, 7,
25, 43, 82, 87, 91, 93). At present, those involved in viral
infectivity enhancement remain to be identified, as does the stage(s)
in the life cycles of HIV-1 and other viruses that is affected by this
signal(s). Syndecans are one group of prototypic proteoglycans that
have been extensively studied; their expression changes dramatically
during cell development and differentiation and is influenced by cell
activation (13). Syndecans and another proteoglycan, CD44,
have been shown to associate with protein tyrosine kinases from the Src
family (38, 69). Useful information might accrue from
studies in these general areas.
| |
ACKNOWLEDGMENTS |
We are very grateful to David Kabat, Dan Littman, and Tanya
Dragic for providing cell lines, to Bernard Moss and Robert Doms for
the recombinant vaccinia viruses used in cell-cell fusion assays, to
Larry Arthur for gradient-purified HIV-1IIIB and control microvesicles, and to Fréderic Borlat, Jazza Segal, and Simon Monard for technical assistance.
This work was supported by RO1 AI41420 and by the Pediatric AIDS
Foundation. A.T. is a Fellow of the Austrian Program for Advanced
Research and Technology; J.P.M. is an Elizabeth Glaser Scientist of the
Pediatric AIDS Foundation.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: The Aaron
Diamond AIDS Research Center, 455 First Ave., New York, NY 10021. Phone: (212) 725-0018. Fax: (212) 725-1126. E-mail:
atrkola{at}adarc.org.
| |
REFERENCES |
| 1.
|
Alkhatib, G.,
C. Combadiere,
C. C. Broder,
Y. Feng,
P. E. Kennedy,
P. M. Murphy, and E. A. Berger.
1996.
CC CKR5: a RANTES, MIP-1, MIP-1 receptor as a fusion cofactor for macrophage-tropic HIV-1.
Science
272:1955-1958[Abstract].
|
| 2.
|
Amara, A.,
S. Le Gall,
O. Schwartz,
J. Salamero,
M. Montes,
P. Loetscher,
M. Baggiolini,
J.-L. Virelizier, and F. Arenzana-Seisdedos.
1997.
HIV coreceptor downregulation as antiviral principle: SDF-1-dependent internalization of the chemokine receptor CXCR4 contributes to inhibition of HIV replication.
J. Exp. Med.
186:139-146[Abstract/Free Full Text].
|
| 3.
|
Amzazi, S.,
Y. L. Ylisastigul,
Y. Bakri,
L. Rabehi,
L. Gattegno,
M. Parmentier,
J. C. Gluckman, and A. Benjouad.
1998.
The inhibitory effect of RANTES on the infection of primary macrophages by R5 human immunodeficiency virus type-1 depends on the macrophage activation state.
Virology
252:96-105[Medline].
|
| 4.
|
Aramori, I.,
S. S. G. Ferguson,
P. D. Bieniasz,
B. R. Cullen, and M. G. Caron.
1997.
Molecular mechanism of desensitization of the chemokine receptor CCR-5: receptor signalling and internalization are dissociable from its role as an HIV-1 co-receptor.
EMBO J.
16:4606-4616[Medline].
|
| 5.
|
Arenzana-Seisedos, F.,
J.-L. Virelizier,
D. Rousset,
I. Clark-Lewis,
P. Loetscher,
B. Moser, and M. Baggiolini.
1996.
HIV blocked by chemokine antagonist.
Nature
383:400[Medline].
|
| 6.
|
Bacon, K. B.,
B. A. Premack,
P. Gardner, and T. J. Schall.
1995.
Activation of dual T cell signaling pathways by the chemokine RANTES.
Science
269:1727-1730[Abstract/Free Full Text].
|
| 7.
|
Bacon, K. B.,
T. J. Schall, and D. J. Dairaghi.
1998.
RANTES activation of phospholipase D in Jurkat T cells: Requirement of GTP-binding proteins ARF and RhoA.
J. Immunol.
160:1894-1900[Abstract/Free Full Text].
|
| 8.
|
Berger, E. A.
1997.
HIV entry and tropism: the chemokine receptor connection.
AIDS
11(Suppl. A):S3-S16.
|
| 9.
|
Bess, J. W.,
R. J. Gorelick,
L. E. Henderson, and L. O. Arthur.
1997.
Microvesicles are a source of contaminating cellular proteins found in purified HIV-1 preparations.
Virology
230:134-144[Medline].
|
| 10.
|
Burns, J. M.,
R. C. Gallo,
A. L. DeVico, and G. K. Lewis.
1998.
A new monoclonal antibody, mAb 4A12, identifies a role for the glycosoaminoglycan (GAG) binding domain of RANTES in the antiviral effect against HIV-1 and intracellular Ca2+ signaling.
J. Exp. Med.
188:1917-1927[Abstract/Free Full Text].
|
| 11.
|
Cantin, R.,
J.-F. Fortin,
G. Lamontagne, and M. Tremblay.
1997.
The presence of host-derived HLA-DR1 on human immunodeficiency virus type 1 increases viral infectivity.
J. Virol.
17:1922-1930.
|
| 12.
|
Capobianchi, M. R.,
I. Abbate,
G. Antonelli,
O. Turriziani,
A. Dolei, and F. Dianzani.
1998.
Inhibition of HIV type 1 BaL replication by MIP-1, MIP-1, and RANTES in macrophages.
AIDS Res. Hum. Retroviruses
14:233-240[Medline].
|
| 13.
|
Carey, D.
1997.
Syndecans: multifunctional cell-surface co-receptors.
Biochem. J.
327:1-16.
|
| 14.
|
Cerami, C.,
U. Frevert,
P. Sinnis,
B. Takacs, and V. Nussenzweig.
1994.
Rapid clearance of malaria circumsporozoite protein (CS) by hepatocytes.
J. Exp. Med.
179:695-701[Abstract/Free Full Text].
|
| 15.
|
Chen, B. K.,
K. Saksela,
R. Andino, and D. Baltimore.
1994.
Distinct modes of human immunodeficiency virus type 1 proviral latency revealed by superinfection of nonproductively infected cell lines with recombinant luciferase-encoding viruses.
J. Virol.
68:654-660[Abstract/Free Full Text].
|
| 16.
|
Chen, Y.,
T. Maguire,
R. Hileman,
J. Fromm,
J. Esko,
R. Linhardt, and R. Marks.
1997.
Dengue virus infectivity depends on envelope protein binding to target cell heparan sulfate.
Nat. Med.
3:866-871[Medline].
|
| 17.
|
Choe, H.,
M. Farzan,
Y. Sun,
N. Sullivan,
B. Rollins,
P. D. Ponath,
L. Wu,
C. R. Mackay,
G. LaRosa,
W. Newman,
N. Gerard,
G. Gerard, and J. Sodroski.
1996.
The -chemokine receptors CCR3 and CCR5 facilitate infection by primary HIV-1 isolates.
Cell
85:1135-1148[Medline].
|
| 18.
|
Chuck, A. S., and B. O. Palsson.
1996.
Consistent and high rates of gene transfer can be obtained using flow-through transduction over a wide range of retroviral titers.
Hum. Gene Ther.
7:743-750[Medline].
|
| 19.
|
Chung, C.-S.,
J.-C. Hsiao,
Y.-S. Chang, and W. Chang.
1998.
A27L protein mediates vaccinia virus interaction with cell surface heparan sulfate.
J. Virol.
72:1577-1585[Abstract/Free Full Text].
|
| 20.
|
Chung, C. W.,
R. M. Cooke,
A. E. Proudfoot, and T. N. C. Wells.
1995.
The three-dimensional solution structure of RANTES.
Biochemistry
34:9307-9314[Medline].
|
| 21.
|
Clore, G. M.,
E. Appella,
M. Yamada,
K. Matsushima, and A. M. Gronenborn.
1990.
Three-dimensional structure of interleukin 8 in solution.
Biochemistry
29:1689-1696[Medline].
|
| 22.
|
Cocchi, F.,
A. L. DeVico,
A. Garzino-Demo,
S. K. Arya,
R. C. Gallo, and P. Lusso.
1995.
Identification of RANTES, MIP-1 alpha and MIP-1 beta as the major HIV suppressive factors produced by CD8+ T cells.
Science
270:1811-1815[Abstract/Free Full Text].
|
| 23.
|
Connor, R. I.,
K. E. Sheridan,
D. Ceradini,
S. Choe, and N. R. Landau.
1997.
Change in coreceptor use correlates with disease progression in HIV-1 infected individuals.
J. Exp. Med.
185:621-628[Abstract/Free Full Text].
|
| 24.
| Czaplewski, L. G., J. McKeating, C. J. Craven,
L. D. Higgins, V. Appay, A. Brown, T. Dudgeon, L. A. Howard,
T. Meyers, J. Owen, S. R. Palan, P. Tan, G. Wilson, N. R. Woods, C. M. Heyworth, B. I. Lord, D. Brotherton, R. Christison, S. Craig, S. Cribbes, R. M. Edwards, S. J. Evans,
R. Gilbert, P. Morgan, E. Randle, N. Schofield, P. G. Varley,
J. P. Waltho, and M. G. Hunter. Identification of amino
acid residues critical for aggregation of human CC chemokines MIP-1,
MIP-1 and RANTES: characteristics of active disaggregated chemokine
variants. J. Biol. Chem., in press.
|
| 25.
|
Dairaghi, D. J.,
K. S. Soo,
E. R. Oldham,
B. A. Premack,
T. Kitamura,
K. B. Bacon, and T. J. Schall.
1998.
RANTES-induced T cell activation correlates with CD3 expression.
J. Immunol.
160:426-433[Abstract/Free Full Text].
|
| 26.
|
Dolei, A.,
A. Biolchini,
C. Serra,
S. Currali,
E. Gomes, and F. Dianzani.
1998.
Increased replication of a T-cell-tropic HIV strain and CXC chemokine receptor-4 induction in T cells treated with macrophage inflammatory protein (MIP)-1, MIP-1 and RANTES -chemokines.
AIDS
12:183-190[Medline].
|
| 27.
|
Doms, R. W., and S. C. Peiper.
1997.
Unwelcome guests with master keys: how HIV uses chemokine receptors for cellular entry.
Virology
235:179-190[Medline].
|
| 28.
|
Doranz, B. J.,
J. Rucker,
Y. Yi,
R. J. Smyth,
M. Samson,
S. Peiper,
M. Parmentier,
R. G. Collman, and R. W. Doms.
1996.
A dual-tropic, primary HIV-1 isolate that uses fusin and the -chemokine receptors CKR-5, CKR-2b as fusion cofactors.
Cell
85:1149-1159[Medline].
|
| 29.
|
Dragic, T.,
V. Litwin,
G. P. Allaway,
S. R. Martin,
Y. Huang,
K. A. Nagashima,
C. Cayanan,
P. J. Maddon,
R. A. Koup,
J. P. Moore, and W. A. Paxton.
1996.
HIV-1 entry into CD4+ cells is mediated by the chemokine receptor CC-CKR-5.
Nature
381:667-673[Medline].
|
| 30.
|
Esko, J. D.
1989.
Replica plating of animal cells.
Methods Cell Biol.
32:387-422[Medline].
|
| 31.
|
Esko, J. D.,
T. E. Stewart, and W. H. Taylor.
1985.
Animal cell mutants defective in glycosaminoglycan biosynthesis.
Proc. Natl. Acad. Sci. USA
82:3197-3201[Abstract/Free Full Text].
|
| 32.
|
Feng, Y.,
C. C. Broder,
P. E. Kennedy, and E. A. Berger.
1996.
HIV-1 entry cofactor: functional cDNA cloning of a seven-transmembrane G protein-coupled receptor.
Science
272:872-877[Abstract].
|
| 33.
|
Fortin, J.-F.,
R. Cantin,
G. Lamontagne, and M. Tremblay.
1997.
Host-derived ICAM-1 glycoproteins incorporated on human immunodeficiency virus type 1 are biologically active and enhance viral infectivity.
J. Virol.
71:3588-3596[Abstract].
|
| 34.
|
Gantt, S. M.,
P. Clavijo,
X. Bai,
J. D. Esko, and P. Sinnis.
1997.
Cell adhesion to a motif shared by the malaria circumsporozoite protein and thrombospondin is mediated by its glycosaminoglycan-binding region and not by CSVTCG.
J. Biol. Chem.
272:19205-19213[Abstract/Free Full Text].
|
| 35.
|
Gluschankof, P.,
I. Mondor,
H. R. Gelderblom, and Q. J. Sattentau.
1997.
Cell membrane vesicles are a major contaminant of gradient-enriched human immunodeficiency virus type 1 (HIV-1) preparations.
Virology
230:125-133[Medline].
|
| 36.
|
Gordon, C. J.,
M. A. Muesing,
A. E. I. Proudfoot,
C. A. Power,
J. P. Moore, and A. Trkola.
1999.
Enhancement of human immunodeficiency virus type 1 infection by the CC-chemokine RANTES is independent of the mechanism of virus-cell fusion.
J. Virol.
73:684-694[Abstract/Free Full Text].
|
| 37.
|
Hoogewerf, A. J.,
G. S. Kuschert,
A. E. Proudfoot,
F. Borlat,
I. Clark-Lewis,
C. A. Power, and T. N. Wells.
1997.
Glycosaminoglycans mediate cell surface oligomerization of chemokines.
Biochemistry
36:13570-13578[Medline].
|
| 38.
|
Ilangumaran, S.,
A. Briol, and D. Hoessli.
1998.
CD44 selectively associates with active src family tyrosine kinases lck and fyn in glycosphongollipid rich plasma membrane domains of human peripheral blood lymphocytes.
Blood
91:3901-3908[Abstract/Free Full Text].
|
| 39.
|
Ito, M.,
M. Baba,
A. Sato,
R. Pauwels,
E. De Clerq, and S. Shigeta.
1987.
Inhibitory effect of dextran sulfate and heparin on the replication of human immunodeficiency virus (HIV) in vitro.
Antiviral Res.
7:361-367[Medline].
|
| 40.
|
Jackson, T.,
F. Ellard,
R. Ghazaleh,
S. Brookes,
W. Blakemore,
A. Corteyn,
D. Stuart,
J. Newman, and A. King.
1996.
Efficient infection of cells in culture by type O foot-and-mouth disease virus requires binding to cell surface heparan sulfate.
J. Virol.
70:5282-5287[Abstract/Free Full Text].
|
| 41.
|
Kadan, M. J.,
S. Sturm,
W. F. Anderson, and M. A. Eglitis.
1992.
Detection of receptor-specific murine leukemia virus binding to cells by immunofluorescence analysis.
J. Virol.
66:2281-2287[Abstract/Free Full Text].
|
| 42.
|
Kakkanaiah, V. N.,
E. A. Ojo-Amaize, and J. B. Peter.
1998.
Concentrations of circulating beta-chemokines do not correlate with viral load in human immunodeficiency virus-infected individuals.
Clin. Diagn. Lab. Immunol.
5:499-502[Abstract/Free Full Text].
|
| 43.
|
Karpus, W. J.,
N. W. Lukacs,
K. J. Kennedy,
W. S. Smith,
S. D. Hurst, and T. A. Barrett.
1997.
Differential CC chemokine-induced enhancement of T helper cell cytokine production.
J. Immunol.
158:4129-4136[Abstract].
|
| 44.
|
Kelly, M. D.,
H. M. Naif,
S. L. Adams,
A. L. Cunningham, and A. R. Lloyd.
1998.
Dichotomous effects of -chemokines on HIV replication in monocytes and monocyte-derived macrophages.
J. Immunol.
160:3091-3095[Abstract/Free Full Text].
|
| 45.
|
Kinter, A.,
A. Catanzaro,
J. A. Monaco,
M. Ruiz,
J. Justement,
S. Moir,
J. Arthos,
A. Oliva,
L. Ehler,
S. Mizell,
R. Jackson,
M. Ostrowski,
J. Hoxie,
R. Offord, and A. S. Fauci.
1998.
CC-chemokines enhance the replication of T tropic strains of HIV-1 in CD4+ T cells: role of signal transduction.
Proc. Natl. Acad. Sci. USA
95:11880-11885[Abstract/Free Full Text].
|
| 46.
|
Klimstra, W.,
K. Ryman, and R. Johnston.
1998.
Adaptation of Sindbis virus to BHK cells selects for use of heparan sulfate as an attachment receptor.
J. Virol.
72:7357-7366[Abstract/Free Full Text].
|
| 47.
|
Kozak, S. L.,
E. J. Platt,
N. Madani,
F. E. Ferro, Jr.,
K. Peden, and D. Kabat.
1997.
CD4, CXCR-4, and CCR-5 dependencies for infection by primary patient and laboratory-adapted isolates of human immunodeficiency virus type 1.
J. Virol.
71:873-882[Abstract].
|
| 48.
|
Krowka, J. F.,
M. L. Gesner,
M. S. Ascher, and H. W. Sheppard.
1997.
Lack of associations of chemotactic cytokines with viral burden, disease progression, or lymphocyte subsets in HIV-infected individuals.
Clin. Immunol. Immunopathol.
85:21-27[Medline].
|
| 49.
|
Lidholt, K.,
J. L. Weinke,
C. S. Kiser,
F. N. Lugemwa,
K. J. Bame,
S. Cheifetz,
J. Massague,
U. Lindahl, and J. D. Esko.
1992.
A single mutation affects both N-acetylglucosaminyltransferase and glucuronosyltransferase activities in a Chinese hamster ovary cell mutant defective in heparan sulfate biosynthesis.
Proc. Natl. Acad. Sci. USA
89:2267-2271[Abstract/Free Full Text].
|
| 50.
|
Lubkowski, J.,
G. Bujacz,
L. Boque,
P. J. Domaille,
T. M. Handel, and A. Wlodawer.
1997.
The structure of MCP-1 in two crystal forms provides a rare example of variable quaternary interactions.
Nat. Struct. Biol.
4:64-69[Medline].
|
| 51.
|
Mack, M.,
B. Luckow,
P. J. Nelson,
J. Lihak,
G. Simmons,
P. R. Clapham,
N. Signoret,
M. Marsh,
M. Stangassinger,
F. Borlat,
T. N. C. Wells,
D. Schlöndorff, and A. E. I. Proudfoot.
1998.
Aminooxypentane-RANTES induces CCR5 internalization but inhibits recycling: a novel inhibitory mechanism of HIV infectivity.
J. Exp. Med.
187:1215-1224[Abstract/Free Full Text].
|
| 52.
|
McKenzie, S. W.,
G. Dallalio,
M. North,
P. Frame, and R. T. Means.
1996.
Serum chemokine levels in patients with non-progressing HIV infection.
AIDS
10:F29-F33[Medline].
|
| 53.
|
Miller, D. G., and A. D. Miller.
1994.
A family of retroviruses that utilize related phosphate transporters for cell entry.
J. Virol.
68:8270-8276[Abstract/Free Full Text].
|
| 54.
|
Mondor, I.,
S. Ugolini, and Q. J. Sattentau.
1998.
Human immunodeficiency virus type 1 attachment to HeLa CD4 cells is CD4 independent and gp120 dependent and requires cell surface heparans.
J. Virol.
72:3623-3634[Abstract/Free |
Top
Abstract
Introduction
