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Journal of Virology, June 2000, p. 5016-5023, Vol. 74, No. 11
0022-538X/00/$04.00+0
Coreceptor Competition for Association with CD4 May
Change the Susceptibility of Human Cells to Infection with T-Tropic and
Macrophagetropic Isolates of Human Immunodeficiency Virus
Type 1
Shirley
Lee,1
Cheryl K.
Lapham,1
Hong
Chen,2
Lisa
King,1
Jody
Manischewitz,1
Tatiana
Romantseva,1
Howard
Mostowski,3
Tzanko S.
Stantchev,2
Christopher C.
Broder,2 and
Hana
Golding1,*
Division of Viral
Products1 and Division of Cell and Gene
Therapy,3 Center for Biologics Evaluation and
Research, Food and Drug Administration, Bethesda, Maryland 20892, and
Department of Microbiology and Immunology, Uniformed Services
University of the Health Sciences, Bethesda, Maryland
208142
Received 24 November 1999/Accepted 7 March 2000
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ABSTRACT |
The chemokine receptors CCR5 and CXCR4 were found to function in
vivo as the principal coreceptors for M-tropic and T-tropic human
immunodeficiency virus (HIV) strains, respectively. Since many primary
cells express multiple chemokine receptors, it was important to
determine if the efficiency of virus-cell fusion is influenced not only
by the presence of the appropriate coreceptor (CXCR4 or CCR5) but also
by the levels of other coreceptors expressed by the same target cells.
We found that in cells with low to medium surface CD4 density,
coexpression of CCR5 and CXCR4 resulted in a significant reduction in
the fusion with CXCR4 domain (X4) envelope-expressing cells and in
their susceptibility to infection with X4 viruses. The inhibition could
be reversed either by increasing the density of surface CD4 or by
antibodies against the N terminus and second extracellular domains of
CCR5. In addition, treatment of macrophages with a combination of
anti-CCR5 antibodies or 
-chemokines increased their fusion with X4
envelope-expressing cells. Conversely, overexpression of CXCR4 compared
with CCR5 inhibited CCR5-dependent HIV-dependent fusion in 3T3.CD4.401
cells. Thus, coreceptor competition for association with CD4 may occur
in vivo and is likely to have important implications for the course of
HIV type 1 infection, as well as for the outcome of coreceptor-targeted therapies.
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INTRODUCTION |
Most of the cells that were found to
be targets for human immunodeficiency virus (HIV) infection in vivo
(i.e., T cells, macrophages, and dendritic cells) express both CD4 and
multiple chemokine receptors. Among the chemokine receptors that were
shown in recent years to function as coreceptors for HIV type 1 (HIV-1)
viral entry in vitro, CCR5 and CXCR4 emerged as the predominant
coreceptors for primary isolates in vivo. The potential of a given
chemokine receptor to function as an HIV-1 coreceptor may depend on
multiple parameters such as its surface density (29),
posttranslational modifications (11), and interactions
with other membrane components such as CD4 and other chemokine
receptors. Previously, we demonstrated that exposure of human cell
lines to soluble T-tropic HIV-1 envelope at 37°C can induce the
formation of a trimolecular complex between CD4, gp120, and the
chemokine receptor CXCR4 that was evidenced by their
coimmunoprecipitation with CD4 (22). In the promonocytic cell line U937, a low-level coprecipitation of CD4 and CXCR4 was seen
prior to treatment with gp120, suggesting that some constitutive association between CD4 and chemokine receptors may exist in certain cells. Recently, in a study on human monocytes and macrophages, we
found preexisting CD4-CCR5 and CD4-CXCR4 complexes in the absence of
prior exposure to HIV-1 or soluble gp120 (sgp120), which correlated with the fusion potential of the cells with X4 and R5 (CXCR4- and
CCR5-dependent HIV) envelope-expressing cells (22). In a separate study, using either murine 3T3.CD4+ cells infected
with a recombinant vaccinia-CCR5 virus (vCCR5) or primary human
monocytes and macrophages, coprecipitation of CD4 with CCR5 was
demonstrated in the absence of exposure to viral envelope
(36). Together, these findings suggested that in certain cells with low CD4 densities, the relative levels of CCR5 and CXCR4
expression and their ability to associate with CD4 may influence the
susceptibility of the cells to infection with X4 and R5 viruses, as was
previously speculated (5). In the present study, we provide
evidence that CCR5 and CXCR4, when expressed in the same cell,
interfere with each other's function during HIV-1 envelope-mediated cell fusion and viral cell entry. This interference is likely manifested through competition for association with limiting CD4 molecules and can be reversed by various coreceptor-specific antibodies and -chemokines.
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MATERIALS AND METHODS |
Recombinant vaccinia viruses and fusion assay.
Constructions
of the recombinant vaccinia viruses vCB3 (human CD4 [huCD4])
(6), vCBFY1 (huCXCR4) (12), vHC-1 (huCCR5) (36), vCB28 (JR-FL envelope) (4), and vCB43 (Ba-L
envelope) (4) were previously described. Syncytium formation
was measured after 2.5 to 4 h (for T-tropic envelopes) and 5 to
18 h (for M-tropic envelopes) coculture (1:1 ratio,
105 cells each, in triplicates) of target cells with CD4
12E1 cells infected with recombinant vaccinia viruses expressing HIV-1
M-tropic envelopes (JR-FL [vCB28] and Ba-L [vCB43] at 10 PFU/cell)
or with the human lymphoid cell line TF228.1.16, which stably expresses HIV-1 IIIB/BH10 (T-tropic) envelope (a gift from Z. L. Jonak, SmithKline Beechham Pharmaceuticals) (19). Where indicated, preimmune rabbit immunoglobulin G (IgG), rabbit anti-CXCR4, anti-CCR5, and anti-STRL33 (all produced in our laboratory) (22, 38) or
monoclonal antibodies (MAbs) against CCR5 and CXCR4 (NIH AIDS Reagent
Repository, R&D Systems, Minneapolis, Minn., or PharMingen, San Diego,
Calif.) were added to the target cells for 1 h at 37°C at 10 µg/ml before the addition of envelope-expressing effector cells.
Flow cytometry.
The following antibodies were used:
fluorescein isothiocyanate (FITC)-labeled mouse anti-huCD4 MAb (Leu3a;
Becton Dickinson, San Jose, Calif.), MAb against CXCR4 (12G5) or CCR5
(2D7) (PharMingen), or murine isotype controls followed by
FITC-conjugated goat anti-mouse IgG (Fc specific; Sigma). Gating on
live cells was assisted by using propidium iodide at 5 µg/ml. Ten
thousand events were collected per sample and analyzed by
fluorescence-activated cell sorting (FACS) using the FL-1 (FITC
channel) on a FACScan (Becton Dickinson) with CellQuest software.
Delta mean fluorescence channels (
MFC) were calculated by
subtracting the isotype control antibody MFC from the experimental
values. In some experiments, cells infected with vCCR5 were sorted into
CCR5neg, CCR5med, and CCR5hi
subsets. The sorted cells were acquired on a Becton Dickinson FACStar
Plus with a 5-W 488 Argon Laser Coherent Innova 90, using CellQuest
(Becton Dickinson) on an Apple Macintosh Quadra 650. Coulter's
Immuno-Check beads were used to maximize the PMTs, and Becton
Dickinson's CaliBrite beads were used to show the efficiency of
separation between positive and negative cells (linear scale). Live/dead separation of cells was based on side scatter on the x axis and forward scatter on the y axis. A live
gate (R3) encompassed the live cells. The cell surface phenotypic
marker was mouse 2D7 plus goat anti-mouse FITC. Therefore, the PMT of
choice was FL-1. Appropriate filters floating positive gate
(bright/dulls) (R1) and a negative gate (R2) were used to separate the
positives from the negatives. The sort mode was set on normal R (high
purity, high recovery). A 100-µm sorting nozzle was used, as well as
a moderately slow event rate of approximately 2,200 events/s, and EDTA
was added due to the size and clumping of the cells. The threshold
forward scatter/side scatter was set at 20 to give a more accurate
event count of nozzle passage.
Infection of A2.01.CD4.401 cells with X4 and R5 HIV-1.
Infections of A2.01.CD4.401 cells and PCR analyses were performed as
previously described (39). Two million cells were infected with NL4-3 (multiplicity of infection [MOI] of 0.05) or LAI (MOI of
0.02). Viral stocks were treated with DNase for 45 min at 37°C before
infection. After incubation with the virus for 1 h, cells were
washed four to five times to remove unbound particles. After overnight
incubation at 37°C, cells were recovered and counted. DNA lysates
(the equivalent 104 cells/group) were amplified by PCR with
gag-specific primers (SK38 and SK39), and the products were
hybridized to a 32P-end-labeled SK19 probe as previously
described (39). When indicated, target cells were
preincubated with various murine anti-CCR5 MAbs, rabbit polyclonal
anti-CCR5 IgGs, or control antibodies (at 10 µg/ml) for 1 h at
37°C before viral infection.
Coprecipitation of CD4 and CXCR4.
A2.01.CD4.401 cells were
infected with a control recombinant vaccinia virus or with vCCR5 (15 PFU/cell, 7 h, 37°C) and were lysed at a concentration of 2 × 107 cells/ml in buffer containing 1% Brij 97 (22). CD4 was immunoprecipitated by mixing MAb
OKT4-conjugated protein G-Sepharose beads with cell lysates at 4°C
for 3 h. Preliminary data confirmed that under these conditions,
CD4 was precipitated to completion. Beads were washed five times with
lysis buffer and boiled with an equal volume of 2× Laemmli sample
buffer containing 8 M urea. Samples (4 × 107 cells
per lane) were analyzed by sodium dodecyl sulfate-polyacrylamide gel
electrophoresis on 10% gels and electrophoretically transferred to
nitrocellulose membranes. Membranes were blocked and incubated with a
rabbit polyclonal antibody raised against a peptide corresponding to
the N terminus of CXCR4. The membranes were washed and incubated with
horseradish peroxidase (HRP)-conjugated anti-rabbit antibody diluted in
blocking buffer at 4°C (Amersham), followed by Supersignal Ultra
chemiluminescent substrate (Pierce) for 5 min, and exposed to film.
Membranes were stripped by wetting in 100% methanol and washing with
blotting buffer. They were incubated in 0.5 M glycine (pH 2.5) with
0.05% Tween for 30 min at 60°C, washed in blotting buffer, and
blocked. The membranes were reacted with rabbit polyclonal anti-CD4
(Intracel), HRP-conjugated anti-rabbit chemiluminescent reagent and
were exposed to film. The relative amounts of CD4 and CXCR4
coimmunoprecipitated from cells infected with control vaccinia virus
(vSC8) or vCCR5 were determined by densitometry.
Generation of MDM.
Elutriated monocytes and differentiated
macrophages (MDM) were 100% CD3neg, >85%
CD14+, and >95% HLA-DR+ as determined by flow
cytometry. MDM were derived from elutriated monocytes in 5- to 7-day
cultures in Dulbecco modified Eagle medium supplemented with
recombinant human granulocyte-macrophage colony-stimulating factor
(1,000 U/ml) and 10% pooled human serum (heat inactivated) (23,
38). Prior to use in the fusion assay, MDM were treated for
1 h at 37°C with various anti-CCR5 antibodies (10 µg/ml) or -chemokines (1 to 100 ng/ml) and were then mixed (1:1 ratio) with
target cells expressing X4 or R5 envelopes. Syncytium formation was
scored after 18 h. In some experiments, MDM were first treated with pertussis toxin (PT; Sigma) at 1 µg/ml for 1 h at 37°C,
washed twice, and then incubated with -chemokines. This treatment
with PT blocked protein G-dependent Ca2+ flux response to
-chemokines and SDF-1
(M. Zaitseva, unpublished data).
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RESULTS |
Introduction of CCR5 into CD4+ CXCR4+ cell
lines results in a reduction of fusion with target cells expressing X4
envelopes.
To study the effects of CCR5 expression on CXCR4
function, a recombinant vaccinia virus expressing human CCR5 was used
to infect CEM cells and two CEM-derived cell lines that express
different levels of CD4. The A2.01.CD4.401 cells express tailless CD4
molecules (A2.01.401) (13). The 17D9 cell clone was derived
from CEM cells in our laboratory (18). The rank order of
surface CD4 expression levels was found to be CEM > A2.01.CD4.401 > 17D9. CXCR4 was expressed at similar levels on
CEM and 17D9 cells and somewhat lower levels on A2.01.CD4.401 cells
(Table 1). Infection of the three cell lines with vCCR5 did not affect CD4 expression and only modestly reduced CXCR4 surface expression (1 to 20% reduction in >20
experiments) (Table 1 and data not shown). The ability of these cells
to fuse with X4 and R5 HIV-1 envelopes was evaluated in a syncytium
assay using 12E cells (CD4neg) infected with recombinant
vaccinia viruses expressing X4 or R5 envelope. In all cells, vCCR5
infection resulted in similar levels of surface CCR5 expression and the
acquisition of fusion potential with various R5 envelopes such as JR-FL
(Table 1), ADA, and Ba-L (not shown). The effect of CCR5 expression on
fusion with X4 envelopes varied in accordance with the levels of CD4 expression. In the case of CEM cells (CD4high), CCR5
expression resulted in a moderate reduction (5 to 30% in 10 experiments) of fusion with IIIB envelope-expressing cells. In
contrast, introduction of CCR5 into either 17D9 or A2.01.CD4.401 (CD4med) resulted in a reproducibly significant diminution
of the X4 fusion (40 to 65% inhibition in >20 experiments [Table 1
and data not shown]). Similar results were obtained with other
X4-dependent (RF and SF2) envelope-expressing effector cells (data not
shown).
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TABLE 1.
The relative density of surface CD4 on human T cells may
determine the ability of CCR5 to reduce CXCR4-mediated cell fusion
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Since we often noted variations in the levels of surface CCR5
expression following vCCR5 infection, it was of interest to
sort for
cell subsets expressing different levels of surface CCR5
(Fig.
1). Importantly, no reduction in the
expression of surface
CXCR4 was seen even on the CCR5
hi
subset (data not shown). As can be seen in Table
2, the vCCR5-infected
unsorted
A2.01.CD4.401 cells exhibited 44% reduction in fusion
with
IIIB-expressing target cells compared with the control (vSC8)-infected
cells. In contrast, the sorted CCR5
med and
CCR5
hi populations showed 65 and 93% reduction in IIIB
envelope-mediated
fusion, respectively (Table
2). Thus, introduction of
CCR5 into
CXCR4
+CD4
med T cells interfered with
their ability to fuse with an X4 envelope
in a CCR5 surface
concentration-dependent manner.
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FIG. 1.
Sorting of vCCR5-infected A2.01.401 cells. Cells were
infected with vCCR5-1107 at 10 PFU/cell for 6 h and then stained
with the CCR5-specific MAb 2D7 (or isotype control antibody) followed
by FITC-conjugated goat anti-mouse IgG. vSC8-infected cells were used
as negative controls. The cells were analyzed and sorted on a Becton
Dickinson FACSStar Plus. Profiles of the presorted cells (A) and of the
three sorted populations (CCR5neg, CCR5med, and
CCR5hi) (B) are shown. Data shown are from one of two
experiments with similar results.
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TABLE 2.
Sorting of surface CCR5hi A2.01.CD4.401 cells
(vCCR5 infected) increases the observed reduction in fusion with
T-tropic envelope-expressing cellsa
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Introduction of CCR5 into CD4+ CXCR4+ cells
reduces their ability to be infected with a T-tropic HIV-1 strain.
To further determine the biological relevance of the observed reduction
in cell fusion, vSC8- and vCCR5-infected A2.01.CD4.401 cells were
exposed to the T-tropic HIV-1 strain NL4-3 for 1 h. Viral entry
was measured after 12 to 18 h by a viral DNA PCR analysis. As
shown in Fig. 2, a significantly reduced
signal was seen in vCCR5-infected cells compared with
CCR5neg vSC8-infected cells. Based on the ACH-2-derived
standard curve, the frequency of infected cells was reduced twofold in
CCR5+ cells. Thus, introduction of CCR5 into
CD4+ CXCR4+ cells resulted in twofold reduction
in both X4 envelope fusion and X4 HIV-1 cell entry.
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FIG. 2.
Introduction of CCR5 into CD4+
CXCR4+ A2.01.401 cells reduces their ability to be infected
with a T-tropic HIV-1 strain. A2.01.401 cells (104) were
infected (in duplicate) with vaccinia virus recombinant control (vSC8)
or vCCR5-1107 at 20 PFU/cell and 7 h later were infected with the
T-tropic HIV-1 strain NL4-3 (MOI of 0.02) for 24 h. DNA lysates
were PCR amplified with gag-specific primers. In parallel,
DNA extracts from serially diluted ACH-2 cells were amplified as an
internal standard control. The data represent four experiments.
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Competition for association with CD4 may be responsible for the
reduction of fusion with X4 envelopes in cells expressing CCR5.
Several mechanisms may explain the observed reduction in the potential
for fusion of CD4+ CXCR4+ cells, expressing
surface CCR5 molecules, with X4 envelope-expressing cells. It is
possible that CCR5 expression, especially after infection with a
recombinant vaccinia virus, reduces CXCR4 (or CD4) transcription or
interferes with their transport to the cell surface. Indeed, in murine
3T3.CD4.401 cells that were coinfected with recombinant vaccinia
viruses expressing CXCR4 (vCBYF1; 5 PFU/cell) and CCR5 at increasing
PFU per cell, a gradual reduction in surface CXCR4 expression was noted
(data not shown). However, in all experiments with T-cell lines that
express endogenous CXCR4, even high expression of surface CCR5
following infection with a recombinant vaccinia virus resulted in a
minimal (Table 1) or no reduction in the surface expression of either
CXCR4 or CD4 as mentioned before. Another possibility is that surface
CCR5 and CXCR4 have a natural affinity for CD4 molecules and compete
for association with limiting CD4 molecules either before or after
encounter of the HIV-1 envelope.
To test this hypothesis, A2.01.CD4.401 cells were infected with either
vCCR5 (15 PFU/cell) or vCCR5 plus vCD4 (vCB3; 3 PFU/cell).
Fusion with
IIIB Env-expressing cells was inhibited by 60% after
infection with
vCCR5 compared with control (vSC8)-infected cells.
However, this
inhibition was completely reversed in cells coinfected
with vCCR5 and
vCD4, even though only a modest increase in the
density of surface CD4
was measured (
MFC, 206 and 251, respectively)
(Table
3). These findings support the hypothesis
put forward
by Pratt et al. (
29) and by our previous study
(
23) that the
fusion potential of a cell with X4 or R5
envelopes may depend
on threshold concentrations of CD4 and coreceptors
(and possibly
of CD4-CCR5 and CD4-CXCR4 complexes). Thus, even a modest
increase
in CD4 surface concentration may be sufficient to increase the
interactions between CD4 and CXCR4 above the threshold required
for
initiation of fusion with T-tropic envelope-expressing cells
(despite
the presence of CCR5 at high density). In a second approach,
we used a
biochemical assay that directly evaluates CD4-CXCR4
interactions. We
have previously demonstrated that coimmunoprecipitation
of surface CD4
and CXCR4 from CD4
+ CXCR4
+ human cell lines was
achieved after exposure of cells to sgp120
at 37°C (
22).
In the present study, vSC8- or vCCR5-infected
A2.01.401 cells were
incubated with sgp120 (LAI) for 1 h at 37°C
followed by cell
lysis and immunoprecipitation with OKT4-conjugated
Sepharose beads. The
relative amounts of CXCR4 and CD4 in the
immunoprecipitates were
determined by Western blotting using anti-CXCR4
and anti-CD4 polyclonal
antibodies (Fig.
3). In four experiments,
the ratios of CXCR4/CD4 precipitation in CCR5-expressing A2.01.CD4.401
cells were two- to fourfold lower than in cells infected with
control
vaccinia virus (Fig.
3). Thus, direct
evidence was provided
in support of the hypothesis that in cells
expressing both CXCR4
and CCR5, the ability of CXCR4 to associate with
CD4 molecules
(after exposure to HIV-1 envelope) is reduced.
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TABLE 3.
Increased density of surface CD4 on human T cells can
reverse the ability of CCR5 to reduce CXCR4-mediated
cell fusiona
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FIG. 3.
Reduced coprecipitation of CD4 and CXCR4 from A2.01.401
cells infected with vCCR5. vSC8- or vCCR5-infected A2.01.CD4.401 cells
(7-h infection, 15 PFU/cell) were incubated with gp120 (LAI; Intracel,
Seattle, Wash.) at 10 µg/ml for 1 h at 37°C. Cell lysates were
immunoprecipitated with antibody OKT4 covalently linked to protein
G-Sepharose beads. Eluted samples were analyzed by Western blotting
with rabbit polyclonal IgG raised against the N terminus of CXCR4. The
same membranes were reacted with polyclonal rabbit antiserum against
huCD4, followed by HRP-conjugated antibody against rabbit IgG. The
bands were detected using chemiluminescence, and the CXCR4/CD4 ratios
in the immunoprecipitates were determined by densitometric analysis.
The data are representative of four experiments.
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Anti-CCR5 antibodies can reverse the reduction in fusion with X4
envelopes seen in A2.01.401 cells infected with vCCR5.
The data
described above support the possibility that CCR5 competes with CXCR4
for association with CD4 molecules. This competition may take place
either after binding of the HIV-1 envelope or due to constitutive
interactions between CD4 and coreceptors as previously demonstrated
(9, 23, 36). To further dissect these interactions, a panel
of murine MAbs and rabbit polyclonal antibodies specific for either the
N terminus (identified by "N") or the three extracellular loops
(EC1, EC2, and EC3) of CCR5 (17, 24) were used. These antibodies were tested in parallel for their ability to block the
fusion of vCCR5-infected A2.01.CD4.401 cells with R5 (JR-FL) Env-expressing cells and to reverse the reduction in fusion of the same
cells with X4 Env-expressing cells (Table
4). Of the panel of antibodies used, MAb
2D7 (EC2) was the most effective in blocking R5-envelope fusion (85%).
However, MAbs 502 (CCR5/N) and rabbit anti-CCR5 (N peptide) also
blocked R5 envelope fusion by 50 to 60% (Table 4 and reference
37). In the same experiment, infection of
A2.01.CD4.401 cells with vCCR5 resulted in 45% inhibition of their
fusion with X4 Env-expressing cells. This reduction was reversed by the
same murine anti-CCR5 MAbs (2D7; R&D product no. 502) and rabbit
anti-CCR5 (N) IgG that blocked the R5-envelope fusion. Interestingly,
one MAb (R&D product no. 549) did not block R5 Env-mediated cell fusion
but did reverse the inhibition of fusion with X4 Env-expressing cells.
This MAb was recently categorized as recognizing a multidomain (MD)
CCR5 epitope (24). In a separate set of experiments, the
same panel of antibodies were tested for the ability to reverse the
reduction in LAI (or NL4-3) entry into A2.01.CD4.401 cells infected
with vCCR5. In the infectivity experiments, vCCR5 infection of
A2.01.CD4.401 cells resulted in 53% reduction of X4 viral entry. In
three experiments, the CCR5-specific MAbs 2D7 (EC2), 502 (N), and 549 (MD) and rabbit polyclonal IgG (CCR5/N) restored viral entry to 80 to
95% of level for control (vSC8)-infected A2.01.401 cells, as
determined by densitometry (Fig. 4 and
data not shown). Together, these data suggest that the reduction in X4-envelope fusion potential resulting from the introduction of CCR5
into cells expressing endogenous CD4 and CXCR4 was mediated by the
surface CCR5 molecules in a specific manner.
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TABLE 4.
Anti-CCR5 MAb and rabbit IgG that block fusion with cells
expressing M-tropic envelope can reverse the reduction in fusion with
T-tropic envelope due to CCR5 expression in
A2.01.CD4.401 cellsa
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FIG. 4.
Treatment of vCCR5-infected A2.01.401 cells with
anti-CCR5 antibodies can increase their susceptibility to infection
with a T-tropic HIV-1 strain. A2.01.401 cells were infected with
recombinant vaccinia virus vSC8 or vCCR5 (20 PFU/cell) for 7 h.
When indicated, cells were treated for 1 h with anti-CCR5 or
control antibodies at 37°C. Treated and untreated cells were exposed
to HIV-1 strain LAI (MOI of 0.02) for 1 h at 37°C, after which
the virus and antibodies were washed away. DNA extraction and PCR
analysis (gag primers) were conducted after 24 h as
described in Material and Methods and in the legend to Fig. 2. The data
represent one out of four experiments with similar results. NRIgG,
normal rabbit IgG.
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Overexpression of CXCR4 can reduce CCR5-dependent cell fusion with
R5 envelope-expressing cells.
Thus far, it was found that a
competition for association with CD4 molecules favors CCR5-CD4
association and results in an inhibition of CXCR4-dependent fusion. It
was of interest to determine if this competition could be reversed by
increasing the expression of CXCR4 in the same cells. To address this
question, 3T3.CD4.401 (14) cells were coinfected with vCXCR4
or vCCR5 at different ratios. Since this CD4.401-transfected cell line
expresses a higher level of CD4 than do A2.01.401 cells, no significant
inhibition of fusion with either a T-tropic or M-tropic envelope was
seen in cells infected with vCCR5 and vCXCR4 at a 1:1 ratio (each at 5 PFU/cell) (data not shown). However, coinfection with vCCR5 and vCXCR4
at a 1:4 ratio resulted in a reduced fusion capacity with target cells
expressing the JR-FL, Ba-L, or ADA R5 envelope (Table
5 and data not shown). Under these
conditions, the cells expressed 20 to 30% lower levels of surface CCR5
compared with cells infected only with vCCR5. However, the reduction in
fusion ranged between 50 and 65% in three separate experiments. The
role of surface CXCR4 in this inhibition was demonstrated by treatment with phorbol ester myristate acetate (PMA), which was shown to induce
downmodulation of CXCR4 but not of CCR5 (15). While CD4 molecules are normally highly susceptible to PMA-induced
downmodulation, the tailless CD4.401 molecules do not internalize
following PMA treatment (1, 14). As shown in Table 5,
PMA-treated cells lost 80% of their surface CXCR4 molecules, but no
increase in surface CCR5 was observed. However, the PMA-treated cells
fully recovered their ability to fuse with R5 envelopes (Table 5 and data not shown). These data suggest that under conditions of CXCR4 overexpression compared with CCR5, cells may be more predisposed to
infection with T-tropic (X4-dependent) viral strains. In subsequent experiments, we tested a panel of commercially available CXCR4-specific MAbs, as well as our rabbit polyclonal anti-CXCR4 IgG. We found that
the only antibodies that could inhibit X4-envelope fusion were 12G5 (30 to 40% inhibition) and rabbit anti-CXCR4 (N) IgG (45 to 55%
inhibition). These antibodies could also reverse the reduction of
fusion with R5 Env-expressing cells observed when 3T3.CD4.401 cells
were coinfected with vCCR5 and vCXCR4 at a 1:4 ratio (data not shown).
Treatment of macrophages with anti-CCR5 antibodies or
-chemokines can enhance their fusion with X4 envelope-expressing
cells.
Based on the above findings in cell lines, It was important
to determine if the coreceptor competition for association with CD4 is
operative in vivo. To address this question, we chose to examine
primary cells known to express multiple coreceptors and a relatively
low number of surface CD4 molecules. It was previously shown by several
laboratories that MDM preferentially fuse with M-tropic (R5) HIV
envelopes and support infection with M-tropic better than T-tropic
lab-adapted viral strains (4, 7, 8, 30). This restricted
susceptibility could not be attributed simply to lack of CXCR4
expression on MDM (9, 23, 30, 38) and may, at least
partially, be due to a decrease in "fusion-active" CXCR4 molecules
on macrophages (23). In addition, this restricted tropism
profile could also be explained by the competition phenomenon described
above (9, 23). Thus, we treated MDM with the panel of
anti-CCR5 MAbs and rabbit IgGs, alone or in combination, and tested
their ability to fuse with cells expressing the IIIB envelope. As
depicted in Fig. 5, elutriated monocytes
generated high numbers of syncytia with TF228 (IIIB/BH10 Env) cells
(269 ± 5 syncytia), while the MDM derived from them fused very
poorly with the same cells (8 ± 1 syncytia). Treatment with MAb
2D7, 502, or 549 or with the rabbit anti-CCR5 (N) antibody increased
the number of syncytia only modestly (25 to 35 syncytia per well).
However, treatment of cells with a combination of antibodies against
the EC2 (2D7) and N terminus (MAb 502 or rabbit polyclonal IgG)
resulted in a more significant increase in fusion with IIIB
Env-expressing cells (87 ± 7 syncytia). Since -chemokine
analogs are under development as therapeutic agents for HIV-1-infected
individuals (33) it was important to determine whether
treatment of MDM with CCR5-binding -chemokines could result in
augmented fusion with X4 envelopes. As depicted in Fig.
6, treatment of MDM with increasing
concentrations of MIP-1-, MIP-1-, and RANTES (1 to 100 ng/ml)
resulted in a dose-dependent reduction of R5-fusion (JR-FL) and in a
gradual increase in the X4 (IIIB) syncytium formation. No such increase was seen in MCP-1 (or I309 [not shown])-treated MDM. The observed increase in X4 fusion could not be attributed to protein G signaling via the CCR5 receptor (20), since treatment of cells with PT did not prevent it (Fig. 6). Thus, one likely explanation for both
findings is that binding of the -chemokines (or anti-CCR5 antibodies) either reversed or prevented the association of CCR5 to
surface CD4 molecules, which in turn allowed better CD4-CXCR4 association and improved the ability of cells to fuse with T-tropic envelopes. We still observed considerably fewer IIIB syncytia than with
the elutriated monocytes of the same donor, suggesting that several
mechanisms may be responsible for the reduced function of CXCR4
molecules in differentiated macrophages. We have previously shown that
the predominant form of CXCR4 on the surface MDM (but not in monocytes)
appears as high-molecular-weight species rather than as a monomer.
These high-molecular-weight species do not associate with CD4
molecules, as determined by coimmunoprecipitation experiments
(23). In contrast, CCR5 molecules were coprecipitated equally well with CD4 in monocytes and MDM. Thus, the functionality of
CXCR4 molecules in primary cells such as monocytes/macrophages may be
determined by multiple factors including posttranslational modifications, relative densities of other coreceptors, and a competition for association with surface CD4 molecules.
View larger version (16K):
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|
FIG. 5.
Anti-CCR5 antibody treatment can modestly increase the
fusion efficiency of macrophages with X4 envelopes. Elutriated
monocytes (Mon) and the macrophages derived from them after 5-day
cultures (MDM) were untreated or treated with various CCR5-specific
murine (mouse [M] or normal rabbit [NR]) MAbs (or isotype control
antibody) or with rabbit (R) polyclonal anti-CCR5 IgG (or preimmune
IgG) at 10 µg/ml for 1 h at 37°C; the cells were then mixed at
1:1 ratio with TF228 cells expressing IIIB/BH10 envelope in
triplicates. Syncytia were scored after 18 h. Data represent one
of four experiments.
|
|
View larger version (16K):
[in this window]
[in a new window]
|
FIG. 6.
Treatment of MDM with -chemokines result in a
PT-resistant reduction of R5 fusion and a parallel increase in X4
fusion. MDM were generated as described in the legend to Fig. 5. MDM
were treated (open symbols) or untreated (closed symbols) with PT (1 µg/ml) at 37°C for 1 h and washed twice. Treated and untreated
cells were incubated with a combination of MIP-1, MIP-1, and
RANTES at increasing concentrations (1, 10, and 100 ng/ml) for 1 h
at 37°C. All groups were then mixed at 1:1 ratio with either
12E1/vCB28 (JR-FL envelope) ( ,  ) or TF228 cells expressing
IIIB/BH10 envelope ( ,  ). Control cells were treated with MCP-1 at
100 ng/ml and were mixed with 12E1/vCB28 ( ,  ) or TF228 cells
( ,  ). Syncytia were scored after 18 h. The experiment was
repeated three times.
|
|
| |
DISCUSSION |
This study was designed to test the hypothesis that the efficiency
of HIV-1-cell fusion is influenced not only by the presence of CD4 and
the appropriate coreceptor (CXCR4 or CCR5) but also by the levels of
other coreceptors expressed by the same target cells. Therefore, in the
setting of limited surface CD4, the presence of both CCR5 and CXCR4 at
given concentrations will yield fewer successful viral interactions
than in the presence of a single chemokine receptor at the same
concentration, using viruses (or target cells expressing viral
envelopes) of the appropriate tropism. This is an important issue to
address since most of the target cells for HIV-1 infections in vivo
express multiple coreceptors and may be subjected to in vivo factors
that differentially affect the levels of individual coreceptors. Among
the cellular targets for HIV-1 at the mucosal surfaces are dendritic
cells and macrophages, both of which cell types express relatively low
levels of surface CD4 (25). In previous studies, we and
others provided evidence that CD4, the primary receptor of HIV-1, may
have a natural affinity for the chemokine receptors CCR5 and
CXCR4 (9, 23, 32, 35, 36). Thus, the susceptibility of
cells with limited CD4 to infection with viral strains of different
tropism may be influenced not only by the density of the appropriate
coreceptors but also by a competition for association with CD4 either
before or after exposure to viral envelopes. In this study, we tested
this hypothesis by introducing CCR5 into CD4+
CXCR4+ cells and measuring their ability to fuse with X4
and R5 envelopes and their susceptibility to infection with T-tropic
HIV-1 strains. We also coinfected NIH 3T3.CD4.401 cells with
recombinant vaccinia viruses expressing CCR5 or CXCR4 at different ratios.
The principal findings in this current study were as follows. (i)
Infection of CD4+ CXCR4+ T cells with
recombinant vCCR5 resulted in a significant reduction in their fusion
with effector cells expressing X4 envelopes. Consistent with these
findings, a similar reduction was seen in their susceptibility to
infection with the T-tropic strains LAI and NL4-3 (Table 1; Fig. 2).
(ii) The reduction in X4-dependent fusion and infection was inversely
correlated with the density of surface CD4 and positively correlated
with the levels of CCR5 surface expression (Tables 1 to 3; Fig. 1 and
2; data not shown). (iii) CCR5 surface expression played a direct role
in the reduction of CXCR4-dependent fusion, since several antibodies
against the N terminus and second extracellular loop of CCR5 (EC2)
reversed this inhibition. (iv) The inhibitory effects of CCR5
correlated with a competition for association with CD4, since
coimmunoprecipitation of CD4 and CXCR4 molecules was reduced two- to
threefold in vCCR5-infected cells. Furthermore, the inhibition was
reversed by increasing the levels of surface CD4 (Table 3). (v)
Overexpression of CXCR4 compared with CCR5 resulted in reduced fusion
with R5 Env-expressing cells. (vi) Treatment of macrophages with a
combination of anti-CCR5 antibodies (N plus EC2) or with a mixture of
CCR5-binding -chemokines resulted in augmented fusion with X4
Env-expressing cells.
Platt et al. (29) have shown that the concentrations of CD4
and CCR5 required for efficient infection of HeLa cells by M-tropic HIV-1 are interdependent, and the requirement for each is increased when the other component is present in a limiting amount. Our data
suggest that this interdependence is further complicated by the
presence of other coreceptors in the same cells. Several mechanisms may
explain the observed competition. (i) Overexpression of one chemokine
receptor may result in a reduction in the expression of other
coreceptors (i.e., transport interference). However, in most of the
experiments described in this study, expression of CCR5 in
CD4+ CXCR4+ T cells reduced their X4 fusion
without significant alterations in their CXCR4 surface expression. (ii)
According to the second model, the fusion process is a multistep event
that requires recruitment first of CD4 and then of the appropriate
coreceptor into a stable trimolecular complex. Unlike the high-affinity
binding between envelope and CD4, the binding of envelope to the
coreceptors is of much lower affinity. The additional interactions
between the coreceptors and CD4 within the same complexes may further
stabilize them. As shown in this study, the recruitment of the
appropriate coreceptor into the fusion complex may be negatively
affected by the presence (and density) of other coreceptors on the cell membrane. According to this model, agents that can bind specifically to
relevant regions of the wrong coreceptor could indirectly promote recruitment of the appropriate coreceptor into the trimolecular complex. Such a mechanism is at least partially supported by our finding that several antibodies against CCR5 (or CXCR4) N terminus and
EC2 could reverse the fusion inhibition observed in our experimental system. It is also supported by a recent study (10) in which the half-life of CD4-Env binding was calculated to be <1 min, while
the half-life for coreceptor recruitment was 5.8 min (for JR-FL
envelope). (iii) According to the third model, CCR5 and CXCR4 may have
a tendency to constitutively associate with CD4 molecules in some
cells. In cells with limited CD4 molecules, the ratio of preexisting
CD4-CCR5 to CD4-CXCR4 complexes may contribute to the susceptibility
profile of the cells. In this scenario, changes in the relative
densities of the coreceptors could have a major impact due to
competition for association with a limited number of CD4 molecules. Two
independent studies from our laboratories provided evidence that
CD4-coreceptor complexes can be coimmunoprecipitated from monocytes and
macrophages by using either an anti-CD4 (OKT4 MAb) or anticoreceptor
antibody as the precipitating agent (9, 23, 36). This
spontaneous association may be stronger for CCR5-CD4 than for
CXCR4-CD4, although no direct measurements of their association rates
were attempted in this or previous studies. Furthermore, in this study,
we demonstrated that treatment of macrophages with combinations of
anti-CCR5 antibodies or with -chemokines resulted in a
dose-dependent reduction in R5 fusion and an increase in R4 fusion.
Importantly, the increase in X4 fusion was not sensitive to treatment
of cells with the G-protein inhibitor PT. Thus, the observed effect was
not due to signaling and/or cell activation as previously suggested by
Kinter et al., based on experiments with peripheral blood mononuclear
cells (20). In a separate set of experiments, it was found
that treatment of macrophages with a combination of anti-CCR5
antibodies (2D7 and 3C3) plus staphylococcal protein G, and with
RANTES, resulted in a significant increase (78%) in their fusion with
LAV Env-expressing cells (T. Stanchev and C. Broder, unpublished data).
Both mechanisms may be operational in vivo to various degrees in
different cell types. We and others have demonstrated constitutive and
gp120-induced association between CD4 and coreceptors (9, 23, 32,
36). Such mechanisms may also shed some light on the recent
findings by Yi et al. that the dualtropic viruses 89.6 and DH12 utilize
primarily CCR5 during infection of normal macrophages but use only
CXCR4 during infection of CCR5neg macrophages
(37). It is conceivable that the preferential use of CCR5 in
normal macrophages reflects the higher density of preexisting CD4-CCR5
complexes in these cells (23). Competition for association with CD4 may be a contributing factor to the efficiency of viral cell
entry and cell-to-cell transmission in vivo, since most
HIV-1-susceptible cells express multiple chemokine receptors.
Furthermore, several important target cells of HIV-1, such as
macrophages and dendritic cells, express relatively low concentrations
of surface CD4 molecules (26).
Coreceptor competition may also explain earlier studies with human
thymocytes in which preferential infection of double-positive thymocytes with T-tropic viruses was observed (3, 21, 28, 33), despite expression of low-level CCR5 in both double-positive and single-positive thymocyte subpopulations as recently demonstrated (39). Significantly higher expression of CXCR4 compared with CCR5 was found on immature double-positive thymocytes (but not on the
mature single-positive thymocytes) (21, 39). Based on the
findings in the present study with 3T3.CD4.401 cells (Table 5), high
surface CXCR4/CCR5 ratios may result in the inhibition of CCR5-mediated
cell fusion with M-tropic envelope-expressing cells.
In addition to the absolute numbers of coreceptor molecules,
posttranslational modifications may affect their ability to form complexes with CD4 and/or HIV-1 envelope, resulting in a reduced or
enhanced fusion potential. In addition to previously published studies
(11, 23), it was recently found that CXCR4 with removed N-linked glycosylation sites can function as a coreceptor for R5 HIV-1
envelope glycoproteins (D. J. Chabot, X. Xiao, D. S. Dimitrov, and C. C. Broder, submitted for publication).
Coreceptor competition in vivo may also be affected by the cytokine
milieu in the tissues and mucosal surfaces. Several cytokines were
shown to upregulate or downmodulate CD4 and coreceptor surface expression in various cell types (16, 26, 40). Thus, changes in the cytokine milieu due to infections or vaccinations, and high
local production of -chemokines, may result in either increase or
decrease in the susceptibility of target cells to infection with X4 and
R5 viruses. Recent findings in our laboratory showed that macrophages
treated with several proinflammatory cytokines are more susceptible to
infection with X4 viruses while demonstrating increased resistance to
R5 infection. Both phenomena could not be attributed to changes in
surface expression of CCR5 or CXCR4 but correlated better with
-chemokine production (M. Zaitseva and S. Lee, submitted for publication).
Together, these data contribute to understanding the possible effects
of in vivo alterations in CD4 and coreceptor densities (or coreceptor
availability) on HIV-1 cell entry and disease progression. Furthermore,
the development of -chemokine analogs as antiviral agents (28,
32, 35) should take into account their potential to alter
coreceptor-CD4 interactions and to alter the susceptibility of target
cells to infection with viruses of different coreceptor usage (2,
27, 31).
| |
ACKNOWLEDGMENTS |
Shirley Lee and Cheryl K. Lapham made equal contributions to this study.
We thank Zdenka Jonak for providing the TF228 cell line; Keith Peden
for providing viral stocks; and Keith Peden, Marina Zaitseva, and
Joshua Farber for critical reviews of the manuscript.
This work was supported in part by a grant from the NIH Intramural AIDS
Targeted Antiviral Program (H.G.), by a grant from the Office of
Women's Health, FDA (H.G.), and by NIH grant RO1AI43885 (C.C.B.).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Division of
Viral Products, Center for Biologics Evaluation and Research, FDA,
HFM-454. Bldg. 29B/Rm. 4NN04, 8800 Rockville Pike, Bethesda, MD 20892. Phone: (301) 827-0784. Fax: (301) 496-1810. E-mail:
GoldingH{at}CBER.FDA.gov.
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Journal of Virology, June 2000, p. 5016-5023, Vol. 74, No. 11
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Abstract
Introduction
