Previous Article | Next Article 
Journal of Virology, May 2000, p. 4404-4413, Vol. 74, No. 9
0022-538X/00/$04.00+0
N-Linked Glycosylation of CXCR4 Masks Coreceptor
Function for CCR5-Dependent Human Immunodeficiency Virus Type
1 Isolates
Donald J.
Chabot,1
Hong
Chen,1
Dimiter S.
Dimitrov,2 and
Christopher C.
Broder1,*
Department of Microbiology and Immunology,
Uniformed Services University of the Health Sciences, Bethesda,
Maryland 20814-4799,1 and Laboratory of
Experimental and Computational Biology, National Cancer
Institute-Frederick Cancer Research and Development Center,
National Institutes of Health, Frederick, Maryland
21702-12012
Received 17 December 1999/Accepted 8 February 2000
 |
ABSTRACT |
The chemokine receptors CXCR4 and CCR5 are the principal
coreceptors for infection of X4 and R5 human immunodeficiency virus type 1 (HIV-1) isolates, respectively. Here we report on the unexpected observation that the removal of the N-linked glycosylation sites in
CXCR4 potentially allows the protein to serve as a universal coreceptor
for both X4 and R5 laboratory-adapted and primary HIV-1 strains. We
hypothesize that this alteration unmasks existing common extracellular
structures reflecting a conserved three-dimensional similarity of
important elements of CXCR4 and CCR5 that are involved in HIV envelope
glycoprotein (Env) interaction. These results may have far-reaching
implications for the differential recognition of cell type-dependent
glycosylated CXCR4 by HIV-1 isolates and their evolution in vivo. They
also suggest a possible explanation for the various observations of
restricted virus entry in some cell types and further our understanding
of the framework of elements that represent the Env-coreceptor contact sites.
| |
INTRODUCTION |
Coreceptor molecules belonging or
related to the chemokine receptor family of seven-transmembrane-domain
G-protein-coupled receptors are required along with CD4 for human
immunodeficiency virus (HIV-1) envelope glycoprotein (Env)-mediated
membrane fusion and virus entry (reviewed in references 8, 12,
27, 36, 38, and 64). Although some 15 related coreceptor molecules have been shown by one or more
laboratories to function in the fusion or entry of at least one HIV
isolate, it is now well recognized that the principal HIV-1 coreceptors
remain the initially discovered CXC chemokine receptor CXCR4 and the
CC-chemokine receptor CCR5 (7, 21). Previously, it was
hypothesized that the very first step in HIV-1 entry involves the
formation of a trimolecular complex between the viral Env, CD4, and a
coreceptor molecule (18, 33, 52), and both functional and
biochemical evidence to support this hypothesis has been reported
(35, 59, 84, 88, 90). Defining the elements of the
coreceptor molecules involved in these interactions is of critical
importance for our understanding of the virus entry mechanism. To date,
multiple studies, largely employing the use of genetic chimeras, have
provided an extensive framework of important structural information on
several coreceptors, which has been reviewed in detail (10, 12,
34, 38, 64). Although not in complete agreement with each other,
these studies have clearly shown that multiple extracellular domains
are required for coreceptor function, which involves cooperativity
between particular elements of the N-terminal domain and one or more of the three extracellular loops. However, there remains the possibility that many of the chimeric receptors produced in these studies are
functional due to compensatory conditions brought about by distal
regions of the background receptor, and this could result in regions
important for coreceptor function being overlooked (64).
We recently studied a large battery of CXCR4 mutants (23).
Those results indicated that negatively charged glutamic acid residues
in the N terminus and the aspartic acid residue D97 in extracellular
loop 1 (ecl-1) are important for CXCR4 function as a coreceptor for X4
isolates. We and others have speculated that the role of the negatively
charged CXCR4 residues is related to their electrostatic interactions
with positively charged Env residues in the V3 loop region of the
previously classified syncytium-inducing X4 Envs (32, 50).
However, other consequences of the site-directed mutagenesis,
specifically the effect of removal of N-linked glycosylation sites
(resulting in what will henceforth be referred to as non-N-linked glycosylated CXCR4) on the coreceptor function of CXCR4, have not been
completely explored. Here we report the first observation of an
unexpected and dramatic effect of N-linked glycosylation site removal
in an AIDS-related molecule: the expansion of both laboratory-adapted
and primary R5 HIV-1 isolates.
We found that CXCR4 N-linked glycosylation results in the loss of
coreceptor activity for those HIV-1 isolates which are dominant during
the early stages of HIV-1 disease as well as in virus transmission to
an uninfected individual (so-called non-syncytium-forming, macrophage-tropic R5 isolates). Thus, alleviation of the N-linked glycosylation of CXCR4 can allow the protein to serve as a universal coreceptor for some R5 and X4 HIV-1 Envs. Taken together with other
reports, our data suggest that there is an existing underlying conserved framework of elements between CXCR4 and CCR5 and that removal
of masking glycosylation moieties reveals these structures. Thus,
differential glycosylation of CXCR4 may modulate the ability of
particular HIV-1 isolates to infect various cell types. The possible
existence of CXCR4 glycoforms with altered coreceptor activities,
perhaps as the result of cell type-dependent glycosylation differences,
may have far-reaching implications for the differential recognition of
CXCR4 by HIV-1 isolates, for their evolution in vivo, and for the
mechanism of HIV-1 entry into cells, as well as for future development
of novel drugs and vaccines.
| |
MATERIALS AND METHODS |
Cells and culture conditions.
Human HeLa cells and simian
BSC-1 cells were obtained from the American Type Culture Collection,
Manassas, Va., while human glioblastoma cell line U373-MG and the
U373-MG-CD4+ derivative cell line were provided by Adam P. Geballe, Fred Hutchinson Cancer Research Center, Seattle, Wash.
(53). Cell cultures were maintained at 37°C in a
humidified 5% CO2 atmosphere. HeLa and BSC-1 cell
monolayers were maintained in Dulbecco's modified Eagle's medium
(Quality Biologicals, Gaithersburg, Md.) supplemented with 10% bovine
calf serum (BCS), 2 mM L-glutamine, and antibiotics (DMEM-10). U373 cell monolayers were maintained in the same way except
that 15% BCS was used (DMEM-15). U373-MG-CD4+ cell
monolayers were also supplemented with 200 µg of G418 (Calbiochem, La
Jolla, Calif.)/ml.
Plasmids and recombinant vaccinia viruses.
For Env
expression, we employed a battery of plasmids and recombinant vaccinia
viruses encoding the env genes from several R5, X4, and R5X4
HIV-1 isolates. The following recombinant vaccinia viruses expressing
gp160 from different HIV-1 isolates (whose names are in parentheses)
were used: vCB-28 (JR-FL), vCB-32 (SF162), vCB-34 (SF2), vCB-39 (ADA),
vCB-41 (LAV), vCB-43 (Ba-L), vCB-52 (CM235), vCB-53 (CM243)
(17), and vDC-1 (89.6 [28]) gp160 linked to
a strong synthetic vaccinia virus early-late promoter (pSC59
[25]). Purified vaccinia virus stocks were used at a multiplicity of infection of 10 PFU/cell. Plasmids encoding functional gp160, from a variety of HIV-1 primary isolates, linked to the T7
promoter were obtained from the National Institutes of Health AIDS
Research and Reagent Program (Rockville, Md.). They include 93BR019.10
(clade F/B), 92UG975.10 (clade G), 93BR029.2 (clade F), 92TH022.4
(clade E), MA301965.26 (clade C), 92BR025.9 (clade C), 91US005.11
(clade B), 92BR020.4 (clade B), 92UG037.8 (clade A), and 92RW020.5
(clade A). For CD4 expression, we used recombinant vaccinia virus vCB-3
(19). Bacteriophage T7 RNA polymerase was produced by
infection with vTF1-1 (containing the P11 natural late vaccinia virus
promoter) (2). The Escherichia coli lacZ gene
linked to the T7 promoter was introduced into cells by infection with
vaccinia virus recombinant vCB21R-LacZ, which was described previously
(3). For coreceptor expression, we employed recombinant vaccinia viruses or one of two alternative plasmid expression protocols. Vaccinia virus vHC-1 (also vvCCR5-1107), encoding CCR5, was
described previously (90). Vaccinia viruses encoding
wild-type and mutant CXCR4 (vHC-3 [wild-type CXCR4], vHC-5 [N176A
CXCR4], vHC-6 [C-terminal CXCR4 deletion], vHC-7 [N11A N176A
CXCR4], and vHC-8 [N11A D187A CXCR4]) were prepared by subcloning
the appropriate cDNA into the SmaI site of pMC1107
(22). The recombinant viruses were then obtained by standard
techniques employing (Ecogpt) selection (20). For
cell fusion assays, we either infected cells with the appropriate
vaccinia virus encoding a chemokine receptor linked to the 7.5k
vaccinia virus promoter or transfected cell monolayers with plasmids
containing coreceptor genes linked to a strong synthetic vaccinia virus
early-late promoter (pSC59) (25) followed by infection
2 h later with the Western Reserve (WR) wild-type strain of
vaccinia virus, and transfection of monolayers was performed with DOTAP
{N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethylammonium methylsulfate}. For virus infection assays, cells were transfected with coreceptor genes linked to the cytomegalovirus promoter in pCDNA3
(Invitrogen, Carlsbad, Calif.) and transfection was performed by the
DEAE-dextran procedure, as described below.
Mutagenesis.
CCR5 and CXCR4 mutations were induced by using
a QuikChange site-directed mutagenesis kit (Stratagene, La Jolla,
Calif.) in accordance with the manufacturer's instructions. Two
mutagenic polyacrylamide gel electrophoresis (PAGE)-purified
oligonucleotides were used per mutation. The identities of all CXCR4
mutant constructs were confirmed by DNA sequencing.
Cell-cell fusion assays.
Fusion between Env-expressing and
receptor-expressing cells was measured by a reporter gene assay in
which the cytoplasm of one cell population contained vaccinia
virus-encoded T7 RNA polymerase and the cytoplasm of the other
contained the E. coli lacZ gene linked to the T7 promoter;
-galactosidase (-Gal) was synthesized in fused cells
(66). Vaccinia virus-encoded proteins were produced by
incubating infected cells at 31°C overnight (9). Cell-cell fusion reactions were conducted with the various cell mixtures in
96-well plates at 37°C. Typically, the ratio of CD4-expressing to
Env-expressing cells was 1:1 (2 × 105 total cells per
well, 0.2-ml total volume). Cytosine arabinoside (40 µg/ml) was added
to the fusion reaction mixture to reduce nonspecific -Gal production
(9). For quantitative analyses, Nonidet P-40 was added
(0.5% final) at 2.5 h and aliquots of the lysates were assayed
for -Gal at ambient temperature with the substrate chlorophenol
red--D-galactopyranoside (Roche Molecular Biochemicals). Fusion results were calculated and expressed as rates of
-Gal activity (change in optical density at 570 nm per minute × 1,000) (66).
HIV-1 infection studies.
U373-MG-CD4+ target
cells were prepared in 48-well plates and transfected with the desired
coreceptor-encoding plasmid by the DEAE-dextran method. Briefly, 0.2 µg of DNA mixed in 110 µl of DMEM-2.5 with 100 µM chloroquine
diphosphate and 1.1 µl of a DEAE-dextran stock (10 mg/ml) in
phosphate-buffered saline (PBS) was added to each well of semiconfluent
cells. After 4 h, the medium was replaced with PBS-10% dimethyl
sulfoxide for 2 min. Monolayers were then washed with PBS and incubated
overnight in DMEM-15. Viral infection assays were performed with a
luciferase reporter HIV-1 Env pseudotyping system (29).
Viral stocks were prepared, as previously described, by transfecting
293T cells with plasmids encoding the luciferase virus backbone
(pNL-Luc-ER) and Env from HIV strain JR-FL (67) or NL4-3
(LAV) (1, 71). The resulting supernatant was clarified by
centrifugation for 10 min at 2,000 rpm in a Sorvall RT-7 centrifuge
(RTH-750 rotor) and stored at 4°C. Monolayers were infected with 100 µl of virus preparation containing 8 µg of DEAE-dextran/ml. After
2 h, 0.5 ml of DMEM-15 was added to each well. Cells were lysed at
72 h postinfection by resuspension in 105 µl of cell lysis
buffer (Promega, Madison, Wis.), and 50 µl of the resulting lysate
was assayed for luciferase activity, using an equal volume of
luciferase substrate (Promega).
Western blot analysis.
BSC-1 cell monolayers were infected
overnight with vaccinia virus encoding wild-type or mutant CXCR4 at
multiplicity of infection of 10. Western blot detection of CXCR4 was
performed essentially as described previously (49) but with
some modifications. Cells were extracted with 0.5% Triton X-100 in 20 mM Tris-HCl, pH 8.0, containing 100 mM NaCl, and the nuclei were
removed by centrifugation. Extracts from 5 × 104
cells (total) were loaded per well onto a sodium dodecyl sulfate (SDS)-10% polyacrylamide gel; samples were incubated for 30 min at
37°C and not boiled, since boiling often induces aggregation of
seven-transmembrane-domain proteins. Following electrophoresis, proteins were transferred to nitrocellulose paper, the blot was probed
with 4G10, an anti-CXCR4 murine monoclonal antibody (MAb) (C. C. Broder and E. A. Berger, unpublished observations). The blot was then
incubated with horseradish peroxidase-conjugated rabbit anti-mouse
immunoglobulin G and developed with a Pierce (Rockford, Ill.)
SuperSignal chemiluminescence kit.
Cell surface staining.
Coreceptor expression levels were
determined by fluorescent-antibody cell surface staining. Appropriate
cells were transfected or infected and incubated overnight as described
above. Cells were then kept on ice; 106 cells were washed
twice with PBS and once with PBS containing 2.5% BCS, incubated in PBS
containing 2.5% BCS and 4 µg of 2D7 MAb (for CCR5) or 2 µg of 12G5
or 4G10 MAb (for CXCR4)/100 µl for 1 h washed three times with
PBS, incubated in PBS containing 2.5% goat serum and 10 of
phycoerythrin-labeled goat anti-mouse immunoglobulin G per 100 µl for
45 min, washed three times with PBS, and fixed with PBS-2%
paraformaldehyde. Fluorescence was measured with a Coulter (Miami,
Fla.) EPIC XL flow cytometer.
Molecular modeling.
Theoretical three-dimensional structures
of the HIV-1 coreceptors CXCR4 and CCR5 were based on the physically
determined structures of both bacteriorhodopsin and rhodopsin (79,
85, 86), as well as analysis of the amino acid sequences of
related G-protein-coupled receptors (34, 36). A
molecular-modeling software package (Insight II 98.0; Molecular
Simulations, Inc., San Diego, Calif.) was used to add a hypothetical
three-branched N-linked carbohydrate structure with a molecular mass of
6 kDa (based on the analysis of the CXCR4 non-N-linked glycosylated
mutants) to the N terminus of the CXCR4 molecule.
| |
RESULTS |
R5 isolate use of altered CXCR4 molecules.
Coreceptor genes
were expressed by using either a vaccinia virus promoter system or the
cytomegalovirus promoter in a plasmid transfection protocol, depending
on the particular assay employed. An alanine-scanning mutagenesis
strategy (51) was performed to identify residues involved in
CXCR4 coreceptor activity (23). Shown in Fig.
1 is a representation of the
extracellular domains of CXCR4 with the locations of several point
mutations highlighted: N11A, C28A, and R30A in the N terminus; N176A,
D187A, and D193A in ecl-2; and C274A in ecl-3. The mutation of these
residues individually by substitution with alanine was noted to enhance
the ability of CXCR4 to serve as a coreceptor for otherwise
R5-dependent HIV-1 isolates, while full function was retained for X4
and R5X4 isolates. Only the cysteine mutations had moderately reduced
X4 Env coreceptor activity (23). A combination of both
substitutions for cysteine residues (i.e., C28A C274A) yielded a mutant
CXCR4 with an enhanced coreceptor activity for R5 Envs, better than
that resulting from substitution for either one alone. Figure 1 also
shows the locations of the two potential N-linked glycosylation sites,
located in the N terminus and in ecl-2. Using a protocol involving 12G5
or 4G10 MAbs, cell surface staining, and fluorescence-activated cell sorter analysis, all CXCR4 mutants used in the present study had surface expression levels quite comparable to that of wild-type CXCR4
(85 to 115%) (reference 23 and data not shown).
Similar N-linked glycosylation site-deleted mutant CXCR4 receptor cell surface expression findings were reported by others (69).
Further, the non-N-linked glycosylated CXCR4 mutants in this study
reacted equally well with a panel of six additional
conformation-dependent anti-CXCR4 MAbs supplied by R&D Systems (D. J. Chabot, F. Baribaud, R. W. Doms, and C. C. Broder,
unpublished observations).
View larger version (21K):
[in this window]
[in a new window]
|
FIG. 1.
Diagram of CXCR4 extracellular domains. Residues that
when converted to alanine enhance fusion with R5 HIV-1 Env
glycoproteins are highlighted by enclosure within dark black circles.
Locations of the potential N-linked glycosylation sites are
indicated.
|
|
Removal of N-linked glycosylation sites expands CXCR4 coreceptor
activity.
The vaccinia virus-based -Gal cell fusion assay was
performed to examine the non-N-linked glycosylated CXCR4 mutants in an experiment in which human U373 target cells expressing CD4 and infected
with the vCB-21R-LacZ reporter virus were transfected with plasmids
encoding mutant or wild-type CXCR4. Env-expressing HeLa effector cells
were produced by infection with the appropriate Env-encoding vaccinia
virus and a vaccinia virus encoding T7 RNA polymerase (9, 17,
66). One of the most potent single mutations that allowed CXCR4
to serve as an R5 isolate coreceptor was N11A (Fig.
2). This alteration potentially
eliminated an N-terminal N-linked glycosylation structure.
Site-directed mutagenic removal of the asparagine residue of an
N-linked glycosylation site motif is a more definitive means of
glycosylation site identification than enzymatic removal of the
carbohydrate moiety, and more importantly for the present study, it
permits a functional examination of effects of glycosylation. We
confirmed by mutagenesis that the N11A phenotype was likely due to the
elimination of a glycosylation site by disruption of the consensus
glycosylation sequence (N-X-S/T) by an alternative mutation (T13A). In
Env-mediated cell fusion assays with a panel of prototypic R5 Envs
(Fig. 2), the T13A CXCR4 mutant exhibited coreceptor activity nearly
equivalent to that of the N11A mutant. This result strongly indicates
that it was the carbohydrate modification at asparagine 11, rather than
the asparagine amino acid itself, that was mediating the CXCR4 mutant phenotype of enhanced R5 coreceptor activity. We also examined the
other potential N-linked glycosylation site in CXCR4, located in ecl-2,
using the N176A mutant and found that it also had some enhanced
coreceptor activity for R5 Env-mediated fusion, although the level of
activity was significantly lower than that of the N-terminal site
mutant. Therefore, we chose to not examine an additional S178A mutant
but rather focus on the N-terminal glycosylation site and examine a
double mutant both functionally and biochemically. The double
non-N-linked glycosylated CXCR4 (N11A N176A) was constructed, and this
non-N-linked glycosylated CXCR4 exhibited a coreceptor activity for
several R5 HIV-1 isolate Envs, including JR-FL, ADA, Ba-L, and SF162,
that was further enhanced over that of the single N11A construct (Fig.
2). The data shown in Fig. 2 are the actual rates of reporter activity,
with background levels of both vector alone, wild-type CXCR4, and the
CCR5 activity shown for comparison. The N11A N176A mutant CXCR4
retained full coreceptor activity for LAV Env (Fig. 2) and for several
other X4 or R5X4 Envs (data not shown), in agreement with earlier
reports (16, 69). The expanded tropism of the non-N-linked
glycosylated CXCR4 was quite significant, with activities ranging from
35 to 125% of the level of coreceptor activity observed with CCR5 in
the same experiment (Fig. 2). Similar results were achieved when these
CXCR4 mutants were expressed along with CD4 in mouse 3T3 cells, rabbit
RK13 cells, and monkey BSC-1 cells (data not shown). These N-linked glycosylations could potentially block interactions between CXCR4 and
certain regions within a particular Env, or they might alter the
conformation of CXCR4 in a way that prevents such interactions.
View larger version (40K):
[in this window]
[in a new window]
|
FIG. 2.
Coreceptor function of non-N-linked glycosylated CXCR4
mutants in cell fusion assays with R5 HIV-1 Envs. U373 target cells
were transfected with a plasmid encoding the wild-type or a mutant
coreceptor linked to the vaccinia virus promoter and infected with
vCB21R-LacZ and vCB-3 (CD4). HeLa effector cells were infected with a
vaccinia virus encoding an HIV-1 Env and with a vaccinia virus encoding
T7 polymerase (vTF1-1). Cell mixtures (duplicates) were incubated at
37°C for 2.5 h. Fusion was assessed by measurement of -Gal in
detergent lysates of cells. The rates of -Gal activity shown were
obtained from separate samples in the same experiment. Error bars
indicate the standard deviations of the mean values obtained from
duplicate fusion assays. This experiment was performed three times, and
the data from a representative experiment are shown in the figure.
Abs570nm, absorbance at 570 nm.
|
|
In light of these surprising observations, we examined the Env-mediated
fusion activities of HIV-1 primary isolates and those
of alternate
clades. Shown in Fig.
3 are the results
obtained
in testing a battery of primary R5 isolate Envs with the
individual
non-N-linked glycosylated CXCR4 mutants in comparison to
wild-type
CXCR4 and CCR5 in the cell fusion assay. Two primary clade B
isolates
(91US005.11 and 92BR020.4), a clade F/B mosaic (93BR019.10-all
gp120 F), and a clade A (92RW020.5) R5 Env could utilize the N11A
CXCR4
coreceptor. The overall reporter gene signal levels were
lower in this
experiment than in the experiment shown in Fig.
2 because both the
coreceptor genes and the Env genes (most driven
by a T7 promoter
system) were transfected as plasmids in this
assay. For this reason, a
plasmid encoding the Ba-L Env is included
for comparison. In other
experiments (data not shown), the double
non-N-linked glycosylated
CXCR4 mutant yielded a slightly more
elevated level of coreceptor
activity than the single N11A mutant
for the same panel of Envs tested
in the study shown in Fig.
3,
but the N-terminal site clearly had the
greatest influence, and
the control mutation (T13A) imparted this
expanded coreceptor
activity as well (Fig.
3). The fact that some R5
Envs from alternate
clades, like the two clade C Envs examined, were
not able to use
the non-N-linked glycosylated CXCR4 is not surprising
because
clade C X4 isolates rarely occur (
14,
70). This may
indicate
that the clade C R5 Env-coreceptor interaction is more
distinct
than that of R5 Envs from other clades, like A, B, and F; on
the
other hand, we predict that a clade D R5 isolate would have been
able to utilize the non-N-linked CXCR4 mutant coreceptor had there
been
a cloned gp160 available for testing.
View larger version (39K):
[in this window]
[in a new window]
|
FIG. 3.
Coreceptor function of non-N-linked glycosylated CXCR4
mutants in cell fusions assays with primary isolate R5 HIV-1 Envs. U373
target cells were transfected with a plasmid encoding the wild-type or
a mutant coreceptor linked to the vaccinia virus promoter and infected
with vCB21R-LacZ and vCB-3 (CD4). HeLa effector cells were transfected
with a plasmid encoding Env (clades are indicated in parentheses)
linked to a T7 promoter and infected with a vaccinia virus encoding T7
polymerase (vTF1-1). Duplicate cell mixtures were incubated at 37°C
for 3 h. Fusion was assessed by measurement of -Gal in
detergent lysates of cells. The rates of -Gal activity shown were
obtained from separate samples in the same experiment. Error bars
indicate the standard deviations of the mean values obtained for
duplicate fusion assays. Data from a representative experiment are
shown in the figure. Abs570nm, absorbance at 570 nm.
|
|
The HIV-1 Env-mediated cell fusion assay presents a proven and reliable
model of HIV-1 Env-mediated fusion and receptor function
(
4,
17,
26,
41,
42,
49,
62,
76). However, an
examination of the
activities of these CXCR4 mutants in an alternate
assay for virus entry
was also performed. The data in Fig.
4
show
that the non-N-linked glycosylated CXCR4 molecule can also support
infection by a CCR5-dependent virus in an R5 JR-FL-pseudotyped
luciferase reporter system. Both the single (N11A) and double
(N11A
N176A) non-N-linked glycosylated CXCR4 mutants supported
this R5
Env-mediated virus infection, and the double mutant yielded
a higher
level of coreceptor activity. The background signals
obtained with
plasmid vector alone and with wild-type CXCR4 and
CCR5 are shown for
comparison. In additional experiments, the
level of signal obtained
with the single N176A CXCR4 mutant appeared
no higher than that of
wild-type CXCR4 activity in the pseudovirus
assay. We have consistently
observed that levels of R5 virus entry
signal for cells expressing
non-N-linked glycosylated CXCR4 in
the luciferase pseudovirus assay are
often lower than those of
the cell fusion assay, and this was also
observed with the charged-to-alanine
(D187A) CXCR4 mutant, another
R5-enhancing alteration also found
by another group (
23,
87). On the one hand, the pseudovirus
assay is dependent on
Env-mediated fusion as well as reverse transcription,
pre-integration
complex formation, and nuclear translocation,
while our recombinant Env
cell-cell fusion system was devised
to eliminate the dependency on
these postentry events in measuring
Env fusion activity
(
17). These differences between the two
systems may be
inherent. Alternatively, the differences in the
relative signal levels
of the two assays might reflect postbinding
roles of CCR5 for R5 HIV-1
isolates. Whether there are indeed
other mechanisms at work in the
entry process of HIV that can
account for the efficiency differences
described here, such as
an event during the postentry phase of virus
replication, as demonstrated
with simian immunodeficiency virus
(
24), remains to be shown.
Nevertheless, the results
obtained by both of these assay systems
support the hypothesis that
non-N-linked glycosylated CXCR4 can
serve as a coreceptor for R5 Envs.
View larger version (28K):
[in this window]
[in a new window]
|
FIG. 4.
Coreceptor function of non-N-linked glycosylated CXCR4
mutants in virus infection assays with an R5 HIV-1 Env. U373
CD4+ cells were transfected with a plasmid (pCDNA3)
encoding the wild-type or a mutant coreceptor. Wells of cells
(triplicate) were infected with the indicated HIV-1 Env-luciferase
reporter virus. Infection was assessed at day 4 by measuring the
amounts of luciferase activity in cell lysates. Error bars indicate the
standard deviations of the mean values obtained from triplicate wells.
This experiment was performed three times, and the data from a
representative experiment are shown in the figure.
|
|
Identification of CXCR4 N-linked glycosylations.
Previously we
examined recombinant vaccinia virus-expressed CXCR4 by Western blot
analysis with a polyclonal rabbit antiserum raised against the N
terminus of the molecule (49). In those studies, the
predominant molecular species of CXCR4 had a molecular mass of
approximately 47 to 48 kDa. Also apparent was a second, less-intense
band with an apparent molecular mass of ~94 to 97 kDa, double that of
the predominant species. We have consistently observed this
monomer/dimer pattern for CXCR4 as well as CCR5 (data not shown), and
the ratios of the two bands can vary depending on the SDS-PAGE
conditions. Virtually identical results were obtained by Doms and
colleagues with an hemagglutinin epitope-tagged CXCR4-vaccinia virus
construct (11). The predicted molecular mass of CXCR4, 39.7 kDa, indicated that a posttranslational N-linked glycosylation event
likely had occurred on the protein. The first clear evidence that CXCR4
was indeed N glycosylated on at least one of these sites was provided
by experiments using endoglycosidase F treatment of recombinant
vaccinia virus-expressed CXCR4 followed by SDS-PAGE and Western
blotting (11). To expand on these observations and precisely
identify the sites of N-linked glycosylation
and, more importantly,
correlate these findings to functional activitywe performed a
biochemical analysis by SDS-PAGE and Western blotting of the
non-N-linked glycosylated CXCR4 mutants.
Western blot detection of CXCR4 following SDS-PAGE separation has been
notoriously difficult. We and others have found analysis
by SDS-PAGE
and Western blotting of wild-type CXCR4 or mutants
that are expressed
transiently by plasmid-transfected cells unsatisfactory.
This is likely
due to a combination of low-level expression and
low-affinity antibody.
In order to obtain unambiguous results,
we constructed several new
recombinant vaccinia viruses encoding
wild-type or one of several
mutant CXCR4s. We analyzed lysates
of cells infected with these
vaccinia viruses to biochemically
characterize the CXCR4 N
glycosylations by Western blotting with
MAb 4G10, raised against the
CXCR4 N terminus. Binding of 4G10
to CXCR4 also appeared to be
unaffected by the N-terminal glycosylation
(
23) (Fig.
5 and data not shown). Using this
approach, we determined
that the N11A mutant had a significantly lower
apparent molecular
mass (monomer, ~41 to 42 kDa) than wild-type CXCR4
and was very
close to the predicted size of unmodified CXCR4 (~40
kDa). There
was no detectable size difference between the single N176A
mutant
and wild-type CXCR4 or between the double N11A N176A mutant and
the single N11A CXCR4 mutant. The blot was purposefully overexposed
to
show the two-band pattern in the N11A and N11A N176A lanes.
A shorter
autoradiographic exposure period revealed the same broad
band at both
positions for the other samples (data not shown),
as was noted in prior
work with wild-type and epitope-tagged CXCR4
(
11,
49). Thus,
if there is any N-linked glycosylation present
at N176A, it is too
small of a modification to be measurable in
this assay. The
non-N-linked glycosylated CXCR4 monomer was even
smaller than that of
an additional CXCR4 mutant that was used
as a relative molecular mass
marker in this experiment (a C-terminal
42-amino-acid [5-kDa]
deletion construct with a molecular mass
of ~42 to 43 kDa). Also, the
apparent dimer bands were equally
shifted downward in all cases (Fig.
5). Taken together, our data
indicate that the principal site of
N-linked glycosylation of
CXCR4 is in the N terminus and consists of an
approximated 5-
to 6-kDa carbohydrate moiety. Using these
CXCR4-encoding recombinant
vaccinia viruses to express CXCR4, we
observed identical molecular
mass patterns of monomeric and dimeric
CXCR4 in a variety of cells,
including primary human macrophages as
well as the mouse 3T3 and
human HeLa, U373, and HOS cell lines (data
not shown). The double
non-N-linked glycosylated CXCR4 mutant-encoding
vaccinia virus
was also examined functionally (Fig.
6), and although there might
have been a
slight decrease in relative expression efficiencies
in whole-cell
lysates (Fig.
5), this mutant was clearly quite
efficient in supporting
Env-mediated fusion by several prototypic
R5 isolates in comparison to
vaccinia virus-expressed CCR5. The
non-N-linked glycosylated mutants
were fully functional for prototypic
X4 (LAV) and R5X4 (89.6) Envs as
well (Fig.
6).
View larger version (65K):
[in this window]
[in a new window]
|
FIG. 5.
Biochemical analysis of non-N-linked glycosylated mutant
CXCR4s: Western blot of wild-type CXCR4 and non-N-linked glycosylated
CXCR4 mutants expressed by recombinant vaccinia viruses.  C-terminal, C-terminal 42-amino-acid deletion construct with a
molecular mass of ~43 kDa. Lysates were prepared from BSC-1 cells
infected with a vaccinia virus encoding the indicated CXCR4 gene and
analyzed by SDS-PAGE followed by Western blotting with a mouse MAb to
CXCR4 (4G10).
|
|
View larger version (40K):
[in this window]
[in a new window]
|
FIG. 6.
Functional analysis of vaccinia virus-expressed double
non-N-linked glycosylated CXCR4: coreceptor function of recombinant
vaccinia virus-encoded non-N-linked glycosylated mutant CXCR4 in cell
fusion assays with clade B Envs. Target cells were infected with
vCB-21R-LacZ, vCB-3 (CD4), and either WR, vHC-7 (N11A/N176A), vHC-1
(CCR5), or vHC-3 (CXCR4). HeLa HIV-1 Env-expressing effector cells were
infected with a vaccinia virus encoding T7 polymerase (vTF1-1) and the
indicated Env. Cell mixtures (duplicates) were incubated at 37°C for
2.5 h. Fusion was assessed by measurement of -Gal in detergent
lysates of cells. The rates of -Gal activity shown were obtained
from separate samples in the same experiment. Error bars indicate the
standard deviations of the mean values obtained from duplicate fusion
assays. This experiment has been performed multiple times, and the data
from a representative experiment are shown in the figure.
Abs570nm, absorbance at 570 nm.
|
|
| |
DISCUSSION |
The HIV-1 coreceptors have complex membrane topologies consisting
of an N-terminal domain, three extracellular and intracellular loops,
and a cytoplasmic C-terminal tail. Their exact three-dimensional structure is presently unknown. However, theoretical models of CXCR4
and CCR5 based on the physically determined structures of both
bacteriorhodopsin and rhodopsin (79, 85, 86) as well as
analysis of the amino acid sequences of related receptors have been
constructed (34, 36; S. Durell, personal
communication). Most recently, a model for CCR5 derived by a similar
methodology was presented in which further constraints were placed on
the theoretical modeling procedure by incorporation of MAb binding data
(61). These models suggest that the coreceptors are barrel shaped, with the extracellular loops and N terminus brought closer together by two extracellular disulfide bonds; perhaps more
significantly, a clear distinction of electrostatic potentials in the
extracellular elements is evident, with CXCR4 possessing a more
negative surface charge. Indeed, data suggesting that both pairs of
cysteines are likely involved in disulfide bond formation have been
provided (15, 23), and these observations aid in grasping
the many reports that indicate multiple extracellular regions in CCR5
(5, 13, 39, 43, 46, 47, 54, 62, 68, 72, 75, 76, 89) as well
as CXCR4 (16, 23, 40, 62, 69, 83) coreceptor function and
that coreceptor-Env interactions are quite complex. An additional
complexity to this interaction comes from the assessment of the Env
regions involved in coreceptor use and goes well beyond the notion of
just an electrostatic interaction between the V3 loop and a coreceptor
(see recent reviews in references 8 and 55).
In this study we showed that the removal of N-linked glycosylation
sites of CXCR4 allows this molecule to serve as a functional coreceptor
for otherwise-restricted R5 isolate Envs. Unlike CXCR4, the other
principal coreceptor, CCR5, does not appear to possess any N-linked
glycosylation modifications, although there is a potential site in the
receptor's ecl-3 (48). Rather, it was concluded that only
O-linked glycosylation modifications to CCR5 were evident. Further, it
was reported that sulfation of the N terminus of the CCR5 coreceptor is
important for function, with sulfated tyrosines contributing to the
binding of CCR5 natural ligands as well as gp120-CD4 complexes
(48). Along this line, the removal of a carbohydrate moiety
from CXCR4 likely results in an even more-negative surface charge on
the molecule, although at this time we cannot exclude the possibility
that the N-linked carbohydrate structure is further modified in a way
that affects the overall charge (e.g., sialic acid addition). Although
our results show some additive biological effect of double N-linked glycosylation site removal, they clearly show that only one site (i.e.,
at the N terminus) predominates in its biological effect; additionally,
we showed biochemically that only the N-terminal site imparts a
modification measurable by SDS-PAGE, and since N-linked carbohydrate
structures are invariably large, this strongly indicates that only this
site is used in the BSC-1 (Fig. 5), murine 3T3, human HOS, HeLa, and
U373-MG cell lines and in primary human macrophages (data not shown).
Our attempts to measure these biological effects of N-linked
glycosylation site removal by other means, including tunicamycin
treatment of cells, were unsuccessful, apparently due to cellular
toxicity (data not shown). Indeed, the finding that prevention of
N-linked glycosylation would allow CXCR4 to function as a coreceptor
for R5 Envs while full function for X4 Envs was retained was quite unexpected.
We hypothesize that removal of the carbohydrate moieties in CXCR4
results in its enhanced coreceptor activity with CCR5-dependent R5 Envs
by unmasking existing structures capable of interacting with these
Envs. It may be that CCR5-restricted Envs are adapted to recognizing a
coreceptor with a non-N-linked glycosylated N terminus whereas
CXCR4-restricted Envs can accommodate such a configuration. Taken
together, our data further support the notion that despite differences
in the primary sequences of their extracellular regions, there is
perhaps an underlying conserved similarity between the
three-dimensional structures of CXCR4 and CCR5 and that subtle alterations in CXCR4 (i.e., removal of carbohydrate), or mutation in
Env to accommodate CXCR4 N glycosylation, allows R5 Envs to utilize it
as a coreceptor. We also note that among the set of CXCR4 mutations
that result in enhanced coreceptor activity for R5 Envs is the
disruption of what is likely a disulfide bond between the N terminus
and ecl-3 (23). A possible explanation for the underlying
mechanism of this prior observation, in light of the present data, is
that this alteration relaxes the barrel shape of CXCR4 and thereby
repositions the existing N-terminal glycosylation moiety, allowing
better exposure of contact sites for R5 Env interaction.
We have also consistently observed the apparent monomer/dimer pattern
of CXCR4 and CCR5 (Fig. 5 and data not shown). The first suggestion of
an oligomeric feature of an HIV coreceptor was shown by an
immunoprecipitation assay using metabolically labeled CCR5; a
monomer/dimer pattern was reported in a low-SDS environment (6). More recently, a similar SDS-PAGE pattern has been
reported for CXCR4 and CCR5 (74); the chemokine ligands were
shown to induce a monomer-to-dimer transition. Further studies need to be performed to determine the nature and significance of these observations. Our data are derived from SDS-PAGE analysis under reducing conditions, but samples were not boiled; this suggests that
strong hydrophobic interactions are involved. We feel that the
high-molecular-mass species we observed is not an alternative or more
heavily glycosylated CXCR4 molecule, since we still observed a dimer in
the double non-N-linked glycosylated mutant, although one might
speculate that the N-terminal carbohydrate moiety plays a role in
stabilizing the dimer, based on the data shown in Fig. 5. The fact that
the anti-CXCR4 MAb 12G5 had been demonstrated to differentially inhibit
HIV-1 infection in both a cell type- and virus strain-dependent manner
(63) had first prompted the suggestion that the CXCR4
molecule itself is differentially processed, as in macrophages,
resulting in it being utilized differently by various isolates
(37). It has been suggested that a high-molecular-mass species of CXCR4 that is defective in coreceptor activity is present in
human macrophages (60) and that posttranslational
glycosylation could account for this observation; however, we noted
that recombinant-expressed wild-type and non-N-linked glycosylated
CXCR4 in human macrophages yielded molecular mass patterns identical to
those shown in Fig. 5. Indeed, if multimeric-complex formation between
the oligomeric HIV-1 Env and its cellular receptors is required for
fusion pore formation (65) and subsequent virus entry, then
the very existence of CD4-independent strains of HIV-1, HIV-2 (56,
58, 73), and simian immunodeficiency virus (44)
supports the notion of oligomeric coreceptors.
A revised schematic model of CXCR4, in which we have incorporated a
hypothetical three-branched 6-kDa carbohydrate structure on the
molecule's N-terminal domain based on our estimated molecular mass
differences, is shown in Fig. 7. In
viewing this model, it becomes readily apparent how such a structure
could potentially mask elements of the coreceptor's extracellular
domains. Although theoretical, we feel it is quite relevant to present
this model in the context of this report because it dramatically shows
how readily such a structure could cover underlying elements of not only the coreceptor's N terminus but the extracellular loops as well,
a feature rarely appreciated in stick figure diagrams. As more MAbs
specific for the CXCR4 coreceptor become available to complement the
growing number of available mutant coreceptor molecules, further
detailed mapping and modeling constraints will be possible to help
refine these theoretical three-dimensional models.
View larger version (26K):
[in this window]
[in a new window]
|
FIG. 7.
Schematic model of the HIV-1 coreceptor CXCR4 with a
representation of the amino-terminal N-linked glycosylation moiety. The
carbohydrate is drawn as a simple three-branch structure with a
molecular mass of ~6 kDa based on the measured molecular mass shift
observed during SDS-PAGE analysis under reducing conditions. Green
represents carbon, red represents oxygen, yellow represents nitrogen,
and white represents hydrogen. (A) Side view; (B) top view.
|
|
Our results concerning the CXCR4 N-terminal glycosylation also suggest
that just a posttranslational modification of CXCR4 could prevent an R5
isolate from exhibiting a dualtropic phenotype. The CCR5 coreceptor
does not have an N-terminal N-linked glycosylation site, and,
interestingly, the rarely employed CCR2 coreceptor, whose primary
sequence is most homologous to that of CCR5, contains an N-terminal
N-linked glycosylation site. However, removal of this site did not
expand CCR2 coreceptor activity; only a fourfold increase, to 10% of
the activity of CCR5 with a single R5 Env, ADA (data not shown),
occurred, while several other isolates yield 35 to 125% of the level
of CCR5 coreceptor activity with the non-N-linked glycosylated CXCR4
(Fig. 2). A larger study with more R5 isolates appears warranted in
order to fully assess and validate the breadth of these present
findings. Taken together, our data provide further evidence suggesting
that there is significant homology on a three-dimensional level for Env
interaction sites of the CXCR4 and CCR5 coreceptors, perhaps even more
so than that between CCR5 and CCR2.
It is R5 HIV-1 strains that are largely responsible for virus
transmission, and individuals who lack CCR5 due to a natural mutation
in the gene (ccr532 allele) are resistant to HIV-1
infection (31, 57, 78). HIV-1 X4 isolates tend to emerge
much later in the infection course, and the tropism switch from R5 to
X4 viruses correlates with progression of the infection to symptomatic AIDS (30, 81, 82). Part of the nature of this tropism switch is clearly related to genetic changes in the env nucleotide
sequence, but not all infected individuals who progress to AIDS develop X4 isolates, and the precise nature of the driving force behind the in
vivo evolution of HIV is not wholly understood. Our findings now add
further complexity to this area because they demonstrate the
possibility that early-stage primary R5 isolates could infect target
cells via CD4-CXCR4 receptors under circumstances of differential glycosylation of CXCR4 without an accompanying genetic change in Env.
Although clearly speculative, the existence of non-N-linked glycosylated CXCR4 or CXCR4 glycoforms in an individual, as result of
genetic or environmental influences or even the infection process itself, that allow for R5 Env recognition could have broad-reaching implications for the HIV infection and pathogenesis process, as well as
for outcomes in the host. Indeed, glycoforms of a protein may be cell
type or even cell cycle dependent (77). Whether there are
alternate glycoforms of CXCR4 in vivo remains to be determined by
experiments that would certainly be highly challenging considering the
present difficulty in detecting endogenous CXCR4 by blotting techniques.
Finally, unlike the CCR5-CD4 interaction, the association of CXCR4 with
CD4 appears to be greatly enhanced by gp120; the coimmunoprecipitation of CXCR4 and CD4 is largely gp120 dependent (35, 59, 90). We
are now examining whether these CXCR4 mutants, which have the capacity
to serve as universal HIV-1 coreceptors, have an enhanced affinity for
CD4, similar to the CCR5-CD4 interaction, or whether they exhibit their
effect through an enhanced Env-coreceptor interaction. A more universal
coreceptor has better potential in the development of novel therapeutic
agents targeted against HIV-infected cells, such as a cytocidal
pseudovirus (45, 80) with CD4 and non-N-linked glycosylated
CXCR4 on its surface, by targeting a wider range of HIV-1
isolate-infected cells. The continued characterization of the
interactions between HIV-1 Env and its coreceptors will aid in our
understanding of the virus infection process and in devising methods to
prevent it.
| |
ACKNOWLEDGMENTS |
We thank Agnes Jones-Trower for assistance in densitometer
scanning and molecular mass determinations, Tzanko Stantchev for help
with flow cytometry, and Joseph Isaac for viruses and cells. We are
grateful to Frantisek Bizik, Stuart Durell, and Pradman Qasba for help
with the molecular modeling of CXCR4 structures. A number of reagents
were obtained through the AIDS Research and Reference Reagent Program,
Division of AIDS, NIAID, NIH.
This study was supported by NIH grants R29AI414110 and R01AI43885 and
USUHS grant RO73FG to C.C.B.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology and Immunology, F. Edward Hébert School of Medicine,
Uniformed Services University of the Health Sciences, 4301 Jones Bridge Rd., Bethesda, MD 20814-4799. Phone: (301) 295-3401. Fax: (301) 295-1545. E-mail: cbroder{at}mxb.usuhs.mil.
| |
REFERENCES |
| 1.
|
Adachi, A.,
H. E. Gendelman,
S. Koenig,
T. Folks,
R. Willey,
A. Rabson, and M. A. Martin.
1986.
Production of acquired immunodeficiency syndrome-associated retrovirus in human and nonhuman cells transfected with an infectious molecular clone.
J. Virol.
59:284-291[Abstract/Free Full Text].
|
| 2.
|
Alexander, W. A.,
B. Moss, and T. R. Fuerst.
1992.
Regulated expression of foreign genes in vaccinia virus under the control of bacteriophage T7 RNA polymerase and the Escherichia coli lac repressor.
J. Virol.
66:2934-2942[Abstract/Free Full Text].
|
| 3.
|
Alkhatib, G.,
C. C. Broder, and E. A. Berger.
1996.
Cell type-specific fusion cofactors determine human immunodeficiency virus type 1 tropism for T-cell lines versus primary macrophages.
J. Virol.
70:5487-5494[Abstract/Free Full Text].
|
| 4.
|
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].
|
| 5.
|
Atchison, R. E.,
J. Gosling,
F. S. Monteclaro,
C. Franci,
L. Digilio,
I. F. Charo, and M. A. Goldsmith.
1996.
Multiple extracellular elements of CCR5 and HIV-1 entry: dissociation from response to chemokines.
Science
274:1924-1926[Abstract/Free Full Text].
|
| 6.
|
Benkirane, M.,
D. Y. Jin,
R. F. Chun,
R. A. Koup, and K. T. Jeang.
1997.
Mechanism of transdominant inhibition of CCR5-mediated HIV-1 infection by ccr532.
J. Biol. Chem.
272:30603-30606[Abstract/Free Full Text].
|
| 7.
|
Berger, E. A.,
R. W. Doms,
E. M. Fenyö,
B. T. Korber,
D. R. Littman,
J. P. Moore,
Q. J. Sattentau,
H. Schuitemaker,
J. Sodroski, and R. A. Weiss.
1998.
A new classification for HIV-1.
Nature
391:240[CrossRef][Medline].
|
| 8.
|
Berger, E. A.,
P. M. Murphy, and J. M. Farber.
1999.
Chemokine receptors as HIV-1 coreceptors: roles in viral entry, tropism, and disease.
Annu. Rev. Immunol.
17:657-700[CrossRef][Medline].
|
| 9.
|
Berger, E. A.,
O. Nussbaum, and C. C. Broder.
1995.
HIV envelope glycoprotein/CD4 interactions: studies using recombinant vaccinia virus vectors, p. 123-145.
In
J. Karn (ed.), HIV: a practical approach, vol. 2. Oxford University Press, Oxford, United Kingdom.
|
| 10.
|
Berson, J. F., and R. W. Doms.
1998.
Structure-function studies of the HIV-1 coreceptors.
Semin. Immunol.
10:237-248[CrossRef][Medline].
|
| 11.
|
Berson, J. F.,
D. Long,
B. J. Doranz,
J. Rucker,
F. R. Jirik, and R. W. Doms.
1996.
A seven-transmembrane domain receptor involved in fusion and entry of T-cell-tropic human immunodeficiency virus type 1 strains.
J. Virol.
70:6288-6295[Abstract].
|
| 12.
|
Bieniasz, P. D., and B. R. Cullen.
1998.
Chemokine receptors and human immunodeficiency virus infection.
Front. Biosci.
3:D44-D58.
|
| 13.
|
Bieniasz, P. D.,
R. A. Fridell,
I. Aramori,
S. S. Ferguson,
M. G. Caron, and B. R. Cullen.
1997.
HIV-1-induced cell fusion is mediated by multiple regions within both the viral envelope and the CCR-5 co-receptor.
EMBO J.
16:2599-2609[CrossRef][Medline].
|
| 14.
|
Bjorndal, A.,
A. Sonnerborg,
C. Tscherning,
J. Albert, and E. M. Fenyö.
1999.
Phenotypic characteristics of human immunodeficiency virus type 1 subtype C isolates of Ethiopian AIDS patients.
AIDS Res. Hum. Retrovir.
15:647-653[CrossRef][Medline].
|
| 15.
|
Blanpain, C.,
B. Lee,
J. Vakili,
B. J. Doranz,
C. Govaerts,
I. Migeotte,
M. Sharron,
V. Dupriez,
G. Vassart,
R. W. Doms, and M. Parmentier.
1999.
Extracellular cysteines of CCR5 are required for chemokine binding, but dispensable for HIV-1 coreceptor activity.
J. Biol. Chem.
274:18902-18908[Abstract/Free Full Text].
|
| 16.
|
Brelot, A.,
N. Heveker,
O. Pleskoff,
N. Sol, and M. Alizon.
1997.
Role of the first and third extracellular domains of CXCR-4 in human immunodeficiency virus coreceptor activity.
J. Virol.
71:4744-4751[Abstract].
|
| 17.
|
Broder, C. C., and E. A. Berger.
1995.
Fusogenic selectivity of the envelope glycoprotein is a major determinant of human immunodeficiency virus type 1 tropism for CD4+ T-cell lines vs. primary macrophages.
Proc. Natl. Acad. Sci. USA
92:9004-9008[Abstract/Free Full Text].
|
| 18.
|
Broder, C. C., and D. S. Dimitrov.
1996.
HIV and the 7-transmembrane domain receptors.
Pathobiology
64:171-179[Medline].
|
| 19.
|
Broder, C. C.,
D. S. Dimitrov,
R. Blumenthal, and E. A. Berger.
1993.
The block to HIV-1 envelope glycoprotein-mediated membrane fusion in animal cells expressing human CD4 can be overcome by a human cell component(s).
Virology
193:483-491[CrossRef][Medline].
|
| 20.
|
Broder, C. C., and P. L. Earl.
1999.
Recombinant vaccinia viruses: design, generation and isolation.
Mol. Biotechnol.
13:223-246[CrossRef][Medline].
|
| 21.
|
Broder, C. C., and A. Jones-Trower.
1999.
Coreceptor use by primate lentiviruses, p. 20-45.
In
B. Korber, B. Foley, T. Leitner, F. McCutchan, B. Hahn, J. W. Mellors, G. Myers, and C. Kuilen (ed.), Human retroviruses and AIDS, vol. III. Theoretical Biology and Biophysics Group, Los Alamos National Laboratory, Los Alamos, N.Mex.
|
| 22.
|
Carroll, M. W.
1993.
Expression, analysis and immunogenicity of human immunodeficiency type I envelope glycoprotein in vaccinia virus. Ph.D. dissertation.
University of Manchester, Manchester, United Kingdom.
|
| 23.
|
Chabot, D. J.,
P. F. Zhang,
G. V. Quinnan, and C. C. Broder.
1999.
Mutagenesis of CXCR4 identifies important domains for human immunodeficiency virus type 1 X4 isolate envelope-mediated membrane fusion and virus entry and reveals cryptic coreceptor activity for R5 isolates.
J. Virol.
73:6598-6609[Abstract/Free Full Text].
|
| 24.
|
Chackerian, B.,
E. M. Long,
P. A. Luciw, and J. Overbaugh.
1997.
Human immunodeficiency virus type 1 coreceptors participate in postentry stages in the virus replication cycle and function in simian immunodeficiency virus infection.
J. Virol.
71:3932-3939[Abstract].
|
| 25.
|
Chakrabarti, S.,
J. R. Sisler, and B. Moss.
1997.
Compact, synthetic, vaccinia virus early/late promoter for protein expression.
BioTechniques
23:1094-1097[Medline].
|
| 26.
|
Choe, H.,
M. Farzan,
Y. Sun,
N. Sullivan,
B. Rollins,
P. D. Ponath,
L. Wu,
C. R. Mackay,
G. LaRosa,
W. Newman,
N. Gerard,
C. Gerard, and J. Sodroski.
1996.
The -chemokine receptors CCR3 and CCR5 facilitate infection by primary HIV-1 isolates.
Cell
85:1135-1148[CrossRef][Medline].
|
| 27.
|
Clapham, P. R.,
J. D. Reeves,
G. Simmons,
N. Dejucq,
S. Hibbitts, and A. McKnight.
1999.
HIV coreceptors, cell tropism and inhibition by chemokine receptor ligands.
Mol. Membr. Biol.
16:49-55[CrossRef][Medline].
|
| 28.
|
Collman, R.,
J. W. Balliet,
S. A. Gregory,
H. Friedman,
D. L. Kolson,
N. Nathanson, and A. Srinivasan.
1992.
An infectious molecular clone of an unusual macrophage-tropic and highly cytopathic strain of human immunodeficiency virus type 1.
J. Virol.
66:7517-7521[Abstract/Free Full Text].
|
| 29.
|
Connor, R. I.,
B. K. Chen,
S. Choe, and N. R. Landau.
1995.
Vpr is required for efficient replication of human immunodeficiency virus type 1 in mononuclear phagocytes.
Virology
206:935-944[CrossRef][Medline].
|
| 30.
|
Connor, R. I.,
K. E. Sheridan,
D. Ceradini,
S. Choe, and N. R. Landau.
1997.
Change in coreceptor use coreceptor use correlates with disease progression in HIV-1-infected individuals.
J. Exp. Med.
185:621-628[Abstract/Free Full Text].
|
| 31.
|
Dean, M.,
M. Carrington,
C. Winkler,
G. A. Huttley,
M. W. Smith,
R. Allikmets,
J. J. Goedert,
S. P. Buchbinder,
E. Vittinghoff,
E. Gomperts,
S. Donfield,
D. Vlahov,
R. Kaslow,
A. Saah,
C. Rinaldo,
R. Detels,
S. J. O'Brien, and Hemophilia Growth and Development Study, Multicenter AIDS Cohort Study, Multicenter Hemophilia Cohort Study, San Francisco City Cohort, and ALIVE Study.
1996.
Genetic restriction of HIV-1 infection and progression to AIDS by a deletion allele of the CKR5 structural gene.
Science
273:1856-1862[Abstract/Free Full Text].
|
| 32.
|
De Jong, J.-J.,
A. De Ronde,
W. Keulen,
M. Tersmette, and J. Goudsmit.
1992.
Minimal requirements for the human immunodeficiency virus type 1 V3 domain to support the syncytium-inducing phenotype: analysis by single amino acid substitution.
J. Virol.
66:6777-6780[Abstract/Free Full Text].
|
| 33.
|
Dimitrov, D. S.
1996.
Fusina place for HIV-1 and T4 cells to meet.
Nat. Med.
2:640-641[CrossRef][Medline].
|
| 34.
|
Dimitrov, D. S., and C. C. Broder.
1997.
HIV and membrane receptors.
Landes Bioscience, Austin, Tex.
|
| 35.
|
Dimitrov, D. S.,
D. Norwood,
T. S. Stantchev,
Y. Feng,
X. Xiao, and C. C. Broder.
1999.
A mechanism of resistance to HIV-1 entry: inefficient interactions of CXCR4 with CD4 and gp120 in macrophages.
Virology
259:1-6[CrossRef][Medline].
|
| 36.
|
Dimitrov, D. S.,
X. Xiao,
D. J. Chabot, and C. C. Broder.
1998.
HIV coreceptors.
J. Membr. Biol.
166:75-90[CrossRef][Medline].
|
| 37.
|
Dittmar, M. T.,
A. McKnight,
G. Simmons,
P. R. Clapham,
R. A. Weiss, and P. Simmons.
1997.
HIV-1 tropism and co-receptor use.
Nature
385:495-496[CrossRef][Medline].
|
| 38.
|
Doms, R. W., and S. C. Peiper.
1997.
Unwelcomed guests with master keys: how HIV uses chemokine receptors for cellular entry.
Virology
235:179-190[CrossRef][Medline].
|
| 39.
|
Doranz, B. J.,
Z. H. Lu,
J. Rucker,
T. Y. Zhang,
M. Sharron,
Y. H. Cen,
Z. X. Wang,
H. H. Guo,
J. G. Du,
M. A. Accavitti,
R. W. Doms, and S. C. Peiper.
1997.
Two distinct CCR5 domains can mediate coreceptor usage by human immunodeficiency virus type 1.
J. Virol.
71:6305-6314[Abstract].
|
| 40.
|
Doranz, B. J.,
M. J. Orsini,
J. D. Turner,
T. L. Hoffman,
J. F. Berson,
J. A. Hoxie,
S. C. Peiper,
L. F. Brass, and R. W. Doms.
1999.
Identification of CXCR4 domains that support coreceptor and chemokine receptor functions.
J. Virol.
73:2752-2761[Abstract/Free Full Text].
|
| 41.
|
Doranz, B. J.,
J. Rucker,
Y. Yi,
R. J. Smyth,
M. Samson,
S. C. 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-3, and CKR-2b as fusion cofactors.
Cell
85:1149-1158[CrossRef][Medline].
|
| 42.
|
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-CKR5.
Nature
381:667-673[CrossRef][Medline].
|
| 43.
|
Edinger, A. L.,
A. Amedee,
K. Miller,
B. J. Doranz,
M. Endres,
M. Sharron,
M. Samson,
Z. H. Lu,
J. E. Clements,
M. Murphey-Corb,
S. C. Peiper,
M. Parmentier,
C. C. Broder, and R. W. Doms.
1997.
Differential utilization of CCR5 by macrophage and T cell tropic simian immunodeficiency virus strains.
Proc. Natl. Acad. Sci. USA
94:4005-4010[Abstract/Free Full Text].
|
| 44.
|
Edinger, A. L.,
C. Blanpain,
K. J. Kunstman,
S. M. Wolinsky,
M. Parmentier, and R. W. Doms.
1999.
Functional dissection of CCR5 coreceptor function through the use of CD4-independent simian immunodeficiency virus strains.
J. Virol.
73:4062-4073[Abstract/Free Full Text].
|
| 45.
|
Endres, M. J.,
S. Jaffer,
B. Haggarty,
J. D. Turner,
B. J. Doranz,
P. J. O'Brien,
D. L. Kolson, and J. A. Hoxie.
1997.
Targeting of HIV- and SIV-infected cells by CD4-chemokine receptor pseudotypes.
Science
278:1462-1464[Abstract/Free Full Text].
|
| 46.
|
Farzan, M.,
H. Choe,
K. A. Martin,
Y. Sun,
M. Sidelko,
C. R. Mackay,
N. P. Gerard,
J. Sodroski, and C. Gerard.
1997.
HIV-1 entry and macrophage inflammatory protein-1-mediated signaling are independent functions of the chemokine receptor CCR5.
J. Biol. Chem.
272:6854-6857[Abstract/Free Full Text].
|
| 47.
|
Farzan, M.,
H. Choe,
L. Vaca,
K. Martin,
Y. Sun,
E. Desjardins,
N. Ruffing,
L. Wu,
R. Wyatt,
N. Gerard,
C. Gerard, and J. Sodroski.
1998.
A tyrosine-rich region in the N terminus of CCR5 is important for human immunodeficiency virus type 1 entry and mediates an association between gp120 and CCR5.
J. Virol.
72:1160-1164[Abstract/Free Full Text].
|
| 48.
|
Farzan, M.,
T. Mirzabekov,
P. Kolchinsky,
R. Wyatt,
M. Cayabyab,
N. P. Gerard,
C. Gerard,
J. Sodroski, and H. Choe.
1999.
Tyrosine sulfation of the amino terminus of CCR5 facilitates HIV-1 entry.
Cell
96:667-676[CrossRef][Medline].
|
| 49.
|
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].
|
| 50.
|
Fouchier, R. A.,
M. Groenink,
N. A. Kootstra,
M. Tersmette,
H. G. Huisman,
F. Miedema, and H. Schuitemaker.
1992.
Phenotype-associated sequence variation in the third variable domain of the human immunodeficiency virus type 1 gp120 molecule.
J. Virol.
66:3183-3187[Abstract/Free Full Text].
|
| 51.
|
Gibbs, C. S., and M. J. Zoller.
1991.
Identification of electrostatic interactions that determine the phosphorylation site specificity of the cAMP-dependent protein kinase.
Biochemistry
30:5329-5334[CrossRef][Medline].
|
| 52.
|
Golding, H.,
D. S. Dimitrov,
J. Manischewitz,
C. C. Broder,
J. Robinson,
S. Fabian,
D. R. Littman, and C. K. Lapham.
1995.
Phorbol ester-induced down modulation of tailless CD4 receptors requires prior binding of gp120 and suggests a role for accessory molecules.
J. Virol.
69:6140-6148[Abstract].
|
| 53.
|
Harrington, R. D., and A. P. Geballe.
1993.
Cofactor requirement for human immunodeficiency virus type 1 entry into a CD4-expressing human cell line.
J. Virol.
67:5939-5947[Abstract/Free Full Text].
|
| 54.
|
Hill, C. M.,
D. Kwon,
M. Jones,
C. B. Davis,
S. Marmon,
B. L. Daugherty,
J. A. DeMartino,
M. S. Springer,
D. Unutmaz, and D. R. Littman.
1998.
The amino terminus of human CCR5 is required for its function as a receptor for diverse human and simian immunodeficiency virus envelope glycoproteins.
Virology
248:357-371[CrossRef][Medline].
|
| 55.
|
Hoffman, T. L., and R. W. Doms.
1999.
HIV-1 envelope determinants for cell tropism and chemokine receptor use.
Mol. Membr. Biol.
16:57-65[CrossRef][Medline].
|
| 56.
|
Hoxie, J. A.,
C. C. LaBranche,
M. J. Endres,
J. D. Turner,
J. F. Berson,
R. W. Doms, and T. J. Matthews.
1998.
CD4-independent utilization of the CXCR4 chemokine receptor by HIV-1 and HIV-2.
J. Reprod. Immunol.
41:197-211[CrossRef][Medline].
|
| 57.
|
Huang, Y.,
W. A. Paxton,
S. M. Wolinsky,
A. U. Neumann,
L. Zhang,
T. He,
S. Kang,
D. Ceradini,
Z. Jin,
K. Yazdanbakhsh,
K. Kunstman,
D. Erickson,
E. Dragon,
N. R. Landau,
J. Phair,
D. D. Ho, and R. A. Koup.
1996.
The role of a mutant CCR5 allele in HIV-1 transmission and disease progression.
Nat. Med.
2:1240-1243[CrossRef][Medline].
|
| 58.
|
Kolchinsky, P.,
T. Mirzabekov,
M. Farzan,
E. Kiprilov,
M. Cayabyab,
L. J. Mooney,
H. Choe, and J. Sodroski.
1999.
Adaptation of a CCR5-using, primary human immunodeficiency virus type 1 isolate for CD4-independent replication.
J. Virol.
73:8120-8126[Abstract/Free Full Text].
|
| 59.
|
Lapham, C. K.,
J. Ouyang,
B. Chandrasekhar,
N. Y. Nguyen,
D. S. Dimitrov, and H. Golding.
1996.
Evidence for cell-surface association between fusin and the CD4-gp120 complex in human cell lines.
Science
274:602-605[Abstract/Free Full Text].
|
| 60.
|
Lapham, C. K.,
M. B. Zaitseva,
S. Lee,
T. Romanstseva, and H. Golding.
1999.
Fusion of monocytes and macrophages with HIV-1 correlates with biochemical properties of CXCR4 and CCR5.
Nat. Med.
5:303-308[CrossRef][Medline].
|
| 61.
|
Lee, B.,
M. Sharron,
C. Blanpain,
B. J. Doranz,
J. Vakili,
P. Setoh,
E. Berg,
G. Liu,
H. R. Guy,
S. R. Durell,
M. Parmentier,
C. N. Chang,
K. Price,
M. Tsang, and R. W. Doms.
1999.
Epitope mapping of CCR5 reveals multiple conformational states and distinct but overlapping structures involved in chemokine and coreceptor function.
J. Biol. Chem.
274:9617-9626[Abstract/Free Full Text].
|
| 62.
|
Lu, Z.,
J. F. Berson,
Y. Chen,
J. D. Turner,
T. Zhang,
M. Sharron,
M. H. Jenks,
Z. Wang,
J. Kim,
J. Rucker,
J. A. Hoxie,
S. C. Peiper, and R. W. Doms.
1997.
Evolution of HIV-1 coreceptor usage through interactions with distinct CCR5 and CXCR4 domains.
Proc. Natl. Acad. Sci. USA
94:6426-6431[Abstract/Free Full Text].
|
| 63.
|
McKnight, A.,
D. Wilkinson,
G. Simmons,
S. Talbot,
L. Picard,
M. Ahuja,
M. Marsh,
J. A. Hoxie, and P. R. Clapham.
1997.
Inhibition of human immunodeficiency virus fusion by a monoclonal antibody to a coreceptor (CXCR4) is both cell type and virus strain dependent.
J. Virol.
71:1692-1696[Abstract].
|
| 64.
|
Moore, J. P.,
A. Trkola, and T. Dragic.
1997.
Co-receptors for HIV-1 entry.
Curr. Opin. Immunol.
9:551-562[CrossRef][Medline].
|
| 65.
|
Munoz-Barroso, I.,
S. Durell,
K. Sakaguchi,
E. Appella, and R. Blumenthal.
1998.
Dilation of the human immunodeficiency virus-1 envelope glycoprotein fusion pore revealed by the inhibitory action of a synthetic peptide from gp41.
J. Cell Biol.
140:315-323[Abstract/Free Full Text].
|
| 66.
|
Nussbaum, O.,
C. C. Broder, and E. A. Berger.
1994.
Fusogenic mechanisms of enveloped-virus glycoproteins analyzed by a novel recombinant vaccinia virus-based assay quantitating cell fusion-dependent reporter gene activation.
J. Virol.
68:5411-5422[Abstract/Free Full Text].
|
| 67.
|
O'Brien, W. A.,
Y. Koyanagi,
A. Namazie,
J. Q. Zhao,
A. Diagne,
K. Idler,
J. A. Zack, and I. S. Y. Chen.
1990.
HIV-1 tropism for mononuclear phagocytes can be determined by regions of gp120 outside the CD4-binding domain.
Nature
348:69-73[CrossRef][Medline].
|
| 68.
|
Picard, L.,
G. Simmons,
C. A. Power,
A. Meyer,
R. A. Weiss, and P. R. Clapham.
1997.
Multiple extracellular domains of CCR-5 contribute to human immunodeficiency virus type 1 entry and fusion.
J. Virol.
71:5003-5011[Abstract].
|
| 69.
|
Picard, L.,
D. Wilkinson,
A. McKnight,
P. Gray,
J. Hoxie,
P. Clapham, and R. Weiss.
1997.
Role of the amino-terminal extracellular domain of CXCR-4 in human immunodeficiency virus type 1 entry.
Virology
231:105-111[CrossRef][Medline].
|
| 70.
|
Ping, L. H.,
J. A. Nelson,
I. F. Hoffman,
J. Schock,
S. L. Lamers,
M. Goodman,
P. Vernazza,
P. Kazembe,
M. Maida,
D. Zimba,
M. M. Goodenow,
J. J. Eron, Jr.,
S. A. Fiscus,
M. S. Cohen, and R. Swanstrom.
1999.
Characterization of V3 sequence heterogeneity in subtype C human immunodeficiency virus type 1 isolates from Malawi: underrepresentation of X4 variants.
J. Virol.
73:6271-6281[Abstract/Free Full Text].
|
| 71.
|
Quinnan, G. V., Jr.,
P. F. Zhang,
D. W. Fu,
M. Dong, and J. B. Margolick.
1998.
Evolution of neutralizing antibody response against HIV type 1 virions and pseudovirions in multicenter AIDS cohort study participants.
AIDS Res. Hum. Retrovir.
14:939-949[Medline].
|
| 72.
|
Rabut, G. E.,
J. A. Konner,
F. Kajumo,
J. P. Moore, and T. Dragic.
1998.
Alanine substitutions of polar and nonpolar residues in the amino-terminal domain of CCR5 differently impair entry of macrophage- and dualtropic isolates of human immunodeficiency virus type 1.
J. Virol.
72:3464-3468[Abstract/Free Full Text].
|
| 73.
|
Reeves, J. D.,
S. Hibbitts,
G. Simmons,
A. McKnight,
J. M. Azevedo-Pereira,
J. Moniz-Pereira, and P. R. Clapham.
1999.
Primary human immunodeficiency virus type 2 (HIV-2) isolates infect CD4-negative cells via CCR5 and CXCR4: comparison with HIV-1 and simian immunodeficiency virus and relevance to cell tropism in vivo.
J. Virol.
73:7795-7804[Abstract/Free Full Text].
|
| 74.
|
Rodriguez-Frade, J. M.,
A. J. Vila-Coro,
A. Martín,
M. Nieto,
F. Sanchez-Madrid,
A. E. Proudfoot,
T. N. Wells,
A. C. Martínez, and M. Mellado.
1999.
Similarities and differences in RANTES- and (AOP)-RANTES-triggered signals: implications for chemotaxis.
J. Cell Biol.
144:755-765[Abstract/Free Full Text].
|
| 75.
|
Ross, T. M.,
P. D. Bieniasz, and B. R. Cullen.
1998.
Multiple residues contribute to the inability of murine CCR-5 to function as a coreceptor for macrophage-tropic human immunodeficiency virus type 1 isolates.
J. Virol.
72:1918-1924[Abstract/Free Full Text].
|
| 76.
|
Rucker, J.,
M. Samson,
B. J. Doranz,
F. Libert,
J. F. Berson,
C. C. Broder,
G. Vassart,
R. W. Doms, and M. Parmentier.
1996.
Regions in -chemokine receptors CCR-5 and CCR-2b that determine HIV-1 cofactor specificity.
Cell
87:437-446[CrossRef][Medline].
|
| 77.
|
Rudd, P. M.,
H. C. Joao,
E. Coghill,
P. Fiten,
M. R. Saunders,
G. Opdenakker, and R. A. Dwek.
1994.
Glycoforms modify the dynamic stability and functional activity of an enzyme.
Biochemistry
33:17-22[CrossRef][Medline].
|
| 78.
|
Samson, M.,
F. Libert,
B. J. Doranz,
J. Rucker,
C. Liesnard,
C.-M. Farber,
S. Saragosti,
C. Lapoum-Eroulie,
J. Cogniaux,
C. Forceille,
G. Muyldermans,
C. Verhofstede,
G. Burtonboy,
M. Georges,
T. Imai,
S. Rana,
Y. Yi,
R. J. Smyth,
R. G. Collman,
R. W. Doms,
G. Vassart, and M. Parmentier.
1996.
Resistance to HIV-1 infection of Caucasian individuals bearing mutant alleles of the CCR5 chemokine receptor gene.
Nature
382:722-725[CrossRef][Medline].
|
| 79.
|
Schertler, G. F., and P. A. Hargrave.
1995.
Projection structure of frog rhodopsin in two crystal forms.
Proc. Natl. Acad. Sci. USA
92:11578-11582[Abstract/Free Full Text].
|
| 80.
|
Schnell, M. J.,
J. E. Johnson,
L. Buonocore, and J. K. Rose.
1997.
Construction of a novel virus that targets HIV-1-infected cells and controls HIV-1 infection.
Cell
90:849-857[CrossRef][Medline].
|
| 81.
|
Schuitemaker, H.,
M. Koot,
N. A. Kootstra,
M. W. Dercksen,
R. E. de Goede,
R. P. van Steenwijk,
J. M. Lange,
J. K. Schattenkerk,
F. Miedema, and M. Tersmette.
1992.
Biological phenotype of human immunodeficiency virus type 1 clones at different stages of infection: progression of disease is associated with a shift from monocytotropic to T-cell-tropic virus populations.
J. Virol.
66:1354-1360[Abstract/Free Full Text].
|
| 82.
|
Simmons, G.,
D. Wilkinson,
J. D. Reeves,
M. T. Dittmar,
S. Beddows,
J. Weber,
G. Carnegie,
U. Desselberger,
P. W. Gray,
R. A. Weiss, and P. R. Clapham.
1996.
Primary, syncytium-inducing human immunodeficiency virus type 1 isolates are dual-tropic and most can use either Lestr or CCR5 as coreceptors for virus entry.
J. Virol.
70:8355-8360[Abstract].
|
| 83.
|
Strizki, J. M.,
J. D. Turner,
R. G. Collman,
J. Hoxie, and F. González-Scarano.
1997.
A monoclonal antibody (12G5) directed against CXCR-4 inhibits infection with the dual-tropic human immunodeficiency virus type 1 isolate HIV-189.6 but not the T-tropic isolate HIV-1HxB.
J. Virol.
71:5678-5683[Abstract].
|
| 84.
|
Trkola, A.,
T. Dragic,
J. Arthos,
J. M. Binley,
W. C. Olson,
G. P. Allaway,
C. Cheng-Mayer,
J. Robinson,
P. J. Maddon, and J. P. Moore.
1996.
CD4-dependent, antibody-sensitive interactions between HIV-1 and its co-receptor CCR-5.
Nature
384:184-187[CrossRef][Medline].
|
| 85.
|
Unger, V. M.,
P. A. Hargrave,
J. M. Baldwin, and G. F. Schertler.
1997.
Arrangement of rhodopsin transmembrane alpha-helices.
Nature
389:203-206[CrossRef][Medline].
|
| 86.
|
Unger, V. M., and G. F. Schertler.
1995.
Low resolution structure of bovine rhodopsin determined by electron cryo-microscopy.
Biophys. J.
68:1776-1786[Medline].
|
| 87.
|
Wang, Z. X.,
J. F. Berson,
T. Y. Zhang,
Y. H. Cen,
Y. Sun,
M. Sharron,
Z. H. Lu, and S. C. Peiper.
1998.
CXCR4 sequences involved in coreceptor determination of human immunodeficiency virus type-1 tropism. Unmasking of activity with M-tropic Env glycoproteins.
J. Biol. Chem.
273:15007-15015[Abstract/Free Full Text].
|
| 88.
|
Wu, L.,
N. P. Gerard,
R. Wyatt,
H. Choe,
C. Parolin,
N. Ruffing,
A. Borsetti,
A. A. Cardoso,
E. Desjardin,
W. Newman,
C. Gerard, and J. Sodroski.
1996.
CD4-induced interaction of primary HIV-1 gp120 glycoproteins with the chemokine receptor CCR-5.
Nature
384:179-183[CrossRef][Medline].
|
| 89.
|
Wu, L.,
G. LaRosa,
N. Kassam,
C. J. Gordon,
H. Heath,
N. Ruffing,
H. Chen,
J. Humblias,
M. Samson,
M. Parmentier,
J. P. Moore, and C. R. Mackay.
1997.
Interaction of chemokine receptor CCR5 with its ligands: multiple domains for HIV-1 gp120 binding and a single domain for chemokine binding.
J. Exp. Med.
186:1373-1381[Abstract/Free Full Text].
|
| 90.
|
Xiao, X.,
L. Wu,
T. S. Stantchev,
Y. R. Feng,
S. Ugolini,
H. Chen,
Z. Shen,
J. L. Riley,
C. C. Broder,
Q. J. Sattentau, and D. S. Dimitrov.
1999.
Constitutive cell surface association between CD4 and CCR5.
Proc. Natl. Acad. Sci. USA
96:7496-7501[Abstract/Free Full Text].
|
Journal of Virology, May 2000, p. 4404-4413, Vol. 74, No. 9
0022-538X/00/$04.00+0
This article has been cited by other articles:
-
Brass, A. L., Dykxhoorn, D. M., Benita, Y., Yan, N., Engelman, A., Xavier, R. J., Lieberman, J., Elledge, S. J.
(2008). Identification of Host Proteins Required for HIV Infection Through a Functional Genomic Screen. Science
319: 921-926
[Abstract]
[Full Text]
-
Lobo, P. I., Schlegel, K. H., Yuan, W., Townsend, G. C., White, J. A.
(2008). Inhibition of HIV-1 Infectivity through an Innate Mechanism Involving Naturally Occurring IgM Anti-Leukocyte Autoantibodies. J. Immunol.
180: 1769-1779
[Abstract]
[Full Text]
-
Lobo, P. I., Schlegel, K. H., Spencer, C. E., Okusa, M. D., Chisholm, C., Mchedlishvili, N., Park, A., Christ, C., Burtner, C.
(2008). Naturally Occurring IgM Anti-Leukocyte Autoantibodies (IgM-ALA) Inhibit T Cell Activation and Chemotaxis. J. Immunol.
180: 1780-1791
[Abstract]
[Full Text]
-
Kubo, Y., Yokoyama, M., Yoshii, H., Mitani, C., Tominaga, C., Tanaka, Y., Sato, H., Yamamoto, N.
(2007). Inhibitory role of CXCR4 glycan in CD4-independent X4-tropic human immunodeficiency virus type 1 infection and its abrogation in CD4-dependent infection. J. Gen. Virol.
88: 3139-3144
[Abstract]
[Full Text]
-
Xu, C., Sui, J., Tao, H., Zhu, Q., Marasco, W. A.
(2007). Human Anti-CXCR4 Antibodies Undergo VH Replacement, Exhibit Functional V-Region Sulfation, and Define CXCR4 Antigenic Heterogeneity. J. Immunol.
179: 2408-2418
[Abstract]
[Full Text]
-
Venzke, S., Michel, N., Allespach, I., Fackler, O. T., Keppler, O. T.
(2006). Expression of Nef Downregulates CXCR4, the Major Coreceptor of Human Immunodeficiency Virus, from the Surfaces of Target Cells and Thereby Enhances Resistance to Superinfection. J. Virol.
80: 11141-11152
[Abstract]
[Full Text]
-
Clevestig, P., Pramanik, L., Leitner, T., Ehrnst, A.
(2006). CCR5 use by human immunodeficiency virus type 1 is associated closely with the gp120 V3 loop N-linked glycosylation site.. J. Gen. Virol.
87: 607-612
[Abstract]
[Full Text]
-
Zaitseva, M., Romantseva, T., Manischewitz, J., Wang, J., Goucher, D., Golding, H.
(2005). Increased CXCR4-dependent HIV-1 fusion in activated T cells: role of CD4/CXCR4 association. J. Leukoc. Biol.
78: 1306-1317
[Abstract]
[Full Text]
-
Platt, E. J., Shea, D. M., Rose, P. P., Kabat, D.
(2005). Variants of Human Immunodeficiency Virus Type 1 That Efficiently Use CCR5 Lacking the Tyrosine-Sulfated Amino Terminus Have Adaptive Mutations in gp120, Including Loss of a Functional N-Glycan. J. Virol.
79: 4357-4368
[Abstract]
[Full Text]
-
Palermo, L. M., Hueffer, K., Parrish, C. R.
(2003). Residues in the Apical Domain of the Feline and Canine Transferrin Receptors Control Host-Specific Binding and Cell Infection of Canine and Feline Parvoviruses. J. Virol.
77: 8915-8923
[Abstract]
[Full Text]
-
Lin, G., Baribaud, F., Romano, J., Doms, R. W., Hoxie, J. A.
(2002). Identification of gp120 Binding Sites on CXCR4 by Using CD4-Independent Human Immunodeficiency Virus Type 2 Env Proteins. J. Virol.
77: 931-942
[Abstract]
[Full Text]
-
Lapham, C. K., Romantseva, T., Petricoin, E., King, L. R., Manischewitz, J., Zaitseva, M. B., Golding, H.
(2002). CXCR4 heterogeneity in primary cells: possible role of ubiquitination. J. Leukoc. Biol.
72: 1206-1214
[Abstract]
[Full Text]
-
Jurat-Fuentes, J. L., Gould, F. L., Adang, M. J.
(2002). Altered Glycosylation of 63- and 68-Kilodalton Microvillar Proteins in Heliothis virescens Correlates with Reduced Cry1 Toxin Binding, Decreased Pore Formation, and Increased Resistance to Bacillus thuringiensis Cry1 Toxins. Appl. Environ. Microbiol.
68: 5711-5717
[Abstract]
[Full Text]
-
Zhou, N., Luo, Z., Luo, J., Fan, X., Cayabyab, M., Hiraoka, M., Liu, D., Han, X., Pesavento, J., Dong, C.-Z., Wang, Y., An, J., Kaji, H., Sodroski, J. G., Huang, Z.
(2002). Exploring the Stereochemistry of CXCR4-Peptide Recognition and Inhibiting HIV-1 Entry with D-Peptides Derived from Chemokines. J. Biol. Chem.
277: 17476-17485
[Abstract]
[Full Text]
-
Platt, E. J., Kuhmann, S. E., Rose, P. P., Kabat, D.
(2001). Adaptive Mutations in the V3 Loop of gp120 Enhance Fusogenicity of Human Immunodeficiency Virus Type 1 and Enable Use of a CCR5 Coreceptor That Lacks the Amino-Terminal Sulfated Region. J. Virol.
75: 12266-12278
[Abstract]
[Full Text]
-
Bannert, N., Craig, S., Farzan, M., Sogah, D., Santo, N. V., Choe, H., Sodroski, J.
(2001). Sialylated O-Glycans and Sulfated Tyrosines in the NH2-Terminal Domain of CC Chemokine Receptor 5 Contribute to High Affinity Binding of Chemokines. JEM
194: 1661-1674
[Abstract]
[Full Text]
-
Pontow, S., Ratner, L.
(2001). Evidence for Common Structural Determinants of Human Immunodeficiency Virus Type 1 Coreceptor Activity Provided through Functional Analysis of CCR5/CXCR4 Chimeric Coreceptors. J. Virol.
75: 11503-11514
[Abstract]
[Full Text]
-
Tanaka, R., Yoshida, A., Murakami, T., Baba, E., Lichtenfeld, J., Omori, T., Kimura, T., Tsurutani, N., Fujii, N., Wang, Z.-X., Peiper, S. C., Yamamoto, N., Tanaka, Y.
(2001). Unique Monoclonal Antibody Recognizing the Third Extracellular Loop of CXCR4 Induces Lymphocyte Agglutination and Enhances Human Immunodeficiency Virus Type 1-Mediated Syncytium Formation and Productive Infection. J. Virol.
75: 11534-11543
[Abstract]
[Full Text]
-
Zhou, N., Luo, Z., Luo, J., Liu, D., Hall, J. W., Pomerantz, R. J., Huang, Z.
(2001). Structural and Functional Characterization of Human CXCR4 as a Chemokine Receptor and HIV-1 Co-receptor by Mutagenesis and Molecular Modeling Studies. J. Biol. Chem.
276: 42826-42833
[Abstract]
[Full Text]
-
Baribaud, F., Edwards, T. G., Sharron, M., Brelot, A., Heveker, N., Price, K., Mortari, F., Alizon, M., Tsang, M., Doms, R. W.
(2001). Antigenically Distinct Conformations of CXCR4. J. Virol.
75: 8957-8967
[Abstract]
[Full Text]
-
Overbaugh, J., Miller, A. D., Eiden, M. V.
(2001). Receptors and Entry Cofactors for Retroviruses Include Single and Multiple Transmembrane-Spanning Proteins as well as Newly Described Glycophosphatidylinositol-Anchored and Secreted Proteins. Microbiol. Mol. Biol. Rev.
65: 371-389
[Abstract]
[Full Text]
-
Dragic, T.
(2001). An overview of the determinants of CCR5 and CXCR4 co-receptor function. J. Gen. Virol.
82: 1807-1814
[Full Text]
-
Labrosse, B., Treboute, C., Brelot, A., Alizon, M.
(2001). Cooperation of the V1/V2 and V3 Domains of Human Immunodeficiency Virus Type 1 gp120 for Interaction with the CXCR4 Receptor. J. Virol.
75: 5457-5464
[Abstract]
[Full Text]
-
de Parseval, A., Elder, J. H.
(2001). Binding of Recombinant Feline Immunodeficiency Virus Surface Glycoprotein to Feline Cells: Role of CXCR4, Cell-Surface Heparans, and an Unidentified Non-CXCR4 Receptor. J. Virol.
75: 4528-4539
[Abstract]
[Full Text]
-
Bieniasz, P. D., Cullen, B. R.
(2000). Multiple Blocks to Human Immunodeficiency Virus Type 1 Replication in Rodent Cells. J. Virol.
74: 9868-9877
[Abstract]
[Full Text]
-
Doms, R. W., Trono, D.
(2000). The plasma membrane as a combat zone in the HIV battlefield. Genes Dev.
14: 2677-2688
[Full Text]
-
Chabot, D. J., Broder, C. C.
(2000). Substitutions in a Homologous Region of Extracellular Loop 2 of CXCR4 and CCR5 Alter Coreceptor Activities for HIV-1 Membrane Fusion and Virus Entry. J. Biol. Chem.
275: 23774-23782
[Abstract]
[Full Text]
-
Pollakis, G., Kang, S., Kliphuis, A., Chalaby, M. I. M., Goudsmit, J., Paxton, W. A.
(2001). N-Linked Glycosylation of the HIV Type-1 gp120 Envelope Glycoprotein as a Major Determinant of CCR5 and CXCR4 Coreceptor Utilization. J. Biol. Chem.
276: 13433-13441
[Abstract]
[Full Text]
-
Dimitrov, A. S., Xiao, X., Dimitrov, D. S., Blumenthal, R.
(2001). Early Intermediates in HIV-1 Envelope Glycoprotein-mediated Fusion Triggered by CD4 and Co-receptor Complexes. J. Biol. Chem.
276: 30335-30341
[Abstract]
[Full Text]
-
Hoffman, T. L., Canziani, G., Jia, L., Rucker, J., Doms, R. W.
(2000). A biosensor assay for studying ligand-membrane receptor interactions: Binding of antibodies and HIV-1 Env to chemokine receptors. Proc. Natl. Acad. Sci. USA
97: 11215-11220
[Abstract]
[Full Text]
Top
Abstract
Introduction
