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Journal of Virology, December 2000, p. 10984-10993, Vol. 74, No. 23
Department of Cancer Immunology and AIDS,
Dana-Farber Cancer Institute, and Department of Pathology, Harvard
Medical School,1 and Department of
Immunology and Infectious Diseases, Harvard School of Public
Health,2 Boston, Massachusetts 02115
Received 19 May 2000/Accepted 30 August 2000
The entry of primate immunodeficiency viruses into cells is
dependent on the interaction of the viral envelope
glycoproteins with receptors, CD4, and specific members of
the chemokine receptor family. Although in many cases the tropism of
these viruses is explained by the qualitative pattern of coreceptor
expression, several instances have been observed where the expression
of a coreceptor on the cell surface is not sufficient to allow
infection by a virus that successfully utilizes the coreceptor in a
different context. For example, both the T-tropic simian
immunodeficiency virus (SIV) SIVmac239 and the
macrophagetropic (M-tropic) SIVmac316 can utilize CD4 and
CCR5 as coreceptors, and both viruses can infect primary T lymphocytes,
yet only SIVmac316 can efficiently infect CCR5-expressing
primary macrophages from rhesus monkeys. Likewise, M-tropic strains of
human immunodeficiency virus type 1 (HIV-1) do not infect primary
rhesus monkey macrophages efficiently. Here we show that the basis of
this restriction is the low level of CD4 on the surface of these cells.
Overexpression of human or rhesus monkey CD4 in primary rhesus monkey
macrophages allowed infection by both T-tropic and M-tropic SIV and by
primary M-tropic HIV-1. By contrast, CCR5 overexpression did not
specifically compensate for the inefficient infection of primary monkey
macrophages by T-tropic SIV or M-tropic HIV-1. Apparently, the limited
ability of these viruses to utilize a low density of CD4 for target
cell entry accounts for the restriction of these viruses in
primary rhesus monkey macrophages.
Infection with human
immunodeficiency virus types 1 and 2 (HIV-1 and HIV-2) causes AIDS in
humans, which is characterized by a progressive loss of CD4-positive T
lymphocytes and fatal opportunistic infections (7, 33, 35).
A similar illness can be induced in Asian macaques by infection with
various strains of simian immunodeficiency virus (SIV), a closely
related lentivirus (23, 46). The similarities of the
viruses, hosts, and pathological sequelae in HIV-infected humans and
SIV-infected monkeys make the latter system an excellent model for
understanding AIDS pathogenesis and for the evaluation of potential
therapeutics and vaccines (24).
HIV and SIV infection is usually initiated by binding of the viral
envelope glycoproteins, a heavily glycosylated, trimeric complex of noncovalently associated gp120 and gp41 subunits, to the CD4
receptor on the target cell (14, 20, 43). This interaction triggers conformational changes in gp120, creating or unmasking a
high-affinity binding site for a second cellular receptor (62, 70,
73). The interaction with this coreceptor is believed to induce
structural changes in the transmembrane glycoprotein gp41
that lead to the fusion of viral and target cell membranes (72,
74).
The predominant coreceptors used by HIV-1 are the chemokine receptors
CCR5 and CXCR4 (2, 16, 18, 21, 27). All HIV-1 isolates
studied to date utilize at least one of these coreceptors, and the
expression pattern of the receptors usually explains
the observed cell tropism of HIV-1 variants. CCR5 has been
shown to be the major coreceptor for macrophagetropic (M-tropic)
primary HIV-1 isolates, whereas CXCR4 serves as a coreceptor for
primary T-cell-tropic (T-tropic) and T-cell line-adapted HIV-1 strains (11, 19, 38). One subject of ongoing controversy is the extent to which T-cell line-adapted HIV-1 strains can infect and replicate in CXCR4-positive, primary human macrophages (8, 45, 66,
71, 76). It has been suggested that cell-type-specific modulation
of postentry events and/or the presence of functionally restricted
CXCR4 forms may limit productive infection of these cells (26, 45,
64). Whatever the cause of the poor infectability of primary
human macrophages by T-cell line-adapted HIV-1, this example points out
that coreceptor use does not always explain the tropism of primate
immunodeficiency viruses. In addition to CCR5 and CXCR4, some HIV-1
strains can utilize, at lower levels of efficiency, the alternative
coreceptors CCR3, CCR2b, Apj, CCR8, and US28 (17, 27, 39,
58). HIV-2 is more closely related to SIV than to HIV-1, and this
relationship is also mirrored in the preferences of HIV-2 for
coreceptors (12, 22, 51). Most SIV strains can use very
efficiently a number of coreceptors, including CCR5,
STRL33, gpr15, gpr1, and ChemR23 (3, 17, 22, 31, 60,
61). This provides the means for SIV to replicate in peripheral
blood mononuclear cells (PBMC) from individuals homozygous for a 32-bp
deletion in CCR5 and in some CCR5-negative T-cell lines as well
(16). However, the in vivo relevance of the usage of
alternative coreceptors besides CCR5 by SIV is still uncertain, and
with very few exceptions, all SIV isolates are able to use CCR5
(29).
SIV variants that differ in target cell tropism and the ability to
induce particular pathological sequelae have been described previously
(1, 25, 48, 68). Several of these variants arose in vivo
from SIVmac239, a molecularly cloned virus that replicates
efficiently in rhesus monkey T lymphocytes but not in primary
macrophages (4, 6, 34, 40, 55, 59, 65). SIVmac239
typically causes AIDS-like disease in inoculated monkeys, but a subset
of infected animals develop meningoencephalitis or granulomatous
interstitial pneumonia. Central nervous system or pulmonary disease is
associated with primary infection of microglia or tissue
macrophages, respectively, and with the emergence of SIV variants that
replicate efficiently in cultured macrophages. One such variant,
SIVmac316, was isolated from the alveolar macrophages of a
rhesus monkey infected with SIVmac239 (25). The
macrophage tropism of SIVmac316 is determined by five of the
sequence differences between the envelope glycoproteins of
SIVmac316 and SIVmac239 (54). The
tropism change is apparently not due to qualitative alterations in
coreceptor use, as both SIVmac316 and SIVmac239 envelope glycoproteins support entry into cells expressing
CD4 and either CCR5, gpr15, or STRL33 (63). Indeed, one
report has suggested that this env-associated change in
tropism is determined at a postentry step in SIV replication
(53).
Here we examine the ability of primary rhesus monkey macrophages
to be infected with recombinant viruses containing the
envelope glycoproteins of SIVmac239,
SIVmac316, and several HIV-1 strains. The basis for the
restricted entry of SIVmac239 and primary M-tropic HIV-1 into these cells is investigated.
Cells.
Cf2Th, HeLa, and HEK293 cells were obtained from the
American Type Culture Collection and maintained in Dulbecco's modified Eagle's medium containing 10% fetal calf serum, 100 U of
penicillin/ml, and 100 U of streptomycin/ml. A Cf2Th cell line stably
expressing high levels of human CCR5 has been described previously
(52). Cf2Th cells stably expressing low levels of human CCR5
were obtained from a population of cells expressing a broad range of
CCR5 by fluorescence-activated cell sorting (FACS) on a Vantage flow
cytometer (Becton Dickinson) using dialyzed anti-CCR5 phycoerythrin
(PE)-conjugated antibody (2D7; Pharmingen) for staining.
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
The Level of CD4 Expression Limits Infection of
Primary Rhesus Monkey Macrophages by a T-Tropic Simian Immunodeficiency
Virus and Macrophagetropic Human Immunodeficiency Viruses
ABSTRACT
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
INTRODUCTION
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
-mercaptoethanol, 50 U of granulocyte-macrophage colony-stimulating factor/ml, and 5 U of
macrophage colony-stimulating factor/ml. Cultures were washed three
times every 3 days for 2 weeks to remove nonadherent cells, and fresh
medium was added to the adherent cells.
Plasmids and recombinant viruses.
The SIVmac-based
retroviral vector pSHIV
envCAT, described previously (13),
was generated by inserting an env-deleted, HIV-1 HXBc2
fragment containing tat and rev sequences into a
plasmid containing an SIVmac239 provirus. The chloramphenicol
acetyltransferase (CAT) gene was cloned into the BamHI site,
thus inactivating the rev gene. Thus, CAT is expressed in a
Rev-independent manner from a multiply spliced mRNA. Cloning of
pSIvec1envGFP has been described elsewhere (37). This
vector is similar to pSHIVenvCAT but contains the green
fluorescent protein (GFP) gene in place of the CAT
gene. Plasmids pSIvec1envhuCD4, pSIvec1envrhCD4,
pSIvec1envrhCCR5, and pSIvec1envhuCXCR4 were generated by
replacing the AgeI-NotI fragment containing the
GFP gene in pSIvec1envGFP with the cDNA sequences of human and
rhesus monkey CD4, rhesus monkey CCR5, and human codon-optimized CXCR4,
respectively. The CD4 and coreceptor sequences were amplified from
previously described plasmids (32) using the Pfu
DNA polymerase and primers with introduced restriction sites for
cloning. The AgeI site in human and rhesus CD4 (position 1346) has been removed by introduction of a silent mutation
changing the CGG encoding arginine to CGA. The HIV-1-based retroviral
vector pHXBH10envCAT contains an HIV-1 provirus with a deletion in
env and the CAT gene replacing the nef open
reading frame (69). Plasmids pSIVgpv239 and pSIVgpv316
(50) were used to express the envelope
glycoproteins of SIVmac239 and
SIVmac316, respectively. Envelope glycoproteins
of HIV-1 strains YU2 and JR-FL were expressed using the previously
published pSVIIIenv vectors (18, 36). The similar plasmid
pSVIIIKS contains a deletion in env and was used as a
control. Plasmid pHCM-VSV-G encodes the vesicular stomatitis virus
envelope glycoprotein (VSV G) (75). The previously
described pcDNA3 plasmids (18, 50, 50a) were used for
expression of human or rhesus monkey CD4 and CCR5 in Cf2Th cells.
envCAT were
generated in HeLa cells; all other recombinant viruses were generated
in 293T cells, and the concentration of virus was normalized based on
reverse transcriptase activity.
Transduction of macrophages with CD4- or chemokine receptor-expressing viral vectors. Eleven-day-old monocyte-derived rhesus monkey macrophages were transduced with VSV G-pseudotyped recombinant viruses encoding human CD4, rhesus CD4, rhesus CCR5, human CXCR4, or GFP. Transductions were performed overnight with 90,000 reverse transcriptase units (RT units) for the CD4- and GFP-expressing vectors and 20,000 RT units for the CCR5- and CXCR4-expressing vectors. Three days later, the transduction efficiency was evaluated by FACS as described below. The transduction efficiency of the GFP-expressing vector was >90% (data not shown). Both transduced and native macrophages from the same donor preparation were infected overnight with 50,000 RT units of CAT reporter viruses containing the envelope glycoproteins of SIVmac239, SIVmac316, and the M-tropic HIV-1 strains YU2 and JR-FL as described below.
env complementation assay. The efficiency of a single round of infection by CAT-expressing recombinant virions was determined by using the previously published env complementation assay (36). The target cells were 3 × 106 PBMC, rhesus macrophages derived from 3 × 106 PBMC, or 2 × 105 Cf2Th cells. PBMC and macrophages were cultured in 12-well plates and incubated with 50,000 RT units of virus in 1 ml for 12 h at 37°C. Cf2Th cells were incubated in six-well plates with 10,000 RT units of virus at 37°C for 12 h or, for the experiments with TAK-779, for 1 h.
Cytofluorometric analyses. Macrophages were detached by treatment with 25 mM EDTA-PBS, followed by gentle scraping of already rounded cells. CD4 expression was determined by staining with the anti-CD4 monoclonal antibody (MAb) OKT4 conjugated with fluorescein isothiocyanate (FITC) (Ortho Diagnostics). For determination of CCR5 expression on rhesus macrophages, a biotin-conjugated anti-CCR5 MAb (clone 45531.111; R&D Systems) and PE-conjugated streptavidin were used. Human CCR5 expression on Cf2Th cells and CXCR4 expression on rhesus macrophages were measured by staining with PE-conjugated MAbs 2D7 (Pharmingen) and 12G5, respectively. Nonrelated mouse antibodies of corresponding isotype and conjugation were used as negative controls. Cells were fixed in 2% formaldehyde and analyzed on a FACscan cytometer (Becton Dickinson).
Virus replication assay. SIVmac239 and SIVmac316 viruses were provided by Ronald Desrosiers, New England Regional Primate Research Center. Macrophages cultured as described above were infected with 50,000 RT units of replication-competent virus for 12 h, washed three times, and refed with 2.5 ml of fresh medium. Cell-free supernatants (0.5 ml) were collected every second day and replaced with fresh medium. The collected supernatants were assayed for the presence of SIV p27 core protein by enzyme-linked immunoassay (Coulter).
TAK-779 and soluble CD4. TAK-779 was kindly provided by Masahiko Fujino (Takeda Chemical Industries, Osaka, Japan). Human soluble CD4 (sCD4) was donated by Raymond Sweet (SmithKline Beecham, King of Prussia, Pa.).
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RESULTS |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Restriction of SIVmac239 and M-tropic
HIV-1 infection in rhesus macrophages.
The pathogenic
molecular clone SIVmac239 is able to replicate in
rhesus monkey T lymphocytes but is restricted for replication in rhesus
monkey macrophages. This restriction is determined by the
env sequences (54). The reported inability of a
simian-human immunodeficiency virus chimera (SHIV) carrying an envelope
glycoprotein from the M-tropic HIV-1 JR-FL to replicate in
rhesus macrophages (15) prompted us to include M-tropic
HIV-1 envelope glycoproteins in our studies. To study the
extent and nature of these tropism restrictions, we examined the
ability of recombinant SHIV virions carrying different SIV or HIV-1
envelope glycoproteins to infect various target cell types.
A defective SHIV provirus with a deleted env gene and the
nef gene replaced by a CAT gene (37) was
cotransfected with plasmids expressing the envelope
glycoproteins of interest. The recombinant viruses produced
were normalized based on reverse transcriptase activity and incubated
with primary target cells from rhesus monkeys. The level of CAT
expression in the target cells reflects the efficiency of a single
round of the retroviral infection cycle. Similar levels of CAT
activity were found in lysates of stimulated rhesus PBMC infected with
SHIVs pseudotyped with the SIVmac239 and SIVmac316
envelope glycoproteins (Fig. 1A), a result consistent with previous
reports (42, 54). In sharp contrast, only the virus with the
SIVmac316 envelope glycoproteins could
efficiently infect rhesus monkey macrophages (Fig. 1B). Viruses with
the M-tropic HIV-1 envelope glycoproteins efficiently infected rhesus monkey PBMC (Fig. 1A and data not shown) but did not
infect rhesus monkey macrophages (Fig. 1B). These results demonstrate
that efficient infection of rhesus monkey macrophages by
SIVmac239 and M-tropic HIV-1 strains is impaired at a step that is determined by the envelope glycoproteins on the
infecting virus. As these M-tropic HIV-1 envelope
glycoproteins support efficient infection of primary human
macrophages, the results also point to a difference in the
susceptibility of rhesus monkey and human macrophages to particular
HIV-1 isolates, consistent with previous results (15).
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Coreceptor usage of SIVmac316 on rhesus monkey
macrophages.
In addition to CCR5, SIVmac strains are
able to use a broad variety of coreceptors for entry.
SIVmac316 has been shown to use some of these other receptors
much more efficiently than SIVmac239 or M-tropic HIV-1
strains (17, 61). To determine whether CCR5 serves as the
principal coreceptor for SIVmac316 entry into rhesus macrophages, we used a previously published (5) nonpeptide compound, TAK-779, in our single-round infection assay. It has been
shown that TAK-779 specifically binds to human CCR5 and inhibits infection of M-tropic HIV-1 in vitro. TAK-779 also exhibits a low
affinity for CCR2b, but as CCR2b does not support entry of SIVmac316 (17), this is not likely to be a
problem in our assays. At a concentration of 100 nM, TAK-779
significantly inhibited infection of Cf2Th cells expressing either
human or rhesus monkey CD4 and CCR5 by a virus containing the
SIVmac316 envelope glycoproteins (Fig.
2A and data not shown). Thus, TAK-779
blocks virus infection mediated by human and rhesus monkey CCR5.
No inhibition was detected on Cf2Th cells expressing CD4 together
with gpr15, STRL33, Apj, or gpr1 (data not shown), alternative
coreceptors used by SIVmac316 in in vitro assays (17,
31). On rhesus monkey macrophages, TAK-779 inhibited infection by
viruses with the SIVmac316 envelope glycoproteins
in a concentration-dependent manner, with an estimated 50%
inhibitory concentration of ~4 nM (Fig. 2B). No significant inhibition of infection by a virus pseudotyped with VSV G was observed (Fig. 2C). This result indicates that CCR5 is the major coreceptor used by SIVmac316 for entry into rhesus
monkey macrophages.
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Effect of CD4 and CCR5 overexpression on entry into rhesus
macrophages.
The expression of CD4 on the surface of macrophages
is several times lower than the expression level on CD4-positive
lymphocytes (47, 56). It is therefore conceivable that the
efficiency of CD4 utilization by different SIV strains influences the
ability to infect particular cell types. To evaluate whether CD4
overexpression in rhesus monkey macrophages can overcome the
block to infection of SIVmac239 and M-tropic HIV-1 strains,
we created lentiviral vectors expressing human and rhesus monkey CD4.
Replication-incompetent, VSV G-pseudotyped viruses encoding CD4
were produced in 293T cells and used for infection of rhesus monkey
macrophages. The transduction efficiency was greater than 90%
(Fig. 3A).
A similar construct expressing GFP was
used as a control and exhibited a similar transduction efficiency (data
not shown). Three days after transduction, the macrophages were
incubated with CAT reporter viruses containing either SIV or HIV-1
envelope glycoproteins. The overexpression of human or
rhesus monkey CD4 in the macrophages resulted in a three- to
fourfold enhancement of infection by viruses with the SIVmac316 envelope glycoproteins (Fig. 3B).
By contrast, infection by the viruses with SIVmac239, YU2, or
JR-FL envelope glycoproteins was dramatically (100- to
300-fold) stimulated by overexpression of either human or rhesus monkey
CD4 and almost reached the level attained by viruses with the
SIVmac316 envelope glycoproteins. Truncation of
the cytoplasmic tails of human and rhesus monkey CD4 at position 401 (9) did not decrease the observed enhancement of infection,
indicating that signal transduction events mediated by CD4 are not
responsible for the increase (data not shown). A slight (~2-fold)
increase in the CAT activity in control macrophages expressing GFP was
observed after infection with all of the viruses. This nonspecific
activation could be explained by the production of Tat by the
CD4-expressing lentivirus vector. These results demonstrate that the
low level of CD4 expression on rhesus monkey macrophages is a major
factor limiting efficient infection by SIVmac239 and M-tropic
HIV-1 strains.
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Effect of CD4 overexpression on the replication of infectious
viruses.
To determine the ability of SIVmac239 to
replicate in rhesus monkey macrophages expressing elevated CD4 levels,
we transduced 11-day-old macrophages with the human CD4 gene and then
infected them 72 h later with 50,000 RT units each of
replication-competent SIVmac239 and SIVmac316.
After 12 h, the cells were washed and returned to medium;
supernatant samples were collected at 2-day intervals to assay for
viral p27 concentration. Consistent with previous reports showing a
100- to 1,000-fold-higher replication efficiency of SIVmac316
compared with SIVmac239 in rhesus monkey macrophages
(42, 53), the replication of SIVmac239 on
untransduced cells was either undetectable or very poor, depending on
the donor animal. Very low p27 levels (<0.2 ng/ml) were measured in
transduced control cells expressing GFP and infected with
SIVmac239 (Fig. 4). A similar
p27 level was detected in the supernatants of all transduced uninfected
macrophages (data not shown) and probably resulted from gag
expression by the env-deficient vector used to express GFP
or overexpress CD4. The expression of gag from this vector
is impaired by the lack of the HIV-1 Rev protein in the transduced
cells and the fact that SIV Rev, provided by the replication-competent
SIV after infection, does not function on the HIV-1 Rev-responsive
element present in our SHIV vectors (10). SIVmac239 infection of rhesus macrophages overexpressing
human or rhesus CD4 resulted in a considerable level of virus
replication, with peak p27 levels greater than 1 ng/ml (Fig. 4). CD4
overexpression did not significantly enhance the replication of
SIVmac316, which was still fivefold higher than that of
SIVmac239. These results indicate that the replication
efficiency of SIVmac239 can be strongly enhanced by
overexpressing CD4 on rhesus monkey macrophages, but it did not reach
the replication level of SIVmac316 under the conditions
present in our system.
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CD4 dependence of SIV and HIV-1 entry into Cf2Th cells in the
presence of high and low CCR5 levels.
A remarkable feature of many
SIV strains is their ability to bind CCR5 and to enter CCR5-expressing
cells independently of CD4 (28, 30, 63). The results
presented above suggest that the CD4 and CCR5 levels on rhesus monkey
macrophages support entry of SIVmac316 but restrict efficient
entry of SIVmac239. To study the CD4 and CCR5 requirements
for entry in more detail, we generated Cf2Th canine thymocytes stably
expressing high and low levels of human CCR5 (Fig.
5A and B). These cells were then
transiently transfected with increasing amounts of a CD4-expressing
plasmid, keeping the total DNA amount constant by addition of an
irrelevant plasmid. Two days after transfection, the cells were
infected with CAT reporter viruses containing different envelope
glycoproteins; in parallel, the CD4 expression level was
determined by FACS. The efficiency with which viruses with the
SIVmac316 envelope glycoproteins infected
CD4-negative Cf2Th cells was strongly dependent on the level of CCR5
expression. Viruses with SIVmac316 envelope glycoproteins efficiently infected cells with a high level
of CCR5 regardless of the presence or level of expression of CD4 (Fig.
5C). By contrast, in cells expressing low CCR5 levels, infection by
viruses with the SIVmac316 envelope glycoproteins
was significantly enhanced by coexpression of CD4 (Fig. 5D). Detectable
infection of cells expressing either high or low levels of CCR5 by
viruses with the SIVmac239 and YU2 envelope
glycoproteins was strictly CD4 dependent. The efficiency of
infection by viruses with the SIVmac239 envelope
glycoproteins exhibited the greatest dependence on CD4
levels. These data demonstrate that, depending on the level of CCR5
expressed on the target cell surface, the level of CD4 expressed can
give rise to differences in the efficiency of SIVmac316 and
SIVmac239 infection that range from 3- to 1,000-fold. As the CCR5 expression level on primary rhesus monkey macrophages more closely
resembles that on our Cf2Th cells expressing low levels of CCR5, the
low levels of CD4 on primary macrophages could readily account
for the observed differences in the efficiency with which SIVmac316 and SIVmac239 infect these
cells.
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CD4 requirement of SIVmac316 for infection of rhesus
macrophages.
To evaluate whether SIVmac316 requires CD4
for infection of rhesus monkey macrophages, we used the anti-CD4
antibody OKT4a to inhibit the entry of recombinant viruses with
the SIVmac316 envelope glycoproteins. A
concentration-dependent inhibition of infection by OKT4a was observed;
at the highest concentration of antibody tested, infection was almost
completely inhibited (Fig. 6A). An
isotype-matched antitrinitrophenol antibody used as a control had no
effect on the infection of viruses with the SIVmac316
envelope glycoproteins (data not shown). The effects of the OKT4a
antibody were specific, as this antibody did not inhibit a virus
pseudotyped with VSV G (Fig. 6B).
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DISCUSSION |
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Abstract
Introduction
Materials and Methods
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Discussion
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In this study, we examined the target cell variables that govern SIV cell tropism. As representative strains for our study, we used SIVmac239, the best-characterized T-tropic SIV isolate, and SIVmac316, an M-tropic strain isolated from the alveolar macrophages of a rhesus monkey infected with SIVmac239 (41, 44, 55). Previous studies suggested that the SIVmac239 envelope glycoproteins determined a postentry replication block in rhesus monkey macrophages (53). We also examined the basis of the previously reported inability of a SHIV bearing the envelope glycoproteins of the M-tropic HIV-1 isolate JR-FL to replicate on rhesus monkey macrophages (15). The use of recombinant viruses pseudotyped with the envelope glycoproteins of these viruses allowed us to examine events in the infection process specifically modulated in trans by viral env sequences. Our results indicate that a single round of infection of primary rhesus macrophages was mediated by the SIVmac239 envelope glycoproteins 30 to 100 times less efficiently than by the SIVmac316 envelope glycoproteins. Likewise, reporter viruses containing the envelope glycoproteins of several M-tropic HIV-1 strains were extremely inefficient at infecting primary rhesus monkey macrophages. As SIVmac239 and the M-tropic HIV-1 utilize monkey CD4 and CCR5 (16, 50a), which are expressed on the primary macrophages, the observed blocks could not be explained by the qualitative absence of appropriate receptors.
We examined whether quantitative increases in the expression of CD4, CCR5, or CXCR4 could influence the infectability of the primary rhesus monkey macrophages by the recombinant viruses. Our results show that only CD4 overexpression specifically overcame the restriction observed for viruses bearing the SIVmac239 or M-tropic HIV-1 envelope glycoproteins. Similar results were obtained by overexpressing a truncated CD4 glycoprotein lacking the cytoplasmic tail, indicating that signal transduction through CD4 is not necessary for overcoming the replication block. This result strongly suggests that a major restriction against infection of primary rhesus monkey macrophages by SIVmac239 and M-tropic HIV-1 occurs at the level of virus entry. Once this restriction is overcome, all of the steps in the virus replication cycle monitored by the single-round, env complementation assay occur efficiently. Indeed, overexpression of full-length CD4 in rhesus monkey macrophages allowed the replication of infectious SIVmac239. The level of replication observed was still lower than that of SIVmac316, possibly due to insufficient CD4 expression or to other factors, such as the previously described inefficiency of SIVmac239 envelope glycoprotein precursor processing in primary macrophages (67).
Our results imply that a major variable governing SIV macrophage tropism is the efficiency with which low levels of CD4 on the target cell surface can be utilized to support entry. The ability to utilize low levels of CD4 may reflect a higher affinity of the SIVmac316 envelope glycoproteins for CD4, relative to the affinities of the SIVmac239 and M-tropic HIV-1 envelope glycoproteins. Indeed, the binding affinity of monomeric gp120 from SIVmac316 for sCD4 is higher than that of SIVmac239 gp120 (63). Differences in affinity or cooperativity in CD4 binding might be even more apparent in the context of a trimeric envelope glycoprotein spike. The CD4 binding affinity of the assembled envelope glycoprotein complex of primary, M-tropic HIV-1 strains has been suggested to be low (52a). This could account for the observed restriction in primary rhesus macrophages against viruses with M-tropic HIV-1 envelope glycoproteins.
Our results demonstrate that CCR5 is the major coreceptor used by SIV and M-tropic HIV-1 isolates to infect primary rhesus monkey macrophages. mRNAs for other SIV receptors, such as gpr1 and gpr15 (31), have been found in macrophages, but the inhibition experiments using TAK-779 clearly indicate the dominant use of CCR5 by the viruses studied. The level of CCR5 expression can influence the dependency of SIV or M-tropic HIV-1 infection on CD4 expression levels, consistent with previous results (57). At the low CCR5 levels on the surface of rhesus monkey macrophages, SIVmac316 requires surface CD4 for efficient entry. By contrast, at high levels of CCR5 expression, efficient SIVmac316 entry can occur in the complete absence of CD4 on the target cell. It is noteworthy that other SIV variants that are M-tropic exhibit some measure of CD4 independence. For example, SIV/17E-Fr, which was derived from the brain of an SIVmac239-infected monkey, readily infects CD4-negative brain capillary endothelial cells (30, 49). CD4 independence in the presence of high surface levels of CCR5 may be a manifestation of the properties of M-tropic SIV envelope glycoproteins that allow the low levels of CD4 on primary monkey macrophages to be efficiently utilized. In addition to the increases in CD4 binding discussed above, these properties may include the more efficient attainment of a trimeric envelope glycoprotein conformation able to bind CCR5 at a lower state of occupancy by CD4.
The extremely inefficient infection of rhesus monkey macrophages by viruses with M-tropic HIV-1 envelope glycoproteins stands in contrast to the efficient infection of primary human macrophages by these viruses. This observation implies that differences, perhaps in levels of surface CD4 expression, exist between primary macrophages derived from humans and rhesus monkeys. These species-dependent distinctions have apparently shaped the evolution of M-tropic SIV and HIV-1 differently. The ability of the viral envelope glycoproteins to mediate fusion with a cell membrane containing sparse CD4, a property critical for infection of monkey macrophages, appears not to be essential for HIV-1 to enter human macrophages. Further investigation of this coincidence of viral and host cell characteristics may lead to a better understanding of the importance of macrophage tropism in the biology of the primary immunodeficiency viruses.
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ACKNOWLEDGMENTS |
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We acknowledge Ronald Desrosiers, Raymond Sweet, and M. Fujino for reagents. We thank Maris Handley at the Dana-Farber Cancer Institute flow cytometry core facility for excellent technical support and Yvette McLaughlin and Sheri Farnum for manuscript preparation.
This work was supported by National Institutes of Health grants AI24755 and AI41851 and by Center for AIDS Research grant AI28691. Additional support was provided by the G. Harold and Leila Y. Mathers Foundation, the late William F. McCarty-Cooper, the Friends 10, and Douglas and Judith Krupp. N. Bannert was supported by a fellowship from the Deutsche Forschungsgemeinschaft (DFG).
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FOOTNOTES |
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* Corresponding author. Mailing address: Dana-Farber Cancer Institute, 44 Binney St., JFB 824, Boston, MA 02115. Phone: (617) 632-3371. Fax: (617) 632-4338. E-mail: Joseph_Sodroski{at}dfci.harvard.edu.
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Journal of Virology, December 2000, p. 10984-10993, Vol. 74, No. 23
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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(2009). Fibrils of Prostatic Acid Phosphatase Fragments Boost Infections with XMRV (Xenotropic Murine Leukemia Virus-Related Virus), a Human Retrovirus Associated with Prostate Cancer. J. Virol.
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Grove, J., Nielsen, S., Zhong, J., Bassendine, M. F., Drummer, H. E., Balfe, P., McKeating, J. A.
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DeGottardi, M. Q., Lew, S. K., Piatak, M. Jr., Jia, B., Feng, Y., Lee, S. J., Brenchley, J. M., Douek, D. C., Kodama, T., Lifson, J. D., Evans, D. T.
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Martin-Garcia, J., Cocklin, S., Chaiken, I. M., Gonzalez-Scarano, F.
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Walter, B. L., Wehrly, K., Swanstrom, R., Platt, E., Kabat, D., Chesebro, B.
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Overholser, E. D., Babas, T., Zink, M. C., Barber, S. A., Clements, J. E.
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Moore, M. J., Dorfman, T., Li, W., Wong, S. K., Li, Y., Kuhn, J. H., Coderre, J., Vasilieva, N., Han, Z., Greenough, T. C., Farzan, M., Choe, H.
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Peters, P. J., Bhattacharya, J., Hibbitts, S., Dittmar, M. T., Simmons, G., Bell, J., Simmonds, P., Clapham, P. R.
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Painter, S. L., Biek, R., Holley, D. C., Poss, M.
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von Lindern, J. J., Rojo, D., Grovit-Ferbas, K., Yeramian, C., Deng, C., Herbein, G., Ferguson, M. R., Pappas, T. C., Decker, J. M., Singh, A., Collman, R. G., O'Brien, W. A.
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Johnson, W. E., Lifson, J. D., Lang, S. M., Johnson, R. P., Desrosiers, R. C.
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Imamichi, H., Igarashi, T., Imamichi, T., Donau, O. K., Endo, Y., Nishimura, Y., Willey, R. L., Suffredini, A. F., Lane, H. C., Martin, M. A.
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Rogers, A. B., Mathiason, C. K., Hoover, E. A.
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Gorry, P. R., Taylor, J., Holm, G. H., Mehle, A., Morgan, T., Cayabyab, M., Farzan, M., Wang, H., Bell, J. E., Kunstman, K., Moore, J. P., Wolinsky, S. M., Gabuzda, D.
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Bannert, N., Craig, S., Farzan, M., Sogah, D., Santo, N. V., Choe, H., Sodroski, J.
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Gorry, P. R., Bristol, G., Zack, J. A., Ritola, K., Swanstrom, R., Birch, C. J., Bell, J. E., Bannert, N., Crawford, K., Wang, H., Schols, D., De Clercq, E., Kunstman, K., Wolinsky, S. M., Gabuzda, D.
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Mansfield, K. G., Veazey, R. S., Hancock, A., Carville, A., Elliott, M., Lin, K.-C., Lackner, A. A.
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Martín, J., LaBranche, C. C., González-Scarano, F.
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Means, R. E., Matthews, T., Hoxie, J. A., Malim, M. H., Kodama, T., Desrosiers, R. C.
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Kim, S. S., You, X. J., Harmon, M.-E., Overbaugh, J., Fan, H.
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