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J Virol, June 1998, p. 5035-5045, Vol. 72, No. 6
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
In Vivo Distribution of the Human
Immunodeficiency Virus/Simian Immunodeficiency Virus
Coreceptors: CXCR4, CCR3, and CCR5
Linqi
Zhang,1
Tian
He,1
Andrew
Talal,1
Gloria
Wang,1
Sarah S.
Frankel,2 and
David D.
Ho1,*
Aaron Diamond AIDS Research Center, The
Rockefeller University, New York, New York
10016,1 and Division of Retrovirology, Walter
Reed Army Institute of Research, Rockville, Maryland 20850, and
Department of Parasitic and Infectious Disease Pathology,
Armed Forces Institute of Pathology, Washington, D.C.
203062
Received 1 December 1997/Accepted 3 March 1998
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ABSTRACT |
We have evaluated the in vivo distribution of the major human
immunodeficiency virus/simian immunodeficiency virus (HIV/SIV) coreceptors, CXCR4, CCR3, and CCR5, in both rhesus macaques and humans.
T lymphocytes and macrophages in both lymphoid and nonlymphoid tissues
are the major cell populations expressing HIV/SIV coreceptors, reaffirming that these cells are the major targets of HIV/SIV infection
in vivo. In lymphoid tissues such as the lymph node and the thymus,
approximately 1 to 10% of the T lymphocytes and macrophages are
coreceptor positive. However, coreceptor expression was not detected on
follicular dendritic cells (FDC) in lymph nodes, suggesting that the
ability of FDC to trap extracellular virions is unlikely to be mediated
by a coreceptor-specific mechanism. In the thymus, a large number of
immature and mature T lymphocytes express CXCR4, which may render these
cells susceptible to infection by syncytium-inducing viral variants
that use this coreceptor for entry. In addition, various degrees of
coreceptor expression are found among different tissues and also among
different cells within the same tissues. Coreceptor-positive cells are
more frequently identified in the colon than in the rectum and more
frequently identified in the cervix than in the vagina, suggesting that
the expression levels of coreceptors are differentially regulated at
different anatomic sites. Furthermore, extremely high levels of CXCR4
and CCR3 expression are found on the neurons from both the central and
peripheral nervous systems. These findings may be helpful in
understanding certain aspects of HIV and SIV pathogenesis and
transmission.
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INTRODUCTION |
Viral entry into target cells is
mediated through a complex interaction between the viral envelope
proteins and specific cellular receptors. The CD4 glycoprotein is the
primary receptor for human immunodeficiency virus types 1 and 2 (HIV-1
and HIV-2) and simian immunodeficiency virus (SIV) (12, 32).
However, expression of the CD4 molecule alone is not sufficient for
viral entry, suggesting the need for one or more additional cellular
coreceptors (4, 38). The recent identification of multiple
chemokine receptors as the coreceptors for HIV/SIV entry has greatly
assisted our understanding of HIV/SIV pathogenesis, transmission,
and tropism. Currently, eight coreceptors, CXCR4, CCR2b, CCR3, CCR5,
Bonzo (STRL33), BOB (GPR15), GPR1, and US28, have been found to play an
essential role in HIV/SIV entry (1, 7, 9, 14-17, 19, 20,
36). Among these coreceptors, CXCR4, CCR3, and CCR5 are the major
ones used by HIV isolates for efficient entry (1, 7, 16, 17,
20). Additionally, phenotypic characteristics dictate the
specific coreceptor(s) used by viral isolates (11, 49, 58).
Non-syncytium-inducing (NSI) or macrophage (M)-tropic primary viruses
predominantly use CCR5, whereas syncytium-inducing (SI) T-cell line
(T)-tropic viruses preferentially use CXCR4 (11, 49, 58).
Some NSI and SI isolates also use CCR3, although the number is
extremely small. M-tropic viruses are preferentially transmitted
through sexual contact and predominate in the majority of infected
individuals, whereas T-tropic viruses, which emerge during the late
stages of infection, are more virulent and are associated with higher
rates of CD4+-T-cell decline (10, 48, 51, 59,
60).
The ability of viruses to infect target cells is dependent not only on
the viral phenotype but also on the availability and expression levels
of the appropriate primary receptors and coreceptors. The primary
receptor CD4 is differentially expressed on different cell subsets,
with significantly lower levels of expression on macrophages than on T
lymphocytes. The lower level of CD4 expression has rendered macrophages
relatively resistant to infection by many of the primary viruses,
especially those that are heavily dependent on a high level of CD4
expression for entry (33, 45). The coreceptors CXCR4 and
CCR5 are also differentially regulated on different cell subsets. In
freshly isolated peripheral blood lymphocytes, CXCR4 is found
predominantly on naive
(CD26lowCD45RA+CD45RO
)
T lymphocytes whereas CCR5 is expressed on memory T lymphocyte subsets
(CD26highCD45RACD45RO+)
(3, 56). The reciprocal pattern of coreceptor
expression may partially explain the previous observations that
CD4+ memory T lymphocytes are preferentially infected by
HIV-1 in vitro (8, 47).
The complex pattern of primary-receptor and coreceptor expression is
probably reflected by an equally complex pattern of HIV/SIV infection
in vivo. Many of the stromal and lymphoid cells in the bone marrow,
thymus, lymph nodes, and spleen are infected by HIV/SIV (2, 6, 21,
29, 53). In the early stages of HIV/SIV infection of lymph nodes,
the majority of viral replication occurs primarily in macrophages and
lymphocytes, whereas in the later stages, viral RNA is concentrated
primarily in the germinal center, colocalizing with the follicular
dendritic cells (FDC) (22, 44). HIV/SIV infection of the
thymus has shown another level of complexity. SI viruses replicate
faster, generate higher viral titers, and cause a more severe depletion
of CD4+ thymocytes than do NSI isolates (30,
50), which suggests that the phenotypic switch from NSI to SI
during the course of infection is likely to trigger more severe
cytopathic effects on thymocytes. In addition, the mucosa-associated
lymphoid tissue is a target for HIV/SIV infection. Infectious viral
particles have been successfully isolated directly from tissues of the
gastrointestinal (GI) and genitourinary (GU) tracts (25, 26, 37,
40, 42). The primary infected cells in the mucosa-associated
lymphoid tissue have been identified as tissue macrophages, dendritic
cells, and T lymphocytes located in the lamina propria adjacent to the
surface epithelium (26, 27, 40-42).
Although significant advancement has been made recently in identifying
and characterizing multiple novel coreceptors for HIV/SIV infection,
the majority of these studies have been performed in vitro. Due to the
complex pattern of coreceptor regulation and signaling by the
chemokines, it is difficult to assess the significance of a particular
coreceptor without understanding the pattern and level of its
expression in vivo. For these reasons, we sought to investigate the in
vivo expression pattern of the three major coreceptors used by HIV/SIV,
CXCR4, CCR3, and CCR5, in human and rhesus monkey tissues.
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MATERIALS AND METHODS |
Animals.
Tissue samples were collected from four
SIV-infected (5685, 1204, 1216, and 1208) and two uninfected (1360 and
1366) rhesus macaques (Table 1). Of these
four SIV-infected animals, one (5685) was at the terminal stage of SIV
infection, with clinical symptoms consistent with simian AIDS, and the
remaining three (1204, 1216, and 1208) were clinically asymptomatic at
the time of necropsy. The last three animals were included in our
previous studies on the effects of progesterone implants on SIV vaginal
transmission (39). These animals were sacrificed 3 or 4 days
after vaginal inoculation with SIVmac251 (39). The
uninfected animals (1360 and 1366) were healthy at the time of
necropsy. These animals were multiparous adult females and were
maintained at the Laboratory for Experimental Medicine and Surgery in
Primates (Tuxedo, N.Y.) in accordance with American Association for
Accreditation of Laboratory Animal Care standards.
Tissue collection and processing.
Samples were obtained from
the thymus, lymph nodes, brain, and GI (rectum and colon) and GU
(vagina and cervix) tracts of the rhesus monkeys. An axillary and a
cervical lymph node were obtained from two HIV-1-infected humans on
combination antiretroviral therapy (Table 1). Multiple fixed
paraffin-embedded human vaginal mucosal samples were obtained from the
pathology department archive at Georgetown University Hospital. The
tissues were completely deidentified. The tissue samples were sectioned
into pieces approximately 0.3 by 0.3 by 0.3 cm, washed in
phosphate-buffered saline, and fixed in Streck's tissue fixative
(Streck Laboratories, Inc., Omaha, Nebr.) for 1 week. The tissue
samples were then embedded into paraffin with an automated tissue
processor under heat and vacuum pressure.
Immunohistochemistry.
Immunohistochemistry was performed
with the LSAB2 kit (Dako Diagnostics, Carpinteria, Calif.) as specified
by the manufacturer. Sections approximately 8 µm thick were fixed
onto positively charged slides coated with 3-aminopropylethoxysilane.
The sections were then deparaffinized in xylene and rehydrated through
graded alcohol concentrations (100, 95, and 70%). Citra solution
(BioGenex, San Ramon, Calif.) was applied to the sections at 90°C for
6 min to retrieve the antigens from the fixed specimens. Immunostaining was performed for 60 min at room temperature and was developed by the
avidin-biotin-peroxidase complex technique with the chromogen aminoethylcarbazole (AEC). The following dilutions and antibodies (all
from Dako Diagnostics), which were found to cross-react with macaque
antigens, were used: major histocompatibility complex class II, mouse
anti-human-HLA-DR (clone TAL.1B5), 1:50; an anti-lysosomal membrane
antibody which is highly expressed on monocytes/macrophages and some
dendritic cells, mouse anti-human CD68 (clone KP1), 1:33; T
lymphocytes, rabbit anti-human CD3 (polyclonal), 1:33; and dendritic cells, rabbit anti-cow S-100 (polyclonal), 1:100. Coreceptor-specific monoclonal antibodies were used in the following dilutions: 1:800 for
mouse anti-human CXCR4 antibody 12G5; 1:50 for mouse anti-human CCR3
antibody 7B11, and 1:20 for mouse anti-human CCR5 antibody 2D7. The
coreceptor-specific antibodies have been extensively characterized and
were found to stain strongly both fresh and activated peripheral blood
mononuclear cells (3, 18, 24, 55). They are also capable of
blocking HIV-1 or HIV-2 infection of peripheral blood mononuclear cells
in vitro (18, 23, 55). 12G5 detects both naive and memory T
lymphocytes (3), whereas 2D7 readily stains activated T
lymphocytes (55). 7B11 binds strongly to eosinophils and
blocks HIV-1 infection of neuronal microglia (23, 24). All
tissue sections were counterstained with Mayer's hematoxylin and
mounted with Crystal/Mount (Biomeda, Culver City, Calif.), and a
coverslip was applied for microscopic examination. Nonreactive mouse
and rabbit antibodies of a similar isotype were used as negative
controls. Appropriate controls were run on all sections.
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RESULTS |
Using immunohistochemistry, we have detected numerous
coreceptor-positive cells in both lymphoid and nonlymphoid tissues. The
majority of the coreceptor-positive cells are T lymphocytes and tissue
macrophages. Although we studied samples from six animals (Table 1), we
did not observe significant differences in coreceptor expression
between SIV-infected and uninfected subjects. Therefore, we decided to
illustrate the expression pattern of these coreceptors in vivo by using
one uninfected animal (1360). Additionally, human specimens from the
lymph nodes and vagina were studied. To quantify the differences
between various tissues, we measured the number of coreceptor-positive
cells per square millimeter of tissue (Table 2). As shown in Table 2, significant
differences were noted between different tissues and between different
cell types within the same tissue. Approximately 51 and 176 coreceptor-positive cells mm2 were found in the lymph
node and the thymus, respectively. This is equivalent to 1 to 10% of
the T lymphocytes and the macrophages in the lymphoid tissue. In the GI
and GU tracts, however, the coreceptor-positive cells were identified
more frequently in the colon (51 mm2) than in the rectum
(12 mm2) and more frequently in the cervix (19 mm2) than in the vagina (<6 mm2).
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TABLE 2.
Quantitative analysis of the number of
coreceptor-positive cells per square millimeter in various tissues from
rhesus macaques
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Abundant expression of coreceptors in lymphoid tissues.
Figure
1a demonstrates the expression pattern of
the coreceptors in an ileal lymph node. The CXCR4- and
CCR3-positive cells were located predominantly in the medulla and
inside the germinal center. Based on their morphological appearances,
the majority of the cells are macrophages and T lymphocytes. However,
there appeared to be variable expression of both coreceptors. The
CXCR4- and CCR3-positive cells constituted only a small proportion of the entire cell population, suggesting that the expression of coreceptors may be regulated. In a previous report, tissue macrophages were also CCR3 positive (24). Therefore, the coreceptor
CCR3, although originally isolated and cloned from eosinophils
(13, 46), is unlikely to be eosinophil specific.
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FIG. 1.
(a) Immunohistochemical localization and phenotypes of
coreceptor-positive cells in an ileal lymph node from rhesus macaque
1360 (AEC with hematoxylin counterstain; magnification, ×156 except as
otherwise indicated). Some of the representative positive cells are
indicated by arrowheads. The CXCR4-positive cells in the medulla are
shown at two magnifications (×156 and ×468). The CCR3-positive cells
are inside and surrounding the two germinal centers. The CCR5-positive
cells are surrounding rather than inside the germinal centers. T
lymphocytes and macrophages in the medulla are identified by the
anti-CD3 and the anti-CD68 antibodies, respectively. No detectable
levels of coreceptors were identified on the FDC, despite the presence
of an intact FDC network in the germinal center. (b)
Immunohistochemical localization and phenotypes of coreceptor-positive
cells in an axillary lymph node from HIV-1-infected individual Hu1004
(AEC with hematoxylin counterstain; magnification, ×600). Some of the
representative positive cells are indicated by arrowheads. The CXCR4-
and CCR3-positive cells in the medulla are morphologically similar to
macrophages identified by anti-CD68 antibody. A large number of T
lymphocytes were identified by anti-CD3 antibody, but the CCR5-positive
cells were not visualized. No detectable levels of CXCR4, CCR3, or CCR5
on the FDC were demonstrated despite the presence of an intact FDC
network.
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In contrast, the expression pattern of CCR5 in the lymph nodes was
quite distinct. The majority of the CCR5-positive cells
were found in
the medulla and the cortex surrounding, rather than
inside, the
germinal centers (Fig.
1a). Almost all of these cells
had a typical
lymphocyte morphology; however, only a minority
of the lymphocytes
expressed CCR5. In addition, FDC did not express
any of the three
coreceptors.
The coreceptor expression pattern in a human axillary lymph node was
not significantly different from that observed in rhesus
macaques (Fig.
1b). The CXCR4- and CCR3-positive cells were found
primarily in the
medulla and in the germinal centers. Morphologically,
these cells
appeared to be macrophages. However, we could not
detect CCR5-positive
cells from this specimen despite the existence
of a substantial number
of T lymphocytes (Fig.
1b), suggesting
that the expression of CCR5 in
this node is quite limited. Furthermore,
similar to rhesus macaques,
the FDC in the human lymph node did
not express CXCR4, CCR3, or CCR5
(Fig.
1b).
In the thymus, the coreceptor expression pattern was dramatically
different from that observed in the lymph nodes. Most of
the cells in
the cortex, predominantly immature T lymphocytes,
and in the central
portion of the medulla, mostly mature T lymphocytes,
were positive for
CXCR4 (Fig.
2). The mature T lymphocytes,
in
the central portion of the medulla, were heavily stained with
anti-CD3 antibody (Fig.
2). In contrast, the CCR3-positive cells
were
rarely demonstrated in either the cortex or the medulla.
Based on the
staining pattern with S-100 and CD68 antibodies,
these cells were
either dendritic cells or macrophages. Furthermore,
the CCR5-positive
cells populated two distinct regions of the
thymus: the outer cortex
and the central region of medulla. The
cells in the outer cortex were
invariably larger than those in
the deep medulla (Fig.
2), consistent
with the morphological appearance
of lymphoblasts (
5). The
smaller cells in the deep medulla,
believed to be the daughter cells of
lymphoblast mitosis, are
likely to be mature T lymphocytes
(
5). As observed in the lymph
node and the spleen, CCR5 was
expressed on a minority of the mature
and immature T lymphocytes in the
thymus.
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FIG. 2.
Immunohistochemical localization and phenotypes of
coreceptor-positive cells in the thymus of rhesus macaque 1360 (AEC
with hematoxylin counterstain; magnification, ×100). Some of the
representative positive cells are indicated by arrowheads. Due to the
high density, the CXCR4-positive cells in the cortex are not as obvious
as in the lymph node. The CCR3-positive cells are large and irregular
compared to their neighboring cells and are believed to be macrophages
identified by the anti-CD68 antibody. The majority of the CCR5-positive
cells are located in the outer cortex and the central region of
medulla, although a few are also identified in the interlobular septa.
The epithelial framework of the thymus is stained strongly with
anti-HLA-DR antibody.
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Differential expression of coreceptors in different proportions of
the GI tract.
In the rectum, the CXCR4-positive cells were
infrequent, had a morphology similar to the macrophages or dendritic
cells stained by anti-CD68 and anti-HLA-DR antibodies, and were located
primarily in the lamina propria (Fig. 3).
In contrast, the CCR3-positive cells were readily detected in the
lamina propria and were morphologically similar to macrophages and
dendritic cells stained by anti-CD68 and anti-S-100 antibodies,
respectively. Many of the eosinophils located in the lamina propria
were also CCR3 positive (data not shown). A large number of
CCR5-positive cells were identified in the rectum, had a morphological
appearance similar to T lymphocytes (Fig. 3), and were randomly
distributed in the lamina propria. As noted above for the lymphoid
tissues, the coreceptor-positive cells constituted only a small
proportion of the entire lymphocyte and macrophage population.
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FIG. 3.
Immunohistochemical localization and phenotypes of
coreceptor-positive cells in the rectum of rhesus macaque 1360 (AEC
with hematoxylin counterstain; magnification, ×154 except as otherwise
indicated). Some of the representative positive cells are indicated by
arrowheads. The CXCR4-positive cells are minimal and are barely visible
at high magnification (×462). The CCR3- and CCR5-positive cells are
located primarily in the lamina propria. A large number of T
lymphocytes, macrophages, HLA-DR-positive cells, and dendritic cells
are readily detected.
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The expression of CXCR4 was higher in the colon than in the rectum
(Fig.
4; Table
2), although the location,
morphological
appearance, and staining characteristics of the
CXCR4-positive
cells in the colon were similar to those observed in the
rectum
(Fig.
4). The CCR3-positive cells were also abundant in the
colon
and were morphologically similar to macrophages, dendritic cells,
or T lymphocytes. The lamina propria eosinophils were also positive
for
CCR3 (data not shown). The CCR5-positive cells were frequently
identified in the lamina propria and had a morphological appearance
typical of either macrophages or lymphocytes (Fig.
4). The coreceptor
distribution is consistent with previous studies in which
virus-infected
cells are identified predominantly as T lymphocytes and
macrophages
in the lamina propria adjacent to the surface epithelium
(
26,
27).
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FIG. 4.
Immunohistochemical localization and phenotypes of
coreceptor-positive cells in the colon of rhesus macaque 1360 (AEC with
hematoxylin counterstain; magnification, ×164 except as otherwise
indicated). Some of the representative positive cells are indicated by
arrowheads. The CXCR4-positive cells are demonstrated in the lamina
propria (magnifications, ×164 and ×492). Both the CCR3- and
CCR5-positive cells are shown in cross section and longitudinal
section. Numerous T lymphocytes and macrophages are detected in the
lamina propria. S-100 antibody avidly stains the dendritic cells in the
lamina propria as well as the nerve fibers from the unnamed plexus.
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The cervical mucosa expresses high levels of coreceptors in the GU
tract.
We could not demonstrate coreceptor expression in the
vagina in multiple samples from either infected or uninfected rhesus macaques (Fig. 5a) or from an uninfected
human (Fig. 5b), despite the presence of a large number of T
lymphocytes, macrophages, and HLA-DR-positive cells in the submucosa.
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FIG. 5.
(a) Immunohistochemical localization and phenotypes of
coreceptor-positive cells in the vagina of rhesus macaque 1360 (AEC
with hematoxylin counterstain; magnification, ×400). Some of the
representative positive cells are indicated by arrowheads. No CXCR4-,
CCR3-, or CCR5-positive cells were identified in the lamina propria of
the vagina, despite the presence of a large number of T lymphocytes,
macrophages, and dendritic cells, stained by anti-CD3, anti-CD68, and
anti-S-100 antibodies, respectively. (b) Immunohistochemical
localization and phenotypes of coreceptor-positive cells in the vagina
of human HuVM. The arrowheads indicate some of the HLA-DR-positive
cells (AEC with hematoxylin counterstain; magnification, ×600). As in
rhesus macaque 1360, no CXCR4-, CCR3-, or CCR5-positive cells were
identified in the lamina propria of the vagina.
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In the cervix, many coreceptor-positive cells were detected. The
CXCR4-positive cells, which appeared morphologically as tissue
macrophages or dendritic cells, were located in the lamina propria
beneath the columnar epithelium, whereas a few positive cells
were also
found in the epithelial lining (Fig.
6).
The CCR3-positive
cells, either macrophages or dendritic cells, were
also prevalent
in the lamina propria (Fig.
6). However, only a few
CCR5-positive
cells were identified in this tissue. These cells were
located
in the lamina propria adjacent to the epithelial layer and
appeared
morphologically as T lymphocytes (Fig.
6).
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FIG. 6.
Immunohistochemical localization and phenotypes of
coreceptor-positive cells in the cervix of rhesus macaque 1360 (AEC
with hematoxylin counterstain; magnification, ×400). Some of the
representative positive cells are indicated by arrowheads. The majority
of the CXCR4- and CCR3-positive cells are believed to be macrophages or
dendritic cells and are located primarily in either the lamina propria
or the epithelial lining. The CCR5-positive cells are located adjacent
to the epithelium. A few HLA-DR-positive cells are also located below
the epithelium.
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High levels of CXCR4 and CCR3 are expressed in the central and
peripheral nervous systems.
In the brain and regional ganglia of
the rhesus macaque, neurons expressed extremely high levels of CXCR4
and CCR3, especially in the cell body (Fig.
7). In addition, macrophages located
primarily in the walls of small blood vessels expressed CXCR4 (data not shown) and CCR3, which had previously been found to be the major targets for HIV/SIV infection in the central nervous system (CNS) (34). In contrast to CXCR4 and CCR3, CCR5 could not be
demonstrated in the neurons or the regional ganglia. Oligodendrocytes
in the CNS, which stained strongly with S-100 antibody, were negative for all three coreceptors (Fig. 7). The Schwann cells in the regional ganglia, although highly positive for HLA-DR and S-100, were also negative for all three coreceptors (Fig. 7).
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FIG. 7.
Immunohistochemical localization and phenotypes of
coreceptor-positive cells in the brain (upper two panels) and in the
regional ganglia (lower two panels) of rhesus macaque 1360 (AEC with
hematoxylin counterstain; magnification, ×200 except as otherwise
indicated). Some of the representative positive cells are indicated by
arrowheads. Neurons in the brain and regional ganglia express high
levels of CXCR4 (magnifications, ×400 and ×600) and CCR3
(magnification, ×400) but no detectable level of CCR5 (magnification,
×400). Macrophages located on the wall of small blood vessels
(magnification, ×600) are also positive for CXCR4 (data not shown) and
CCR3 (magnification, ×400). S-100 antibody stains oligodendrocytes in
the CNS (magnification, ×600) and Schwann cells in the regional
ganglia. Schwann cells are also positive for HLA-DR.
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DISCUSSION |
We have studied the in vivo distribution of the chemokine
receptors CXCR4, CCR3, and CCR5, which are the major coreceptors for
HIV/SIV infection. Although we did not evaluate the distribution pattern of other chemokine receptors in this study, the future availability of reagents such as high-quality antibodies specific for
other chemokine receptors will certainly make this type of study
possible. It should be emphasized that other chemokine receptors such
as CCR1, CCR2b, Bonzo (STRL33), BOB (GPR15), GPR1, and US28 may also
play some roles in HIV/SIV pathogenesis.
In this study, we found that T lymphocytes and macrophages in both
lymphoid and nonlymphoid tissues represent the majority of the
coreceptor-positive cells, reaffirming that these cells are the major
targets for HIV/SIV infection in vivo and therefore are potentially
subject to viral cytopathic consequences. The high level of coreceptor
expression may also explain the initial and persistent viral (HIV/SIV)
infection of lymphoid tissues throughout the course of infection
(21, 22, 29, 44). In addition, the high level of CXCR4
expression on both immature and mature thymocytes is likely to render
these cells particularly susceptible to the SI isolates. Our finding is
consistent with reports that SI isolates are relatively thymocyte
tropic and replicate faster than NSI isolates both in vitro and in
SCID-hu mice (30, 31, 50). Therefore, HIV/SIV can mediate
lymphocyte depletion by directly infecting and replicating in
thymocytes in vivo during all stages of T-lymphocyte maturation. The
phenotypic switch from NSI to SI during infection is also likely to
trigger more severe cytopathic effects in the thymus. Furthermore, the
failure to detect coreceptor expression on FDC despite the presence of
an intact FDC network suggests that the trapping and presentation of
viral particles to target T lymphocytes in germinal centers is
independent of coreceptors.
Coreceptor-positive cells are frequently identified in both the GI and
GU tracts. However, the level of expression is generally higher in the
proximal than the distal parts of the GI and GU tracts, suggesting that
the expression may be differentially regulated. Since only a small
proportion of the macrophages and the T lymphocytes express the
coreceptors, a strict regulatory mechanism may govern the timing, the
location, and the level of coreceptor expression. Although the exact
mechanism is currently unknown, we believe that the degree of cellular
maturation, the level of activation, and the concentration of the
coreceptor-specific chemokines (e.g., SDF-1 and 
-chemokine within
the tissue environment are all likely to affect the level of coreceptor
expression.
The coreceptor-positive T lymphocytes and macrophages in the distal
portion of the GI and GU tracts may serve as a portal of viral entry as
well as a source of viral dissemination. Based on our current
knowledge, NSI rather than SI viruses are predominantly transmitted
through the GI and GU tracts (59, 60), which suggests the
existence of selective pressure in favor of NSI isolates during sexual
contact. Is this selective pressure imposed on the viral replication
rate, the preferential usage of certain coreceptors, or the degree of
cytopathicity? In the rectum, since numerous CCR5- and CCR3-positive
cells are readily detected in the lamina propria whereas the
CXCR4-positive cells are barely visible, the coreceptor expression
pattern may serve as one selective pressure for initial infection
by NSI isolates. In contrast, the expression pattern of
coreceptors in the GU tract is quite different. Although we did not
detect coreceptor expression in the vagina, a large number of CXCR4-
and CCR3-positive, but not CCR5-positive, cells are frequently
identified in the cervix. Coreceptor expression in the GU tract is
therefore not necessarily in favor of CCR5-using or NSI viruses. One
intriguing question raised from this observation is whether the
coreceptor CXCR4 can be utilized initially if SI isolates are present
in the inoculum. That individuals who have homozygous defective CCR5
are indeed infectable by an SI isolate may indicate that CXCR4 can
actually be used during the sexual transmission (43, 52). A
simian/human immunodeficiency virus strain which uses exclusively CXCR4
in vitro can also penetrate the GU mucosal barrier and establish
infection in a rhesus macaque (6a). Collectively, these
findings suggest that not only CCR5 but also CXCR4 can be used during
sexual transmission. Both host factors and the phenotypic composition
of the infecting virus will influence coreceptor selection during this
process. The delineation of the selection process will require further
investigation.
Consistent with previous reports, a high level of CXCR4 was found on
the neurons in both the CNS and the peripheral nervous system (28,
35, 54, 57). In addition, we found a high level of CCR3 in
neuronal tissues. Other chemokine receptors such as CXCR2 and the Duffy
antigen are also expressed in neurons, but the biological function of
these chemokine receptors in neuronal development, function, and
disease remains to be determined (28). The level of
expression may also promote the entry of CD4-independent viral
isolates, found primarily among HIV-2 strains (18). An intriguing finding, however, is that the macrophages located primarily in the walls of small blood vessels are also positive for CXCR4 and
CCR3. These perivascular macrophages or microglia, previously shown to
be the targets of HIV/SIV infection (34), can therefore serve as a mechanism for viral dissemination to the CNS.
| |
ACKNOWLEDGMENTS |
This work was supported by grants from the NIH (AI35168, AI45218,
and AI40387), GCRC support to The Rockefeller University, the Glaxo
Wellcome Institute for Digestive Health, and the Aaron Diamond
Foundation.
We thank Preston A. Marx, Agegnehu Gettie, and Christian Hangen for
providing animal and human tissue specimens, and we thank Charles R. Mackay and James A. Hoxie for providing the coreceptor-specific antibodies. We also thank J. Moore and C. Cheng-Mayer for helpful discussions.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: The Aaron
Diamond AIDS Research Center, 455 First Ave., 7th Floor, New York, NY
10016. Phone: (212) 725-0018. Fax: (212) 725-1126. E-mail:
dho{at}adarc.org.
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J Virol, June 1998, p. 5035-5045, Vol. 72, No. 6
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
