Previous Article | Next Article 
Journal of Virology, August 2000, p. 7320-7330, Vol. 74, No. 16
The Center for Blood Research, Harvard
Medical School,1 and Department of
Medicine, Brigham and Women's Hospital,2
Boston, Massachusetts 02115
Received 14 February 2000/Accepted 17 May 2000
Although human immunodeficiency virus (HIV)-infected subjects
without AIDS have a high frequency of HIV-specific CD8 T lymphocytes, cellular immunity is unable to control infection. Freshly isolated lymphocytes often do not lyse HIV-infected targets in 4-h cytotoxicity assays. A large fraction of circulating CD8 T cells from HIV-infected donors down-modulate CD3 During the asymptomatic phase of
human immunodeficiency virus (HIV) infection there is a high frequency
of circulating virus-specific CD8 T cells (17, 26). As many
as 1 in 100 circulating CD8 T cells are specific for a single HIV
peptide epitope in untreated patients (1, 37). The frequency
of HIV-infected CD4 cells in either untreated patients or patients
given highly active antiretroviral therapy (HAART) is generally many
orders of magnitude lower. Even though the frequency of HIV-specific
CD8 T cells falls as the viral load drops with treatment
(40), there are still probably many more antiviral CD8 T
cells than potential HIV-infected targets in patients who do not have
AIDS (24). Nevertheless, effective immunosurveillance
against HIV does not usually develop even after months of viral
suppression with HAART; when antiviral drugs are withdrawn, HIV levels
generally rebound (38). The following question then arises:
why don't antiviral cytotoxic T lymphocytes (CTL) provide better
protection? There are some recent clues to help answer this question.
Many viruses have devised strategies to evade an immune response
(42). During latent infection, viral proteins are not
expressed and therefore latently infected cells are hidden from immune
surveillance. Recent reports indicate that HIV Nef induces
down-modulation of major histocompatibility complex class I molecules
from the surface of the infected cell (8, 50). This is
sufficient to inhibit recognition of HIV-infected cells by some, but
not all, CTL (8, 51, 52, 59).
Although part of the reason for the lack of effective immune
surveillance may stem from defects in antigen presentation of HIV-infected cells, we have also provided evidence that CD8 cytotoxic T-cell function is compromised in HIV infection. When freshly isolated
blood mononuclear cells from HIV-infected donors who have not
progressed to symptomatic disease are tested in short-term (4-h)
cytotoxicity assays, they generally are unable to lyse HIV-infected targets at levels much above background (58). High levels of antiviral cytotoxicity develop in peripheral blood mononuclear cells
(PBMC) from less-advanced patients in vitro; however, this occurs after
overnight culture in an interleukin 2 (IL-2)-dependent manner. This
suggests that circulating HIV-specific CD8 T cells may be partially
anergic and may be unable to eliminate HIV-infected targets in vivo,
especially in the setting of lacking or functionally impaired
HIV-specific helper CD4 T cells (41, 46), which would normally provide IL-2 or other cytokines and possibly other forms of
help that require cell-cell contact.
The molecular basis and etiology of the lack of cytotoxicity by freshly
isolated cells are not certain (23, 55). A large fraction of
circulating CD8 T cells in HIV-infected donors are already activated,
as evidenced by high levels of expression of CD38, HLA-DR, and CD57 and
the cytolytic serine esterase granzyme A (9, 14, 16, 45, 58,
60). Moreover, there is a good correlation in circulating CD8 T
cells (but not in lymph node T cells [2]) between
granzyme A and perforin expression (L. W. Kam and J. Lieberman,
unpublished data). Therefore, it seems likely that they are armed for cytolysis.
In HIV infection, there is an increased proportion of activated/memory
T cells that do not express CD28 (19, 28, 48, 62).
HIV-specific cytotoxicity is mediated by the CD28 Anomalies of T-cell signaling after activation in CD8 T cells from
HIV-infected donors have been described (4, 23, 54, 58, 61).
In fact, a large fraction of CD8 T cells in HIV-infected donors have
down-modulated cell surface expression of CD3 The aim of this study was to explore the phenotypic and functional
properties of CD8 T cells with down-modulated CD3 Subjects.
Subjects were healthy volunteers and HIV type 1 (HIV-1)-seropositive patients at various disease stages (6)
(Table 1). This study was approved by the
Brigham and Women's Hospital and the Center for Blood Research
institutional review boards, and informed consent was obtained from
each subject. Samples were either freshly obtained or were
cryopreserved using a programmed cell freezer (model 9000; Gordinier,
Roseville, Mich.). Flow cytometry results obtained from thawed cells
were comparable to those from freshly isolated cells in two samples
studied.
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Human Immunodeficiency Virus-Specific Circulating
CD8 T Lymphocytes Have Down-Modulated CD3
and CD28, Key
Signaling Molecules for T-Cell Activation
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
, the signaling component of the T-cell receptor complex, which is reexpressed in vitro coincident with the
return of cytotoxic function. To investigate further the link between
CD3 down-modulation and possible CD8 T-cell functional defects, we
used flow cytometry to characterize further the properties of the
CD3-down-modulated subset. HIV-specific CD8 T cells, identified by
tetramer staining, are CD3
. CD8 T cells with
down-modulated CD3 also do not express the key costimulatory
receptor CD28 and have the cell surface phenotype of activated or
memory T cells (HLA-DR+ CD62L). After T-cell
activation, CD3-down-modulated cells express the activation marker
CD69 but not the high-affinity interleukin 2 (IL-2) receptor 
-chain
CD25 and produce gamma interferon but not IL-2. Therefore HIV-specific
CD8 T cells have down-modulated key signaling molecules for T-cell
activation and costimulation and require exogenous cytokine
stimulation. The typical impairment of HIV-specific CD4 T helper cells,
which would normally provide specific CD8 T-cell stimulation, means
that in vivo CTL function in vivo is compromised in most HIV-infected
individuals. In AIDS patients, the functional defect is more severe,
since CD3 is not reexpressed even after IL-2 exposure.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
CD8
T-cell subpopulation (10, 62, 64). After activation by
T-cell receptor (TCR) engagement, CD28 CD8 T cells in
HIV-infected subjects produce gamma interferon (IFN-
) but not IL-2
and have reduced proliferative capacity (5, 23, 28, 53).
This suggests that CD28 CD8 T cells are terminally
differentiated effector CTL.
, the key proximal
signaling chain of the TCR (54, 58). CD3 expression decreases early in infection and correlates with declining CD4 counts
and disease stage (13, 58). In less-advanced patients, CD8
T-cell CD3 expression increases in vitro after 6 to 8 h of culture in an IL-2-dependent manner, coincident with detection of
HIV-specific cytotoxicity, which is also IL-2 dependent. A similar
constellation of lack of antigen-specific cytotoxicity, signaling
anomalies, and CD3 down-modulation has been described for
tumor-infiltrating lymphocytes in mouse tumor models and human solid
tumors, in circulating CD8 T cells in human lymphoma patients, in
the blood of patients with systemic lupus erythematosis, and in the
inflamed joints in rheumatoid arthritis (11, 27, 29, 35,
36). Signaling defects of lymphocytes from Hodgkin's disease and
lymphoma patients have also been linked to abnormally low expression of
CD3 (33, 43).
. We found that
HIV-specific CD8 T cells that stain with HIV epitope tetramers have
down-modulated both CD3 and CD28. Upon activation, cells with
decreased expression of CD3 and CD28 do not express CD25 and produce
IFN- but not IL-2. We also found that the small proportion of CD8 T
cells in healthy donors with down-modulated CD3 and CD28 behave
similarly upon T-cell activation. Therefore, the down-modulation of
these key T-cell activation receptors may be part of the normal
regulation of CD8 T cells. However, whereas antigen-specific CD4 T
cells that secrete IL-2 should be able to restore CD3 expression and
cytotoxic function to antigen-specific CD8 T cells in vivo at the site
of infection in healthy individuals, the paucity of HIV-specific CD4
T-cell help in HIV-infected individuals may be a barrier to effective
cytotoxic function in vivo. Moreover, HIV-infected donors with
symptomatic disease or AIDS have a more profound defect in CD3
expression. In advanced subjects, not only is the proportion of
CD3 CD8 T cells greater, but IL-2-induced
up-regulation of CD3 is also impaired.
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
TABLE 1.
CD3 expression on CD8 T cells from late-stage
HIV-infected individuals remains suppressed even after overnight
incubation with IL-2b
Flow cytometry.
For external staining, freshly isolated PBMC
(2 × 105 to 10 × 105/tube) in 50 µl of fluorescence-activated cell sorter (FACS) buffer (phosphate-buffered saline with 2% fetal calf serum and 0.02% NaN3) were stained with 2 µl each of mixtures of the
following antibodies: CD4-Cy-Chrome (monoclonal antibody [MAb]
RPA-T4; Pharmingen, San Diego, Calif.), CD8-phycoerythrin (PE) (MAb
B9.11; Immunotech, Westbrook, Maine), CD8-Cy5 (MAb B9.11; Immunotech),
CD20-PE (MAb B9E9; Immunotech), CD3-Cy5 (MAb UCHT1; Immunotech),
CD28-PE (MAb CD28.2; Immunotech), HLA-DR-PE (MAb 357; Immunotech),
CD38-PE (MAb T16; Immunotech), CD57-PE (MAb NC1; Immunotech), and
immunoglobulin G-fluorescein isothiocyanate (FITC), -PE, and -Cy5
isotype-matched controls (Immunotech). After incubation for 15 min at
4°C, washed cells were permeabilized using the Caltag Laboratories
(Burlingame, Calif.) Fix and Perm kit according to the manufacturer's
protocol and stained for 15 min at room temperature with 1 µl of
CD3-FITC (MAb 6B10.2; Santa Cruz Biotechnology, Santa Cruz, Calif.).
Washed cells in FACS buffer plus 2% formaldehyde were analyzed on a
tightly gated lymphocyte population using FACscalibur (Becton
Dickinson). Gates for external markers were defined by requiring that
<1% of the control antibody-stained cells be positive. Gates for
internal markers were determined using CD20-staining cells as an
internal negative control. Direct staining for CD3 was used to
facilitate costaining for cell surface markers. The mean fluorescence
intensity (MFI) for CD3 staining with FITC-conjugated antibody is
significantly less than that obtained with indirect staining; however,
it is possible, as previously described (58), to set the
CD3 gates using CD20+ B cells as internal negative
controls. When data were analyzed for median fluorescence intensity,
results did not differ by more than 1 from values obtained for means.
Tetramer staining.
Bir A-modified HLA-A2 heavy chain and
2 microglobulin were synthesized and purified from plasmids
(obtained from M. Davis and D. C. Wiley, respectively) and
refolded with an A2-restricted HIV Gag epitope peptide (SLYNTVATL)
(39) or an A2-restricted reverse transcriptase (RT) epitope
(YTAFTIPSI) (51) to produce tetramers as described
previously (1). For tetramer staining, 2 × 106 PBMC from A2-expressing seropositive subjects were
resuspended in 500 µl of FACS buffer and stained with 0.5 µg of
streptavidin-PE-conjugated tetramer/ml for 40 min at 4°C. Cells were
then washed, stained, and analyzed for FITC-CD3 or FITC-CD28 and
CD8-Cy5 as described above.
Analysis of apoptosis by TUNEL assay. Cells were resuspended in 50 µl of Hanks balanced salt solution (HBSS), stained for Cy5-CD8, washed, and fixed and permeabilized and resuspended in 25 µl of terminal deoxynucleotidyltransferase-mediated dUTP-biotin nick end labeling (TUNEL) label and 2.5 µl of TUNEL enzyme (Boehringer Mannheim, Philadelphia, Pa.). The negative control for nonspecific staining was cells incubated with TUNEL label without TUNEL enzyme. Positive controls for apoptosis included overnight stimulation with 1 ng of phorbol 12-myristate 13-acetate (PMA) and 250 ng of A23187 (Sigma, St. Louis, Mo.)/ml. Cells were incubated at 37°C in the dark for 1 h before being washed with 5 ml of HBSS and resuspended in 50 µl of FACS buffer with 1% formaldehyde. Samples were analyzed by flow cytometry on the FACscalibur (Becton Dickinson) within 24 h.
T-cell activation.
PBMC were stimulated with 1 ng of
anti-CD3 MAb (12F6)/ml with and without anti-CD28 MAb L293 (0.5 µg/ml; Becton Dickinson) and cultured overnight at 2 × 106/ml in T-cell medium (25) before staining for
CD8-Cy5 and CD3-FITC with CD69-PE (MAb L78; Becton Dickinson) or
CD25-PE (MAb 2A3; Becton Dickinson).
Cytokine production.
Freshly isolated or cryopreserved PBMC
(3 × 106) enriched for CD28 T cells
were activated with 10 ng of anti-CD3 and 1 ng of PMA (Sigma) in T-cell
medium with 10 µM brefeldin A (Sigma) (12, 63). After
overnight incubation, harvested cells were stained for Cy5-CD8 and, for
some samples, FITC-CD28 or FITC-CD38. Samples were fixed and
permeabilized as described above, stained with FITC-conjugated
anti-CD3 (if not previously stained with anti-CD28 or anti-CD38) and
5 µl of PE-IFN- MAb (25723.11) or PE-IL-2 MAb (5334.2) (R&D
Systems, Minneapolis, Minn.). Control samples were stained with
PE-MslgG1 (R&D Systems).
Statistical analysis. The statistical significance of correlations was evaluated by a two-sided Student t test; a P value less than 0.05 was considered significant.
| |
RESULTS |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
CD3 is down-modulated in HIV-specific CD8 T cells.
To
determine whether CD3 down-modulation is a feature of HIV-specific
CD8 T cells, PBMC from five HLA A2.1-expressing HIV-seropositive donors
were stained for CD8 and for binding to the streptavidin-PE-conjugated HIV Gag peptide (SLVNTVATL) or RT peptide (YTAFTIPSI) A2.1 tetramer (1, 39, 51) and then fixed and permeabilized for staining with FITC-conjugated CD3. (Tetramer binding is not expected to interfere with the binding of antibody to CD3, since the tetramer binds to the outermost surface of the TCR, while the CD3 antibody recognizes an intracytoplasmic determinant of CD3.) Representative flow cytometry analyses for two HIV-infected subjects are shown in Fig.
1 and Table
2. Most (88% ± 8%) of the
tetramer+ CD8 T cells do not express any CD3 above
background. Because HIV-infected patients have an expansion of
CD28 CD8 T cells, we also costained samples from these
subjects for CD28 and A2.1-restricted HIV peptide tetramers. The
proportion of CD28 CD8 T cells was comparable to the
proportion of CD3 CD8 T cells; 85% ± 6% of
tetramer+ CD8 T cells were also CD28.
Therefore, the majority of antigen-specific CD8 T cells have down-modulated both the principal transducing protein for the TCR and
the principal costimulatory signaling molecule.
|
|
CD28 is high, the proportion of
CD3 CD28 cells in the HIV-specific
tetramer+ subset is even higher (data not shown). For
example, the proportion of all CD8 T cells in these five patients that
are CD28 is 68% ± 11% (range, 53 to 83%), compared
with 85% ± 6% of the tetramer+ subset.
CD28 CD8 T cells probably include other HIV-specific
cells that recognize other epitopes, as well as previously activated
CD8 T cells that recognize other pathogens.
CD3 is down-modulated in activated and memory T cells.
To
determine if CD3 down-modulation occurs only in certain
phenotypically defined subsets of CD8 T cells in HIV infection, we
stained PBMC from healthy and HIV-seropositive donors for CD3, CD8,
and another T-cell marker using three-color flow cytometry. In 13 HIV-seropositive donors, CD3 expression was disproportionately reduced in CD28, HLA-DR+, and
CD62L CD8 T cells (Fig. 2;
Table 3). CD28+ CD8 T cells
stained with CD3 at an MFI of 13 ± 3, whereas the MFI of
CD28 CD8 T cells was 9 ± 2 (P < 0.0000003). Similar differences were seen for CD3 expression on
CD62L high-, medium-, and low-expression populations (CD62L high,
14 ± 3; CD62L medium, 12 ± 2; CD62L low, 11 ± 2;
P < 0.008 and P < 0.0002). On the
other hand, CD8 T cells expressing the activation marker HLA-DR had a
CD3 MFI of 9 ± 2 whereas HLA-DR CD8 T cells had
an MFI of 11 ± 2 (P < 0.0008). This suggests that activated and/or memory CD8 T cells have reduced CD3
expression. Differences of CD3 expression were found to be not
significant when cells were analyzed by CD45RA expression. This may
reflect the fact that CD45RA stains both naive T cells and previously activated effector CTL (15, 44).
|
|
Activated CD8 T cells from healthy donors also have down-modulated
CD3.
Surprisingly, similar differences were found when CD3
expression was correlated with activation phenotype in seven
healthy-donor samples (Table 3). Although the proportion of circulating
activated and memory CD8 T cells is much lower in HIV-seronegative
healthy donors than in HIV-seropositive donors, HLA DR+
CD28 CD62L CD8 T cells from healthy-donor
PBMC had significantly lower CD3 expression than CD8 T cells with a
naive-cell phenotype. If anything the differences in CD3 expression
were more striking in healthy-donor samples. This probably reflects the
fact that cells that do not express any one activation marker are truly
naive in healthy donors, whereas in HIV-seropositive donors there is
considerable diversity in phenotypic subsets (44). For
example, cells that are HLA-DR in healthy donors are
likely to be CD28+ CD62L+ CD45RA+
as well, whereas in HIV-infected donors a substantial fraction of
HLA-DR CD8 T cells are not naive and express some of the
activation markers.
CD8 T cells with down-modulated CD3 expression are almost
exclusively CD28.
CD28 expression appears to
correlate most closely with CD3. CD8 T cells that are
CD28, whether from healthy or HIV-infected donors,
uniformly have reduced expression of CD3 (Fig.
3). However, most CD28 T
cells from healthy donors have reduced but not absent -chain expression, while in the CD28 CD8 T-cell population from
HIV-infected donors there is a mixture of CD3dim cells
and truly CD3 cells, in which staining is comparable
to that of CD3 B cells. Although both HIV-seropositive
and seronegative donors have some CD28 CD8 T cells, this
population is greatly expanded in HIV-seropositive subjects. In nine
healthy donors, 22% ± 8% of CD8 T cells were CD28
(range, 11 to 39%) compared with a mean of 57% ± 14% (range, 32 to
83%) in 24 HIV-seropositive samples (P < 0.0000001).
Although the expansion of CD28 CD8 T cells tends to
increase with disease progression, the correlation with CD4 count or
disease stage was not statistically significant for this sample.
|
Expression of CD28 and that of CD3 are not directly linked.
The strong correlation between CD28 and CD3 expression led us to ask
whether expression of these two proteins is directly linked. CD3
expression by CD8 T cells from asymptomatic HIV-infected individuals
normalizes after 8 to 10 h of incubation at 37°C in high
concentrations of IL-2 (58). However, in five samples
studied, there was no change in the proportion of CD28-expressing CD8 T cells after overnight incubation in the presence or absence of IL-2
even though CD3 levels increased significantly (data not shown). In
one representative subject (subject 228), 17% of freshly isolated CD8
T cells were positive for CD28. After overnight incubation in medium
alone, 21% of CD8 T cells were CD28+ while in medium
containing 600 IU of IL-2/ml 18% were CD28+. However, the
percentage of CD8 T cells expressing CD3 increased from 21% in
freshly isolated T cells to 32% after overnight incubation in medium
to 71% in the presence of 600 IU of IL-2/ml. This finding suggests
that different pathways may be involved in controlling CD28 and CD3 expression.
reexpression after overnight incubation with IL-2 might
have been due to preferential apoptosis of the CD3-down-modulated T
cells. To verify that this was not the case, we analyzed PBMC from two
HIV-infected individuals (subjects 356 and 237) for apoptosis using
TUNEL staining. PBMC were incubated overnight in medium alone or in
medium supplemented with 600 IU of IL-2/ml. Cells incubated with PMA
plus the Ca+2 ionophore A23187, which stimulates
activation-induced apoptosis, were stained as a positive control.
Although the proportion of CD3-expressing cells increased as
expected in the presence of IL-2, there was no significant difference
in the proportion of TUNEL+ apoptotic CD8 T cells when IL-2
was added (data not shown). Therefore, it is not likely that
preferential apoptosis of CD3 cells can explain the
up-regulation of CD3 staining after IL-2 exposure.
CD8 T cells from late-stage HIV-infected individuals do not
up-regulate CD3 expression after incubation with IL-2.
To
determine whether up-regulation of CD3 expression might be impaired
in advanced disease, we compared in vitro changes in CD8 T-cell CD3
expression in PBMC samples from 3 healthy donors and from 18 HIV-infected individuals at various stages of disease (Table 1). CD8 T
cells from healthy donors showed a slight decrease in T-cell CD3
expression after overnight incubation in medium alone, which could be
reversed by adding exogenous IL-2. PBMC from seven of eight donors
experiencing primary HIV infection or with asymptomatic stage A disease
had partially restored CD3 expression after overnight incubation in
the absence of exogenous IL-2. We previously showed that this is due
primarily to endogenous production of IL-2, since it can be blocked by
adding IL-2 antibody (58). Restoration of CD3 expression
to a level comparable to that of healthy-donor PBMC occurred after
overnight incubation with 600 IU of IL-2/ml in all eight subjects. T
cells from stage B patients had little change in the percentages of
CD3+ CD8+ T cells after overnight incubation
in medium alone. This was a statistically significant change compared
with the results for stage A donors (P < 0.003). In
the presence of IL-2, CD8 T cells from two of four subjects tested were
able to restore CD3 expression to near normal levels. However, for
six individuals with stage C disease, overnight incubation in medium
had little effect on CD3 levels and IL-2 only partially restored CD8
T-cell -chain expression (Table 1). The differences between stage A
and C patients as to baseline CD3 expression and reexpression in the
absence or presence of IL-2 were all highly significant. Therefore,
loss of CD3 expression becomes irreversible even with exogenous
cytokines around the time of progression to AIDS.
CD3-down-modulated T cells do not express the high-affinity IL-2
receptor upon TCR-mediated activation.
Since phosphorylation of
the -chain is the most important proximal event in TCR-mediated
signal transduction (65), the down-modulation of CD3
should alter activation of these cells via the TCR, perhaps as a way to
regulate excessive cell-mediated lysis. This presumed decrease in TCR
signaling should be exacerbated by the lack of CD28 expression on the
CD3-down-modulated T cells, since CD28 engagement is an important
costimulatory signal. In fact, Stefanova and colleagues have shown
aberrant signaling in T cells in HIV infection (54). To test
whether CD3 down-modulation interferes with activation through the
TCR, we stimulated PBMC from five healthy donors and five HIV-infected
donors with a suboptimal concentration (1 ng/ml) of anti-CD3
antibody 12F6 and 1 µg of anti-CD28/ml and measured the induction of
activation markers CD69 and CD25 the next day. (CD3 and the other
components of the TCR-CD3 complex are not down-modulated when CD3 is
[58].) Data from a representative healthy donor and an
HIV-infected donor are shown in Fig. 4.
In both types of donors, CD69 expression was induced in cells with both
normal and down-modulated CD3 expression, although the level of CD69
cell surface staining was somewhat reduced in the down-modulated T
cells. However, CD25, the -chain of IL-2R required for high-affinity
binding, was induced only on CD3bright cells. Moreover,
the CD3 MFI of cells that were activated to express CD69 or CD25 was
significantly higher than that for CD8 T cells that were not activated
for both healthy and HIV-infected donors. CD8 T cells from five
HIV-seropositive donors with induced CD69 expression stained for CD3
with an MFI of 14 ± 1, while CD8 T cells that were not induced
had a CD3 MFI of 12 ± 2 (background MFI of B cells was 6 ± 1). This difference was statistically significant (P < 0.005). CD25 expression also developed only in T cells that had
increased levels of CD3 expression (-chain MFI of
CD25+ CD8 T cells was 14 ± 2 versus the
CD25 CD8 T cell MFI of 11 ± 1; P < 0.006).
|
expression in CD69+ CD8 T cells (MFI, 15 ± 2)
than in CD69 CD8 T cells (MFI, 12 ± 2; P < 0.0001) and higher expression in CD25+ CD8 T cells
(MFI, 16 ± 2) than in CD25 CD8 T cells (MFI,
12 ± 2; P < 0.006). The B-cell background CD3 MFI was 7 ± 1 for the healthy-donor samples. Levels of induction of CD69 and CD25 expression were similar when cells were activated with
1 ng of anti-CD3/ml without anti-CD28 (data not shown). These results
show that at least some of the signaling changes in
CD3-down-modulated CD8 T cells are not specific to HIV infection but
rather occur as part of a normal immune response.
Because there is a greater proportion of CD3
CD28 T cells in more-advanced patients, we also examined
the proportion of CD8 T cells, which fail to express CD25 when
activated, in HIV-infected patients and healthy controls (Table
4). About 70% of healthy-donor CD8 T
cells are activated by 1 ng of anti-CD3/ml and 0.5 µg of anti-CD28/ml
to express CD69 the next day. About two-thirds of these (44% ± 2%)
coexpress CD25. In five stage A donor samples, the proportion of
CD69+ CD8 T cells activated to express CD69 was somewhat
higher (77%; not significant) and the proportion activated to express
CD25 was significantly higher (61% ± 8%; P < 0.02).
In two patients with advanced disease, however, although a comparable
number of CD8 T cells expressed CD69 (59%), the proportion that
expressed CD25 was only 18% ± 6% (P < 0.006
compared with healthy donors). This substantial reduction in CD25
expression supports the hypothesis that there is more-pronounced CD8
T-cell anergy in more-advanced patients.
|
CD3-down-modulated T cells produce IFN- but not IL-2 or
IL-4.
We next looked at cytokine production on a single-cell basis
with flow cytometry after maximal overnight stimulation of PBMC from
nine HIV-infected donors with PMA and anti-CD3 in the presence of
brefeldin A (Fig. 5). Cells were
costained with CD8 and either CD3, CD28, or CD38 in addition to
IL-2, IFN-, and IL-4. Flow cytometry analysis for gated CD8 T cells
from a representative HIV-infected donor sample is shown in Fig. 5C.
There was no significant IL-4 production by CD8 T cells in any of the
samples (data not shown). IL-2 was produced almost exclusively by cells
with a naive phenotype (CD3+ CD28+
CD38). In samples from nine donors, 84% ± 5% of the
IL-2-producing CD8 T cells were CD3+ and 72% ± 12%
were CD28+. In contrast, the CD3
CD28 population was primarily responsible for IFN-
production; 80% ± 14% of the IFN--producing CD8 T cells were
CD3 and 80% ± 12% were CD28. There
was no clear association of CD38 expression with IFN- production.
Although fewer cells were activated when samples were stimulated with
anti-CD3 and anti-CD28 in place of PMA and anti-CD3, the same
pattern of cytokine production was seen (data not shown).
|
| |
DISCUSSION |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
We recently found that freshly isolated circulating CD8 T cells
from HIV-infected donors have limited ability to lyse HIV-infected target cells but become highly cytolytic after overnight culture in the
presence of IL-2 (58). In looking for a molecular basis for
the lack of cytotoxic function, we found that a large fraction of CD8 T
cells in HIV-infected donors have down-modulated the principal
signaling chain of the TCR-CD3 complex, as has been reported for
tumor-infiltrating lymphocytes in mice and humans (11, 29, 33,
36). We also found that CD3 became up-regulated in parallel
with the return to cytotoxicity. Here we show that HIV-specific CD8 T
cells that stain with HIV peptide epitope tetramers have almost
uniformly down-modulated not only CD3 but also the principal
costimulatory receptor CD28. We previously found that the circulating
tetramer+ cells are likely armed to kill since they stain
for granzyme A (52). Therefore the lack of HIV-specific
cytotoxicity is probably due to aberrant signaling.
CD3 down-modulation is a feature of cells that have been previously
activated, as evidenced by HLA-DR expression and lack of CD28 and CD62L
expression. Because the CD3 CD28
phenotype typically represents 20 to 80% of circulating CD8 T cells in
HIV-infected patients (Table 1), the CD3
CD28 population probably includes not only HIV-specific T
cells but also cells specific for other pathogens.
CD3 down-modulation correlates closely with CD28 down-modulation in
CD8 T cells. Previous studies have shown, and their results are
confirmed here by tetramer staining, that the expanded
CD28 CD8 T-cell subpopulation in HIV infection contains
most of the HIV-specific CTL (10, 62). However, the CD8
T-cell suppressor factor CAF is produced by CD28+ T cells
and is therefore not a product of antigen-specific cells (3). Previous studies have also shown that activation of
CD28 T cells induces IFN- production but not that of
IL-2 and that these cells have reduced proliferative capacity (5,
23, 28, 53). Consistent with this is our finding that cells that
produce IFN- upon TCR activation are predominantly
CD3 CD28, while cells that produce IL-2
are predominantly CD28+ CD3+. The reduced
proliferative capacity of these cells may be linked to their failure to
produce IL-2 and to express the high-affinity IL-2 receptor upon activation.
What is the functional significance of dual down-modulation of CD3
and CD28? Although CD3 is not detectable above background staining
in a large proportion of CD8 (but not CD4) T cells in HIV infection,
there is probably some CD3 present since antibodies to CD3
stimulated CD69 expression and IFN- production by
CD3 cells. Estimates of the numbers of TCR molecules
that need to be engaged for CD8 T-cell activation go down to as few as
one molecule per cell, well below the sensitivity of flow cytometry detection (56). Since the CD3 cells require
IL-2 exposure to up-regulate CD3 before they are cytotoxic
(58), the dually down-modulated cells are partially anergic;
they produce IFN- but are not cytotoxic and do not produce IL-2.
Therefore, the threshold for triggering cytotoxicity may be higher than
that needed to activate CD69 expression or to trigger IFN-
production. That the parallel down-regulation of CD3 and cytotoxicity is a major factor in the lack of immune surveillance in
cancer and HIV seems likely but is a matter of conjecture.
CD3 down-modulation, which increases with disease progression and
which interferes with T-cell activation, is corrected within 6 to
10 h of in vitro culture in an IL-2-dependent manner
(58). However, development of cytotoxic function in vitro
requires a longer incubation time (16 to 24 h) than that required
for reexpression of CD3 (data not shown). Therefore the lack of
cytolytic function is not simply due to CD3 down-modulation.
Reversal of modifications of the key TCR-associated tyrosine kinases
Lck, Fyn, and ZAP70, which have been described in HIV infection
(56), may be required before cytotoxicity can be triggered.
We do not know what induces CD3 and CD28 down-modulation in CD8 T
cells in HIV infection, cancer, and autoimmunity. However, in this
study we found that in healthy donors approximately 5 to 10% of CD8 T
cells have down-modulated both CD3 and CD28. Moreover, the
down-modulated cells behave after TCR stimulation like their
counterparts in HIV infection. This suggests that CD3 and CD28
down-modulation may be a normal consequence of CD8 T-cell activation
and not an aberration secondary to chronic immune stimulation or HIV
infection. In support of this, we recently found a massive expansion of
CD3 CD28 CD8 T cells in three patients
undergoing acute viral infections of diverse etiologies
(57). These cells, like the comparable subset in HIV
infection, were effector CTL that produced IFN- but not IL-2 and
were not cytotoxic until cultured in high concentrations of IL-2. Like
the down-modulated cells in HIV-seropositive donors, upon TCR
activation they failed to express CD25. Moreover, corroborative results
were found in a mouse green fluorescent protein model recently
developed to study CD8 T-cell differentiation (32). In the
mice, CD3 mRNA is decreased in effector CD8 CTL. The mouse effector
cells also had limited proliferative capacity, produced IFN- but not
IL-2, and, in fact, mostly underwent apoptosis upon TCR activation
unless they were provided with IL-2.
These findings taken together suggest that CD3 and CD28
down-modulation is a normal correlate of CD8 T-cell activation. We suspect that it serves two purposes: (i) to prevent immunopathology due
to cytolysis of bystander cells that may express self peptide-HLA pairs
with low affinity for the TCR and (ii) to insure that CD8 T cells are
dependent on T-cell help for their function and proliferation. Lack of
IL-2 production and high-affinity IL-2R expression means that the
activated CTL are likely dependent on exogenous cytokines not only for
survival but also for cytolytic function. This finding is consistent
with a recent study of murine lymphocytic choriomeningitis virus
infection in which functional antigen-specific CD8 T cells did not
provide antiviral protection in mice depleted of CD4 T cells
(66). In HIV infection, the paucity of HIV-specific CD4 helper T-cell function is also likely to be an important contributor to
HIV-specific CTL dysfunction (18, 58).
Our finding of partial anergy in the antiviral CD8 T-cell compartment
may also be true of the HIV response of CD4 T cells. A CD4
proliferative response to HIV antigens is generally not detectable
above background except in some long-term nonprogressors or in some
instances after treatment (30, 31, 46, 47, 49). This finding
led investigators to assume that HIV-specific CD4 T cells are absent in
most HIV-infected individuals. However, a recent study showed that in
most HIV-infected patients CD4 memory cells that produce IFN- in
response to stimulation with the HIV Gag protein are readily detectable
by flow cytometry (41). This suggests that the HIV-specific
CD4 T-cell response is not absent but partially anergized. It may be
that the absence of a proliferative response to HIV antigens seen in
most patients reflects a lack of IL-2 secretion, similar to what we
find for CD8 T cells. IL-2 production is likely required for CD4 T-cell
proliferation in response to an antigen and may be needed for effective
help for CD8 CTL function.
Based on this study and results with acute viral infection
(57) and with the mouse green fluorescent protein model
(32), we propose a working model for CD8 T-effector-cell
differentiation outlined in Fig. 6. After
TCR activation, CD8 T cells, unlike their CD4 counterparts,
down-modulate expression of CD3 and CD28. The dually down-modulated
cells secrete IFN- upon repeat exposure to antigens but are not
cytotoxic unless they encounter antigens in proximity to IL-2-secreting
antigen-specific CD4 helper cells. In that case they upregulate CD3
expression, become cytotoxic, and proliferate. If they reencounter
antigens in the absence of specific helper cells, the CD8 T cells,
although they have the molecular machinery for cytolysis, are not
cytolytic and do not proliferate.
|
We previously found that the defect in CD3 expression is more
pronounced in HIV-infected patients with more advanced immunodeficiency (58). This is corroborated by reference
13 and the study of additional patients reported
here. We now find that IL-2 does not restore in vitro CD3 expression
on CD8 T cells in advanced patients and that the defect in expression
of the high-affinity IL-2 receptor after T-cell activation is more
profound in advanced patients. This suggests that antigen excess,
prolonged chronic antigenic stimulation, or particular HIV gene
products (such as Tat) (6, 55) might result in additional
alterations in the signaling pathway or transcription factors that are
important in normal CD8 CTL development. This finding may also be a
contributing factor to the lack of response to IL-2 therapy in
more-advanced patients (20). Global defects in CD3
expression on T and NK cells and profound signaling defects have been
found in tumor-infiltrating cells in mice and humans with advanced
cancers (21, 34). A recent study of tetramer-staining
melanoma-specific CD8 T cells in patients with metastatic melanoma
found that melanoma-specific CD8 T cells in these patients were
profoundly anergic (22). Although they were
perforin+, they were not cytotoxic against their specific
targets. In addition, specific CD8 T cells from these patients did not
express CD69 or produce cytokines after specific antigenic exposure. In
more recent work (P. Shankar, M. Russo, B. Harnisch, M. Patterson, P. R. Skolnik, and J. Lieberman, submitted for publication), we also found that IFN- production in response to HIV-infected primary T cells or by HIV tetramer+ cells is compromised in
more-advanced HIV-infected donors. In some donors, the IFN-
production defect, like the defect in cytotoxicity, can be reversed by
supplying IL-2 in vitro. Our results suggest that a similarly profound
anergy might be found in HIV-infected patients with AIDS and might
reflect derangements of immune regulation associated with chronic
antigenic excess. The functional properties of HIV-specific T cells in
more-advanced patients require further study.
| |
ACKNOWLEDGMENTS |
|---|
We thank Chiron Oncology for recombinant human IL-2, M. Davis and
D. Wiley for plasmids used to express A2.1 and 2 microglobulin to
produce tetramers, Rachel Friedman, Melissa Russo, and Zhan Xu for
expert technical assistance, and N. Manjunath for useful discussions.
J.L. was supported by National Institutes of Health grants 42519 and 45406 from the National Institute for Allergy and Infectious Diseases.
| |
FOOTNOTES |
|---|
* Corresponding author. Mailing address: The Center for Blood Research, 800 Huntington Ave., Boston, MA 02115. Phone: (617) 278-3381. Fax: (617) 278-3493. E-mail: lieberman{at}cbr.med.harvard.edu.
Present address: Dana Farber Cancer Institute, Boston, MA 02115.
| |
REFERENCES |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
| 1. |
Altman, J. D.,
P. A. H. Moss,
P. J. R. Goulder,
D. H. Barouch,
M. G. McHeyzer-Williams,
J. I. Bell,
A. J. McMichael, and M. M. Davis.
1996.
Phenotypic analysis of antigen-specific T lymphocytes.
Science
274:94-96 |
| 2. | Andersson, J., H. Behbahani, J. Lieberman, E. Connick, A. Landay, B. Patterson, A. Sonnerborg, K. Lore, S. Uccini, and T. E. Fehniger. 1999. Perforin is not co-expressed with granzyme A within cytotoxic granules in CD8 T lymphocytes present in lymphoid tissue during chronic HIV infection. AIDS 13:1295-1303[CrossRef][Medline]. |
| 3. | Barker, E., K. N. Bossart, S. H. Fujimura, and J. A. Levy. 1997. CD28 costimulation increases CD8+ cell suppression of HIV replication. J. Immunol. 159:5123-5131[Abstract]. |
| 4. |
Borthwick, N. J.,
M. Bofill,
W. M. Gombert,
A. N. Akbar,
E. Medina,
K. Sagawa,
M. C. Lipman,
M. A. Johnson, and G. Janossy.
1994.
Lymphocyte activation in HIV-1 infection. II. Functional defects of CD28 T cells.
Acta Chem. Scand.
8:431-441.
|
| 5. | Caruso, A., S. Licenziati, A. D. Canaris, A. Cantalamessa, M. Corulli, B. Benzoni, L. Peroni, A. Balsari, and A. Turano. 1996. Characterization of T cell subsets involved in the production of IFN-gamma in asymptomatic HIV-infected patients. AIDS Res. Hum. Retroviruses 12:135-141[Medline]. |
| 6. | Centers for Disease Control. 1993. 1993 revised classification system for HIV infection and expanded surveillance case definition for AIDS among adolescents and adults. Morbid. Mortal. Weekly Rep. 41:1-19. |
| 7. | Chirmule, N., S. Than, S. A. Khan, and S. Pahwa. 1995. Human immunodeficiency virus Tat induces functional unresponsiveness in T cells. J. Virol. 69:492-498[Abstract]. |
| 8. | Collins, K. L., B. K. Chen, S. A. Kalams, B. D. Walker, and D. Baltimore. 1998. HIV-1 Nef protein protects infected primary cells against killing by cytotoxic T lymphocytes. Nature 391:397-401[CrossRef][Medline]. |
| 9. | Cossarizza, A., C. Ortolani, C. Mussini, V. Borghi, G. Guaraldi, N. Mongiardo, E. Bellesia, M. G. Franceschini, B. De Rienzo, and C. Franceschi. 1995. Massive activation of immune cells with an intact T cell repertoire in acute human immunodeficiency virus syndrome. J. Infect. Dis. 172:105-112[Medline]. |
| 10. | Dalod, M., S. Fiorentino, C. Delamare, C. Rouzioux, D. Sicard, J. G. Guillet, and E. Gomard. 1996. Delayed virus-specific CD8+ cytotoxic T lymphocyte activity in an HIV-infected individual with high CD4+ cell counts: correlations with various parameters of disease progression. AIDS Res. Hum. Retroviruses 12:497-506[Medline]. |
| 11. |
Finke, J. H.,
A. H. Zea,
J. Stanley,
D. L. Longo,
H. Mizoguchi,
R. R. Tubbs,
R. H. Wiltrout,
J. J. O'Shea,
S. Kudoh,
E. Klein, et al.
1993.
Loss of T-cell receptor zeta chain and p56lck in T-cells infiltrating human renal cell carcinoma.
Cancer Res.
53:5613-5616 |
| 12. |
Fujiwara, T.,
K. Oda,
S. Yokota,
A. Takatsuki, and Y. Ikehara.
1988.
Brefeldin A causes disassembly of the Golgi complex and accumulation of secretory proteins in the endoplasmic reticulum.
J. Biol. Chem.
263:18545-18552 |
| 13. |
Geertsma, M. F.,
A. van Wengen-Stevenhagen,
E. M. van Dam,
K. Risberg,
F. P. Kroon,
P. H. P. Groeneveld, and P. H. Nibbering.
1999.
Decreased expression of molecules by T lymphocytes is correlated with disease progression in human immunodeficiency virus-infected persons.
J. Infect. Dis.
180:649-658[CrossRef][Medline].
|
| 14. | Gougeon, M. L., A. G. Laurent-Crawford, A. G. Hovanessian, and L. Montagnier. 1993. Direct and indirect mechanisms mediating apoptosis during HIV infection: contribution to in vivo CD4 T cell depletion. Semin. Immunol. 5:187-194[CrossRef][Medline]. |
| 15. |
Hamann, D.,
P. A. Baars,
M. H. Rep,
B. Hooibrink,
S. R. Kerkhof-Garde,
M. R. Klein, and R. A. van Lier.
1997.
Phenotypic and functional separation of memory and effector human CD8+ T cells.
J. Exp. Med.
186:1407-1418 |
| 16. | Ho, H. N., L. E. Hultin, R. T. Mitsuyasu, J. L. Matud, M. A. Hausner, D. Bockstoce, C. C. Chou, S. O'Rourke, J. M. Taylor, and J. V. Giorgi. 1993. Circulating HIV-specific CD8+ cytotoxic T cells express CD38 and HLA-DR antigens. J. Immunol. 150:3070-3079[Abstract]. |
| 17. | Hoffenbach, A., P. Langlade-Demoyen, G. Dadaglio, E. Vilmer, F. Michel, C. Mayaud, B. Autran, and F. Plata. 1989. Unusually high frequencies of HIV-specific cytotoxic T lymphocytes in humans. J. Immunol. 142:452-462[Abstract]. |
| 18. |
Kalams, S. A., and B. D. Walker.
1998.
The critical need for CD4 help in maintaining effective cytotoxic T lymphocyte responses.
J. Exp. Med.
188:2199-2204 |
| 19. | Kammerer, R., A. Iten, P. C. Frei, and P. Burgisser. 1996. Expansion of T cells negative for CD28 expression in HIV infection. Relation to activation markers and cell adhesion molecules, and correlation with prognostic markers. Med. Microbiol. Immunol. 185:19-25[CrossRef][Medline]. |
| 20. |
Kovacs, J. A.,
M. Baseler,
R. J. Dewar,
S. Vogel,
R. T. Davey, Jr.,
J. Falloon,
M. A. Polis,
R. E. Walker,
R. Stevens,
N. P. Salzman, et al.
1995.
Increases in CD4 T lymphocytes with intermittent courses of interleukin-2 in patients with human immunodeficiency virus infection. A preliminary study.
N. Engl. J. Med.
332:567-575 |
| 21. |
Lai, P.,
H. Rabinowich,
P. A. Crowley-Nowick,
M. C. Bell,
G. Mantovani, and T. L. Whiteside.
1996.
Alterations in expression and function of signal-transducing proteins in tumor-associated T and natural killer cells in patients with ovarian carcinoma.
Clin. Cancer Res.
2:161-173 |
| 22. | Lee, P. P., C. Yee, P. A. Savage, L. Fong, D. Brockstedt, J. S. Weber, D. Johnson, S. Swetter, J. Thompson, P. D. Greenberg, M. Roederer, and M. M. Davis. 1999. Characterization of circulating T cells specific for tumor-associated antigens in melanoma patients. Nat. Med. 5:677-685[CrossRef][Medline]. |
| 23. | Lewis, D. E., D. S. Tang, A. Adu-Oppong, W. Schober, and J. R. Rodgers. 1994. Anergy and apoptosis in CD8+ T cells from HIV-infected persons. J. Immunol. 153:412-420[Abstract]. |
| 24. | Lieberman, J. 1999. Cytotoxic T lymphocyte adoptive immunotherapy for HIV infection, p. 441. In M. V. Sitkovsky, and P. A. Henkart (ed.), Cytotoxic cells: basic mechanisms and medical applications. Lippincott Williams & Wilkins, Philadelphia, Pa. |
| 25. | Lieberman, J., J. A. Fabry, M. C. Kuo, P. Earl, B. Moss, and P. R. Skolnik. 1992. Cytotoxic T lymphocytes from HIV-1 seropositive individuals recognize immunodominant epitopes in Gp160 and reverse transcriptase. J. Immunol. 148:2738-2747[Abstract]. |
| 26. | Lieberman, J., J. A. Fabry, P. Shankar, L. Beckett, and P. R. Skolnik. 1995. Ex vivo expansion of HIV type 1-specific cytolytic T cells from HIV type 1-seropositive subjects. AIDS Res. Hum. Retroviruses 11:257-271[Medline]. |
| 27. | Liossis, S. N., X. Z. Ding, G. J. Dennis, and G. C. Tsokos. 1998. Altered pattern of TCR/CD3-mediated protein-tyrosyl phosphorylation in T cells from patients with systemic lupus erythematosis. J. Clin. Investig. 101:1448-1457[Medline]. |
| 28. | Lloyd, T. E., L. Yang, D. N. Tang, T. Bennett, W. Schober, and D. E. Lewis. 1997. Regulation of CD28 costimulation in human CD8+ T cells. J. Immunol. 158:1551-1558[Abstract]. |
| 29. | Loeffler, C. M., M. J. Smyth, D. L. Longo, W. C. Kopp, L. K. Harvey, H. R. Tribble, J. E. Tase, W. J. Urba, A. S. Leonard, H. A. Young, et al. 1992. Immunoregulation in cancer-bearing hosts. Down-regulation of gene expression and cytotoxic function in CD8+ T cells. J. Immunol. 149:949-956[Abstract]. |
| 30. | Lori, F., H. Jessen, J. Lieberman, D. Finzi, E. Rosenberg, C. Tinelli, R. F. Siliciano, B. Walker, and J. Lisziewicz. 1999. Treatment of human immunodeficiency virus infection with hydroxyurea, didanosine, and a protease inhibitor before seroconversion is associated with normalized immune parameters and limited viral reservoir. J. Infect. Dis. 180:1827-1832[CrossRef][Medline]. |
| 31. | Lori, F., E. Rosenberg, J. Lieberman, A. Foli, R. Maserati, E. Seminari, F. Alberici, B. Walker, and J. Lisziewicz. 1999. Hydroxyurea and didanosine long-term treatment prevents HIV breakthrough and normalizes immune parameters. AIDS Res. Hum. Retroviruses 15:1333-1338[CrossRef][Medline]. |
| 32. |
Manjunath, N.,
P. Shankar,
B. Stockton,
P. D. Dubey,
J. Lieberman, and U. H. von Andrian.
1999.
A transgenic mouse model to analyze CD8+ effector T cell differentiation in vivo.
Proc. Natl. Acad. Sci. USA
96:13932-13937 |
| 33. | Massaia, M., C. Attisano, E. Beggiato, A. Bianchi, and A. Pileri. 1994. Correlation between disease activity and T-cell CD3 zeta chain expression in a B-cell lymphoma. Br. J. Haematol. 88:886-888[Medline]. |
| 34. | Matsuda, M., M. Petersson, R. Lenkei, J.-L. Taupin, I. Magnusson, H. Mellstedt, P. Anderson, and R. Kiessling. 1995. Alterations in the signal-transducing molecules of T cells and NK cells in colorectal tumor-infiltrating, gut mucosal and peripheral lymphocytes: correlation with the stage of the disease. Int. J. Cancer 61:765-772[Medline]. |
| 35. | Maurice, M. M., A. C. Lankester, A. C. Bezemer, M. F. Geertsma, P.-P. Tak, F. C. Breedveld, R. A. W. van Lier, and C. L. Verweij. 1997. Defective TCR-mediated signaling in synovial T cells in rheumatoid arthritis. J. Immunol. 159:2973-2978[Abstract]. |
| 36. |
Mizoguchi, H.,
J. J. O'Shea,
D. L. Longo,
C. M. Loeffler,
D. W. McVicar, and A. C. Ochoa.
1992.
Alterations in signal transduction molecules in T lymphocytes from tumor-bearing mice.
Science
258:1795-1798 |
| 37. |
Moss, P. A.,
S. L. Rowland-Jones,
P. M. Frodsham,
S. McAdam,
P. Giangrande,
A. J. McMichael, and J. I. Bell.
1995.
Persistent high frequency of human immunodeficiency virus-specific cytotoxic T cells in peripheral blood of infected donors.
Proc. Natl. Acad. Sci. USA
92:5773-5777 |
| 38. | Neumann, A. U., R. Tubiana, V. Calvez, C. Robert, T. S. Li, H. Agut, B. Autran, and C. Katlama. 1999. HIV-1 rebound during interruption of highly active antiretroviral therapy has no deleterious effect on reinitiated treatment. Comet Study Group. AIDS 13:677-683[CrossRef][Medline]. |
| 39. | Nixon, D. F., A. R. Townsend, J. G. Elvin, C. R. Rizza, J. Gallwey, and A. J. McMichael. 1988. HIV-1 gag-specific cytotoxic T lymphocytes defined with recombinant vaccinia virus and synthetic peptides. Nature 336:484-487[CrossRef][Medline]. |
| 40. |
Ogg, G. S.,
X. Jin,
S. Bonhoeffer,
P. Moss,
M. A. Nowak,
S. Monard,
J. P. Segal,
Y. Cao,
S. L. Rowland-Jones,
A. Hurley,
M. Markowitz,
D. D. Ho,
A. J. McMichael, and D. F. Nixon.
1999.
Decay kinetics of human immunodeficiency virus-specific effector cytotoxic T lymphocytes after combination antiretroviral therapy.
J. Virol.
73:797-800 |
| 41. | Pitcher, C. J., C. Quittner, D. M. Peterson, M. Connors, R. A. Koup, V. C. Maino, and L. J. Picker. 1999. HIV-1-specific CD4+ T cells are detectable in most individuals with active HIV-1 infection, but decline with prolonged viral suppression. Nat. Med. 5:518-525[CrossRef][Medline]. |
| 42. |
Ploegh, H. L.
1998.
Viral strategies of immune evasion.
Science
280:248-253 |
| 43. |
Renner, C.,
S. Ohnesorge,
G. Held,
S. Bauer,
W. Jung,
J. P. Pfitzenmeier, and M. Pfreundschuh.
1996.
T cells from patients with Hodgkin's disease have a defective T-cell receptor zeta chain expression that is reversible by T-cell stimulation with CD3 and CD28.
Blood
88:236-241 |
| 44. | Roederer, M., S. C. De Rosa, N. Watanabe, and L. A. Herzenberg. 1997. Dynamics of fine T-cell subsets during HIV disease and after thymic ablation by mediastinal irradiation. Semin. Immunol. 9:389-396[CrossRef][Medline]. |
| 45. | Roederer, M., J. G. Dubs, M. T. Anderson, P. A. Raju, L. A. Herzenberg, and L. A. Herzenberg. 1995. CD8 naive T cell counts decrease progressively in HIV-infected adults. J. Clin. Investig. 95:2061-2066. |
| 46. |
Rosenberg, E. S.,
J. M. Billingsley,
A. M. Caliendo,
S. L. Boswell,
P. E. Sax,
S. A. Kalams, and B. D. Walker.
1997.
Vigorous HIV-1-specific CD4+ T cell responses associated with control of viremia.
Science
278:1447-1450 |
| 47. | Rosenberg, E. S., L. LaRosa, T. Flynn, G. Robbins, and B. D. Walker. 1999. Characterization of HIV-1-specific T-helper cells in acute and chronic infection. Immunol. Lett. 66:89-93[CrossRef][Medline]. |
| 48. |
Saukkonen, J. J.,
H. Kornfeld, and J. S. Berman.
1993.
Expansion of a CD8+CD28 cell population in the blood and lung of HIV-positive patients.
J. Acquir. Immune Defic. Syndr.
6:1194-1204.
|
| 49. | Schwartz, D., U. Sharma, M. Busch, K. Weinhold, T. Matthews, J. Lieberman, D. Birx, H. Farzedagen, J. Margolick, T. Quinn, et al. 1994. Absence of recoverable infectious virus and unique immune responses in an asymptomatic HIV+ long-term survivor. AIDS Res. Hum. Retroviruses 10:1703-1711[Medline]. |
| 50. | Schwartz, O., V. Marechal, S. Le Gall, F. Lemonnier, and J. M. Heard. 1996. Endocytosis of major histocompatibility class I molecules is induced by the HIV-Nef protein. Nat. Med. 2:338-342[CrossRef][Medline]. |
| 51. | Shankar, P., H. Sprang, and J. Lieberman. 1998. Effective lysis of HIV-1-infected primary CD4+ T cells by a cytotoxic T-lymphocyte clone directed against a novel A2-restricted reverse-transcriptase epitope. J. Acquir. Immune Defic. Syndr. Hum. Retrovirol. 19:111-120[Medline]. |
| 52. |
Shankar, P.,
Z. Xu, and J. Lieberman.
1999.
Viral-specific cytotoxic T lymphocytes lyse HIV-infected primary T lymphocytes by the granule exocytosis pathway.
Blood
94:3084-3093 |
| 53. | Sousa, A., and R. Victorino. 1998. Single-cell analysis of lymphokine imbalance in asymptomatic HIV-1 infection: evidence for a major alteration within the CD8+ T cell subset. Clin. Exp. Immunol. 112:294-302[CrossRef][Medline]. |
| 54. | Stefanova, I., M. W. Saville, C. Peters, F. R. Cleghorn, D. Schwartz, D. J. Venzon, K. J. Weinhold, N. Jack, C. Bartholomew, W. A. Blattner, R. Yarchoan, J. B. Bolen, and I. D. Horak. 1996. HIV infection-induced posttranslational modification of T cell signaling molecules associated with disease progression. J. Clin. Investig. 98:1290-1297[Medline]. |
| 55. | Subramanyam, M., W. G. Gutheil, W. W. Bachovchin, and B. T. Huber. 1993. Mechanism of HIV-1 Tat induced inhibition of antigen-specific T cell responsiveness. J. Immunol. 150:2544-2553[Abstract]. |
| 56. | Sykulev, Y., M. Joo, I. Vturina, T. J. Tsomides, and H. N. Eisen. 1996. Evidence that a single peptide-MHC complex on a target cell can elicit a cytolytic T cell response. Immunity 4:565-571[CrossRef][Medline]. |
| 57. | Trimble, L. A., L. W. Kam, R. S. Friedman, Z. Xu, and J. Lieberman. CD3 and CD28 down-modulation
on CD8 T cells during viral infection. Blood, in press.
|
| 58. |
Trimble, L. A., and J. Lieberman.
1998.
Circulating CD8 T lymphocytes in human immunodeficiency virus-infected individuals have impaired function and downmodulate CD3, the signaling chain of the T-cell receptor complex.
Blood
91:585-594 |
| 59. |
Tsomides, T. J.,
A. Aldovini,
R. P. Johnson,
B. D. Walker,
R. A. Young, and H. N. Eisen.
1994.
Naturally processed viral peptides recognized by cytotoxic T lymphocytes on cells chronically infected by human immunodeficiency virus type 1.
J. Exp. Med.
180:1283-1293 |
| 60. | Vanham, G., L. Kestens, P. Gigase, R. Colebunders, M. Vandenbruaene, L. Brijs, and J. L. Ceuppens. 1990. Evidence for circulating activated cytotoxic T cells in HIV-infected subjects before the onset of opportunistic infections. Clin. Exp. Immunol. 82:3-9[Medline]. |
| 61. | Vingerhoets, J., L. Kestens, G. Penne, H. De Vuyst, M. Vandenbruaene, Y. Pelgrom, E. Bosmans, M. de Boer, A. Kasran, M. Azuma, R. Colebunders, J. L. Ceuppens, and G. Vanham. 1997. CD8+ cells and not CD4+ T cells are hyporesponsive to CD28- and CD40L-mediated activation in HIV-infected subjects. Clin. Exp. Immunol. 107:440-447[CrossRef][Medline]. |
| 62. | Vingerhoets, J. H., G. L. Vanham, L. L. Kestens, G. G. Penne, R. L. Colebunders, M. J. Vandenbruaene, J. Goeman, P. L. Gigase, M. De Boer, and J. L. Ceuppens. 1995. Increased cytolytic T lymphocyte activity and decreased B7 responsiveness are associated with CD28 down-regulation on CD8+ T cells from HIV-infected subjects. Clin. Exp. Immunol. 100:425-433[Medline]. |
| 63. | Waldrop, S. L., C. J. Pitcher, D. M. Peterson, V. C. Maino, and L. J. Picker. 1997. Determination of antigen-specific memory/effector CD4+ T cell frequencies by flow cytometry: evidence for a novel, antigen-specific homeostatic mechanism in HIV-associated immunodeficiency. J. Clin. Investig. 99:1739-1750[Medline]. |
| 64. |
Weekes, M. P.,
A. J. Carmichael,
M. R. Wills,
K. Mynard, and J. G. Sissons.
1999.
Human CD28CD8+ T cells contain greatly expanded functional virus-specific memory CTL clones.
J. Immunol.
162:7569-7577 |
| 65. | Weiss, A., and D. R. Littman. 1994. Signal transduction by lymphocyte antigen receptors. Cell 76:263-274[CrossRef][Medline]. |
| 66. |
Zajac, A. J.,
J. N. Blattman,
K. Murali-Krishna,
D. J. Sourdive,
M. Suresh,
J. D. Altman, and R. Ahmed.
1998.
Viral immune evasion due to persistence of activated T cells without effector function.
J. Exp. Med.
188:2205-2213 |
Journal of Virology, August 2000, p. 7320-7330, Vol. 74, No. 16
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Das, A., Hoare, M., Davies, N., Lopes, A. R., Dunn, C., Kennedy, P. T.F., Alexander, G., Finney, H., Lawson, A., Plunkett, F. J., Bertoletti, A., Akbar, A. N., Maini, M. K.
(2008). Functional skewing of the global CD8 T cell population in chronic hepatitis B virus infection. JEM
205: 2111-2124
[Abstract] [Full Text] -
White, L., Krishnan, S., Strbo, N., Liu, H., Kolber, M. A., Lichtenheld, M. G., Pahwa, R. N., Pahwa, S.
(2007). Differential effects of IL-21 and IL-15 on perforin expression, lysosomal degranulation, and proliferation in CD8 T cells of patients with human immunodeficiency virus-1 (HIV). Blood
109: 3873-3880
[Abstract] [Full Text] -
Boasso, A., Herbeuval, J.-P., Hardy, A. W., Anderson, S. A., Dolan, M. J., Fuchs, D., Shearer, G. M.
(2007). HIV inhibits CD4+ T-cell proliferation by inducing indoleamine 2,3-dioxygenase in plasmacytoid dendritic cells. Blood
109: 3351-3359
[Abstract] [Full Text] -
Rutjens, E., Mazza, S., Biassoni, R., Koopman, G., Radic, L., Fogli, M., Costa, P., Mingari, M. C., Moretta, L., Heeney, J., De Maria, A.
(2007). Differential NKp30 Inducibility in Chimpanzee NK Cells and Conserved NK Cell Phenotype and Function in Long-Term HIV-1-Infected Animals. J. Immunol.
178: 1702-1712
[Abstract] [Full Text] -
Leeansyah, E., Wines, B. D., Crowe, S. M., Jaworowski, A.
(2007). The Mechanism Underlying Defective Fc{gamma} Receptor-Mediated Phagocytosis by HIV-1-Infected Human Monocyte-Derived Macrophages. J. Immunol.
178: 1096-1104
[Abstract] [Full Text] -
Emu, B., Sinclair, E., Favre, D., Moretto, W. J., Hsue, P., Hoh, R., Martin, J. N., Nixon, D. F., McCune, J. M., Deeks, S. G.
(2005). Phenotypic, Functional, and Kinetic Parameters Associated with Apparent T-Cell Control of Human Immunodeficiency Virus Replication in Individuals with and without Antiretroviral Treatment. J. Virol.
79: 14169-14178
[Abstract] [Full Text] -
Potula, R., Poluektova, L., Knipe, B., Chrastil, J., Heilman, D., Dou, H., Takikawa, O., Munn, D. H., Gendelman, H. E., Persidsky, Y.
(2005). Inhibition of indoleamine 2,3-dioxygenase (IDO) enhances elimination of virus-infected macrophages in an animal model of HIV-1 encephalitis. Blood
106: 2382-2390
[Abstract] [Full Text] -
Haring, J. S., Corbin, G. A., Harty, J. T.
(2005). Dynamic Regulation of IFN-{gamma} Signaling in Antigen-Specific CD8+ T Cells Responding to Infection. J. Immunol.
174: 6791-6802
[Abstract] [Full Text] -
McCloskey, T. W., Haridas, V., Pontrelli, L., Pahwa, S.
(2004). Response to Superantigen Stimulation in Peripheral Blood Mononuclear Cells from Children Perinatally Infected with Human Immunodeficiency Virus and Receiving Highly Active Antiretroviral Therapy. CVI
11: 957-962
[Abstract] [Full Text] -
Steinberg, M., Adjali, O., Swainson, L., Merida, P., Bartolo, V. D., Pelletier, L., Taylor, N., Noraz, N.
(2004). T-cell receptor-induced phosphorylation of the {zeta} chain is efficiently promoted by ZAP-70 but not Syk. Blood
104: 760-767
[Abstract] [Full Text] -
Zabaleta, J., McGee, D. J., Zea, A. H., Hernandez, C. P., Rodriguez, P. C., Sierra, R. A., Correa, P., Ochoa, A. C.
(2004). Helicobacter pylori Arginase Inhibits T Cell Proliferation and Reduces the Expression of the TCR {zeta}-Chain (CD3{zeta}). J. Immunol.
173: 586-593
[Abstract] [Full Text] -
Shacklett, B. L., Cox, C. A., Quigley, M. F., Kreis, C., Stollman, N. H., Jacobson, M. A., Andersson, J., Sandberg, J. K., Nixon, D. F.
(2004). Abundant Expression of Granzyme A, but Not Perforin, in Granules of CD8+ T Cells in GALT: Implications for Immune Control of HIV-1 Infection. J. Immunol.
173: 641-648
[Abstract] [Full Text] -
Brenchley, J. M., Hill, B. J., Ambrozak, D. R., Price, D. A., Guenaga, F. J., Casazza, J. P., Kuruppu, J., Yazdani, J., Migueles, S. A., Connors, M., Roederer, M., Douek, D. C., Koup, R. A.
(2004). T-Cell Subsets That Harbor Human Immunodeficiency Virus (HIV) In Vivo: Implications for HIV Pathogenesis. J. Virol.
78: 1160-1168
[Abstract] [Full Text] -
Abel, K., La Franco-Scheuch, L., Rourke, T., Ma, Z.-M., de Silva, V., Fallert, B., Beckett, L., Reinhart, T. A., Miller, C. J.
(2004). Gamma Interferon-Mediated Inflammation Is Associated with Lack of Protection from Intravaginal Simian Immunodeficiency Virus SIVmac239 Challenge in Simian-Human Immunodeficiency Virus 89.6-Immunized Rhesus Macaques. J. Virol.
78: 841-854
[Abstract] [Full Text] -
Persidsky, Y., Gendelman, H. E.
(2003). Mononuclear phagocyte immunity and the neuropathogenesis of HIV-1 infection. J. Leukoc. Biol.
74: 691-701
[Abstract] [Full Text] -
Zhang, D., Shankar, P., Xu, Z., Harnisch, B., Chen, G., Lange, C., Lee, S. J., Valdez, H., Lederman, M. M., Lieberman, J.
(2003). Most antiviral CD8 T cells during chronic viral infection do not express high levels of perforin and are not directly cytotoxic. Blood
101: 226-235
[Abstract] [Full Text] -
Kim, Y.-J., Brutkiewicz, R. R., Broxmeyer, H. E.
(2002). Role of 4-1BB (CD137) in the functional activation of cord blood CD28-CD8+ T cells. Blood
100: 3253-3260
[Abstract] [Full Text] -
Wieckowski, E., Wang, G.-Q., Gastman, B. R., Goldstein, L. A., Rabinowich, H.
(2002). Granzyme B-mediated Degradation of T-Cell Receptor {zeta} Chain. Cancer Res.
62: 4884-4889
[Abstract] [Full Text] -
Keir, M. E., Rosenberg, M. G., Sandberg, J. K., Jordan, K. A., Wiznia, A., Nixon, D. F., Stoddart, C. A., McCune, J. M.
(2002). Generation of CD3+CD8low Thymocytes in the HIV Type 1-Infected Thymus. J. Immunol.
169: 2788-2796
[Abstract] [Full Text] -
Kostense, S., Vandenberghe, K., Joling, J., Van Baarle, D., Nanlohy, N., Manting, E., Miedema, F.
(2002). Persistent numbers of tetramer+ CD8+ T cells, but loss of interferon-gamma + HIV-specific T cells during progression to AIDS. Blood
99: 2505-2511
[Abstract] [Full Text] -
Ortiz, G. M., Hu, J., Goldwitz, J. A., Chandwani, R., Larsson, M., Bhardwaj, N., Bonhoeffer, S., Ramratnam, B., Zhang, L., Markowitz, M. M., Nixon, D. F.
(2002). Residual Viral Replication during Antiretroviral Therapy Boosts Human Immunodeficiency Virus Type 1-Specific CD8+ T-Cell Responses in Subjects Treated Early after Infection. J. Virol.
76: 411-415
[Abstract] [Full Text] -
McKay, P. F., Schmitz, J. E., Barouch, D. H., Kuroda, M. J., Lifton, M. A., Nickerson, C. E., Gorgone, D. A., Letvin, N. L.
(2002). Vaccine Protection Against Functional CTL Abnormalities in Simian Human Immunodeficiency Virus-Infected Rhesus Monkeys. J. Immunol.
168: 332-337
[Abstract] [Full Text] -
Hel, Z., Nacsa, J., Kelsall, B., Tsai, W.-P., Letvin, N., Parks, R. W., Tryniszewska, E., Picker, L., Lewis, M. G., Edghill-Smith, Y., Moniuszko, M., Pal, R., Stevceva, L., Altman, J. D., Allen, T. M., Watkins, D., Torres, J. V., Berzofsky, J. A., Belyakov, I. M., Strober, W., Franchini, G.
(2001). Impairment of Gag-Specific CD8+ T-Cell Function in Mucosal and Systemic Compartments of Simian Immunodeficiency Virus mac251- and Simian-Human Immunodeficiency Virus KU2-Infected Macaques. J. Virol.
75: 11483-11495
[Abstract] [Full Text] -
Lieberman, J., Shankar, P., Manjunath, N., Andersson, J.
(2001). Dressed to kill? A review of why antiviral CD8 T lymphocytes fail to prevent progressive immunodeficiency in HIV-1 infection. Blood
98: 1667-1677
[Abstract] [Full Text] -
Chen, G., Shankar, P., Lange, C., Valdez, H., Skolnik, P. R., Wu, L., Manjunath, N., Lieberman, J.
(2001). CD8 T cells specific for human immunodeficiency virus, Epstein-Barr virus, and cytomegalovirus lack molecules for homing to lymphoid sites of infection. Blood
98: 156-164
[Abstract] [Full Text] -
Krishnan, S., Warke, V. G., Nambiar, M. P., Wong, H. K., Tsokos, G. C., Farber, D. L.
(2001). Generation and biochemical analysis of human effector CD4 T cells: alterations in tyrosine phosphorylation and loss of CD3{zeta} expression. Blood
97: 3851-3859
[Abstract] [Full Text] -
Moser, J. M., Altman, J. D., Lukacher, A. E.
(2001). Antiviral Cd8+ T Cell Responses in Neonatal Mice: Susceptibility to Polyoma Virus-Induced Tumors Is Associated with Lack of Cytotoxic Function by Viral Antigen-Specific T Cells. JEM
193: 595-606
[Abstract] [Full Text] -
Shankar, P., Russo, M., Harnisch, B., Patterson, M., Skolnik, P., Lieberman, J.
(2000). Impaired function of circulating HIV-specific CD8+ T cells in chronic human immunodeficiency virus infection. Blood
96: 3094-3101
[Abstract] [Full Text]
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Copyright © 2009 by the American Society for Microbiology. For an alternate route to Journals.ASM.org, visit: http://intl-journals.asm.org | More Info»