Previous Article | Next Article 
Journal of Virology, April 2001, p. 3740-3752, Vol. 75, No. 8
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.8.3740-3752.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
CD4+ T-Cell Effectors Inhibit
Epstein-Barr Virus-Induced B-Cell Proliferation
Sarah
Nikiforow,1
Kim
Bottomly,1 and
George
Miller2,*
Departments of
Immunobiology1 and Pediatrics,
Epidemiology & Public Health, Molecular Biophysics, and
Biochemistry,2 Yale University School of
Medicine, New Haven, Connecticut 06520
Received 4 October 2000/Accepted 16 January 2001
 |
ABSTRACT |
In immunodeficient hosts, Epstein-Barr virus (EBV) often induces
extensive B-cell lymphoproliferative disease and lymphoma. Without
effective in vitro immune surveillance, B cells infected by the virus
readily form immortalized cell lines. In the regression assay, memory T
cells inhibit the formation of foci of EBV-transformed B cells that
follows recent in vitro infection by EBV. No one has yet addressed
which T cell regulates the early proliferative phase of B cells newly
infected by EBV. Using new quantitative methods, we analyzed T-cell
surveillance of EBV-mediated B-cell proliferation. We found that
CD4+ T cells play a significant role in limiting
proliferation of newly infected, activated CD23+ B cells.
In the absence of T cells, EBV-infected CD23+ B cells
divided rapidly during the first 3 weeks after infection. Removal of
CD4+ but not CD8+ T cells also abrogated immune
control. Purified CD4+ T cells eliminated outgrowth when
added to EBV-infected B cells. Thus, unlike the killing of EBV-infected
lymphoblastoid cell lines, in which CD8+ cytolytic T cells
play an essential role, prevention of early-phase EBV-induced B-cell
proliferation requires CD4+ effector T cells.
| |
INTRODUCTION |
In the absence of effective
T-cell-mediated immune surveillance, Epstein-Barr virus (EBV) behaves
as a potent human tumor virus. For example, recipients of solid-organ
transplants maintained on immunosuppressive drug regimens manifest
dramatically increased risks for developing EBV-associated
lymphoproliferative disease or lymphoma (15, 16, 43). As
many as one quarter of recipients of T-cell-depleted allogeneic bone
marrow transplants (BMT) develop B-cell lymphomas derived from donor
EBV-infected B cells (R. S. Shapiro, A. Chauvenet, W. McGuire, A. Pearson, A. W. Craft, P. McGlave, and A. Filipovich, Letter,
N. Engl. J. Med. 318:1334, 1988). Patients with
AIDS develop Burkitt's lymphoma, non-Hodgkin's B-cell lymphoma, and
central nervous system lymphoma, many of which are EBV related
(23). In addition, children with a variety of congenital
T-cell immunodeficiencies are prone to developing fatal
lymphoproliferative disease and EBV-related lymphoma (60).
Adoptive immunotherapy can restore T-cell surveillance that limits the
proliferation of EBV-infected B cells in some immunodeficient hosts.
Transfers of EBV-specific cytotoxic T-cell lines (CTLs) or lymphocytes
of donor origin can arrest EBV lymphoproliferative disease in BMT
recipients (17, 29, 41, 42, 57). Several assay systems
have explored the identity of the effector cells active against
EBV-transformed B cells. Engraftment of SCID mice with human peripheral
blood mononuclear cells (PBMCs) from EBV-seropositive donors
(hu-PBL-SCID mice), for example, results in the development of
polyclonal EBV-transformed B-cell tumors of human origin, while infusion of T-cell lines raised against EBV-transformed
lymphoblastoid cell lines (LCLs) from the donor of the
PBMCs can prevent these tumors (6, 7, 27, 36, 44, 46,
50, 56, 59). These in vivo data together with in vitro
experiments indicate that memory T cells are required to regulate
outgrowth of EBV-associated lymphomas. However, the crucial T effectors
in the protective response are not well characterized.
Many experiments focus on the role of cytotoxic CD8+ T
cells in the cell-mediated immune response to EBV. CD8+ T
cells make up the majority of "atypical" mononuclear cells characteristic of primary EBV infection, manifested as infectious mononucleosis (2, 68). CD8+ T cells derived
from mononucleosis patients recognize antigenic epitopes of both latent
and lytic-cycle EBV proteins (9, 20, 51, 67). New
techniques such as enzyme-linked immunospot assays and
fluorescence-activated cell sorting (FACS) staining with tetrameric major histocompatibility complex (MHC) class I-peptide complexes reveal
a surprisingly high frequency of circulating CD8+ T cells
specific for individual EBV proteins in healthy seropositive carriers
(63). In vitro stimulation of PBMCs from EBV-seropositive donors with an autologous LCL yields cytotoxic CD8+, HLA
class I-restricted T-cell clones recognizing the same panel of
epitopes, which fall predominantly within the EBNA 3A, -B, and -C and
LMP2 latency proteins as well as lytic-cycle epitopes such as BZLF1 and
BMLF1 (51). In vivo experiments show that transfer of
CD8+ T cells raised against human LCLs can prevent
formation of tumors in hu-PBL-SCID mice after infusion of LCLs from the
same individual (50). Virtually all of the published
experiments investigating the activity of CD8+ T cells
employ fully transformed LCLs expressing the full panel of EBV latent
antigens as the antigen-presenting cells and as targets for cytotoxic T
cells (9, 26, 50, 54, 67).
Less is known about the CD4+, HLA class II-restricted
T-cell response to EBV antigens (35). Until recently, in
vitro cocultivation of PBMCs with LCLs yielded rare cytotoxic
CD4+ T-cell lines; these CTLs recognized epitopes in the
EBNA1 and EBNA2 latent antigens as well as in the BHRF1 lytic antigen
(24, 51). However, new evidence suggests that in vitro
exposure to EBNA1-expressing dendritic cells or to LCLs induced to
lytic-cycle expression yields CD4+ EBV-reactive cytotoxic T
cells (39). In vivo evidence for CD4+-mediated
EBV-specific activity also exists in hu-PBL-SCID mouse systems. In
these mice, CD4+ T-cell lines injected concurrently with
LCLs reduce the incidence of lymphoma (50). Moreover, some
T-cell lines effective in human adoptive immunotherapy trials have
consisted of 98% CD4+ T cells (17, 40, 57).
In the current functional experiments, we explore the role of memory T
cells in limiting early stages of proliferation of CD23+ B
cells recently infected with EBV. Most previous experiments have
focused on cytotoxic T-cell responses to established lymphoblastoid cell lines as opposed to freshly infected B cells. It is likely that
the panel of virally encoded or cellular antigens expressed by newly
infected cells at the time T cells are exerting their inhibitory
effects on proliferation are different from those expressed in LCLs
(64). EBV-infected PBMCs which persist in seropositive individuals in vivo express a very limited panel of latent antigens. Moreover, EBV-infected cells in immunosuppressed patients with increased EBV serum levels display a unique pattern of latency, with
predominant expression of LMP1 and LMP2. Both patterns of EBV antigen
expression are distinct from the latency III pattern displayed by LCLs
(2, 22, 47, 48, 65). Accordingly, control of proliferation
of recently infected B cells may be carried out by mechanisms
physiologically distinct from those that control growth of transformed
LCLs. Employing new approaches to monitor B-cell responses to EBV, our
experiments yield the novel finding that memory CD4+ T
cells play a major role in preventing the expansion of B cells recently
infected by EBV.
| |
MATERIALS AND METHODS |
Cultures of PBMCs.
Cell donors were healthy individuals
between 19 and 40 years of age whose EBV serologic status was
ascertained by standard assays for antibodies to viral capsid antigen
and EBNA (14, 32, 49). Venous blood drawn in a
heparin-coated syringe was diluted with 1 volume of RPMI 1640 medium
and underlaid with 1 volume of lymphocyte separation medium
(Ficoll-Hypaque; ICN). The mixture was centrifuged at 1,000 rpm for 40 min in a clinical centrifuge at room temperature (RT). PBMCs were
isolated from the interface of the gradient and resuspended at
106 cells/ml in complete RPMI 1640 medium containing 10%
heat-inactivated fetal bovine serum (FBS), penicillin, streptomycin,
and amphotericin B. Cultures were seeded in 250-µl aliquots into
96-well U-bottomed plates for proliferation assays or in 2.5-ml
aliquots into flat-bottomed 24-well culture plates (Falcon) for
analysis of cell surface markers. Cultures were maintained at 37°C in
5% CO2. After 2 weeks, either 100 µl or 1 ml of culture
volume was replaced with fresh complete medium.
Preparation of stocks of infectious EBV and mock inoculum.
Virus stocks were prepared from culture supernatants of the
EBV-positive B95-8 cell line (34). B95-8 cells were seeded
at 2 × 105 cells/ml in complete RPMI 1640 medium and
held for 14 days at 37°C without refeeding. Cells were deposited at
1,500 rpm in a clinical centrifuge. Supernatant fluids harvested at
this time contained approximately 105 transforming units/ml
as measured by immortalization of human umbilical cord lymphocytes. The
supernatant was adjusted to contain 10 g of NaCl and 8% (wt/vol)
polyethylene glycol (PEG-8000; Sigma) per liter. The precipitate formed
after overnight incubation at 4°C was collected by centrifugation at
7,500 rpm in a Sorvall centrifuge with a GS3 rotor. The pellet was
resuspended at a ratio of 1 ml of complete medium per 50 ml of starting
culture supernatant. Viral stocks were aliquoted and stored at
70°C. The mock inoculum was prepared in an identical manner from
culture supernatant of the EBV-negative B-lymphoma cell line BJAB
(25).
Infection of PBMCs.
The dilution of EBV stock that would
produce maximal proliferation of PBMCs in the presence of FK506 17 to
20 days after infection was determined by virus titration and
measurement of [3H]deoxythymidine ([3H]dT)
(Amersham) incorporation (55). For different virus stocks, optimal activity occurred with a 1:20 to 1:80 dilution of concentrated virus. A comparable dilution of mock inoculum was used. Thus, cultured
PBMCs received an inoculum representing from a 2.5-fold concentration
to a 1.6-fold dilution of the original B95-8 or BJAB culture
supernatant fluid.
FK506 treatment.
FK506, kindly provided by Fujisawa, Japan,
was prepared as a stock solution at 10 mM in ethanol. FK506-treated
PBMC cultures received a final concentration of 10 nM at 8 to 24 h
prior to the addition of EBV or mock inoculum.
Proliferation assays.
At intervals after infection or mock
inoculation, 1 µCi of [3H]dT in 50 µl of medium was
added to 250-µl cultures of PBMCs in 96-well U-bottomed plates. The
cells were incubated for an additional 24 h at 37°C. Cultures
were collected onto glass fiber filters using an automated sample
harvester (Wallac). Filters were suspended in scintillation fluid, and
the incorporated radioactivity was determined with triplicate samples
for each experimental condition.
Analysis of cell surface molecules.
At intervals after
infection or mock inoculation, 2.5-ml aliquots of cells were collected.
The number of living cells was determined by trypan blue dye exclusion;
viable cells were isolated on a Ficoll-Hypaque density gradient. The
cells were washed once in phosphate-buffered saline (PBS) and
resuspended at 106 cells/ml in PBS containing 5% FBS and
0.01% sodium azide. A mixture of saturating concentrations of two
different fluorochrome-conjugated mouse monoclonal antibodies against
human cell surface molecules was added. These antibodies included
anti-CD3-fluorescein isothiocyanate (FITC), anti-CD4-phycoerythrin
(PE), anti-CD8-PE, anti-CD16-PE, anti-CD19-Quantum Red, and
anti-CD23-FITC. Murine immunoglobulin (Ig) (1 mg/ml) was included in
the mixture to inhibit nonspecific binding. The reactivity of
antibodies to human lymphoid cell surface molecules was compared to the
reactivity of isotype controls consisting of polyclonal murine
IgG1-FITC, IgG1-PE, and IgG2-Quantum Red. All antibodies were purchased
from Sigma or Dako. Antibodies and cells were incubated together for 45 min on ice. The cells were washed twice in PBS and fixed in 1%
paraformaldehyde in PBS. Staining was analyzed on a
fluorescence-activated cell sorter (FACS; Becton Dickinson).
Analysis of EBV gene expression.
Mixed PBMCs were examined
for expression of latent EBNAs by immunofluoresence assays (IFA). PBMCs
from cultures infected with EBV 23 days previously and cultured in the
presence or absence of FK506 were isolated over a Ficoll-Hypaque
gradient and resuspended at 3 × 106 cells/ml in PBS.
Cells were allowed to air-dry for 25 min at RT on glass slides (PGC
Scientifics) and fixed in a 2:1 acetone-methanol solution for 5 min at
RT. Slides were stored at 20°C for up to 1 month. Detection of the
latent EBNAs was performed by incubating cells fixed on the slides with
a 1:10 dilution of human serum, which had been previously determined to
contain antibodies directed against all known EBNAs (58).
Cells were washed in PBS and incubated with a 1:16 dilution of freshly
frozen EBV-seronegative human serum as a source of complement. Another
wash in PBS was followed by incubation with a 1:40 dilution of
anti-human complement conjugated to FITC (Atlantic Antibodies/Incstar).
All incubations were performed for 1 h at 37°C. Negative
controls consisted of cells reacted with complement and
anticomplement-FITC without human serum. Fluorescence was detected
under UV illumination with a Zeiss microscope.
Magnetic activated cell sorting.
Cells expressing low levels
of surface CD23 were separated from those expressing high levels on a
magnetic bead column prior to detection of EBNA antigens by indirect
IFA. Live PBMCs from cultures infected with EBV for 23 days were
harvested over a Ficoll-Hypaque gradient. Cells were incubated with
biotinylated anti-human CD23 for 30 min at 4°C in PBS plus 5% bovine
serum albumin (BSA). Cells were washed and incubated at 10 × 107 cells/ml for 30 min at 4°C in PBS plus 5% BSA with
streptavidin-conjugated 50-nm-diameter magnetic microbeads (Miltenyi
Biotec). Cells were washed and loaded onto a MACS depletion
ferromagnetic matrix column (Miltenyi Biotec) set within a magnetic
field. Cells with negative or low CD23 expression were isolated using a
24-gauge needle under ambient conditions. Cells with high CD23
expression were recovered by removing the column from the magnetic
field and actively plunging the cells through the column. The CD23 low
and high fractions were air-dried on separate glass slides. The level
of CD23 expression on each of the fractions was verified by costaining
with avidin-PE and analysis by FACS.
Analysis of dividing cells.
PBMCs isolated on a
Ficoll-Hypaque gradient were washed once in PBS and resuspended at
107 cells/ml in PBS. They were incubated with 1 µM
carboxyfluorescein diacetate succinymidyl ester (CFSE; Molecular
Probes) for 10 min at 37°C and washed in ice-cold RPMI 1640 plus 10%
FBS. CFSE-labeled cells were cultured and infected as described. At
intervals after infection, viable cells were isolated on a
Ficoll-Hypaque gradient. Lymphocyte cell surface molecules were
detected in two steps. In the first step, the cells were incubated with
biotinylated anti-CD3, anti-CD4, anti-CD8, anti-CD19, or anti-CD23
antibodies at saturating concentrations for 45 min at 4°C.
Anti-CD23-biotin was obtained from Pharmingen. Anti-CD19-biotin was
purchased from Dako. All other biotinylated antibodies were purchased
from Sigma. Cells were washed in PBS, and in the second step, avidin-PE
was added for a 1-h incubation at 4°C. Cells were fixed in 1%
paraformaldehyde and analyzed by FACS.
Depletion of lymphocyte and specific T-cell subpopulations.
Fresh PBMCs isolated on a Ficoll-Hypaque gradient were resuspended at
2 × 107 cells/ml in PBS plus 2% FBS. They were
incubated for 30 min at 4°C with magnetic beads conjugated to murine
anti-human CD3, anti-CD4, or anti-CD8 antibodies (against T-cell
antigens) or to anti-human CD16 antibodies (against a natural killer
cell antigen), at the concentrations recommended by the manufacturer
(Dynal). Beads and bound cells were removed using magnets (PerSeptive
Biosystems). CD14+ CD45+ monocytes were
depleted by standard plastic-adherence protocols (11). The
remaining cells were resuspended in complete RPMI 1640, cultured, and
infected. The efficiency of depletion was determined immediately after
separation by assessment of cell surface molecule expression. In the
majority of experiments, less than 1.5% of the remaining final
population consisted of cells targeted for depletion.
Isolation of B and T-cell populations by positive selection.
PBMCs freshly isolated on a Ficoll-Hypaque gradient were resuspended at
5 × 106 to 1 × 107 cells/ml in PBS
plus 2% FBS, based on suggestions of the magnetic bead manufacturer.
Cells were incubated with antibody-conjugated magnetic beads using the
conditions employed for negative selection. Anti-human CD4 or anti-CD19
antibody-conjugated beads and bound cells were recovered using magnets
and resuspended at 108 cells/ml in RPMI 1640 plus 1% FBS.
A detachment solution consisting of competing polyclonal goat or sheep
antibodies raised against mouse Igs was added, and cells were incubated
with gentle agitation for 1 h at RT. CD3+ cells were
recovered from the anti-CD3-conjugated beads by incubating the
positively selected cell-bead mixture in RPMI 1640 plus 10% FBS at
37°C for at least 6 h, since competing antibodies were not
available. Beads were removed by using magnets, and the cells that had
been freed from the beads were harvested. The efficiency of isolation
of each population was determined immediately after isolation by
assessment of cell surface molecule expression. Selected populations
were greater than 84.6% pure.
Use of CD23 expression as a marker of B cells activated by
EBV.
The number of CD19+ CD23+ cells was
used as a marker of immune control over EBV-infected B cells when
cultures were initiated from mixed PBMC populations (see Fig. 2).
However, cultures depleted of various T-cell subsets manifest different
growth properties regardless of infection by EBV. Therefore, in
depleted cultures, the percentages, not numbers, of CD19+
CD23+ cells were used as an indicator of immune control
(see Fig. 5 to 7).
| |
RESULTS |
Lack of memory T-cell activity augments proliferation in
EBV-infected PBMC cultures from EBV-seropositive individuals.
To
analyze the role of T cells and effector mechanisms active in immune
surveillance over early stages of EBV infection, we examined the
effects of FK506 on EBV-induced lymphoproliferation in vitro. Most
previous in vitro studies have monitored PBMC culture responses to EBV
via a regression assay, in which the readout is microscopic enumeration
of transformed-cell foci after 4 weeks in culture or isolation of
transformed lymphoblastoid lines (37, 40). As a
quantitative and rapid assay for T-cell control, we initially assessed
cell proliferation in EBV-infected and mock-inoculated PBMC cultures by
measuring [3H]dT incorporation 17 to 18 days after
inoculation (13, 26, 33, 55).
Proliferation of infected cells from EBV-seropositive donors was much
increased in the presence of FK506, a well-known inhibitor of T-cell
activation (10, 12). In the experiment illustrated in Fig.
1A, the incorporation of
[3H]dT in EBV-infected seropositive cultures was 8.7-fold
greater in the presence of FK506 than in the absence of FK506. When
results from 35 seropositive donors were pooled, incorporation of
[3H]dT in EBV-infected cultures was 5.4 (±0.9)-fold
greater in the presence of FK506 than in the absence of FK506. In
contrast, the proliferation of PBMCs from seronegative donors following
EBV infection was high in both the presence and the absence of FK506, as shown in Fig. 1B. When results from five seronegative donors were
pooled, incorporation of [3H]dT in EBV-infected cultures
was not any greater (1.2 [±0.2]-fold) in the presence of FK506.
View larger version (33K):
[in this window]
[in a new window]
|
FIG. 1.
Effects of FK506 on the kinetics of proliferation of
uninfected and EBV-infected PBMCs as measured by incorporation of
[3H]dT. PBMCs from EBV-seropositive donors (A and C) or
EBV-seronegative donors (B and D) were infected with EBV (shaded bars
and triangles, EBV+) or a control inoculum (solid bars and
circles, EBV ) in the presence or absence of FK506. (A and
B) Seventeen days after infection, [3H]dT was added to
the PBMC cultures; the incorporated radioactivity was measured 24 h later. Results represent the mean ± standard error of the mean (SEM)
of triplicate samples for each experimental condition. (C and D) Solid
lines indicate addition of FK506; dashed lines represent PBMC cultures
without FK506. [3H]dT incorporation was determined at
intervals from 2 to 15 days after infection.
|
|
To determine when T-cell activity impacts EBV-induced
lymphoproliferation, kinetic analysis of [
3H]dT
incorporation in response to EBV infection of PBMC cultures
was
performed. When the donors of PBMCs were seropositive, the
EBV-infected
cultures grown in the absence of FK506 proliferated
for 7 to 10 days to
a level somewhat higher than in mock-infected
cultures, but thereafter
the proliferation rate declined (Fig.
1C). In contrast, when the PBMC
donors were EBV seronegative,
the EBV-infected cultures continued to
proliferate and eventually,
15 days after infection, reached the same
level of [
3H]dT incorporation measured in EBV-infected
cultures treated with
FK506 (Fig.
1D). PBMC cultures from all donors
infected with EBV
in the presence of FK506 displayed progressively
increasing proliferative
activity to high levels after infection. The
proliferation seen
in mock-inoculated cultures was not unexpected, as
the mock inoculum
contains many antigens from FBS and EBV-negative
cells which might
cause T cells to proliferate. This proliferation was
abolished
by FK506 treatment (
26). These experiments
showed that the ablation
of the T-cell response eliminates regression
of early proliferation
of EBV-infected PBMCs from seropositive donors
just as it leads
to outgrowth of foci in classical regression assays.
This regression
of early proliferation is reproducibly manifested 7 to
10 days
after infection. This inhibition of proliferation is mediated
by memory T cells, since it is not observed in cultures from
EBV-seronegative
donors.
Memory T-cell activity selectively prevents the outgrowth of
EBV-infected proliferating CD23+ B cells in PBMC
cultures.
CD23 has been regularly associated with latent infection
and B-cell blast transformation induced by EBV (1, 8, 21, 62). To determine whether outgrowth of CD23+ cells
was selectively inhibited after EBV infection in vitro, we analyzed the
numbers and proliferation profiles of T- and B-cell subsets in infected
cultures. As illustrated in Fig. 2A, the
presence of T-cell activity in PBMCs from seropositive donors
dramatically decreased the number of CD23+ B cells seen
after EBV infection. By day 17.5 after infection of the FK506-treated
cultures, in the absence of T-cell control, CD19+ B cells
made up 57% of the population, and notably 37% of lymphocytes were
CD23+ B cells. In contrast, by day 17.5, the untreated
cultures consisted of 96% T cells, 3.2% CD19+ B cells,
and 0.6% CD19+ CD23+ cells. Up to 6.5 days
after infection, the untreated and FK506-treated cultures were
indistinguishable in expression of lymphocyte surface markers. At this
time, both cultures contained a significant number of CD19+
CD23+ B cells, 4.4% of the culture, but these were
subsequently eliminated in the presence of T-cell activity in the
untreated culture. Although CD23 may also appear on activated
CD4+ T cells and follicular dendritic cells as well as
activated B cells, in our experiments CD23 expression was not detected
on any T-cell populations (data not shown) (5, 38).
View larger version (27K):
[in this window]
[in a new window]
|
FIG. 2.
Composition and proliferation of PBMC cultures infected
with EBV in the absence or presence of FK506. (A and B) PBMCs from an
EBV-seropositive donor were infected with EBV. The numbers of
CD3+ (black), CD19+ (hatched), and
CD23+ (white) cells were determined by FACS four times
after infection with EBV in the absence (A) or presence (B) of FK506.
(C and D) PBMCs from an EBV-seropositive donor were incubated with CFSE
dye and then infected with EBV in either the absence (C) or presence
(D) of FK506. Living cells were analyzed for CD3, CD19, and CD23
expression and the intensity of CFSE fluorescence 3 and 17.5 days after
infection. Progressive rounds of cell division are reflected in
sequential halvings of fluorescence intensity and a shift to the left
in the profile of CFSE staining.
|
|
The CD19
+ CD23
+ cells observed in the absence
of T-cell activity are actively proliferating, as demonstrated in Fig.
2B by cells
labeled with the fluorescent dye CFSE and cell surface
markers.
With each cell division, the CFSE dye partitions to daughter
cells,
and CFSE fluorescence intensity declines by half
(
28). At 3
days after infection, there was no difference
in fluorescence
profile and little cell division was evident between
cultures
grown in the presence or absence of FK506 (data not shown). In
the absence of FK506, by 17.5 days after infection, only a
CD3
+ T-cell population which had undergone multiple rounds
of proliferation
remained (Fig.
2B, left panel). However, in the
presence of FK506,
the CD19
+ and CD23
+
populations had undergone more than seven cell divisions, as
assessed by intermediate time points where six peaks of
proliferation
are clearly visible (data not shown) and by dividing the
intensity
of the nonproliferating peak by 2
7. The majority
of the surviving T cells had not proliferated (Fig.
2B, right panel).
Division of significant numbers of CD3
+ T cells or
CD23
+ B cells was first noted 6 to 8 days after infection
(data not
shown).
The CD19
+ CD23
+ cells which proliferated in the
absence of memory T-cell activity expressed latent EBV proteins
detected by
immunoblotting and anticomplement IFAs (data not shown). At
least
75 to 80% of cells present at 23 days after infection with EBV
in the presence of FK506 stained brightly for EBNAs, the marker
of
latent viral infection. Separation of cultures into CD23-low
and
CD23-high cells showed that the EBNA
+ cells resided mainly
within the CD23-high population (Table
1).
Comparison of the number of CD19
+ CD23
+ cells
present 2 to 3 weeks after EBV infection in the absence and presence of
FK506
reproducibly indicated the presence or absence of EBV
immunosurveillance
by memory T cells in culture. Using cells from four
EBV-seropositive
donors, there were 4- to 20-fold more
CD23
+ B cells in cultures treated with FK506 than in
untreated cultures
(data not shown). Thus, memory T cells act to
prevent rapid proliferation
of EBV-infected CD23
+ B cells
in the first 3 weeks after infection in addition to preventing
eventual
outgrowth of foci and EBV-infected
LCLs.
Control over proliferation of CD23+ B cells is
dependent on cell density, as are established regression assays.
Our data showing a role for memory T cells in preventing early
CD23+ B-cell proliferation are consistent with the
crucial role for T cells in preventing outgrowth demonstrated in
regression assays. We therefore asked whether control over
proliferation of CD23+ B cells was likewise dependent on
the cell density at which infected cultures are initiated; this density
dependence is a classic feature of the regression phenomenon when
assessed by formation of foci of transformed lymphocytes. In cultures
derived from EBV-seropositive donors, regression is noted at high
starting cell density and is eliminated or reduced at low starting cell
densities (31, 52). It is not known whether this
dependence on high cell density reflects a requirement for a critical
number of memory T cells per culture, a need for cell-to-cell contact,
or other factors such as cytokine concentrations.
We found that inhibition of proliferation assessed by the number of
CD19
+ CD23
+ cells was also dependent on
starting cell density (Fig.
3). By
day
16, there were only 3 to 5% CD19
+ CD23
+ cells
when cultures were initiated at 6 × 10
5 cells/ml or
higher in the absence of FK506. However, when cultures
were initiated
at 2 × 10
5 cells/ml, the cultures contained 44%
CD19
+ CD23
+ cells on day 16. In the presence of
FK506, more than 20% of the
infected population were CD19
+
CD23
+, even if the cells were initially seeded at the
highest cell
density (10
6 cells/ml). This fraction rose to
44% when the cells were seeded
at the lowest cell density; this
indicates that even in the presence
of FK506, there may be some
residual immune activity. Thus, the
ability of memory T cells to
regulate CD23
+ B-cell proliferation after new EBV infection
is diminished as
initial culture density decreases.
View larger version (40K):
[in this window]
[in a new window]
|
FIG. 3.
Effect of initial cell density on the proportion of
CD23+ B cells in PBMC cultures infected with EBV in the
presence and absence of FK506. FACS analysis of expression of CD19
(vertical axis) and CD23 (horizontal axis) in PBMC cultures initiated
at starting densities varying between 106 and 2 × 105 cells/ml. All cultures were derived from the same
EBV-seropositive individual, simultaneously infected with EBV, and
analyzed 16 days after infection.
|
|
Depletion of particular T-cell subsets enables outgrowth of
CD23+ B cells.
While FK506 inactivated the entire
T-cell population, depletion of T-cell subsets allowed us to ask which
T cells were crucial in early stages of EBV-specific immune control. As
shown in Fig. 4, depletion of
CD4+ but not of CD8+ T cells
had an impact on CD23+ B-cell appearance. Initially,
cultures of nondepleted PBMCs or cultures depleted of CD3+,
CD4+, or CD8+ cells by magnetic bead selection
contained very low fractions of CD23+ B cells, fewer than
1.1% of the cultures. However, 5 days after infection there began a
rapid progressive increase in the fraction of CD23+ B cells
in the CD3-depleted cultures which was not observed in nondepleted PBMC
cultures (Fig. 4A). Not surprisingly, CD3+ cells were
necessary for immune control. There was a slight increase in the
percentage of CD23-positive cells in CD3-depleted cultures treated with
FK506. This is likely secondary to FK506's ability to block
calcineurin-phosphatase activity in cells other than T cells and its
ability to enhance B-cell viability (3, 18).
View larger version (25K):
[in this window]
[in a new window]
|
FIG. 4.
Effect of depletion of T cells on the proportion
of CD23+ B cells in EBV-infected cultures. At the indicated
times, cultures of EBV-infected cells originally drawn from
EBV-seropositive donors were harvested and analyzed by FACS for the
fraction of CD23+ B cells. (A) Effect of depletion of
CD3+ cells. Cultures depleted of CD3-expressing cells prior
to infection were initiated at 2 × 105 cells/ml and
compared with cultures of PBMC initiated at 106 cells/ml.
Both groups of cells were cultured in the presence (solid lines) and
absence (dashed lines) of FK506. Following CD3+ cell
depletion, cultures from donor 1 contained fewer than 3.3%
CD3+ cells at 5 days after infection, and cultures from
donor 2 contained fewer than 0.8% CD3+ cells. (B) Effect
of depletion of CD4+ and CD8+ cells. PBMC
cultures were initiated at 106 cells/ml; cultures depleted
of CD4+ cells were initiated at 4 × 105
cells/ml; and cultures depleted of CD8+ cells were
initiated at 8 × 105 /mL. CD4-depleted and
CD8-depleted cultures from donor 3 contained fewer than 1.4%
CD4+ cells and fewer than 0.7% CD8+ cells,
respectively. CD4-depleted and CD8-depleted cultures from donor 4 contained fewer than 4.2% CD4+ cells and fewer than 0.5%
CD8+ cells, respectively, measured 3 days after infection.
(C) Effect of depletion of different T-cell subpopulations in an
experiment utilizing PBMCs from one seropositive donor. All cultures
were simultaneously infected with EBV and initiated at the same
starting cell density of 2 × 106 cells/ml. Cultures
depleted of CD3-, CD4-, and CD8-expressing cells contained less than
0.9% CD3+ cells, less than 0.5% CD4+ cells,
and less than 1.4% CD8+ cells respectively, at 8.5 days
after infection. Triangles, PBMCs; diamonds, CD3-depleted cells;
squares, CD4-depleted cells; and X's, CD8-depleted cells.
|
|
A rapid increase in the fraction of CD23
+ B cells also
occurred in EBV-infected cultures depleted of CD4
+ cells
(Fig.
4B). Thus, CD4
+ cells appeared to be necessary for
control over early stages
of CD23
+ B-cell generation.
Surprisingly, regression was maintained in
the CD8-depleted cultures,
which were indistinguishable from PBMC
cultures by CD23 expression 13 days after infection (Fig.
4B).
The addition of FK506 to CD8-depleted
cultures eliminated immune
control (data not shown). This indicated
that CD8 depletion per
se was not inhibitory to EBV-induced
lymphoproliferation.
Comparison of CD3-depleted, CD4-depleted, and CD8-depleted PBMC
cultures derived from a single EBV-seropositive donor confirmed
that
CD4
+ cells were necessary and sufficient to inhibit the
accumulation
of CD23
+ B cells, while CD8
+ cells
on their own could not (Fig.
4C). Outgrowth of CD23
+ B
cells occurred in all 10 trials of depletion of CD3
+ cells,
in 9 of 10 trials of depletion of CD4
+ cells, and in none
of 14 trials of depletion of CD8
+ cells (data not shown).
Depletion of CD3
+ enhanced both the rate and extent of
increase in the CD23
+ fraction over that seen in depletion
of CD4
+ cells, suggesting some role for residual
CD3
+ CD4
cells.
Cultures of PBMCs depleted of CD14
+ CD45
+
monocytes-macrophages maintained the capacity to control outgrowth of
CD23
+ B cells. In these cultures, less than 0.9% of the
residual mononuclear
cells were CD14
+ CD45
+. By
contrast, more than 1.8% of the cells in CD4-depleted cultures
in
which immune control was abrogated were CD14
+
CD45
+. Depletion of CD14
+ CD45
+
cells did not alter the capacity of CD8-depleted cultures to
control
CD23
+ cell proliferation. This demonstrated that loss of
immune control
correlated with depletion of CD4
+ T cells
and not CD4
+ CD14
+ CD45
+ monocytes
or macrophages. Likewise, depletion of CD16
+ natural killer
cells did not affect immunosurveillance (data
not
shown).
CD8-depleted and PBMC cultures are similarly affected by cell
density.
It was unknown whether CD8-depleted cultures could
maintain immune control at initial culture densities lower than
106 cells/ml. Figure 5
demonstrates that cultures depleted of more than 97% of
CD8+ T cells and cultures of mixed PBMCs inhibit
proliferation of CD23+ B cells equally well at various
initial culture densities. There were fewer than 10% CD23+
B cells in mixed PBMC and CD8+ T-cell-depleted cultures
initiated at the two higher cell densities, 106 cells/ml
and 2 × 105 cells/ml; there was a loss of immune
control in both cultures seeded at very low starting cell densities,
such as 4 × 104 cells/mL. In contrast, when cultures
depleted of CD3+ and CD4+ T cells were
initiated at all three cell densities, CD23+ B cells
represented more than 50% of the cell population at the time of
staining.
View larger version (40K):
[in this window]
[in a new window]
|
FIG. 5.
Effect of depletion of T cells on the proportion of
CD23+ B cells in EBV-infected cultures initiated at
different cell densities. PBMC cultures (solid bars) are compared with
CD3-depleted (hatched bars), CD4-depleted (stippled bars), and
CD8-depleted (white bars) cultures, all derived from the same
EBV-seropositive donor. Cultures were infected with EBV and initiated
at the indicated cell densities. Cultures depleted of CD3-, CD4-, and
CD8-expressing cells contained contaminating residual populations of
less than 1.1% CD3+ cells, less than 0.6%
CD4+ cells, and less than 0.8% CD8+ cells,
respectively, at the time of initiation. Results represent cells
analyzed 18 days after infection.  , PBMCs;  , CD3 depleted;  ,
CD4 depleted;  , CD8 depleted.
|
|
CD23+ B cells in cultures depleted of T-cell subsets
have different proliferation profiles.
While PBMC and CD8-depleted
cultures reduced the proportion of CD23+ B cells in
culture, it was unknown whether the proliferation profiles of the few
CD23+ cells that did exist in those cultures resembled the
profiles of CD23+ cells grown in the absence of immune
control. Data from CFSE-labeled cultures showed that CD8+
cell depletion does not alter the early proliferation profile of
CD23+ B cells from that seen in PBMC cultures. However,
CD3+ or CD4+ cell depletion allows rapid
appearance and proliferation of CD23+ B cells (Fig.
6). At 8.5 days after infection, all
cultures contained a low fraction (1.9 to 3.2%) of CD23+ B
cells with similar proliferation profiles. After 4 more days (day
12.5), there was a five- to sevenfold increase in the fraction of
CD23+ cells in the CD3- and CD4-depleted cultures, with
multiple CD23+ cell divisions, as reflected by the large
peaks at low fluorescence intensity. During the same interval in PBMC
and CD8-depleted cultures, there was little change in the fraction of
CD23+ cells or in the CFSE staining profile.
CD23+ cells from PBMC and CD8-depleted cultures that did
divide did not undergo as many rounds of proliferation as those from
CD3- and CD4-depleted cultures. This confirms that the ability to
prevent early CD23+ B-cell proliferation is maintained in
the absence of CD8+ cells and is particularly manifest
between 7 and 12 days after EBV infection in vitro.
View larger version (33K):
[in this window]
[in a new window]
|
FIG. 6.
Effect of depletion of different T-cell subsets on the
proportion of dividing CD23+ cells. Mixed PBMC cultures or
cultures that had been drawn from an EBV-seropositive donors and
depleted of CD3-, CD4-, or CD8-expressing cells were incubated with
CFSE and infected with EBV. At 8.5 and 12.5 days after infection,
CD23+ B cells in the cultures were selectively gated and
analyzed for CFSE fluorescence intensity (horizontal axis). Cultures
depleted of CD3-, CD4-, and CD8-expressing cells contained
contaminating residual populations of less than 0.9% CD3+
cells, less than 0.5% CD4+ cells, and less than 1.4%
CD8+ cells, respectively, at 8.5 days after infection.
Percentages in the upper left corner of each proliferation profile
represent the percentage of CD23+ B cells in that culture
which have undergone proliferation. Percentages in the upper right
corner of each profile represent the percentage that have not yet
undergone proliferation.
|
|
Positively selected CD3+ and CD4+ T-cell
populations exert control over proliferation of EBV-infected
CD23+ B cells.
We explored whether purified
CD4+ T cells are capable of exerting EBV-specific immune
control by adding positively selected T cells to EBV-infected target
cells. This was necessary because depletion of CD8+ cells
yields a population enriched for CD4+ cells but contains
other cells potentially wielding EBV-specific immune activity. In the
experiment illustrated in Fig. 7, the infected target cells were CD3-depleted PBMCs. Addition of increasing numbers of either CD3+ or CD4+ cells to
EBV-infected target cells resulted in a decrease in the number of
CD23+ B cells remaining at 18 days after infection (Fig.
7). Positively selected CD3+ cells appeared to be less
effective than equal numbers of CD4+ cells. The damping
effect of T cells on the number of CD23+ B cells was
strongly manifested when 4 × 105 or more T cells were
added to 2 × 105 CD3-depleted cells per ml. This
ability of CD4+ T cells to exert control over the fraction
of CD23+ B cells present 17 days after EBV infection was
also demonstrated when CD19+ cells were infected and used
as targets (data not shown).
View larger version (30K):
[in this window]
[in a new window]
|
FIG. 7.
Effect of addition of T-cell subpopulations on the
number of CD23+ B cells. (A) EBV-infected cells were either
PBMCs or CD3-depleted PBMCs at 2 × 106 cells/ml. (B)
EBV-infected target cells were CD3-depleted PBMCs (white hatched bar)
seeded at 2 × 105 cells/ml to which were added
increasing numbers of purified, positively selected CD3- (dark hatched
bars) or CD4-expressing (white bars) T cells. There were fewer than
0.4% contaminating CD19+ B cells in the purified
CD3+ population and less than 0.3% CD8+ and
0.2% CD19+ cells in the purified CD4+
population. The cultures were analyzed for the number of
CD23+ B cells 17.5 days after infection. Cells in all
cultures were initially derived from the same EBV-seropositive donor.
|
|
| |
DISCUSSION |
CD4+ T cells inhibit EBV-induced B-cell
proliferation.
In this study we analyzed the capacity of memory T
cells to abrogate the proliferation of CD23+ B cells newly
infected by EBV. A novel finding of our study is that CD4+
T cells taken directly from the peripheral blood of EBV-seropositive donors contribute significantly to preventing the early stages of
EBV-induced lymphoproliferation. In the absence of CD4+ T
cells, CD8+ T cells do not inhibit proliferation of
CD23+ B cells. In cultures depleted of CD4+ T
cells, the fraction of CD23+ B cells increases markedly,
and the majority of these cells actively proliferate between days 6 and
12 after EBV infection (Fig. 4B, 4C, and 6). This increase in
CD23+ B cells does not appear in PBMC cultures or in
cultures depleted of CD8+ cells within the first 3 weeks
after infection. Even at high initial starting cell densities, such as
106 cells/ml, depletion of CD4+ T cells
promotes an increase in CD23+ B cells, while depletion of
CD8+ cells does not allow outgrowth of CD23+ B
cells at the same starting cell density (Fig. 5 and 6). Moreover, after
addition to EBV-infected purified target cells, purified CD4+ T cells are sufficient to prevent the outgrowth of
CD23+ B cells (Fig. 7). These experiments suggest that
CD4+ T cells themselves act as effectors of regression as
well as helpers of a CD8+ T-cell-mediated response.
Advances in assessing functional immune control of
proliferation.
Our conclusions that CD4+ T cells
separated from CD8+ T cells are competent to mediate immune
control of EBV-induced B-cell activation and proliferation exploit
powerful quantitative tools for studying early events following EBV
infection. We have employed assays based on proliferation of the total
culture ([3H]dT incorporation), the composition of the
culture (the number and fraction of CD23+ B cells), and
analysis of the number of cells in the culture that have undergone cell
division (CFSE dye dilution). All of these assays permit a more
accurate, quantitative, and reproducible assessment of the T-cell
response to new EBV infection in vitro than does the subjective
enumeration of clumps of putatively transformed cells. Moreover, these
assays allow monitoring of the kinetic evolution of cell populations
responding to EBV infection and indicate the time between 6 and
12 days postinfection as the time of major T-cell expansion and
activity (Fig. 3, 5, and 7).
Similarities of findings in assays based on CD23+
B-cell proliferation and morphologic changes.
Our assays, which
enumerate CD23+ B cells within the first 2 to 3 weeks after
EBV infection, may not measure the same events as the classical
regression assay. Nonetheless, our quantitative assay system reproduces
many of the findings of the classical regression assay, in which foci
of transformed cells are counted under a microscope. Both assays show
that (i) immune surveillance occurs only when target cells for EBV
infection are obtained from EBV-seropositive individuals (Fig. 1), (ii)
T cells are necessary to prevent outgrowth, and inclusion of a T-cell
immunosuppressant, such as FK506, blocks the capacity of memory T cells
to mediate immune surveillance (Fig. 1 to 4), and (iii) immune
surveillance over EBV-induced lymphoproliferation in cultures derived
from EBV-seropositive individuals is exquisitely sensitive to the
density at which the culture was initiated (Fig. 3 and 5)
(53). These observations are consistent hallmarks of the
regression phenomenon. Thus, our CD23+ B-cell assay could
yield quantitative assessment of patient immune status in clinical
disease states, just as classical regression assays have been used to
gauge the vigor of cell-mediated immunity to EBV in immunocompromised
patients (70). Preliminary results indicate that our assay
based on CD23+ B-cell proliferation can be used to monitor
the acquisition of effective T-cell surveillance after primary EBV
infection manifested clinically as infectious mononucleosis (data not shown).
Reconciliation of CD4+ T-cell activity with published
cytotoxic activity of CD8+ T cells against EBV-infected
targets.
That CD4+ T cells can act as both cytotoxic
effectors and immune helpers and thus play a significant role in
preventing early proliferation of activated CD23+
EBV-infected lymphoblasts does not preclude contributions to immunosurveillance by other immune cells, including CD8+ T
cells. Our data show that CD8+ T cells by themselves, in
the absence of CD4+ T cells, are unable to prevent
CD23+ B cell proliferation in the 2 to 3 weeks following
EBV infection in vitro. However, it is likely that CD8+ T
cells are active in the presence of CD4+ T cell help, and
our experiments do not rule out such activity in a primary mixed PBMC
culture. There is no question that CD8+ T cells are highly
reactive and cytotoxic towards EBV-transformed LCLs (9, 20, 51,
67). In fact, HLA class I-restricted (putatively
CD8+) T cells have been isolated from cultures in the
process of regression and shown to inhibit the growth of already
established LCLs (54). However, this experiment does not
address whether these same T cells are responsible for inducing
regression in the primary cultures. Our experiments investigate the
nature of the immune response in regulating B cells in the early stages
of EBV infection and transformation, not the immune response of CTLs to
immortalized LCLs. Newly infected B cells and fully transformed LCLs
are different targets for cell-mediated immunity. Newly infected cells
undergoing EBV-induced proliferation likely express different cellular
and viral antigens than already immortalized cells and may be subject to surveillance by different types of T cells (64). The
design of our experimental system, in terms of the nature of the
EBV-infected targets, the initial resting state of the fresh memory
T cells, the time of analysis, and the CD23+ B-cell
readout, differs from those of assays used previously. Thus, our
findings on the role of CD4+ T cells do not contradict the
established ability of CD8+ T cells to exert immune
surveillance over EBV infection. Both types of T cells appear to be important.
Increasing evidence for the role of CD4+ T cells in EBV
and other viral infections.
In summary, our work using a
physiologically relevant, functional, in vitro assay system solidifies
the role of CD4+ T cells in an in vitro EBV-specific immune
response. Quantitative tools to analyze this role have far-reaching
implications, because CD4+ CTLs can recognize both latent
and lytic-cycle antigens and can be generated from both naive and
memory populations (19, 51, 61). While the antigenic
targets have not yet been identified, reactivation of lytic virus in
LCLs can generate a CD4-dominated rather than a CD8-dominated CTL
response (69). However, CD4+ CTL are not
restricted to lytic-cycle antigens, since Munz et al. have found that
EBNA1, a latent EBV protein which is poorly recognized by
CD8+ CTL because of impaired MHC class I loading of EBNA1,
is particularly important in the CD4+ CTL response
(4, 39). CD4+ CTLs can act through
perforin-mediated cytotoxicity or via a Fas-Fas ligand-mediated pathway
(19, 69). Our study leaves open the possibility that
EBV-specific CD4+ T cells may function by a cytolytic or an
antiproliferative mechanism. Specifically, preliminary studies indicate
that gamma interferon is preferentially produced by CD4+
cells in the presence of virus versus the presence of a mock inoculum.
Other preliminary findings indicate that two clones of EBNA1-specific
CD4+ CTLs which secrete gamma interferon also inhibit
CD23+ B-cell outgrowth in our assay. Moreover,
CD4+ T cells have been found to exert a protective effect
in vivo following infection by respiratory syncytial virus, lymphocytic choriomeningitis virus, and herpes simplex virus in mice (30, 45,
66). Thus, the CD4+ T-cell-mediated inhibition of
EBV-induced proliferation demonstrated here may prove a crucial
component of the in vivo immune response to EBV.
| |
ACKNOWLEDGMENTS |
We thank David Ross and Saul Karpen for helpful discussions at
the outset of this work.
This work was supported by grants CA12055 and CA16038 from the National
Institutes of Health. S. Nikiforow was supported by Medical Scientist
Training Program grant GM07205, the John F. Enders Research Fund of
Yale University School of Medicine, and the Anna Fuller Pediatric
Oncology Fund.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Pediatrics, Yale University School of Medicine, 333 Cedar St., New
Haven, CT 06520. Phone: (203) 785-4758. Fax: (203) 785-6961. E-mail: george.miller{at}yale.edu.
| |
REFERENCES |
| 1.
|
Azim, T., and D. H. Crawford.
1988.
Lymphocytes activated by the Epstein-Barr virus to produce immunoglobulin do not express CD23 or become immortalized.
Int. J. Cancer
42:23-28[Medline].
|
| 2.
|
Babcock, G. J.,
L. L. Decker,
R. B. Freeman, and D. A. Thorley-Lawson.
1999.
Epstein-barr virus-infected resting memory B cells, not proliferating lymphoblasts, accumulate in the peripheral blood of immunosuppressed patients.
J. Exp. Med.
190:567-576[Abstract/Free Full Text].
|
| 3.
|
Beatty, P. R.,
S. M. Krams,
C. O. Esquivel, and O. M. Martinez.
1998.
Effect of cyclosporine and tacrolimus on the growth of Epstein-Barr virus-transformed B-cell lines.
Transplantation
65:1248-1255[CrossRef][Medline].
|
| 4.
|
Blake, N.,
S. Lee,
I. Redchenko,
W. Thomas,
N. Steven,
A. Leese,
P. Steigerwald-Mullen,
M. G. Kurilla,
L. Frappier, and A. Rickinson.
1997.
Human CD8+ T cell responses to EBV EBNA1: HLA class I presentation of the (Gly-Ala)-containing protein requires exogenous processing.
Immunity
7:791-802[CrossRef][Medline].
|
| 5.
|
Bonnefoy, J. Y.,
S. Lecoanet-Henchoz,
J. F. Gauchat,
P. Graber,
J. P. Aubry,
P. Jeannin, and C. Plater-Zyberk.
1997.
Structure and functions of CD23.
Int. Rev. Immunol.
16:113-128[Medline].
|
| 6.
|
Boyle, T. J.,
K. R. Berend,
J. M. DiMaio,
R. E. Coles,
D. F. Via, and H. K. Lyerly.
1993.
Adoptive transfer of cytotoxic T lymphocytes for the treatment of transplant-associated lymphoma.
Surgery
114:218-226[Medline].
|
| 7.
|
Boyle, T. J.,
M. Tamburini,
K. R. Berend,
A. M. Kizilbash,
M. J. Borowitz, and H. K. Lyerly.
1992.
Human B-cell lymphoma in severe combined immunodeficient mice after active infection with Epstein-Barr virus.
Surgery
112:378-386[Medline].
|
| 8.
|
Calender, A.,
M. Billaud,
J. P. Aubry,
J. Banchereau,
M. Vuillaume, and G. M. Lenoir.
1987.
Epstein-Barr virus (EBV) induces expression of B-cell activation markers on in vitro infection of EBV-negative B-lymphoma cells.
Proc. Natl. Acad. Sci. USA
84:8060-8064[Abstract/Free Full Text].
|
| 9.
|
Callan, M. F.,
N. Steven,
P. Krausa,
J. D. Wilson,
P. A. Moss,
G. M. Gillespie,
J. I. Bell,
A. B. Rickinson, and A. J. McMichael.
1996.
Large clonal expansions of CD8+ T cells in acute infectious mononucleosis.
Nat. Med.
2:906-911[CrossRef][Medline].
|
| 10.
|
Cao, S.,
K. L. Cox,
W. Berquist,
M. Hayashi,
W. Concepcion,
G. B. Hammes,
O. K. Ojogho,
S. K. So,
M. Frerker,
R. O. Castillo,
H. Monge, and C. O. Esquivel.
1999.
Long-term outcomes in pediatric liver recipients: comparison between cyclosporin A and tacrolimus.
Pediatr. Transplant.
3:22-26[CrossRef][Medline].
|
| 11.
|
Coligan, J.,
A. Kruisbeek,
D. Margulies,
E. Shevach, and W. Strober (ed.).
1995.
Current protocols in immunology, 1st ed., vol. 1.
John Wiley & Sons, Inc., New York, N.Y.
|
| 12.
|
Cox, K. L.,
L. S. Lawrence-Miyasaki,
R. Garcia-Kennedy,
E. T. Lennette,
O. M. Martinez,
S. M. Krams,
W. E. Berquist,
S. K. So, and C. O. Esquivel.
1995.
An increased incidence of Epstein-Barr virus infection and lymphoproliferative disorder in young children on FK506 after liver transplantation.
Transplantation
59:524-529[Medline].
|
| 13.
|
Crawford, D. H.,
V. Iliescu,
A. J. Edwards, and P. C. Beverley.
1983.
Characterisation of Epstein-Barr virus-specific memory T cells from the peripheral blood of seropositive individuals.
Br. J. Cancer
47:681-686[Medline].
|
| 14.
|
De Schryver, A.,
G. Klein,
G. Henle,
W. Henle,
H. M. Cameron,
L. Santesson, and P. Clifford.
1972.
EB virus-associated serology in malignant disease: antibody levels to viral capsid antigens (VCA), membrane antigens (MA) and early antigens (EA) in patients with various neoplastic conditions.
Int. J. Cancer
9:353-364[Medline].
|
| 15.
|
Finn, L.,
J. Reyes,
J. Bueno, and E. Yunis.
1998.
Epstein-Barr virus infections in children after transplantation of the small intestine.
Am. J. Surg. Pathol.
22:299-309[CrossRef][Medline].
|
| 16.
|
Green, M.,
M. G. Michaels,
S. A. Webber,
D. Rowe, and J. Reyes.
1999.
The management of Epstein-Barr virus associated post-transplant lymphoproliferative disorders in pediatric solid-organ transplant recipients.
Pediatr. Transplant.
3:271-281[CrossRef][Medline].
|
| 17.
|
Heslop, H. E., and C. M. Rooney.
1997.
Adoptive cellular immunotherapy for EBV lymphoproliferative disease.
Immunol. Rev.
157:217-222[CrossRef][Medline].
|
| 18.
|
Ho, S.,
N. Clipstone,
L. Timmermann,
J. Northrop,
I. Graef,
D. Fiorentino,
J. Nourse, and G. R. Crabtree.
1996.
The mechanism of action of cyclosporin A and FK506.
Clin. Immunol. Immunopathol.
80:S40-S45[CrossRef][Medline].
|
| 19.
|
Honda, S.,
T. Takasaki,
K. Okuno,
M. Yasutomi, and I. Kurane.
1998.
Establishment and characterization of Epstein-Barr virus-specific human CD4+ T lymphocyte clones.
Acta Virol.
42:307-313[Medline].
|
| 20.
|
Hoshino, Y.,
T. Morishima,
H. Kimura,
K. Nishikawa,
T. Tsurumi, and K. Kuzushima.
1999.
Antigen-driven expansion and contraction of CD8+-activated T cells in primary EBV infection.
J. Immunol.
163:5735-5740[Abstract/Free Full Text].
|
| 21.
|
Hurley, E. A., and D. A. Thorley-Lawson.
1988.
B cell activation and the establishment of Epstein-Barr virus latency.
J. Exp. Med.
168:2059-2075[Abstract/Free Full Text].
|
| 22.
|
Joseph, A. M.,
G. J. Babcock, and D. A. Thorley-Lawson.
2000.
EBV persistence involves strict selection of latently infected B cells.
J. Immunol.
165:2975-2981[Abstract/Free Full Text].
|
| 23.
|
Karp, J. E., and S. Broder.
1991.
Acquired immunodeficiency syndrome and non-Hodgkin's lymphomas.
Cancer Res.
51:4743-4756[Free Full Text].
|
| 24.
|
Khanna, R.,
S. R. Burrows,
P. M. Steigerwald-Mullen,
S. A. Thomson,
M. G. Kurilla, and D. J. Moss.
1995.
Isolation of cytotoxic T lymphocytes from healthy seropositive individuals specific for peptide epitopes from Epstein-Barr virus nuclear antigen 1: implications for viral persistence and tumor surveillance.
Virology
214:633-637[CrossRef][Medline].
|
| 25.
|
Klein, G.,
J. Zeuthen,
P. Terasaki,
R. Billing,
R. Honig,
M. Jondal,
A. Westman, and G. Clements.
1976.
Inducibility of the Epstein-Barr virus (EBV) cycle and surface marker properties of EBV-negative lymphoma lines and their in vitro EBV-converted sublines.
Int. J. Cancer
18:639-652[Medline].
|
| 26.
|
Konttinen, Y. T.,
H. G. Bluestein, and N. J. Zvaifler.
1985.
Regulation of the growth of Epstein-Barr virus-infected B cells. I. Growth regression by E rosetting cells from VCA-positive donors is a combined effect of autologous mixed leukocyte reaction and activation of T8+ memory cells.
J. Immunol.
134:2287-2293[Abstract].
|
| 27.
|
Lacerda, J. F.,
M. Ladanyi,
D. C. Louie,
J. M. Fernandez,
E. B. Papadopoulos, and R. J. O'Reilly.
1996.
Human Epstein-Barr virus (EBV)-specific cytotoxic T lymphocytes home preferentially to and induce selective regressions of autologous EBV-induced B cell lymphoproliferations in xenografted C.B-17 scid/scid mice J.
Exp. Med.
183:1215-1228. (Erratum, 184:1199.)
|
| 28.
|
Lyons, A. B., and C. R. Parish.
1994.
Determination of lymphocyte division by flow cytometry.
J. Immunol. Methods
171:131-137[CrossRef][Medline].
|
| 29.
|
Mackinnon, S.,
E. B. Papadopoulos,
M. H. Carabasi,
L. Reich,
N. H. Collins, and R. J. O'Reilly.
1995.
Adoptive immunotherapy using donor leukocytes following bone marrow transplantation for chronic myeloid leukemia: is T cell dose important in determining biological response?
Bone Marrow Transplant.
15:591-594[Medline].
|
| 30.
|
Manickan, E.,
R. J. Rouse,
Z. Yu,
W. S. Wire, and B. T. Rouse.
1995.
Genetic immunization against herpes simplex virus. Protection is mediated by CD4+ T lymphocytes.
J. Immunol.
155:259-265[Abstract].
|
| 31.
|
Masucci, M. G.,
M. T. Bejarano,
G. Masucci, and E. Klein.
1983.
Large granular lymphocytes inhibit the in vitro growth of autologous Epstein-Barr virus-infected B cells.
Cell. Immunol.
76:311-321[CrossRef][Medline].
|
| 32.
|
Miller, G., and D. Coope.
1974.
Epstein-Barr viral nuclear antigen (EBNA) in tumor cell imprints of experimental lymphoma of marmosets.
Trans. Assoc. Am. Physicians
87:205-218[Medline].
|
| 33.
|
Miller, G.,
J. Robinson, and L. Heston.
1975.
Immortalizing and nonimmortalizing laboratory strains of Epstein-Barr virus.
Cold Spring Harb. Symp. Quant. Biol.
39:773-781.
|
| 34.
|
Miller, G.,
J. Robinson,
L. Heston, and M. Lipman.
1975.
Differences between laboratory strains of Epstein-Barr virus based on immortalization, abortive infection and interference.
IARC Sci. Publ.
11:395-408.
|
| 35.
|
Misko, I. S.,
J. H. Pope,
R. Hutter,
T. D. Soszynski, and R. G. Kane.
1984.
HLA-DR-antigen-associated restriction of EBV-specific cytotoxic T-cell colonies.
Int. J. Cancer
33:239-243[Medline].
|
| 36.
|
Mosier, D. E.
1996.
Viral pathogenesis in hu-PBL-SCID mice.
Semin. Immunol.
8:255-262[CrossRef][Medline]. (Erratum 8:311.)
|
| 37.
|
Moss, D. J.,
A. B. Rickinson, and J. H. Pope.
1978.
Long-term T-cell-mediated immunity to Epstein-Barr virus in man. I. Complete regression of virus-induced transformation in cultures of seropositive donor leukocytes.
Int. J. Cancer
22:662-668[Medline].
|
| 38.
|
Mossalayi, M. D.,
M. Arock, and P. Debre.
1997.
CD23/Fc epsilon RII: signaling and clinical implication.
Int. Rev. Immunol.
16:129-146[Medline].
|
| 39.
|
Munz, C.,
K. L. Bickham,
M. Subklewe,
M. L. Tsang,
A. Chahroudi,
M. G. Kurilla,
D. Zhang,
M. O'Donnell, and R. M. Steinman.
2000.
Human CD4+ T lymphocytes consistently respond to the latent Epstein-Barr virus nuclear antigen EBNA1.
J. Exp. Med.
191:1649-1660[Abstract/Free Full Text].
|
| 40.
|
Okano, M., and D. T. Purtilo.
1995.
Simple assay for evaluation of Epstein-Barr virus specific cytotoxic T lymphocytes.
J. Immunol. Methods
184:149-152[CrossRef][Medline].
|
| 41.
|
O'Reilly, R. J.,
T. N. Small,
E. Papadopoulos,
K. Lucas,
J. Lacerda, and L. Koulova.
1997.
Biology and adoptive cell therapy of Epstein-Barr virus-associated lymphoproliferative disorders in recipients of marrow allografts.
Immunol. Rev.
157:195-216[CrossRef][Medline].
|
| 42.
|
Papadopoulos, E. B.,
M. Ladanyi,
D. Emanuel,
S. Mackinnon,
F. Boulad,
M. H. Carabasi,
H. Castro-Malaspina,
B. H. Childs,
A. P. Gillio,
T. N. Small, et al.
1994.
Infusions of donor leukocytes to treat Epstein-Barr virus-associated lymphoproliferative disorders after allogeneic bone marrow transplantation.
N. Engl. J. Med.
330:1185-1191[Abstract/Free Full Text].
|
| 43.
|
Paya, C. V.,
J. J. Fung,
M. A. Nalesnik,
E. Kieff,
M. Green,
G. Gores,
T. M. Habermann,
P. H. Wiesner,
J. L. Swinnen,
E. S. Woodle, and J. S. Bromberg.
1999.
Epstein-Barr virus-induced posttransplant lymphoproliferative disorders. ASTS/ASTP EBV-PTLD Task Force and the Mayo Clinic Organized International Consensus Development Meeting.
Transplantation
68:1517-1525[Medline].
|
| 44.
|
Picchio, G. R.,
R. Kobayashi,
M. Kirven,
S. M. Baird,
T. J. Kipps, and D. E. Mosier.
1992.
Heterogeneity among Epstein-Barr virus-seropositive donors in the generation of immunoblastic B-cell lymphomas in SCID mice receiving human peripheral blood leukocyte grafts.
Cancer Res.
52:2468-2477[Abstract/Free Full Text].
|
| 45.
|
Plotnicky-Gilquin, H.,
A. Robert,
L. Chevalet,
J. F. Haeuw,
A. Beck,
J. Y. Bonnefoy,
C. Brandt,
C. A. Siegrist,
T. N. Nguyen, and U. F. Power.
2000.
CD4+ T-cell-mediated antiviral protection of the upper respiratory tract in BALB/c mice following parenteral immunization with a recombinant respiratory syncytial virus G protein fragment.
J. Virol.
74:3455-3463[Abstract/Free Full Text].
|
| 46.
|
Purtilo, D. T.,
K. Falk,
S. J. Pirruccello,
H. Nakamine,
K. Kleveland,
J. R. Davis,
M. Okano,
Y. Taguchi,
W. G. Sanger, and K. W. Beisel.
1991.
SCID mouse model of Epstein-Barr virus-induced lymphomagenesis of immunodeficient humans.
Int. J. Cancer
47:510-517[Medline].
|
| 47.
|
Qu, L.,
M. Green,
S. Webber,
J. Reyes,
D. Ellis, and D. Rowe.
2000.
Epstein-Barr virus gene expression in the peripheral blood of transplant recipients with persistent circulating virus loads.
J. Infect. Dis.
182:1013-1021[CrossRef][Medline].
|
| 48.
|
Qu, L., and D. T. Rowe.
1992.
Epstein-Barr virus latent gene expression in uncultured peripheral blood lymphocytes.
J. Virol.
66:3715-3724[Abstract/Free Full Text].
|
| 49.
|
Reedman, B. M.,
J. Hilgers,
F. Hilgers, and G. Klein.
1975.
Immunofluorescence and anti-complement immunofluorescence absorption tests for quantitation of Epstein-Barr virus-associated antigens.
Int. J. Cancer
15:566-571[Medline].
|
| 50.
|
Rencher, S. D.,
K. S. Slobod,
F. S. Smith, and J. L. Hurwitz.
1994.
Activity of transplanted CD8+ versus CD4+ cytotoxic T cells against Epstein-Barr virus-immortalized B cell tumors in SCID mice.
Transplantation
58:629-633[Medline].
|
| 51.
|
Rickinson, A. B., and D. J. Moss.
1997.
Human cytotoxic T lymphocyte responses to Epstein-Barr virus infection.
Annu. Rev. Immunol.
15:405-431[CrossRef][Medline].
|
| 52.
|
Rickinson, A. B.,
D. J. Moss, and J. H. Pope.
1979.
Long-term T-cell-mediated immunity to Epstein-Barr virus in man. II. Components necessary for regression in virus-infected leukocyte cultures.
Int. J. Cancer
23:610-617[Medline].
|
| 53.
|
Rickinson, A. B.,
M. Rowe,
I. J. Hart,
Q. Y. Yao,
L. E. Henderson,
H. Rabin, and M. A. Epstein.
1984.
T-cell-mediated regression of "spontaneous" and of Epstein-Barr virus-induced B-cell transformation in vitro: studies with cyclosporin A.
Cell. Immunol.
87:646-658[CrossRef][Medline].
|
| 54.
|
Rickinson, A. B.,
L. E. Wallace, and M. A. Epstein.
1980.
HLA-restricted T-cell recognition of Epstein-Barr virus-infected B cells.
Nature
283:865-867[CrossRef][Medline].
|
| 55.
|
Robinson, J.
1975.
Assay for Epstein-Barr virus based on stimulation of DNA synthesis in mixed leukocytes from human umbilical cord blood.
J. Virol.
15:1065-1072[Abstract/Free Full Text].
|
| 56.
|
Rochford, R., and D. E. Mosier.
1994.
Immunobiology of Epstein-Barr virus-associated lymphomas.
Clin. Immunol. Immunopathol.
71:256-259[CrossRef][Medline].
|
| 57.
|
Rooney, C. M.,
C. A. Smith,
C. Y. Ng,
S. Loftin,
C. Li,
R. A. Krance,
M. K. Brenner, and H. E. Heslop.
1995.
Use of gene-modified virus-specific T lymphocytes to control Epstein-Barr-virus-related lymphoproliferation.
Lancet
345:9-13[CrossRef][Medline].
|
| 58.
|
Rowe, D. T.,
P. J. Farrell, and G. Miller.
1987.
Novel nuclear antigens recognized by human sera in lymphocytes latently infected by Epstein-Barr virus.
Virology
156:153-162[CrossRef][Medline].
|
| 59.
|
Rowe, M.,
L. S. Young,
J. Crocker,
H. Stokes,
S. Henderson, and A. B. Rickinson.
1991.
Epstein-Barr virus (EBV)-associated lymphoproliferative disease in the SCID mouse model: implications for the pathogenesis of EBV-positive lymphomas in man.
J. Exp. Med.
173:147-158[Abstract/Free Full Text].
|
| 60.
|
Sayos, J.,
C. Wu,
M. Morra,
N. Wang,
X. Zhang,
D. Allen,
S. van Schaik,
L. Notarangelo,
R. Geha,
M. G. Roncarolo,
H. Oettgen,
J. E. De Vries,
G. Aversa, and C. Terhorst.
1998.
The X-linked lymphoproliferative-disease gene product SAP regulates signals induced through the co-receptor SLAM.
Nature
395:462-469[CrossRef][Medline].
|
| 61.
|
Sun, Q.,
R. L. Burton,
K. E. Pollok,
D. J. Emanuel, and K. G. Lucas.
1999.
CD4(+) Epstein-Barr virus-specific cytotoxic T-lymphocytes from human umbilical cord blood.
Cell. Immunol.
195:81-88[CrossRef][Medline].
|
| 62.
|
Swendeman, S. L., and D. Thorley-Lawson.
1988.
Soluble CD23/BLAST-2 (S-CD23/Blast-2) and its role in B cell proliferation.
Curr. Top. Microbiol. Immunol.
141:157-164[Medline].
|
| 63.
|
Tan, L. C.,
N. Gudgeon,
N. E. Annels,
P. Hansasuta,
C. A. O'Callaghan,
S. Rowland-Jones,
A. J. McMichael,
A. B. Rickinson, and M. F. Callan.
1999.
A re-evaluation of the frequency of CD8+ T cells specific for EBV in healthy virus carriers.
J. Immunol.
162:1827-1835[Abstract/Free Full Text].
|
| 64.
|
Thorley-Lawson, D. A.
1980.
The suppression of Epstein-Barr virus infection in vitro occurs after infection but before transformation of the cell.
J. Immunol.
124:745-751[Abstract].
|
| 65.
|
Thorley-Lawson, D. A., and G. J. Babcock.
1999.
A model for persistent infection with Epstein-Barr virus: the stealth virus of human B cells.
Life Sci.
65:1433-1453[CrossRef][Medline].
|
| 66.
|
Varga, S. M., and R. M. Welsh.
1998.
Detection of a high frequency of virus-specific CD4+ T cells during acute infection with lymphocytic choriomeningitis virus.
J. Immunol.
161:3215-3218[Abstract/Free Full Text].
|
| 67.
|
White, C. A.,
S. M. Cross,
M. G. Kurilla,
B. M. Kerr,
C. Schmidt,
I. S. Misko,
R. Khanna, and D. J. Moss.
1996.
Recruitment during infectious mononucleosis of CD3+ CD4+ CD8+ virus-specific cytotoxic T cells which recognise Epstein-Barr virus lytic antigen BHRF1.
Virology
219:489-492[CrossRef][Medline].
|
| 68.
|
Williams, M. L.,
T. P. Loughran, Jr.,
P. G. Kidd, and G. A. Starkebaum.
1989.
Polyclonal proliferation of activated suppressor/cytotoxic T cells with transient depression of natural killer cell function in acute infectious mononucleosis.
Clin. Exp. Immunol.
77:71-76[Medline].
|
| 69.
|
Wilson, A. D.,
I. Redchenko,
N. A. Williams, and A. J. Morgan.
1998.
CD4+ T cells inhibit growth of Epstein-Barr virus-transformed B cells through CD95-CD95 ligand-mediated apoptosis.
Int. Immunol.
10:1149-1157[Abstract/Free Full Text].
|
| 70.
|
Yao, Q. Y.,
D. S. Croom-Carter,
R. J. Tierney,
G. Habeshaw,
J. T. Wilde,
F. G. Hill,
C. Conlon, and A. B. Rickinson.
1998.
Epidemiology of infection with Epstein-Barr virus types 1 and 2: lessons from the study of a T-cell-immunocompromised hemophilic cohort.
J. Virol.
72:4352-4363[Abstract/Free Full Text].
|
Journal of Virology, April 2001, p. 3740-3752, Vol. 75, No. 8
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.8.3740-3752.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Beal, A. M., Anikeeva, N., Varma, R., Cameron, T. O., Norris, P. J., Dustin, M. L., Sykulev, Y.
(2008). Protein Kinase C{theta} Regulates Stability of the Peripheral Adhesion Ring Junction and Contributes to the Sensitivity of Target Cell Lysis by CTL. J. Immunol.
181: 4815-4824
[Abstract]
[Full Text]
-
Bhaduri-McIntosh, S., Rotenberg, M. J., Gardner, B., Robert, M., Miller, G.
(2008). Repertoire and frequency of immune cells reactive to Epstein-Barr virus-derived autologous lymphoblastoid cell lines. Blood
111: 1334-1343
[Abstract]
[Full Text]
-
Bollard, C. M., Gottschalk, S., Leen, A. M., Weiss, H., Straathof, K. C., Carrum, G., Khalil, M., Wu, M.-f., Huls, M. H., Chang, C.-C., Gresik, M. V., Gee, A. P., Brenner, M. K., Rooney, C. M., Heslop, H. E.
(2007). Complete responses of relapsed lymphoma following genetic modification of tumor-antigen presenting cells and T-lymphocyte transfer. Blood
110: 2838-2845
[Abstract]
[Full Text]
-
MacArthur, G. J., Wilson, A. D., Birchall, M. A., Morgan, A. J.
(2007). Primary CD4+ T-Cell Responses Provide both Helper and Cytotoxic Functions during Epstein-Barr Virus Infection and Transformation of Fetal Cord Blood B Cells. J. Virol.
81: 4766-4775
[Abstract]
[Full Text]
-
Heller, K. N., Gurer, C., Munz, C.
(2006). Virus-specific CD4+ T cells: ready for direct attack. JEM
203: 805-808
[Abstract]
[Full Text]
-
Bare, P., Massud, I., Parodi, C., Belmonte, L., Garcia, G., Nebel, M. C., Corti, M., Pinto, M. T., Bianco, R. P., Bracco, M. M., Campos, R., Ares, B. R.
(2005). Continuous release of hepatitis C virus (HCV) by peripheral blood mononuclear cells and B-lymphoblastoid cell-line cultures derived from HCV-infected patients. J. Gen. Virol.
86: 1717-1727
[Abstract]
[Full Text]
-
Gudgeon, N. H., Taylor, G. S., Long, H. M., Haigh, T. A., Rickinson, A. B.
(2005). Regression of Epstein-Barr Virus-Induced B-Cell Transformation In Vitro Involves Virus-Specific CD8+ T Cells as the Principal Effectors and a Novel CD4+ T-Cell Reactivity. J. Virol.
79: 5477-5488
[Abstract]
[Full Text]
-
Voo, K. S., Peng, G., Guo, Z., Fu, T., Li, Y., Frappier, L., Wang, R.-F.
(2005). Functional Characterization of EBV-Encoded Nuclear Antigen 1-Specific CD4+ Helper and Regulatory T Cells Elicited by In vitro Peptide Stimulation. Cancer Res.
65: 1577-1586
[Abstract]
[Full Text]
-
Liu, A., Arbiser, J. L., Holmgren, A., Klein, G., Klein, E.
(2005). PSK and Trx80 inhibit B-cell growth in EBV-infected cord blood mononuclear cells through T cells activated by the monocyte products IL-15 and IL-12. Blood
105: 1606-1613
[Abstract]
[Full Text]
-
Bollard, C. M., Aguilar, L., Straathof, K. C., Gahn, B., Huls, M. H., Rousseau, A., Sixbey, J., Gresik, M. V., Carrum, G., Hudson, M., Dilloo, D., Gee, A., Brenner, M. K., Rooney, C. M., Heslop, H. E.
(2004). Cytotoxic T Lymphocyte Therapy for Epstein-Barr Virus+ Hodgkin's Disease. JEM
200: 1623-1633
[Abstract]
[Full Text]
-
Kobayashi, H., Nagato, T., Yanai, M., Oikawa, K., Sato, K., Kimura, S., Tateno, M., Omiya, R., Celis, E.
(2004). Recognition of Adult T-Cell Leukemia/Lymphoma Cells by CD4+ Helper T Lymphocytes Specific for Human T-Cell Leukemia Virus Type I Envelope Protein. Clin. Cancer Res.
10: 7053-7062
[Abstract]
[Full Text]
-
Kang, I., Quan, T., Nolasco, H., Park, S.-H., Hong, M. S., Crouch, J., Pamer, E. G., Howe, J. G., Craft, J.
(2004). Defective Control of Latent Epstein-Barr Virus Infection in Systemic Lupus Erythematosus. J. Immunol.
172: 1287-1294
[Abstract]
[Full Text]
-
Bickham, K., Goodman, K., Paludan, C., Nikiforow, S., Tsang, M. L., Steinman, R. M., Munz, C.
(2003). Dendritic Cells Initiate Immune Control of Epstein-Barr Virus Transformation of B Lymphocytes In Vitro. JEM
198: 1653-1663
[Abstract]
[Full Text]
-
Nikiforow, S., Bottomly, K., Miller, G., Munz, C.
(2003). Cytolytic CD4+-T-Cell Clones Reactive to EBNA1 Inhibit Epstein-Barr Virus-Induced B-Cell Proliferation. J. Virol.
77: 12088-12104
[Abstract]
[Full Text]
-
Khanolkar, A., Fu, Z., Underwood, L. J., Bondurant, K. L., Rochford, R., Cannon, M. J.
(2003). CD4+ T Cell-Induced Differentiation of EBV-Transformed Lymphoblastoid Cells Is Associated with Diminished Recognition by EBV-Specific CD8+ Cytotoxic T Cells. J. Immunol.
170: 3187-3194
[Abstract]
[Full Text]
-
Voo, K. S., Fu, T., Heslop, H. E., Brenner, M. K., Rooney, C. M., Wang, R.-F.
(2002). Identification of HLA-DP3-restricted Peptides from EBNA1 Recognized by CD4+ T Cells. Cancer Res.
62: 7195-7199
[Abstract]
[Full Text]
-
Omiya, R., Buteau, C., Kobayashi, H., Paya, C. V., Celis, E.
(2002). Inhibition of EBV-Induced Lymphoproliferation by CD4+ T Cells Specific for an MHC Class II Promiscuous Epitope. J. Immunol.
169: 2172-2179
[Abstract]
[Full Text]
-
Paludan, C., Bickham, K., Nikiforow, S., Tsang, M. L., Goodman, K., Hanekom, W. A., Fonteneau, J.-F., Stevanovic, S., Munz, C.
(2002). Epstein-Barr Nuclear Antigen 1-Specific CD4+ Th1 Cells Kill Burkitt's Lymphoma Cells. J. Immunol.
169: 1593-1603
[Abstract]
[Full Text]
-
Spender, L. C., Cornish, G. H., Sullivan, A., Farrell, P. J.
(2002). Expression of Transcription Factor AML-2 (RUNX3, CBF{alpha}-3) Is Induced by Epstein-Barr Virus EBNA-2 and Correlates with the B-Cell Activation Phenotype. J. Virol.
76: 4919-4927
[Abstract]
[Full Text]
-
Wilson, A. D., Morgan, A. J.
(2002). Primary Immune Responses by Cord Blood CD4+ T Cells and NK Cells Inhibit Epstein-Barr Virus B-Cell Transformation In Vitro. J. Virol.
76: 5071-5081
[Abstract]
[Full Text]
Top
Abstract
Introduction
