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Journal of Virology, May 2000, p. 4429-4432, Vol. 74, No. 9
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
High Frequency of Virus-Specific
Interleukin-2-Producing CD4+ T Cells and Th1 Dominance
during Lymphocytic Choriomeningitis Virus Infection
Steven M.
Varga1,
and
Raymond M.
Welsh2,*
Program in Immunology and
Virology1 and Department of
Pathology,2 University of Massachusetts
Medical Center, Worcester, Massachusetts 01655
Received 16 November 1999/Accepted 8 February 2000
 |
ABSTRACT |
Analysis of C57BL/6 mice acutely infected with lymphocytic
choriomeningitis virus (LCMV) by using intracellular cytokine staining revealed a high frequency (2 to 10%) of CD4+ T cells
secreting the Th1-associated cytokines interleukin-2 (IL-2), gamma
interferon (IFN-
), and tumor necrosis factor alpha, with no
concomitant increase in the frequency of CD4+ T cells
secreting the Th2-associated cytokines IL-4, IL-5, and IL-10 following
stimulation with viral peptides. In LCMV-infected C57BL/6
CD8
/ mice, more than 20% of the CD4+ T
cells secreted IFN- after viral peptide stimulation, whereas less
than 1% of the CD4+ T cells secreted IL-4 under these same
conditions. Mice persistently infected with a high dose of LCMV clone
13 also generated a virtually exclusive Th1 response. Thus, LCMV
induces a much more profound virus-specific CD4+ T-cell
response than previously recognized, and it is dramatically skewed to a
Th1 phenotype.
| |
TEXT |
Many viruses are potent inducers of
T-cell responses (1, 3, 22), and the infection of mice with
lymphocytic choriomeningitis virus (LCMV) is one of the most
well-characterized model systems for
studying T-cell responses to viruses. Most work in the LCMV system has
focused on CD8+ T cells, but by day 7 of an acute LCMV
infection, approximately 25% of the CD4+ T cells are blast
sized and 20 to 30% express activation
markers and adhesion molecules (16, 18). Interleukin-2
(IL-2)-based LDA of LCMV-specific CD4+ T-cell frequencies
account for only a small percentage (<1%) of the activated
CD4+ T cells (17, 18), but intracellular gamma
interferon (IFN-) staining following stimulation with either of only
two LCMV-encoded major histocompatibility complex (MHC) class
II-restricted peptides (10) has revealed that as many as
10% of the CD4+ T cells can be defined as LCMV specific
(17). CD4+ T cells may be separated into
distinct subsets based on the cytokines that they secrete, with Th1
responses characterized by the production of IL-2, IFN-, and tumor
necrosis factor 
(TNF-), and Th2 responses characterized by the
production of IL-4, IL-5, IL-6, IL-10, and IL-13 (7-9). In
this study we sought to examine the frequencies and phenotypes of acute
and memory LCMV-specific CD4+ T cells capable of making Th1
cytokines versus those of cells capable of making Th2 cytokines. We
show here that LCMV induces exclusively a Th1 cytokine response.
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TABLE 1.
Frequency of cytokine-secreting CD4+ T cells
during the acute LCMV infection following GP61-80
peptide stimulationa
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FIG. 1.
Intracellular IL-2 expression of LCMV peptide-specific
CD4+ T cells. Splenocytes from LCMV-infected (day 9)
C57BL/6 mice were stimulated in the presence of IL-2 (Pharmingen, San
Diego, Calif.) and monensin (Sigma, St. Louis, Mo.) with or without one
of the two LCMV MHC class II-restricted peptides, GP61-80 and
NP309-328. The cells were subsequently harvested, blocked with purified
anti-FcRII/III MAb (clone 2.4G2; Pharmingen), and stained with
fluorescein isothiocyanate- or PerCP-conjugated anti-CD4 (clone RM4-5;
Pharmingen). After fixation the cells were stained for intracellular
cytokines using directly conjugated anti-cytokine MAbs or the
appropriate isotype-matched control MAb (all from Pharmingen) in buffer
containing 0.5% saponin (Sigma). Control cells known to express IL-2,
IL-4, IL-10, or IFN- (MiCK-1 and MiCK-2; Pharmingen) were used in
all experiments as positive controls. The percentages shown each
indicate the number of CD4+ T cells that stained positive
for intracellular IL-2 as represented by the R1 gate. Data shown are
representative of five experiments, with two mice per experiment.
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|
Intracellular cytokine analysis during acute LCMV infection into
memory.
Intracellular cytokine staining was performed as described
previously (17), except that monensin instead of brefeldin A was used in some experiments to allow cytokines to accumulate intracellularly. Table 1 shows the frequencies of CD4+ T
cells that produce the Th1-associated cytokines IL-2, IFN-, or
TNF-
when stimulated with the LCMV GP61-80 MHC class
II-restricted peptide at various times during the acute LCMV
infection and into the memory state, and Fig. 1 shows that
approximately 2% of the CD4+ T cells from C57BL/6 mice at
day 9 postinfection (p.i.) with LCMV produced IL-2 following
stimulation with this peptide. Others have failed to show IL-2
production in these assays (14, 19), but we were able to do
so by substituting monensin for brefeldin A. Multicolor flow cytometric
analysis revealed that those CD4+ T cells that expressed
IL-2 also produced either IFN- or TNF-, and most of the cells
that expressed IFN- also produced TNF- (Fig.
2A). However, we failed to detect any
increase, compared to the levels obtained with the appropriate
isotype-matched control monoclonal antibody (MAb), in the intracellular
expression of the Th2 cytokines IL-4, IL-5, and IL-10 in
CD4+ T cells during an acute LCMV infection following viral
peptide stimulation in the presence of monensin (Fig. 2B) or following stimulation with phorbol myristate acetate and ionomycin (reference 17 and data not shown).
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FIG. 2.
Th1 (A) and Th2 (B) cytokine expression of LCMV
peptide-specific CD4+ T cells. Splenocytes from
LCMV-infected (day 9) C57BL/6 mice were prepared and analyzed by flow
cytometry after stimulation with the GP61-80 peptide as described in
the legend for Fig. 1. For panel A, the cells were gated on
CD4+ cells, and the numbers shown represent the percentage
of CD4+ cells that fall into each quadrant. Data shown are
representative of five experiments, with two mice per experiment. For
panel B, the percentages shown each indicate the number of
CD4+ T cells that stained positive for the indicated
cytokine. Data shown for IL-4 are representative of two experiments,
with two individual mice per experiment, and the data shown for IL-5
and IL-10 are from one experiment with two mice.
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|
The expression of intracellular IFN-
and IL-4 was also examined
following LCMV infection of C57BL/6 mice genetically deficient
in
CD8
+ T cells; these mice mount a vigorous LCMV-specific
CD4
+ T-cell response. Figure
3 shows a high frequency of
IFN-
-producing
CD4
+ T cells at day 9 p.i., with no
increase in the frequency of IL-4-producing
CD4
+ T cells.
Thus, there is no significant increase in the frequency
of
IL-4-secreting CD4
+ T cells even in mice that develop a
very strong LCMV-specific
CD4
+ T-cell response.
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FIG. 3.
Intracellular IFN- and IL-4 expression of LCMV
peptide-specific CD4+ T cells from CD8 knockout mice.
Splenocytes from LCMV-infected (day 9) C57BL/6 CD8 knockout mice were
stimulated with one of the two LCMV MHC class II-restricted peptides in
the presence of IL-2 and brefeldin A for 5 h and subsequently
stained as described in the legend to Fig. 1. The percentages shown
each indicate the number of CD4+ T cells that stained
positive for intracellular IFN- or IL-4 as represented by the R1
gate. Data are representative of two experiments, with two mice per
experiment.
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|
Cell surface phenotype of LCMV-specific memory CD4+ T
cells.
In order to analyze the LCMV-specific memory
CD4+ Thp cell phenotype, CD4+ T cells obtained
from LCMV-immune mice were sorted for CD4+ T cells
expressing one of a panel of activation and memory markers (Table
2). We utilized the IL-2-based LDA
(18) to examine the memory CD4+ T-cell
phenotype, as the LDA is able to detect lower frequencies of
virus-specific CD4+ T cells more reliably than the
intracellular cytokine assay presented above is (17). The
virus-specific memory CD4+ Thp cells expressed
predominantly a CD44hi CD45RBlo
CD49dhi CD62Llo CZ-1hi phenotype. A
fairly high frequency of LCMV-specific memory CD4+ Thp
cells were found in both the CD62Llo and
CD62Lhi subsets. CD49d and CZ-1 were two of the best
markers for identifying LCMV-specific CD4+ Thp cells. We
have previously shown CZ-1 to be a CD4+ T-cell activation
and memory marker (16), and expression of CD49d on a high
frequency of Sendai virus-specific memory CD4+ Thp cells
has been reported previously (4).
Intracellular cytokine analysis during persistent LCMV clone 13 infection.
Infection of mice with a high dose of LCMV clone 13 has
been shown to selectively delete the virus-specific CD8+ T
cells by day 7 or 8 p.i. due to the overwhelming virus infection (6). The fate of the virus-specific CD4+ T cells
under these conditions has been less studied. A recent report has
suggested that Th1 cells are more sensitive to activation-induced cell
death than Th2 cells are (21). Therefore, we postulated that
during a high-dose LCMV clone 13 infection there may be a selective
loss of virus-specific CD4+ T cells secreting
Th1-associated cytokines and, if LCMV-specific Th2-like
CD4+ T cells were present, they might be less susceptible
to deletion in an environment with a high viral antigen concentration
and therefore represent a higher proportion of the remaining
virus-specific CD4+ T-cell population. We again utilized
the intracellular cytokine assay to follow the fate of the
IL-4-secreting CD4+ T cells but detected no increase (data
not shown). Figure 4 shows the percentage
of viral peptide-specific IFN-+ CD4+ T cells
present following a high-dose LCMV clone 13 infection. The percentage
of IFN-+ CD4+ T cells never reached the
percentage observed during LCMV Armstrong infection, and the
CD4+ T cells that stained brightest for IFN- in the LCMV
Armstrong-infected mice were absent in the LCMV clone 13-infected
animals (Fig. 4). This may suggest that high-affinity LCMV-specific
CD4+ T cells are rapidly lost following a high-dose LCMV
clone 13 infection. The remaining low-affinity LCMV-specific
CD4+ T cells may then slowly become anergic or unresponsive
due to chronic stimulation by virus-infected antigen-presenting cells (APC), as suggested recently by others (12).
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FIG. 4.
Intracellular IFN- expression of LCMV
peptide-specific CD4+ T cells from LCMV clone 13-infected
C57BL/6 mice. Splenocytes from LCMV Armstrong- or clone 13-infected
mice (both day 10) were stimulated with the LCMV MHC class
II-restricted peptide GP61-80 in the presence of IL-2 and brefeldin A
for 5 h and subsequently stained as described in the legend to
Fig. 1. The percentages shown each indicate the number of
CD4+ T cells that stained positive for intracellular
IFN- as represented by the R1 gate. Data are representative of three
separate experiments, with three mice per experiment.
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|
In this report we demonstrate that the LCMV-induced CD4
+
T-cell response is virtually exclusively a Th1 response associated
with
the production of IL-2, IFN-
, and TNF-
but not IL-4, IL-5,
or
IL-10 (Fig.
1 to
3 and Table
1). During the peak of the acute
LCMV
response, approximately 2% of the CD4
+ T cells make IL-2
following stimulation with either of the two
known LCMV-encoded MHC
class II-restricted peptides (Fig.
1 and
Table
1). Two recent reports
of studies done with the LCMV system
showed that fluorescence-activated
cell sorter (FACS) analysis
following either peptide stimulation
(
19) or anti-CD3 stimulation
(
14) of splenocytes
in the presence of brefeldin A, an inhibitor
of protein transport
between the endoplasmic reticulum and the
Golgi body, failed to detect
IL-2-secreting CD4
+ T cells. Here, we show that using
monensin, an inhibitor of
trans-Golgi
function, allows for
the detection of a high frequency of IL-2-producing
CD4
+ T
cells following viral peptide stimulation. This frequency is
significantly greater than previous estimates by us using LDA
(
18) and others using enzyme-linked immunospot (ELISPOT)
assays
(
19). Multicolor FACS analysis revealed that the
majority of
the CD4
+ T cells that expressed intracellular
IL-2 also synthesized IFN-
(and/or TNF-
) following viral peptide
stimulation (Fig.
2A).
This suggests that the IL-2- and
IFN-
-secreting CD4
+ T cells are not separate populations
of virus-specific CD4
+ T
cells.
Previous studies examining mice infected intracranially with LCMV
revealed the expression of easily detectable IFN-
mRNA
but not IL-4
mRNA in the brain and spleen (
2). More recent
studies from
our laboratory (
17,
18) and others (
5,
11)
have
shown that LCMV-specific CD4
+ T cells make IFN-
but not
IL-4 following stimulation with virus-infected
APC or viral peptides,
using several different techniques, including
LDA, enzyme-linked
immunosorbent assay (ELISA), and ELISPOT assay.
Moreover, analysis of
antibody isotypes produced following acute
LCMV infection has
demonstrated a significant skewing of antibodies
toward the
immunoglobulin G2a isotype (
13,
20), which is promoted
by
IFN-
(
15). All of these results indicate that the
LCMV-specific
CD4
+ T-cell response is predominantly of a
Th1 phenotype. However,
two recent studies have reported elevated
frequencies of CD4
+ T cells secreting IL-4 following LCMV
infection using ELISAs
and ELISPOT assays (
14,
19). We
cannot completely exclude
the possibility that there is a very low
frequency of LCMV-specific
CD4
+ T cells of a Th2 phenotype,
but we could not detect any in this
study. It should be noted that we
have found that the inclusion
of 10% fetal calf serum in the viral
inoculum drives a strong
IL-4 response that is absent if the viral
inoculum is purified
apart from serum, and serum was present in the
inocula in the
two studies showing Th2 responses (
14,
19).
The data presented
here and in another recent report (
5)
clearly establish that
the LCMV-specific CD4
+ T-cell
response is dominated by cells that secrete Th1-associated
cytokines.
| |
ACKNOWLEDGMENTS |
We thank Keith Daniels for his technical assistance and Tammy
Krumpoch and Barbara Fournier for help with the FACS analysis.
This study was supported by Public Health Service Training Grant
AI07439 to Steven M. Varga and Research Grants AI17672, AR35506, and
CA34461 to Raymond M. Welsh.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Pathology, University of Massachusetts Medical Center, Worcester, MA 01655. Phone: (508) 856-5819. Fax: (508) 856-5780. E-mail:
rwelsh{at}bangate.ummed.edu.
Present address: Beirne B. Carter Center for Immunology Research,
University of Virginia Health Sciences Center, Charlottesville, VA 22908.
| |
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Journal of Virology, May 2000, p. 4429-4432, Vol. 74, No. 9
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Haring, J. S., Pewe, L. L., Perlman, S.
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Arbour, N., Naniche, D., Homann, D., Davis, R. J., Flavell, R. A., Oldstone, M. B.A.
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