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Journal of Virology, November 1998, p. 8682-8689, Vol. 72, No. 11
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Human Cytotoxic T-Lymphocyte Repertoire to
Influenza A Viruses
Julie
Jameson,
John
Cruz, and
Francis A.
Ennis*
Center for Infectious Disease and Vaccine
Research, University of Massachusetts Medical Center, Worcester,
Massachusetts 01655
Received 30 April 1998/Accepted 5 August 1998
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ABSTRACT |
The murine CD8+ cytotoxic-T-lymphocyte (CTL) repertoire
appears to be quite limited in response to influenza A viruses.
The CTL responses to influenza A virus in humans were examined to determine if the CTL repertoire is also very limited. Bulk cultures revealed that a number of virus proteins were recognized in CTL assays.
CTL lines were isolated from three donors for detailed study and found
to be specific for epitopes on numerous influenza A viral proteins.
Eight distinct CD8+ CTL lines were isolated from donor 1. The proteins recognized by these cell lines included the nucleoprotein
(NP), matrix protein (M1), nonstructural protein 1 (NS1), polymerases
(PB1 and PB2), and hemagglutinin (HA). Two CD4+ cell lines,
one specific for neuraminidase (NA) and the other specific for M1, were
also characterized. These CTL results were confirmed by
precursor frequency analysis of peptide-specific gamma
interferon-producing cells detected by ELISPOT. The epitopes recognized
by 6 of these 10 cell lines have not been previously described; 8 of
the 10 cell lines were cross-reactive to subtype H1N1, H2N2, and H3N2
viruses, 1 cell line was cross-reactive to subtypes H1N1 and H2N2, and
1 cell line was subtype H1N1 specific. A broad CTL repertoire was
detected in the two other donors, and cell lines specific for the NP,
NA, HA, M1, NS1, and M2 viral proteins were isolated. These
findings indicate that the human memory CTL response to
influenza A virus is broadly directed to epitopes on a wide variety of
proteins, unlike the limited response observed following infection of
mice.
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INTRODUCTION |
Influenza A virus infections and
complications are a major cause of human morbidity and mortality.
Antibody responses to previous infection or vaccination are protective
when the infecting strain is very similar to the vaccinating strain.
However, the hemagglutinin (HA) and neuraminidase (NA) proteins undergo
antigenic shift when these HA and/or NA genes reassort with a virus of
a different subtype, thus evading antibodies (53). HA and NA
can also undergo annual antigenic drift by accruing point mutations
altering antibody binding sites (29, 37). It may be
important for humans to have memory cytotoxic T lymphocytes (CTLs) in
response to internal viral proteins, which are more conserved between
viral subtypes, in view of the highly variable surface glycoproteins HA
and NA on influenza A viruses, which can evade humoral responses.
Virus-specific CTLs have been implicated in clearing influenza A virus
infections in mice and humans (16, 24, 30-32, 34, 48,
54-56). CTLs specific to influenza A virus have been reported to
be either subtype cross-reactive, recognizing targets infected with
subtype H1N1, H2N2, and H3N2 influenza A viruses (24, 58,
59), or subtype specific, recognizing only the infecting subtype
(6, 13). Bulk culture CTL responses specific to internal the
influenza A virus nucleoprotein (NP), polymerases (PB1, PB2, and PA),
and matrix protein (M1) have been reported in mice and humans (2, 3, 16, 42).
The repertoire of CTLs in response to influenza A viruses in inbred
mice has been shown to be limited. It has been reported that there are
low-responder or nonresponder class I alleles for influenza A virus CTL
responses (3). Several murine class I alleles could
not present epitopes to activate T cells on a number of viral
proteins. The recognition of a viral protein by a major histocompatibility complex (MHC) allele was commonly found to be
limited to immunodominant epitopes on one or two viral proteins (50, 52). In humans and mice, the CTL responses detected in bulk culture have been reported to be directed primarily at the NP
(36, 49, 57). In a study of six human donors' peripheral blood mononuclear cells (PBMC) tested for cytotoxicity in bulk cultures
stimulated by influenza A virus, all six recognized the NP, four
recognized PB2, all six recognized M1, one recognized M2, and there was
no recognition of the other viral proteins (16). It is
important to define influenza viral protein and epitope recognition at
the clonal level to determine if the human CTL response is restricted
to a small number of proteins, as in the mouse system, or extends to a
larger number of proteins and epitopes. Therefore, we analyzed in some
detail the memory CTL repertoire in the PBMC of three human donors and
found a very broad CTL response at the clonal level to epitopes on a
wide variety of proteins.
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MATERIALS AND METHODS |
Viruses.
Influenza A viruses A/Puerto Rico/8/34 (H1N1) and
A/Japan/305/57 (H2N2) were kindly provided by the Division of Virology, Bureau of Biologics, Food and Drug Administration, Bethesda, Md. A/Johannesburg/94 (H3N2) was kindly provided by David Burt (Pasteur Merieux Connaught, Toronto, Ontario, Canada). Influenza A viruses were
propagated in 10-day-old, embryonated chicken eggs. Infected allantoic
fluids were harvested 2 days after infection, aliquoted, and stored at
80°C until use. Recombinant vaccinia viruses containing the genes
coding for influenza A viral proteins HA, NA, M1, M2, PB1, PB2, PA,
NS1, and NS2 and the nucleoprotein (NP) were kindly provided by B. Moss. They are all derived from the A/PR/8/34 influenza A virus strain,
except for NS1, which is derived from A/Udorn/72. They were constructed
and propagated as previously described (45). A recombinant
vaccinia virus which expressed segmented portions of the NP was kindly
provided by J. Bennink and L. Eisenlohr.
Human PBMC.
PBMC specimens were obtained from normal,
healthy donors. Most of the donors whose PBMC were tested had
convincing evidence of influenza A virus-specific CTL activity in bulk
culture. We concentrated our efforts on the PBMC of three donors from
whom we were able to obtain repeat samples. PBMC were purified by
Ficoll-Hypaque density gradient centrifugation (5). Cells
were resuspended at 2 × 107/ml in RPMI 1640 with 20%
fetal bovine serum (FBS) (Sigma) and 10% dimethyl sulfoxide and
cryopreserved until use. The HLA alleles of donor 1 were A2.1, A11,
B18, B27, Cw1, Cw7, DR1, DQw1, DQw3, DRw52, and DRw53; those of donor 2 were A2, A24, B7, B62, Cw3, DP2, DR1, DR2, DQw5, and DQw6; and those of
donor 3 were A1, B8, B44, Cw5, DR2, DR3, DQw1, DQw2, and DRw52. HLA
typing was performed in the HLA typing laboratory at the University of
Massachusetts Medical Center.
Bulk cultures of PBMC.
Responder PBMC were suspended
at 106/ml in AIM-V medium (Gibco BRL, Grand Island, N.Y.)
containing 10% human AB serum (NABI, Boca Raton, Fla.),
penicillin-streptomycin, glutamine, and HEPES in a 70-ml flask
(Falcon). Stimulators were infected with A/PR/8/34 at a multiplicity of
infection (MOI) of 15 for 1.5 h at 37°C in 1 ml of
phosphate-buffered saline containing 0.1% bovine serum albumin and
then added to responders in a flask at a stimulator-responder ratio of
1:10. On day 7 of culture, cells were either cloned by limiting
dilution as described below or restimulated with gamma-irradiated (3,000 rads) autologous PBMC infected with A/PR/8/34 at an MOI of 15 for 1.5 h in 1 ml of phosphate-buffered saline containing 0.1%
bovine serum albumin, added at a stimulator-responder ratio of 1:10 in
fresh medium containing 10% human AB serum and 20 U of interleukin-2
(IL-2) (Collaborative Biomedical Products, Bedford, Mass.).
Restimulated cells were either cloned by limiting dilution or assayed
for cytolytic activity 7 days later.
CTL clones.
Influenza virus-specific CTL clones were
established by using a limiting-dilution technique as previously
described (22). PBMC which had been stimulated in bulk
culture for 7 or 14 days were collected and plated at a concentration
of 3, 10, or 30 cells per well in 96-well round-bottom microtiter
plates in 100 µl of AIM-V medium containing 10% FBS, 20 U of IL-2, a
1:1,000 dilution of anti-CD3 monoclonal antibody 12F6 (kindly provided
by Johnson Wong), and 105 gamma-irradiated allogeneic
PBMC/well. On day 7, 50 µl of fresh medium with FBS (Sigma
Immunochemicals, St. Louis, Mo.) and IL-2 were added, and on day 14, fresh medium with 105 gamma-irradiated allogeneic PBMC/well
and a 1:1,000 dilution of the anti-CD3 monoclonal antibody were added.
Growing cells were assayed for cytolytic activity on days 21 and 28. Cells from wells with influenza A virus-specific cytolytic activity
were expanded to 48-well plates.
Preparation of target cells.
Autologous lymphoblastoid cell
lines (BLCL) were established by culturing with Epstein-Barr virus in
24-well plates as previously described (18). BLCL were
infected with recombinant vaccinia viruses at an MOI of 20:1 for
1.5 h at 37°C. The cells were then diluted in 1 ml of medium and
further incubated for 12 to 16 h. Other BLCL were infected with
A/PR/8/34, A/Japan/305/57, or A/Johannesburg/94 in 1 ml of medium
for 12 to 16 h. These infected target cells were labeled with 0.25 mCi of 51Cr for 60 min at 37°C. After four washes, the
target cells were counted and diluted to 2 × 104/ml
for use in the cytotoxicity assay. The partially HLA-matched allogeneic
target cells used in the assays were BLCL produced in our laboratory
from the HLA-typed PBMC of unrelated donors or were obtained from the
National Institute of General Medical Sciences Human Genetic Mutant
Cell Repository or the American Society for Histocompatibility and
Immunogenetics Cell Bank and Repository.
Cytotoxicity assays.
Cytotoxicity assays were performed with
96-well round-bottom plates as previously reported (9).
Briefly, effector cells in 100 µl of RPMI 1640 medium containing 10%
FBS were added to 2 × 103 51Cr-labeled
target cells in 100 µl at an effector-to-target (E-T) ratio of 10:1.
In cytotoxicity assays using synthetic peptides, peptides were added to
target cells at the indicated concentrations and incubated at 37°C
for 30 min, after which the effector cells were added. Several of the
M2, NS1, and NP peptides were kindly provided by Arthur Pedzcak and
Pele Chong (Pasteur Merieux Connaught), and all other peptides were
synthesized at the Core Protein Chemistry Facility directed by R. Carraway (University of Massachusetts Medical Center, Worcester).
Plates were centrifuged at 200 × g for 5 min and
incubated for 4 to 5 h at 37°C. Supernatant fluids were
harvested by using the supernatant collection system (Skatron Instruments, Sterling, Va.), and 51Cr content was measured
in a gamma counter. Percent specific 51Cr release was
calculated with the following formula: (cpm experimental release cpm spontaneous release)/(cpm maximum release cpm spontaneous release) × 100. All assays were performed in triplicate, and the results were calculated from the average of the triplicate wells.
Single-cell ELISPOT assay for IFN-
-secreting cells.
The
ELISPOT assay was done as previously described (26).
Briefly, 96-well filtration plates (Millipore, Bedford, Mass.) were
coated with mouse anti-human gamma interferon (IFN-) antibody (clone
NIB42; Pharmingen, San Diego, Calif.). Cryopreserved PBMC were thawed,
washed, and added to the plates at 5 × 105 per well
in RPMI 1640 medium supplemented with 10% FBS,
penicillin-streptomycin, glutamine, and HEPES. Cells were incubated for
up to 15 h with or without peptide stimulation (10 µg of
peptide/ml). The plates were washed and then incubated with
biotinylated mouse anti-human IFN- antibody (clone 4S.B3;
Pharmingen). Spots were developed by using fresh substrate buffer
(0.3-mg/ml 3-amino-9-ethylcarbazole and 0.015%
H2O2 in 0.1 M sodium acetate [pH 5]). The
precursor frequency of peptide-specific CTLs was calculated based on
the number of spots counted out of the number of cells added to the wells.
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RESULTS |
Donor 1 PBMC in bulk culture exhibit influenza A virus
subtype-cross-reactive lysis directed at multiple viral proteins.
The PBMC from donor 1 were stimulated on days 0 and 7 with A/PR/8/34
(H1N1)-infected autologous stimulators and tested on day 14 against
autologous BLCL infected with influenza A virus strains of each of the
three subtypes (H1N1, H2N2, and H3N2). Uninfected BLCL were used as a
negative control. The effector cells generated from the PBMC of donor 1 lysed targets infected with each of the influenza A virus strains to a
higher degree than control uninfected targets (Fig.
1A).
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FIG. 1.
(A) Influenza A virus subtype-cross-reactive lysis in
bulk culture (donor 1). PBMC were stimulated with A/PR/8/34 virus in
vitro on days 0 and 7 and tested on day 14 at an E-T ratio of 60:1. (B)
Recognition of influenza A virus proteins in a bulk culture CTL assay
(donor 1). The same bulk culture was tested for specific lysis of
influenza viral proteins expressed in vaccinia virus (Vac.) constructs
infected in BLCL at an E-T ratio of 60:1. Lysis of targets infected
with wild-type vaccinia virus was subtracted from lysis of recombinant
vaccinia virus-infected targets.
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Recombinant vaccinia viruses were used to express various influenza A
virus proteins in target cells tested with the same
bulk culture. The
highest level of influenza A virus-specific
lysis was observed on
NP-expressing target cells. Low levels of
specific lysis were also seen
on targets expressing PB1, HA, M1,
and PB2 (Fig.
1B). In some
experiments, low lysis of NA-expressing
target cells was observed (data
not shown).
Isolation of influenza A virus-specific CTL lines from donor
1.
This bulk culture of influenza A virus-specific CTLs and
subsequently two others from this donor were cloned by limiting
dilution, and wells positive for growth were screened for lysis of
influenza A virus-infected targets. All of the CTL lines were stained
for CD4 or CD8 by fluorescent antibodies (data not shown). Ten CTL lines generated from the PBMC of donor 1 were tested for lysis of
targets infected with the recombinant vaccinia viruses and influenza A
virus (A/PR/8/34, H1N1). The results obtained with 6 of the 10 lines
are presented in Table 1. These CTL lines
have novel, previously unreported specificities. The other four cell lines characterized from this donor recognize epitopes that have been
previously reported and are summarized below.
Each of the T-cell lines characterized was specific for one influenza A
virus protein (Table
1). These cell lines and those
with previously
reported specificities recognized the NP, PB2,
M1, HA, PB1, NS1, and
NA, making a total of seven different influenza
A virus proteins
recognized by the memory T lymphocytes of donor
1. These data indicate
that the CTL responses of this donor to
influenza virus are directed
against a broad range of viral proteins
and include both
CD4
+ and CD8
+ components.
CTLs from donor 1 were HLA restricted.
MHC restriction was
assayed by using partially HLA-matched allogeneic BLCL as targets for
CTL lysis. Targets were infected with the recombinant vaccinia virus
that had resulted in significant target cell lysis or with wild-type
vaccinia virus as a negative control. Alternatively, partially
HLA-matched target cells were pulsed with a peptide that contained the
CTL epitope. The results in Fig. 2A show
that targets pulsed with NP peptide containing amino acids (aa) 173 to
193 are lysed by bulk culture effectors if they share HLA B27. Cell
line 10-1C4 was subsequently found to lyse only target cells with B27
in common when pulsed with the same NP peptide, and it is therefore
also B27 restricted (data not shown). Cell lines 10-1B7 and 1-2F8 are
also able to lyse only targets which share B27 and are therefore B27
restricted (Fig. 2B and C). Cell line 4-30E11 is either A11, Cw7, or
Cw1 restricted, because it does not lyse targets expressing A2, B27, and B18 (Fig. 2D). This cell line ceased growing and could not be
tested further. HA-specific cell line 10-1G5 is B18 restricted because
it lyses targets which have only B18 in common (Fig. 2E). We also
tested CD4+ T-cell line 4-10D9-1, which is DR1 restricted
(data not shown) and another four T-cell lines which recognized
previously reported epitopes and were found to be restricted by HLA
A2.1, B27, and DR1 (data not shown) (17, 20, 33, 44). The
results shown in Fig. 2 are a representation of the experiments
done to confirm MHC restriction of the CTL lines. MHC restriction
of each cell line was confirmed in multiple experiments using different
allogeneic targets. A2.1-restricted lines were confirmed by lysis of
infected Hmy C1R A2.1-transfected targets. These results indicate that at least four different class I HLA alleles (A2.1, B18, B27, and A11,
Cw1, or Cw7) and one class II (DR1) HLA allele restrict the CTL lines
isolated from donor 1, and there does not seem to be one influenza A
virus-specific dominant HLA allele.
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FIG. 2.
MHC restriction of cell lines determined by using panels
of partially HLA-matched allogeneic targets infected with vaccinia
virus recombinants expressing either an influenza virus protein or a
specific peptide. Lysis of targets infected with wild-type vaccinia
virus was subtracted from lysis of recombinant vaccinia virus-infected
targets. (A) Bulk culture cells tested against targets loaded with the
NP aa 174 to 184 peptide. (B) Cell line 10-1B7 tested against vaccinia
virus PB2-infected targets. (C) Cell line 1-2F8 tested against vaccinia
virus PB1-infected targets. (D) Cell line 4-30E11 tested against
vaccinia virus M1-infected targets. (E) Cell line 10-1G5 tested against
vaccinia virus HA-infected targets. The E-T ratio was 10:1, except for
panel A, for which the E-T ratio was 30:1.
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T-cell epitope mapping.
Recombinant vaccinia viruses were used
that contain overlapping amino acid regions of the NP gene (aa 1 to
168, 147 to 315, and 296 to 498) to localize the epitope recognized by
NP-specific cell line 10-1C4. This cell line lysed targets infected
with the construct expressing NP aa 147 to 315. We synthesized 20-mer
peptides that spanned aa 147 to 315, and this cell line lysed targets
pulsed with a peptide containing aa 173 to 193. Target cells pulsed
with this peptide were also recognized by effector cells in a 7-day bulk culture from this donor (data not shown). Finer mapping with synthetic peptides indicated that the optimal epitope is contained within aa 174 to 184 (Fig. 3A and
4A). Precursor frequency analysis by
ELISPOT single-cell IFN- secretion indicated that this CTL epitope
is recognized by 1 in 4,156 donor 1 PBMC (Table
2).
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FIG. 3.
Mapping of CTL epitopes by using peptides. The epitopes
recognized by cell line 10-1C4 from donor 1 (A), 3E5 from donor 2 (B),
and 124 (C) and 77 (D) from donor 3 were mapped by using peptide-pulsed
BLCL targets at a concentration of 25 µg/ml. The E-T ratios were 10:1
(A and B), 7.5:1 (C), and 15:1 (D).
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FIG. 4.
Dose response of peptide-pulsed target cell lysis. Cell
line 10-1C4 from donor 1 (A), 3E5 from donor 2 (B), and 124 (C) and 77 (D) from donor 3 recognized target cells pulsed with various peptide
concentrations. The E-T ratios were 10:1 (A and B) and 15:1 (C and
D).
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Peptides containing epitopes that were previously reported were
synthesized and tested for recognition by these CTL lines
if they
shared MHC restriction and viral protein specificities
with the cell
lines we isolated. Cell line 10-2C2 lysed targets
pulsed with a peptide
representing aa 122 to 130 of NS1, line
1-7-K lysed targets pulsed with
peptide aa 58 to 66 of M1, line
1-3 lysed targets pulsed with peptide
aa 17 to 31 of M1, and line
1-1 lysed targets pulsed with peptide aa
383 to 391 of NP. Precursor
analysis of these epitopes in this donor's
PBMC confirmed that
these are not rare CTLs generated by the cloning
process (Table
2).
Donors 2 and 3 also have broad CTL repertoires for influenza A
viral proteins.
After finding a broad repertoire of CTL responses
to influenza A virus in donor 1, we wanted to analyze the PBMC of other donors in a limited way to determine if they also had broad CTL responses. Bulk culture CTL assay results obtained by using PBMC from
donor 2 revealed a similar pattern of influenza A virus-specific lysis
with higher lysis of the NP and a lower level of NS1-specific lysis
(data not shown). A bulk culture was cloned to identify protein
recognition at the clonal level. After one limiting dilution, five
different cell lines were shown to have specific lytic activity against
four different viral proteins (HA, NP, NA, and M1). Three CD4+ lines and two CD8+ lines were
characterized (Table 3). There were two
NP-specific cell lines, CD8+ 3G11 and CD4+ 3E5.
By using recombinant vaccinia viruses expressing the segmented NP, 3G11
lysed targets infected with vaccinia virus NP aa 296 to 498, and 3E5
lysed targets infected with vaccinia virus NP aa 147 to 315. Fine
epitope mapping using synthetic peptides demonstrated that cell line
3E5 recognizes NP aa 256 to 265 at 0.25 mg/ml (Fig. 3B and 4B). Both
cell lines 3F4 and 3G11 were found to be B62 restricted (data not
shown) by lysis of partially HLA-matched targets as described for donor
1. The restricting alleles of the three CD4+ CTL lines were
not determined because of failure to lyse available partially matched
BLCL targets.
PBMC from donor 3 were also tested in a single bulk culture CTL assay,
and specific NP, NS1, and M2 recognition was seen (data
not shown).
This bulk culture was cloned, and two influenza virus-specific
cell
lines were established. Cell line 124 is CD8
+ and
recognizes M2, while cell line 77 is CD4
+ and
recognizes NS1 (Table
3). Synthetic peptides were used to
identify the epitopes. Cell line 124 recognized aa 7 to 15 of
M2 (Fig.
3C and
4C), while cell line 77 recognized aa 34 to 42
(Fig.
3D and
4D).
HLA restriction analysis was performed by using
allogeneic partially
HLA-matched cell lines as done with the two
previous donors; CTL line
124 is restricted by B44, and CTL line
77 is restricted by DR3 (data
not shown).
Subtype cross-reactivity of CTLs isolated from all donors.
It
has been previously shown that influenza virus-specific memory
CTL in mice are either subtype specific or cross-reactive (6,
13, 24, 58, 59). After stimulating PBMC with A/PR/8/34 (H1N1), we infected targets with viral strains of the three
different subtypes (H1N1, H2N2, and H3N2) to analyze the
subtype-cross-reactive nature of these T-cell lines. In all donors,
most of the cell lines that had specificities to internal viral
proteins (10-1C4, 10-1B7, 4-30E11, 1-2F8, 3G11, 10E7, 77, and 3E5) were
H1N1, H2N2, and H3N2 subtype cross-reactive (Table
4). Cell lines with specificity to the
external glycoproteins (10-1G5, 4-10D9-1, 3F4, and 3E9) were either
H1N1 and H2N2 subtype cross-reactive or H1N1 subtype specific. In donor
1, HA-specific cell line 10-1G5 demonstrated H1N1- and
H2N2-cross-reactive killing (Table 4). Cell line 124 is unique in
that it is specific for conserved internal protein M2 and is H1N1
and H2N2 but not H3N2 cross-reactive. These results indicate
that these donors have both subtype-specific and cross-reactive CTLs.
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TABLE 4.
Subtype-cross-reactive and -specific recognition by
influenza virus-specific CTLs from donors 1, 2, and 3
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DISCUSSION |
In this study, we analyzed the influenza virus-specific T-cell
repertoire of three healthy adults. These individuals had bulk CTL
responses to multiple influenza A virus proteins. Previous reports
identified the NP, M1, and PB2 proteins as targets for human influenza
A virus-specific CTLs in bulk culture (16). The NP was
recognized by the T cells of all donors, but PB1- and HA-expressing
targets were also lysed by the bulk culture T cells of donor 1, and
NS1-expressing target cells were also lysed by donor 2 and 3 T cells in
bulk culture. In view of the fact that influenza A virus-stimulated
bulk cultures recognized multiple influenza A virus proteins, we
decided to define CTL epitopes at the clonal level. Previously, a
narrow CTL response to influenza A virus had been reported in mice
(3, 41, 52). For example, targets infected with a vaccinia
virus expressing the NP were lysed by bulk culture T cells from
virus-immune mice with the Kk or
Kd allele but not by the T cells of mice with
the Dk, Dd, or
Ld allele. Moreover, targets infected with a
vaccinia virus expressing PB2 were lysed by T cells only from mice with
the Dd allele (3). Some
nonimmunodominant epitopes have been reported in the
H-2b mouse. They were derived by multiple
peptide immunizations and were not detected in mice after infection
with virus (39, 40).
Human CTLs that recognize influenza A virus-infected targets have been
described, but most reports have focused on a single HLA allele, and
T-cell lines were not usually isolated from the same donor (11,
12, 17, 20, 33, 35, 47). There has been a report of CTLs that
recognize multiple NP epitopes on influenza B virus in one human
(43), but limited information is available on influenza A
virus-specific human T-cell epitopes. CD8+ clones specific
to the NP (11, 12, 20, 35, 47), M1 (17), PB1
(12), and NS1 (33) have been characterized, and CD4+ clones specific to HA (8, 27), the NP
(10), NA (46), and M1 (44) have
been identified. Human CTL epitopes have also been mapped on multiple
proteins in human immunodeficiency virus type 1 infection.
However, most of those CTL epitopes were also mapped in
different individuals (21). Human immunodeficiency virus
infection is persistent and may induce a different pattern of CTL
responses than an acute self-limited infection with influenza A virus.
Many influenza A virus-specific T-cell lines were isolated from these
three donors, and some were characterized in more detail. In donor 1, of the 10 lines characterized, seven different viral proteins were
recognized: NP, NS1, HA, PB1, PB2, M1, and NA. These results reflect a
broad pattern of T-cell recognition of epitopes on multiple influenza
virus proteins. A larger number of cell lines isolated from this donor
were not studied in detail but also reflected this very broad CD8/CD4
CTL recognition of multiple influenza A virus proteins (data not
shown). To our knowledge, this is the first report of human
CD8+ CTL clones that recognize epitopes on the PB2 and HA
proteins of influenza A virus. From donor 2, five cell lines were found to be specific for four different viral proteins: HA, the NP, NA, and
M1 (Table 3). Two cell lines from the PBMC of donor 3 were specific for
two different proteins, NS1 and M2 (Table 3). This is the first
characterization of a human CD8+ CTL line specific for an
epitope on M2 and a CD4+ CTL line specific for NS1. Both
CD8+ and CD4+ CTL lines were isolated from each
of the donors. Our results suggest that humans have memory CTLs that
respond to multiple epitopes on several viral proteins and that there
is no single immunodominant epitope, as reported in the murine system
for influenza and other viral diseases (19, 51, 52). Due to
the antigenic variation of influenza A virus strains, it may be
beneficial for a human host to develop a polyclonal response to ensure
the ability to clear influenza virus-infected cells despite mutations
in the surface glycoproteins.
The cell lines from donor 1 were restricted by several different HLA
alleles, including A2.1, B27, B18, and DR1 (Fig. 2). Donor 2 had cell
lines restricted by B62 and a class II allele, while donor 3 had cell
lines restricted by B44 and DR3. HLA alleles were found to present
multiple epitopes on more than one viral protein, e.g., HLA
B27-restricted epitopes on PB1, PB2, and the NP in donor 1. HLA A2.1
molecules presented peptides in both M1 and NS1. Similarly, in donor 2, B62 molecules presented epitopes on the NP and HA.
To verify that the cell lines we isolated were not rare, precursor
frequency analysis was determined by using ELISPOT single-cell IFN-
secretion to detect peptide-specific CTLs. Other groups have used this
method to detect influenza virus-specific precursor CTLs in humans
(26) and lymphocytic choriomeningitis virus (LCMV)-specific precursor CTLs in mice (38). In donor 1, the most precursor CTLs were directed at NP aa 174 to 184, with a frequency of 1 in 4,156. However, M1 aa 58 to 66, M1 aa 17 to 31, and NP aa 383 to 391 had
precursor frequencies of 1 in 31,250, 1 in 26,316, and 1 in 16,447 respectively, indicating that they are also not rare CTLs (Table 2).
Subtype-cross-reactive and subtype-specific CD8+
CTLs have been isolated from mice (4, 7, 25), and
subtype-cross-reactive CD8+ CTLs have been isolated from
humans (35). In humans, subtype-cross-reactive and
subtype-specific lymphocyte proliferation was previously reported (28). The CTL lines we characterized from our three donors
were usually H1N1, H2N2, and H3N2 subtype cross-reactive if they
recognized epitopes on relatively conserved internal viral proteins,
such as the NP, NS1, PB1, PB2, and M1 (Table 4). These results are consistent with the fact that internal proteins are more conserved than
HA and NA. Memory CTLs to internal conserved viral proteins may be
protective when a different subtype of influenza A virus infects. Cell
lines were also found that were either H1N1 and H2N2 subtype
cross-reactive or H1N1 subtype specific if the CTL line recognized
epitopes on the outer, more variable glycoproteins HA and NA (Table 4).
Hemagglutinins H1 and H2 are much closer in homology than H1 and H3. An
H1-H2-cross-reactive CD8+ epitope on the HA transmembrane
has been reported in H-2d mice (24).
A previous report identified human CD4+ T-lymphocyte clones
that proliferated in response to HA, NA, M1, and NP (28),
and CD4+ HA and NA subtype-specific CTLs have been
identified (46), but to our knowledge, this is the first
report of HA subtype-specific human CD8+ CTLs.
We isolated and defined six CD4+ CTL lines. The role of
CD4+ CTLs in virus infections, including influenza, is not
as well defined as is the role of CD8+ CTLs in the
clearance of infection. 
2-Microglobulin-deficient mice
have delayed viral clearance and increased mortality after a virulent
influenza A virus infection (1). However, these mice can
survive infection with a less virulent influenza A virus and can
eliminate virus from the respiratory tract, whereas infection of nude
mice or mice treated with antibodies to both CD4 and CD8 leads to death
(14). These results suggest that CD4+ CTLs may
play a role in viral clearance that is detectable in the absence of a
CD8+ CTL response.
It is assumed that healthy adults may have had more than one exposure
to influenza A virus because primary influenza A virus infections occur
in early childhood (15). These primary natural infections in
a nonimmune host result in extensive virus replication and would be
expected to stimulate the influenza A virus-specific precursor CTL
repertoire. Most of the CTLs we isolated recognize epitopes on highly
conserved proteins and should be boosted by subsequent influenza A
virus infections.
It is interesting that several novel T-cell epitopes could be defined
by using PBMC of three donors. For example, cell line 10-1C4 of donor 1 recognizes NP aa 174 to 184, line 3E5 of donor 2 is specific to NP aa
256 to 266, line 77 of donor 3 recognizes NS1 aa 34 to 42, and CTL line
124 of donor 3 recognizes M2 aa 7 to 15. The broad CTL repertoire we
have described may benefit humans, who are the natural host for these
highly antigenically variable viruses. In addition to providing new
information on the broad human repertoire of memory CTLs to influenza A
viruses, the results suggest that many of the influenza virus
structural and nonstructural proteins contain epitopes that may be
useful to consider in vaccine development. It would be desirable to
augment cross-reactive memory CTLs to provide a second line of defense against influenza disease, especially where major antigenic
variation occurs at the antibody binding sites in the HA
(23). These results suggest that humans have a broad
repertoire of CTLs in response to influenza A virus.
| |
ACKNOWLEDGMENTS |
This work was supported partially by the NIAID, National
Institutes of Health (AI 07349), and by Pasteur Merieux Connaught, Toronto, Ontario, Canada.
We thank Jack Bennink and Laurence Eisenlohr for providing the
segmented NP recombinant vaccinia virus constructs, Bernard Moss for
providing the other recombinant vaccinia virus constructs containing
influenza A virus genes, and Alan Rothman for critically reading the
manuscript. We thank Arthur Pedzcak, Pasteur Merieux Connaught, for
providing NP, NS1, and M2 peptides.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Center for
Infectious Disease and Vaccine Research, University of Massachusetts
Medical Center, 55 Lake Ave. North, Worcester, MA 01655. Phone: (508) 856-4182. Fax: (508) 856-4890.
| |
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Abstract
Introduction
