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Previous Article | Next Article 
Journal of Virology, February 2001, p. 1229-1235, Vol. 75, No. 3
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.3.1229-1235.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Detection of Diverse Hepatitis C Virus (HCV)-Specific Cytotoxic T
Lymphocytes in Peripheral Blood of Infected Persons by Screening
for Responses to All Translated Proteins of HCV
David K. H.
Wong,1
Darryll D.
Dudley,1
Paul B.
Dohrenwend,1
Georg M.
Lauer,1
Raymond T.
Chung,2
David L.
Thomas,3 and
Bruce D.
Walker1,*
Partners AIDS Research Center, Infectious
Disease Division,1 and Gastrointestinal
Unit,2 Massachusetts General Hospital and
Harvard Medical School, Boston, Massachusetts, and Johns
Hopkins School of Medicine, Baltimore, Maryland3
Received 21 July 2000/Accepted 3 November 2000
 |
ABSTRACT |
Broadly directed hepatitis C virus (HCV)-specific cytotoxic T
lymphocytes (CTL) have been identified from liver-infiltrating lymphocytes but have been more difficult to assess in peripheral blood
of infected persons. To enhance the detection of CTL from peripheral
blood mononuclear cells (PBMC), we cocultured PBMC with autologous
Epstein-Barr virus-transformed B-lymphoblastoid cell lines that had
been infected with recombinant vaccinia virus constructs so that
they expressed the entire translated polyprotein of HCV-H, a type 1a
strain. These stimulated cells from HCV-infected as well as
exposed seronegative persons were then cloned at limiting dilution and
tested for HCV-specific CTL activity using a standard 51Cr
release assay. HCV-specific CTL were detected in PBMC from seven
of nine persons with chronic hepatitis, including five of seven in whom
CTL had previously been detected from liver biopsy specimens but not
PBMC. In a single person with chronic HCV infection, CTL
directed against as many as five different epitopes were detected in
peripheral blood and were similar in specificity to those detected in
liver tissue. This technique was used to evaluate eight subjects identified to be at high risk for HCV exposure due to continued injection drug abuse; no evidence of CTL in PBMC was found. We conclude
that CTL can be detected in PBMC from the majority of persons with
chronic HCV infection but are present at lower levels or absent in
exposed but persistently seronegative persons. The high degree
of concordance of HCV epitopes identified from liver and PBMC
suggests that this strategy is a reasonable alternative to liver
biopsy for characterizing the CTL response to HCV in chronically
infected persons.
| |
INTRODUCTION |
Cytotoxic T lymphocytes (CTL)
potentially play a major role in the pathogenesis of chronic viral
infections because they are capable of recognizing virus-infected cells
(18, 29, 37) and responding either directly, by lysis of
the infected cell, or indirectly, by secreting cytokines that inhibit
viral replication and/or recruit other nonspecific inflammatory cells
(9, 10, 40). In acute hepatitis C virus (HCV) infection, a
strong virus-specific CTL response seems to be associated with
spontaneous viral clearance (6, 8, 24), whereas in chronic
infection, the role of CTL is still under debate. CTL studies of
HCV-infected persons have been hampered by the relatively low frequency
of specific cells in the peripheral blood and by the fact that the
targeted epitopes vary depending on the HLA type of the individual. The majority of studies of HCV-specific CTL in peripheral blood have been
based on testing predicted epitopes, and most have focused on HLA
A2-positive persons (2, 4, 8, 23, 27, 28).
In subjects with chronic HCV infection, HCV-specific CTL responses
presented by A2 and non-A2 alleles have been detected from liver-derived lymphocytes that have been polyclonally expanded using a
CD3-specific monoclonal antibody (19-21, 26, 39). The CTL
responses defined in this manner are presumed to reflect in vivo-determined specificities. However, liver-derived lymphocytes are
not easily studied. The risks and discomforts of liver biopsy make it
difficult to study subjects frequently in a longitudinal fashion or to
study subjects with mild or acute disease for whom liver biopsies are
not clinically indicated.
Peripheral blood-derived lymphocytes are easier to obtain than liver
tissue, but previous attempts to detect HCV-specific CTL activity
from peripheral blood mononuclear cells (PBMC) stimulated with
anti-CD3 have been unsuccessful (21). This finding is
consistent with the hypothesis that HCV-specific responses are
compartmentalized to the liver and are present in PBMC in much lower
frequencies. Other groups have detected CTL from PBMC that had been
stimulated in an antigen-specific manner using synthetic HCV peptides,
but these studies have been largely limited to detection of known or
predicted class I-restricted epitopes (2, 4, 12, 15, 16, 23, 28,
32, 33). CTL responses identified in this manner do not allow
detection of responses restricted by many class I alleles for which
epitope predictions are not available or those that are missed by the
prediction algorithms. Furthermore, some HCV peptides have been
reported to induce CTL responses in HCV-seronegative subjects, raising
the possibility that some of these responses may be due to primary in
vitro sensitization (3, 22).
An alternative approach to antigen-specific stimulation has been
described for detecting virus-specific CTL (14, 25). Recombinant vaccinia virus vectors can be used to introduce antigens into B-lymphoblastoid cell lines for processing through the class I
pathway. After inactivation of the vaccinia virus by psoralen and
long-wave UV irradiation, the cells are used to stimulate PBMC. This
system has the advantage of having all potential CTL epitopes presented
in the context of all the autologous HLA class I alleles.
In this study, we used a vaccinia virus system to express the entire
translated polyprotein of HCV-H (a type 1a strain) in autologous
B-lymphoblastoid cell lines (B-LCL) and then used these cells to
stimulate the PBMC (13). Using this method, we have evaluated CTL responses from cryopreserved PBMC from subjects who had
chronic HCV infection and who were previously assessed for the presence
of liver-derived CTL (19-21, 39). In addition, we have
used this technique to examine a cohort of injection drug users who
remain HCV seronegative despite continued high-risk behavior (34,
35) to determine whether HCV-specific CTL may be detectable in
PBMC. Our results indicate that HCV-specific CTL can be detected in
PBMC in the majority of persons with chronic HCV infection but not, by
this method, in persons who are repeatedly exposed but remain seronegative.
| |
MATERIALS AND METHODS |
Patient samples.
Cryopreserved PBMC from subjects previously
studied for liver-derived HCV-specific CTL were examined
(19-22). PBMC were also obtained from an additional 10 subjects selected from a cohort of injection drug users (34,
36). Eight of these individuals were chosen because they
remained HCV seronegative for over 1 year of follow-up despite
injection drug use patterns associated with the highest risks for HCV
transmission (34). The other two subjects had developed
chronic HCV infection, as determined by being repeatedly positive for
anti-HCV antibodies and HCV RNA.
PBMC were isolated from venous blood by Ficoll-Hypaque density
centrifugation. B-LCL were established through Epstein-Barr virus (EBV)
transformation and maintained as previously described in RPMI 1640 medium (Sigma Chemical Co., St. Louis, Mo.) supplemented with 10 mM
HEPES buffer, 2 mM L-glutamine plus 50 U of penicillin and
50 µg of streptomycin per ml along with 20% heat-inactivated fetal
calf serum (R-20 medium). HLA typing was performed on additional samples of venous blood by the Massachusetts General Hospital Tissue
Typing Laboratory, using standard serologic techniques. Sera and
plasma, as well as the remaining PBMC, were stored at 
80°C.
Informed consent was obtained from all subjects, and the study was
approved by the Massachusetts General Hospital Internal Review Board.
Stimulation of PBMC in bulk cultures.
Lymphocytes
(106 cells) from PBMC were polyclonally expanded in an
antigen-nonspecific manner with the CD3-specific monoclonal antibody
12F6 (0.1 µg/ml) and 20 × 106 irradiated (30 Gy)
allogeneic PBMC feeder cells in 20 ml of R-10 medium. On day 3, recombinant interleukin-2 (rIL-2) was added to achieve a final
concentration of 50 U/ml.
Lymphocytes were also expanded in an antigen-specific manner, using a
protocol modified from Lubaki et al. (25). Stimulator cells that present all potential HCV antigens in the context of the
autologous HLA alleles were prepared by infecting autologous B-LCL
(8 × 106 cells) with the vaccinia virus-HCV (vv-HCV)
recombinant viruses (see below) vv1-966(H1) and vv827-3011(H2) at a
multiplicity of infection of 5 to 10 for 18 h. The vaccinia
viruses were then inactivated by resuspending the stimulator cells in 5 ml of a 10-µg/ml psoralen solution
(4'-aminomethyl-4',5'-8-trimethylpsoralen hydrochloride; HRI
Associates, Concord, Calif.) and then exposing the cells to long-wave
UV light (8-W bulb, 350- to 400-nm light; Fisher Scientific) for 5 min.
PBMC (4 × 106 to 6 × 106 cells)
were stimulated with the stimulator B-LCL (4 × 106
cells) and allogeneic irradiated (30 Gy) PBMC feeder cells (20 × 106) in 20 ml of R-10 medium and incubated at 37°C with
5% CO2. rIL-2 (50 U/ml) was added on day 3. Bulk expanded
cells were tested for CTL recognition of vv1-966(H1) and vv827-3011(H2)
on day 14.
PBMC cloning.
Clones were derived following antigen-specific
stimulation of PBMC by subculturing in 96-well plates at limiting
dilution (25, 10, 5, and 3 cells per well) as described
(39), using the anti-CD3 monoclonal antibody 12F6 as a
stimulus for cellular proliferation. In designated instances, freshly
isolated PBMC were directly cloned in this manner as well. Developing
cells were restimulated in 24-well plates with irradiated (30 Gy)
allogeneic feeder cells (105 cells/well), the CD3-specific
monoclonal antibody 12F6 (0.1 µg/ml), and rIL-2 (100 U/ml) in R-10
medium and then tested for HCV-specific cytolytic recognition of HCV-H
and HCV-1 antigens 7 days later. HCV-specific clones were maintained in
long-term culture in T-25 flasks by restimulating 2 × 106 to 4 × 106 lymphocytes every 3 to 4 weeks with 20 × 106 irradiated (30 Gy) allogeneic
PBMC feeders plus 0.1 µg of 12F6 and 50 U of rIL-2 per ml in 20 ml of
R-10 medium.
vv-HCV constructs.
vv-HCV recombinant viruses were
constructed to express the structural and nonstructural proteins of HCV
as previously described. The following constructs expressed the entire
translated polyprotein of an HCV type 1a strain, HCV-H
(13): vv1-966(H1) expressed amino acids (aa)
Met1 to Asp966, and vv827-3011(H2) expressed aa
Met827 to Arg3011. In addition, the following
constructs expressing the proteins of a second type 1a strain,
HCV-1(5), were used: vv-core/E1 expressed aa Met1 to
Ile340; vv-E2(NS1)/NS2 expressed aa Met347 to
Leu906; vv-E2/NS2/NS3 expressed aa Met364 to
His1619; vv-NS4 expressed Gln1590 to
Arg2050; vv-NS5A expressed Gly2005 to
Gly2396; and vv-NS5B expressed Gly2396 to
Arg3011. All vv-HCV recombinant viruses were demonstrated
to express the appropriate HCV proteins by radioimmunoprecipitation
(7). These recombinant viruses have also been shown to
sensitize B-LCL to lysis by HCV-specific CTL (data not shown). A
construct expressing the Escherichia coli 
-galactosidase
gene (vv-Lac) was used as a negative control.
Synthetic peptides.
Peptides corresponding to the aa
sequences of the HCV-1 strain were synthesized as free acids by
Cambridge Research Biochemicals (Cambridge, Mass.) or Mimotopes
(Chiron, Victoria, Australia) using the Fmoc (9-fluorenylmethoxy
carbonyl) method. Peptides were 20 aa in length, overlapping adjacent
peptides by 10 aa. Fine mapping was achieved using additional smaller
peptides in free acid form that were synthesized on an automated
peptide synthesizer (model 432A; Applied Biosystems, Inc., Foster City,
Calif.). All peptides were reconstituted in sterile distilled water
containing 10% dimethyl sulfoxide (Sigma Chemical Co.) and 1 mM
dithiothreitol (Sigma Chemical Co.).
Cytotoxicity assay using vaccinia virus-infected target
cells.
B-LCL were infected with recombinant vv-HCV vectors at a
multiplicity of 5 to 10 PFU/cell, labeled with
NA2[51Cr]O4 (New England Nuclear,
Boston, Mass.), and incubated overnight at 37°C in 5%
CO2. The following morning, the B-LCL target cells were
washed three times with cold R-10 medium and incubated with effector
cells at 37°C for 4 h. Cellular release of
[51Cr]O4 into the supernatant was measured
using a Top Count Microplate scintillation counter (Packard Instrument
Company, Meriden, Conn.), and the percent specific cytotoxicity was
calculated by the formula % lysis = [(experimental release spontaneous release)/(maximum release spontaneous release)] × 100. Results are reported as the mean of triplicate values, with a
standard deviation of <5%. Samples were scored positive if the
specific lysis at an effector-to-target cell of 100:1 was greater than
20% and at least 15% higher than the percent lysis for the
vv-Lac-infected B-LCL negative control (39).
Data analyses.
All statistical analyses were performed using
the Statistics for Windows 5.1 software package (Statsoft, Tulsa,
Okla.).
| |
RESULTS |
HCV-specific CTL are present in PBMC of persons with chronic HCV
infection.
To determine if HCV-specific CTL can be detected in the
peripheral blood of persons with chronic HCV infection, we initially examined a subject (P1) who had previously been shown to have a broadly
directed response in the liver with five different CTL epitopes
characterized (20). This subject had since completed a
5-month course of interferon therapy (she withdrew from the last month
of treatment), resulting in a complete biochemical and virological
response which has been sustained for over 1 year. A liver biopsy
specimen, obtained prior to initiation of interferon therapy, and
cryopreserved PBMC, obtained 3 months after starting interferon
therapy, were available for study. Bulk stimulated cultures of PBMC
expanded in an antigen-nonspecific manner with the anti-CD3 monoclonal
antibody 12F6 had no evidence of HCV-specific CTL activity (Fig.
1A), which is consistent with our
previous findings (19-21, 38). To increase the
sensitivity of CTL detection, multiple clones were also established
from PBMC by culturing at limiting dilution after stimulation with
12F6. Of the 105 clones tested, 2 lysed autologous B-LCL targets that
expressed E2/NS2 (aa 339 to 906) of HCV-1 (Fig. 1B). CTL of similar
specificity were obtained from intrahepatic lymphocytes with anti-CD3
stimulation (39). These data demonstrate that CTL of the
same specificity as detected in liver can be detected at a clonal level
in peripheral blood, but the frequencies are below the detection limit
of bulk assays.
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FIG. 1.
HCV-specific CTL are present in PBMC at low
frequencies. Subject P1 was selected for study because she had chronic
HCV infection and HCV-specific CTL previously identified from liver
biopsy-derived lymphocytes. (A) PBMC were stimulated with 12F6, a
CD3-specific monoclonal antibody, and tested after 2 weeks for CTL
activity in a standard 4-h chromium release assay. HCV-H antigens were
expressed on autologous B-LCL target cells using a recombinant HCV-vv
infection. No HCV-specific CTL activity was detected compared to cells
expressing the control LacZ protein. (B) Fresh (previously
unstimulated) PBMC were cloned at limiting dilution and stimulated with
12F6 and allogeneic irradiated PBMC feeders. Of the 105 clones screened
for CTL activity, 2 clones (P5-11 and P5-28.6) with CTL activity
against target cells expressing the E2/NS2 proteins of HCV were
identified. This suggested that HCV-specific CTL were present at low
frequencies. (C) PBMC from subject P1 were also stimulated with
antigens from the entire translated polyprotein of HCV-H expressed on
autologous B-LCL. After 2 weeks in culture, the bulk stimulated cells
were tested for CTL activity in a standard 4-h chromium release assay.
HCV-specific CTL activity was detected against B-LCL expressing aa 1 to
966 and 827 to 3011 but not the negative control expressing the
lacZ gene product.
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|
Detection of HCV-specific CTL can be enhanced by antigen-specific
stimulation.
To increase the sensitivity for detecting CTL, PBMC
from the same individual were stimulated with autologous cells
expressing HCV proteins. This was accomplished by infecting
autologous B-LCL with recombinant vv-HCV constructs, leading to the
expression of the entire translated polyprotein of HCV-H, a type
1a strain. Using this method, HCV-specific CTL activity was
detected in bulk PBMC cultures (Fig. 1C). This bulk-stimulated PBMC
culture was also cloned at limiting dilution using anti-CD3 monoclonal
antibody so that the CTL response in peripheral blood could be
characterized and compared to the CTL response in the liver. Of the 120 clones tested, 32 HCV-specific clones were identified. All five CTL
epitopes recognized by the liver-derived clones were also recognized by at least one of the PBMC-derived clones (Fig.
2).
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FIG. 2.
CTL identified from PBMC recognize the same epitopes as
CTL identified from liver of subject P1. PBMC from subject P1 that had
been stimulated with HCV-H antigens expressed by autologous B-LCL were
subcloned and tested for recognition of five epitopes previously
identified from this patient from liver CTL. Synthetic peptides
corresponding to the identified CTL epitopes were incubated with
51Cr-labeled autologous B-LCL and used as target cells in a
standard chromium release assay. CTL clones derived from PBMC (solid
bars) and liver (clear bars) specifically recognized the epitopes (A)
TINYTIFK, aa 621-628 in E2 envelope, (B) TLGFGAYMSK, aa 1261 to 1270, and (C) HSKKKCDEL, aa 1395 to 1403 in the NS3 protein, (D) TLGFGAYMSK,
aa 1636 to 1643 in NS4, and (E) SLTPPHSAK, aa 2510 to 2518 in the
NS5b protein.
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|
To assess the ability of this method to detect CTL in PBMC, we examined
seven subjects with chronic HCV infection in whom CTL had been detected
from liver-derived lymphocytes and for whom cryopreserved PBMC were
available (Fig. 3A). PBMC stimulated with the anti-CD3 monoclonal antibody 12F6 had a 40- to 100-fold expansion in the total number of cells after 2 weeks, as assessed by absolute cell counts (Table 1). This indicates
that the cryopreserved PBMC were viable and able to proliferate.
Proliferation following stimulation with autologous B-LCL infected with
recombinant vv-HCV, in which one would expect preferential expansion of
HCV-specific CTL, had a 0.25- to 40-fold expansion over the same period
of time. Nonspecific responses, possibly reflecting T-cell responses to
vaccinia virus or EBV resulting in vv-Lac-specific lysis of >20%,
were observed in 8 of the 12 subjects tested. However, three of the
seven subjects with intrahepatic CTL also had detectable HCV-specific
PBMC CTL using this antigen-specific stimulation method to establish
polyclonal cell lines (P1, P2, and P3) (Fig. 3B). These results were
confirmed by the establishment of PBMC clones from these three subjects
(Fig. 3B). In addition, CTL were detected in PBMC from an additional
two subjects (P4 and P5) after HCV-vv stimulated PBMC were cloned and
screened for CTL responses (Fig. 3B). The specificities of the
PBMC-derived CTL were identical to those that had been derived from
liver. Another two subjects (P8 and P9) who did not have intrahepatic
CTL were also studied, and neither of these had evidence of CTL in
PBMC. Of the two subjects with discordant results between liver and
PBMC CTL, P6 had a vigorous intrahepatic CTL response but no evidence
of CTL from the PBMC sample obtained 1 year after the liver biopsy.
Unfortunately, no PBMC samples were available from the time when the
liver biopsy was obtained. P7 had a low frequency of intrahepatic CTL
and no evidence of CTL from a PBMC sample from the same time point.
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FIG. 3.
HCV-specific PBMC CTL detected in majority of
subjects with intrahepatic CTL. (A) Seven subjects (P1 to P7) known to
have intrahepatic CTL responses, two subjects with no detectable
intrahepatic CTL responses (P8 and P9), and three HCV-seronegative
controls (N1 to N3) were tested for PBMC CTL after stimulation with
HCV-H antigens expressed on autologous B-LCL using a 4-h chromium
release assay. Assays were scored as positive if the total specific
lysis was greater than 20% and at least 15% greater than the
background nonspecific lysis. HCV-specific CTL activity was detected in
bulk stimulated cultures of subjects P1, P2, and P3 (indicated by
asterisks). (B) Bulk-stimulated cells were subcloned and tested again
for CTL activity. Where the bulk CTL assay had been scored as positive,
HCV-specific CTL clones recognizing the appropriate regions identified
using vaccinia virus vectors were detected in all three subjects (P1 to
P3). Furthermore, PBMC CTL clones targeting epitopes in regions where
the bulk CTL assay was scored as negative were found in subject P3 (aa
2152 to 2160) and in an additional two subjects (P4 and P5). All CTL
clones recognized the optimal epitope in the context of a specific
restricting HLA class I allele with high specificity. Nonspecific lysis
to irrelevant peptides for all clones was <5%.
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TABLE 1.
HCV-specific CTL can be detected in the majority of
subjects with chronic HCV infection in whom CTL had previously been
detected in the livera
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PBMC from three HCV-seronegative subjects were also examined, but
no HCV-specific CTL were detected after antigen-specific stimulation
with autologous B-LCL expressing HCV-H (Fig. 3B). Two of these three
subjects were HLA B35 positive and were previously reported to have HLA
B35-restricted CTL responses in PBMC after in vitro stimulation with
the peptide P401 (aa 234 to 242, NASRCWVAM) (22). Once
again, HLA B35-restricted CTL clones were obtained from both subjects
following stimulation with peptide P401. However, similar to previous
results, these CTL only recognized cells incubated with P401, not the
endogenously processed antigen when the vaccinia virus expression
system was used (22 and data not shown). Together, the
data suggest that antigen-specific stimulation of PBMC using recombinant HCV-vv-driven expression of HCV antigens in autologous B-LCL can be used to detect CTL responses in the majority of subjects with intrahepatic CTL responses and that these responses reflect recognition of endogenously processed antigen.
No evidence of CTL in a cohort at high risk for HCV
exposure.
A cohort of injection drug users in Baltimore has been
followed for incidence and prevalence of several blood-borne pathogens. The prevalence of HCV was very high in this group, with frequent use
and sharing of drug paraphernalia identified as factors for HCV
seroconversion among those who were initially HCV seronegative (35). However, a subgroup remained HCV seronegative
despite a history of continued high-risk behavior. This group was
studied to determine if there was evidence of HCV-specific CTL that
might account for their remaining HCV seronegative. Cryopreserved PBMC from 10 subjects were obtained from this cohort, 8 who remained HCV
seronegative and 2 who had developed chronic HCV infection. Assays were
performed in a blinded fashion. Two of the 10 subjects had detectable
CTL responses in PBMC, and upon unblinding, both were shown to be HCV
seropositive (Table 2). Subject A had a CTL response to one epitope within aa 347 to 906, and subject B had CTL
responses to an epitope in the E1 (aa 285 to 293) and NS2 (aa 838 to
846) proteins (Table 2 and data not shown). The remaining eight
subjects were HCV seronegative and had no evidence of HCV-specific CTL
responses. These data are in conflict with the hypothesis that memory
CTL generated from previous exposure were responsible for the continued
HCV-seronegative status of these individuals. CTL may be present but
below the limit of detection of this assay, in which case they are of
lower magnitude than in persons with chronic progressive infection who
do not control HCV replication.
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TABLE 2.
HCV-specific CTL detected in subjects with chronic HCV
infection but not in uninfected subjects despite the history of
continued injection drug usea
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| |
DISCUSSION |
The role of HCV-specific CTL in the pathogenesis of HCV infection
is still unclear. Most studies have been conducted on chronically infected subjects, which have been the easiest to identify.
HCV-specific CTL have been identified in the majority of these subjects
from lymphocytes isolated from liver (26, 39). CTL have
also been detected by in vitro stimulation with viral peptides. These
methods are largely limited to detection of predicted epitopes and
therefore do not provide a comprehensive analysis of CTL to all
possible presented epitopes (2, 4, 12, 15, 17, 23, 28, 32,
33). In addition, peptide-specific approaches limit the analysis
to known particular peptides and alleles. The ability to study CTL
responses in HLA-diverse populations and to study responses to the
entire translated polyprotein will allow a more comprehensive
characterization of this response. This would be particularly
advantageous for situations when liver biopsy is not feasible, such as
for subjects with acute HCV infection, uninfected subjects, and studies
for which frequent samples are required.
In this study, we have used vaccinia virus infection to express HCV-H
antigens (type 1a strain) in autologous B-lymphoblastoid cells. These
cells were then used to stimulate PBMC. The advantage of this system is
that the PBMC are exposed to antigens from the entire HCV-H genome and
expressed in the context of all autologous HLA alleles. Furthermore,
over 75% of subjects in North America are infected with genotype 1 viruses, which would have a relatively high degree of homology with
HCV-H (1). Our results indicate that the majority of
persons with chronic HCV infection have circulating CTL and that these
target epitopes are similar to those targeted by the intrahepatic CTL response.
A potential problem with this system is that the PBMC are also exposed
to vaccinia virus antigens and EBV antigens (EBV was used to establish
the B-LCL). However, our results show that HCV-specific CTL clones can
be established in the majority of subjects after one round of in vitro
stimulation. Use of cold targets might be expected to lower background
levels of lysis for the bulk expanded cells even further, as has been
shown using this system for other viral infections (25).
The high degree of concordance of HCV epitopes identified from liver
and PBMC CTL suggests that this strategy is a reasonable alternative to
liver biopsy studies for identifying CTL responses and epitopes.
However, whether the T-cell receptor repertoire in the liver is fully
represented in the peripheral blood and whether the frequency of CTL in
blood will reflect frequencies in the liver are important issues that
still need to be addressed.
Virus-specific CTL have been implicated as a possible protective
mechanism in subjects with high-risk viral exposure, such as those
exposed to human immunodeficiency virus (30, 31). To see
if this was also true for HCV, we studied a cohort of injection drug
users who reported prolonged and persistent high-risk behavior. We
found no evidence of HCV-specific CTL that might be responsible for the
persistent lack of HCV infection in these eight individuals. This did
not appear to be caused by technical reasons, such as poor cell
viability, as CTL were identified in the two chronically infected
subjects, whose PBMC were analyzed identically. However, this is a
difficult hypothesis to reject, as there is no guarantee of HCV
exposure despite the history of high-risk behavior. In addition, it is
also possible that CTL are present but below the detection limit.
However, one can say that the levels of CTL are at least well below
those seen in some persons with chronic uncontrolled HCV infection.
Estimating the magnitude of the CTL response using methods that require
in vitro stimulation is potentially problematic since the measurements
reflect the antigen-specific cells that have survived the incubation
period rather than the magnitude of the immune response at the time the
sample of PBMC was obtained. Newer technologies, such as Elispot
detection of cytokine secretion in response to specific antigen
(24) and the use of tetrameric complexes of HLA class I
and viral peptide (11), have an advantage in that they do
not require in vitro stimulation and can give an estimate of the
frequency of antigen-specific CD8 cells within the population of PBMC.
However, both techniques require initial identification of the relevant
CTL epitopes and do not test the ability of CD8 cells to mediate cell
lysis. To date, we have identified 39 different CTL epitopes restricted
by 17 different HLA class I alleles in the HCV genome (19-21,
39). The technique reported here provides a means of identifying
CTL epitopes without the need for preselecting epitopes for screening
or for a liver biopsy. It also allows assessment of the lytic potential
of CTL responses. Together, these techniques provide the means to
investigate the role that CTL play in subjects for whom liver biopsies
cannot be obtained routinely.
In summary, we report the frequent detection of HCV-specific CTL in
PBMC in persons with chronic HCV infection. In these subjects, the
identified epitopes have a high degree of correlation with the epitopes
identified from liver-derived CTL. These data indicate that CTL
circulate in peripheral blood in persons with chronic HCV infection,
and this method provides a means to assess CTL without the need for
liver biopsy.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Partners AIDS
Research Center, Room 5212D, MGH East, 149 13th St., Charlestown, MA 02129. Phone: (617) 724-8332. Fax: (617) 726-4691. E-mail:
bwalker{at}helix.mgh.harvard.edu.
| |
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Journal of Virology, February 2001, p. 1229-1235, Vol. 75, No. 3
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.3.1229-1235.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
