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Journal of Virology, April 2000, p. 3517-3524, Vol. 74, No. 8
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Pathogenesis of Herpes Simplex Virus-Induced Ocular
Immunoinflammatory Lesions in B-Cell-Deficient Mice
Shilpa P.
Deshpande,
Mei
Zheng,
Massoud
Daheshia, and
Barry T.
Rouse*
Department of Microbiology, University of
Tennessee, Knoxville, Tennessee 37996-0845
Received 22 November 1999/Accepted 19 January 2000
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ABSTRACT |
The role of B cells and humoral immunity in herpes simplex virus
(HSV) ocular infections was studied in immunoglobulin µ chain gene-targeted B-cell-deficient mice (µK/O). At doses of virus well
tolerated by immunocompetent mice, heightened susceptibility of
µK/O mice to herpetic encephalitis as well as to herpetic stromal keratitis (HSK) was observed. An explanation was sought for the increased severity of HSK in the µK/O mice. First, the lack of antibody responses in µK/O mice resulted in longer viral persistence and dissemination to the corneal stroma, the site of inflammation. Prolonged virus expression in the corneal stroma was suggested to cause
bystander activation of Th1-type CD4+ T cells, further
contributing to the severity of HSK lesion expression in µK/O mice.
Second, µK/O mice generated minimal Th2 cytokine responses compared
to wild-type mice. Such responses might serve to downregulate the
severity of Th1-mediated HSK lesions.
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INTRODUCTION |
Infection of the human cornea with
herpes simplex virus (HSV) may lead to a blinding immunoinflammatory
disease termed herpetic stromal keratitis (HSK) (33, 34).
The lesion can be modeled in a susceptible mouse strain, where it
regularly occurs as a consequence of primary infection of the cornea
(36). In mice, and likely in humans, the lesion appears to
be a T-cell-mediated immunoinflammatory process (10, 33,
34). For example, the lesion fails to occur in nude mice, which
lack T cells yet possess functional B cells (34).
Additionally, in ocularly HSV-infected SCID mice, which lack their own
T or B lymphocytes, adoptive transfer of CD4+ T cells can
lead to lesion expression (23). Other observations, however,
argue that T-cell-mediated immunity may not totally account for the
lesions and suggest a role for B-cell-mediated immunity in HSK
pathogenesis. For instance, humoral antibody can protect animals from
lesions if it is present in sufficient concentrations soon after
infection (9, 22, 28, 30). Furthermore, B cells may be
important during the clinical phase of the disease, as it has been
reported that suppression of B-cell function, as can be done by
immunoglobulin M (IgM) treatment, diminishes the severity of HSK
(16). HSK thus represents a complex syndrome in which the
role of cellular components, such as B cells and their products,
remains ill defined. With the availability of a convenient animal model
in which B-cell function appears abrogated (18), the
pathogenesis of HSK was reassessed. Our results show that in contrast
to previous observations, B-cell-deficient (µK/O) mice were more
susceptible and developed severe HSK in the absence of B cells. This
greater susceptibility appeared to have two explanations. First, the
production of antibody limited the duration of virus persistence and
dissemination within the cornea. In consequence, in immunocompetent
mice, the virus was virtually confined to the corneal epithelium and
was absent by day 5 postinfection, well before the time of HSK
induction. Surprisingly, in µK/O mice the virus spread to the corneal
stroma from the epithelium and persisted for a longer period, extending
into the time of lesion expression. At the lesion site, the virus
likely acted as an indirect proinflammatory stimulus for invading
CD4+ T cells, causing their bystander activation and
subsequent participation in HSK lesion expression. Second, mice lacking
B cells generated minimal Th2 responses compared to wild-type mice
during the peak clinical phase of HSK lesions. Since the products of
Th2 cells are known to modulate lesion severity (5, 19), it
is likely that the diminished Th2 responses in µK/O mice also
contribute to the greater severity of the infection.
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MATERIALS AND METHODS |
Mice.
BALB/c mice (4 to 6 weeks old) were purchased from
Harlan Sprague-Dawley (Indianapolis, Ind.). B-cell-deficient mice
(µK/O; H-2d background), made by targeted
disruption of the membrane exon of the Ig µ chain gene, were provided
by Werner Muller (Institute for Genetics, University of Cologne,
Germany) (18). The µK/O mice were bred in our
pathogen-free animal facility. The lack of IgM+ B cells in
these mice was confirmed by fluorescence-activated cell sorter
analysis. All experimental procedures were in complete accordance with
the Association for Research in Vision and Opthalmology resolution on
the use of animals in research.
Virus.
HSV type 1 (HSV-1) RE and HSV-1 KOS strains were
propagated and titrated on monolayers of Vero cells (ATCC CCL81) using
standard protocols (31). All virus stocks were aliquoted and
stored at 
80°C.
Corneal HSV infections and clinical observations.
Corneal
infections of all mouse groups were conducted under deep anesthesia
induced by the inhalant anesthetic methoxyfurane (Metofane; Pittman
Moore, Mondelein, Ill.). The mice were scarified on their corneas with
a 27-gauge needle, and a 4-µl drop containing the required virus dose
was applied to the eye and gently massaged with the eyelids. The eyes
were examined on different days postinfection with a slit lamp
biomicroscope (Kowa Co., Nagoya, Japan), and the clinical severity of
keratitis of individually scored mice was recorded. The scoring system
was as follows: +1, mild corneal haze; +2, moderate corneal opacity or
scarring; +3, severe corneal opacity but iris visible; +4, opaque
cornea, iris not visible; and +5, necrotizing stromal keratitis.
Virus recovery and titrations.
At various time points
postinfection, swabs of the corneal surface were taken. The swabs were
put into sterile tubes containing 500 µl of Dulbecco modified Eagle
medium with 10 IU of penicillin/ml and 100 µg of streptomycin (Life
Technologies, Grand Island, N.Y.)/ml and stored at 80°C. For
detection and quantification of HSV in the swabs, the samples were
thawed and vortexed. Duplicate 200-µl aliquots of each sample of
thawed swab medium were plated on Vero cells grown to confluence in
24-well plates at 37°C in 5% CO2 for 1 h and 30 min. The medium was aspirated, and 1 ml of 2× Dulbecco modified Eagle
medium containing 1% low-melting-point agarose was added to each well.
The cultures were observed daily for the development of typical
cytopathic effect. The titers were calculated as PFU per milliliter in
accordance with standard protocols (31).
Passive antibody transfer.
To assess the role of virus
replication in lesion development, mice were infected on the cornea and
5 days later were given intravenously 300 µl of anti-HSV serum (36.5 µg/ml; HSV-specific IgG). Sera were collected from HSV-1 RE-immunized
BALB/c mice and checked for HSV-specific total IgG by standard
enzyme-linked immunosorbent assay (ELISA) as described previously
(21). Briefly, the ELISA plates were coated with 100 µl of
HSV antigens or anti-mouse IgG (1 µg/ml; PharMingen) as a standard in
carbonate buffer (pH 9.8) overnight at 4°C. Serum samples were
diluted 1:200 in phosphate-buffered saline (PBS) and run in triplicate
with purified mouse IgG as a standard (PharMingen), followed by
horseradish peroxidase-conjugated goat anti-mouse IgG (PharMingen).
Quantification was performed with Spectramax ELISA reader softmax,
version 1.2.
Delayed-type hypersensitivity (DTH).
Eight and 18 days after
virus infection on the scarified corneas of mice, test antigens in 20 µl of PBS were injected in the ear pinnae of anesthetized mice, and
ear thickness was measured 48 h postinjection with a screw gauge
meter (Oditest; H. C. Kroeplin GmBH, Schluechtern, Germany) as
described elsewhere (17). The test antigens used were
UV-inactivated HSV-1 KOS (105 PFU prior to UV inactivation)
and Vero cell extract in the right and left ears, respectively. The
mean increase between the thicknesses of the left and right ears was
calculated and expressed as 10
2 mm.
HSV-specific lymphoproliferation assay.
To test whether
HSV-specific T-cell responses of the µK/O and BALB/c mice were
comparable, the mice were sacrificed 8 and 18 days after virus
infection on scarified corneas. Individual spleens and cervical and
mandibular lymph nodes were used as responders for lymphoproliferation
assays. This method has been described in detail elsewhere
(21). Briefly, these responders were restimulated in vitro
with irradiated syngeneic splenocytes infected with UV-inactivated HSV-1 KOS cells (multiplicity of infection, 1.5) or irradiated naïve splenocytes and incubated for 5 days at 37°C. Eighteen hours before the cells were harvested, [3H]thymidine (1.0 µCi/well) was added to all culture wells, and the plates were read
with a 
-scintillation counter (Trace 96; Inotech, Lansing, Mich.).
The results were expressed as mean counts per minute ± standard
deviation for six replicates per sample.
Quantification of cytokines by ELISA.
Mice infected with
virus on their scarified corneas were sacrificed 8 and 18 days after
virus infection. Single-cell suspensions of splenic cells and cervical
and mandibular draining lymph node (DLN) cells (2 × 106/ml) were restimulated in vitro with UV-inactivated
HSV-1 RE at an MOI of 1.5 and incubated for 72 h at 37°C. The
supernatants were analyzed for interleukin 4 (IL 4), IL 10, and gamma
interferon (IFN-
) cytokine production by ELISA. Concanavalin A
(ConA)-stimulated (5 µg/106 cells/ml) and unstimulated
cells were used as positive and negative controls, respectively.
Ninety-six-well microtiter plates were coated with 2 µg of rat
anti-mouse IL-2, IL-4, IL-10, and IFN- antibody (PharMingen) per ml
at 4°C overnight. The plates were then washed three times with PBS
containing 0.5% Tween 20 and blocked with 3% nonfat dry milk for
1 h at 37°C. After the plates were washed, serially diluted
samples and standards (recombinant IL-4 [rIL-4], rIL-10, and
rIFN-) were added and the plates were incubated overnight at 4°C.
The plates were washed with PBS, and 1 µg (each) of biotinylated
anti-IL-2, anti-IL-4, anti-IL-10, and anti-IFN- antibody
(PharMingen) per ml were added to the wells, and the mixtures were
incubated at 37°C for 2 h. Peroxidase-conjugated streptavidin
(Jackson ImmunoResearch, West Grove, Pa.) was added at 37°C for
1 h. The color was developed by adding the substrate solution (11 mg of 2,2'-azino-bis-3-ethylbenzthiazoline-6-sulfonic acid in 25 ml of
0.1 M citric acid, 25 ml of 0.1 M sodium phosphate, and 10 µl of
hydrogen peroxide). Quantification was performed with Spectramax ELISA
reader software version 1.2.
Quantification of cytokine-producing cells by ELISPOT.
Mice
were sacrificed 8 and 18 days after virus infection, and their splenic
and lymph node cells were used as responders. The resulting samples
were analyzed for IL-4, IL-10, and IFN- spot-forming cells by
enzyme-linked immuno-SPOT (ELISPOT). To generate cytokines, the
responders were stimulated with enriched dendritic-cell populations
obtained by the method of Nair et al. (25) that had been
pulsed with UV-inactivated HSV (MOI, 5.0) for 3 h before being
added to the responders. The responders and stimulator dendritic cells
(naïve or pulsed) were added at a responder-to-stimulator ratio
of 50:1, 25:1, or 12.5:1 in 200 µl of RPMI with 10% fetal bovine
serum per well in ELISPOT plates coated with various anti-cytokine
antibodies. After 72 h of incubation, the plates were washed and
biotinylated anti-cytokine antibodies were added. After 1 h of
incubation at 37°C, alkaline phosphatase-conjugated streptavidin in
PBS (1 µg/100 µl) was added and the plates were incubated for
another hour at 37°C. The spots were developed by using nitroblue
tetrazolium and 5-bromo-4-chloro-3-indolylphosphate as a substrate and
counted 24 h later with a dissecting microscope.
Immunohistochemical staining.
Eyes were frozen in optimum
cutting temperature compound (Miles, Elkart, Ind.) on different days
postinfection. Six-micrometer-thick sections were cut, air dried, and
fixed in cold acetone for 5 min. The sections were then blocked with
heat-inactivated goat serum and stained for the presence of HSV
antigens by the use of rabbit anti-HSV anti-serum (Dako Corp.,
Carpentaria, Calif.), which was followed with biotinylated anti-rabbit
Ig (1/20 dilution; Biogenex, San Ramon, Calif.). The sections were then
treated with horseradish peroxidase-conjugated streptavidin (1:1,000)
and 3,3'-diaminobenzidine (Vector, Burlingame, Calif.) and
counterstained with hematoxylin.
Statistical analysis.
Wherever specified, the data obtained
were analyzed for statistical significance by Student's t test.
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RESULTS |
Increased susceptibility of µK/O mice to HSK.
Infection of
the corneas of BALB/c mice with HSV results in an inflammatory reaction
in the stroma, which involves the essential participation of
CD4+ T cells (10, 34). To evaluate a role for
B-cell-mediated immunity in HSK pathogenesis, lesion development was
compared in B-cell-deficient mice (µK/O) and control immunocompetent
BALB/c mice after infection with different doses of HSV-1 RE (5 × 106 to 1 × 104 PFU). Unexpectedly, µK/O
mice were more susceptible than BALB/c mice to HSV-1 ocular challenge
and succumbed to death from encephalitis at doses of virus (5 × 106 to 1 × 106 PFU) well tolerated by
BALB/c mice (Fig. 1). Furthermore, low doses of virus successfully generated HSK in µK/O mice but not in
BALB/c mice (Fig. 2). Thus, at an
infecting dose of 104 PFU, 100% of µK/O mice developed
HSK compared to only 10% of infected BALB/c mice. At higher doses of
infectious virus, the severity of lesions in the µK/O animals usually
exceeded lesion severity in the BALB/c mice exposed to an identical
infectious dose of virus (Fig. 2). Thus, our data demonstrate that the
presence of B cells influences resistance to HSV infection.
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FIG. 1.
Susceptibility of µK/O mice to encephalitis after
infection with high doses of HSV-1 RE. Groups of BALB/c and µK/O mice
were infected with 5 × 106 PFU (n = 6) and 106 PFU (n = 10) of HSV-1 RE on
their scarified corneas and examined for signs of sickness, wasting,
paralysis, and encephalitis. The percentage of survival following virus
infection is plotted.
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FIG. 2.
Susceptibility of µK/O mice to HSK following HSV-1 RE
infection. Groups of BALB/c and µK/O mice (n = 10 to
15) were infected with 106, 105, and
104 PFU of HSV-1 RE on their scarified corneas. The mice
were examined clinically by slit lamp microscope, and the severity of
lesions was scored on a 0-to-5 scale as described in Materials and
Methods. The percentage of mice showing a mean clinical score of  4.0
at day 21 postinfection is plotted. The mean clinical scores at day 21 are shown above the bars.
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How do B cells influence HSK?
Virus clearance from the cornea
usually occurs prior to HSK lesion manifestation in immunocompetent
animals (1). As shown in Table
1, µK/O mice were significantly
impaired in their ability to clear virus from the eye following corneal
infection. Differences were most evident at low infecting doses of
virus. Whereas BALB/c mice cleared the virus by 4 days postinfection,
in µK/O mice the virus persisted for at least 8 days. Of most
striking interest, the locations of viral antigen in the corneas of
infected BALB/c and µK/O mice showed some differences. Thus, the
virus was virtually confined to the epithelium until day 4 postinfection in both mouse strains (data not shown). However, after
that time the predominant location of virus in the µK/O mice was in
stromal tissues. In fact, viral antigen was demonstrable in the
stromata of some µK/O animals until at least 10 days postinfection
(Fig. 3).
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FIG. 3.
Immunoperoxidase staining for viral antigen (as
indicated by the arrows) in the corneas of µK/O mice on day 2 (A) and
day 10 (C) and BALB/c mice on day 2 (B) and day 10 (D) following
infection with 5 × 105 PFU of HSV-1 RE on their
scarified corneas. Magnification, ×200.
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To investigate whether the duration of viral persistence affected
disease outcome, BALB/c and µK/O mice were given passive
transfers of
high titers of mouse anti-HSV serum at day 5 after
ocular HSV
infection. Different patterns of events were observed
in the two
groups. In BALB/c mice, the passive serum transfer
induced no
observable differences in lesion severity. However,
in the µK/O mice
given anti-HSV serum at day 5 postinfection,
the severity of lesions
was significantly reduced compared to
that in control untreated µK/O
mice (Fig.
4). This was correlated
with
viral clearance from ocular secretions from the corneal surface,
indicating that virus in that location could contribute to HSK
lesion development in µK/O mice (Table
2).
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FIG. 4.
Kinetics of HSK in HSV-1 RE-infected µK/O mice and
BALB/c mice following passive transfer of HSV immune serum at day 5 postinfection. Groups of BALB/c (n = 6) and µK/O
(n = 5) mice were infected with 5 × 105 PFU of HSV-1 RE on their scarified corneas. The mice
were examined clinically by slit lamp microscope, and the severity of
lesions was scored on a 0-to-5 scale as described in Materials and
Methods. The mean clinical scores at days 7, 9, 12, 15, and 21 are
plotted for all groups. Error bars (standard deviations) for untreated
µK/O and immune serum-treated µK/O mice are also shown.
Significantly different (P < 0.05) mean scores between
untreated and immune serum-treated µK/O mice are indicated by
asterisks. The mean scores for untreated and immune serum-treated
BALB/c mice are not different (P > 0.05).
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Thus, it seems likely that while virus replication for a minimal time
period is all that is necessary to induce HSK lesions
in
immunocompetent BALB/c mice, the viral dissemination to the
stroma in
immunodeficient mice could account for the increased
severity of HSK
development in µK/O
mice.
T-cell responsiveness in BALB/c and µK/O mice.
The
greater susceptibility of µK/O mice to express HSK could be
associated with an inadequate or unbalanced CD4+-T-cell
response involved in the pathogenesis of the ocular lesion (5, 8,
35). To test this idea, the extent and nature of the
CD4+-T-cell immune responses were compared at two different
time points postinfection in µK/O mice and BALB/c mice. Several
observations supported the idea that CD4+-T-cell responses
in µK/O mice were both delayed and changed in their cytokine balance
compared to those of BALB/c animals. The cervical and mandibular DLN
and splenic HSV-specific proliferative responses, as well as the DTH
reactions, in the µK/O mice were depressed soon after infection (day
8) compared to those of BALB/c mice. Ultimately, at the time of the
peak clinical phase (day 18), however, responses of µK/O mice were
comparable to those of BALB/c animals (Fig.
5 and 6).
These data indicate that T-cell responsiveness is decreased early in
infection in mice lacking B cells. Similarly, a comparison of the
cytokine profiles in the DLNs and spleens of the µK/O mice and the
BALB/c mice by ELISA and ELISPOT assays revealed a decreased IFN-
(Th1 cytokine) production at the early clinical phase (day 8 postinfection) in the µK/O mice (Fig.
7). At the time of peak clinical lesion
(day 18 postinfection), comparable IFN- responses were observed for
both BALB/c and µK/O mice (Fig. 8). On
the other hand, with regard to Th2 cytokines (IL-4 and IL-10), whereas
BALB/c mice generated weak yet positive responses, such responses were
absent or marginal in B-cell-deficient mice (Fig. 8). Therefore, in the
absence of B cells, mice may lack negative regulators of Th1 immune
response and may, in consequence, suffer more severe HSK lesions.
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FIG. 5.
Delayed kinetics of DTH reactions in µK/O mice. Mice
infected with 105 PFU of HSV-1 RE on their scarified
corneas were challenged for DTH reactions at days 8 and 18 postinfection (p.i.). UV-inactivated HSV-1 KOS strain or Vero cell
extract was injected in 20-µl volume into the right or left pinnae,
respectively, of both groups of mice (n = 10 to 12).
The increase in ear thickness was measured 48 h later by a blinded
individual. The mean difference in the right and left ear pinna
thickness is plotted with error bars (± standard deviations). A
significant difference is observed between µK/O and BALB/c mice at
day 8, indicated by an asterisk (P < 0.005), and
between µK/O mice at days 8 and 18, indicated by a double asterisk
(P < 0.05).
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FIG. 6.
Delayed HSV-specific proliferation of spleen cells and
cervical and mandibular DLN cells in µK/O mice. BALB/c mice and
µK/O mice were infected on their scarified corneas with
105 PFU of HSV-1 RE and sacrificed at days 8 and 18 postinfection. Spleen cells and cervical and mandibular DLN cells were
used as responders for proliferation. The responders were mixed with
either irradiated syngeneic splenocytes exposed to UV-inactivated HSV-1
KOS strain (MOI, 1.5) or irradiated syngeneic naïve splenocytes
and incubated for 5 days as described in Materials and Methods. ConA (2 µg/ml) was added to the responder culture as a polyclonal simulator
positive control, and the mixture was incubated for 3 days. Differences
in ConA stimulation for days 8 and 18 postinfection are likely due to
differences in radiolabel incorporation or general health of the
cultures. T-cell proliferation for DLNs and spleen at days 8 and 18 postinfection are shown. The means of counts for responders and
irradiated syngeneic splenocytes are plotted with error bars (± standard deviations). The data represent mean proliferation of
triplicates from two experiments with four individual mice in each
group. Significant difference in the values for HSV-specific
proliferation between µK/O and BALB/c mice are indicated by asterisks
(P < 0.05).
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FIG. 7.
Cervical and mandibular DLN and splenic cells (2 × 106/ml) were obtained on day 8 postinfection from mice
infected with 105 PFU of HSV-1 RE on their scarified
corneas. (Top row) Cells were restimulated in vitro with UV-inactivated
HSV-1 RE at an MOI of 1.5 and incubated for 72 h at 37°C. The
supernatant from each of the groups was collected and analyzed by ELISA
for cytokine production as described in Materials and Methods.
ConA-stimulated (5 µg/106 cells/ml) and unstimulated
cells were used as positive and negative controls, respectively. The
results are means of triplicates from three separate experiments. DLN
cells from the mice (n = 3) were pooled, while spleen
cells from individual mice were used in each experiment. Values are
expressed in picograms per milliliter. SFC, spot-forming cells; UD,
undetectable; *, P < 0.05. (Bottom row) Cells
(2 × 105) in a 100-µl volume per well were
restimulated in vitro for 4 days with either irradiated enriched
dendritic cells that were pulsed with UV-inactivated HSV-1 RE or
irradiated naïve enriched dendritic cells at
stimulator-to-responder ratios of 1:50, 1:25, and 1:12.5.
Frequencies of cytokine SFC were measured by ELISPOT assay as
described in Materials and Methods. The number of SFC after
naïve-dendritic-cell stimulation was substracted
from the values of stimulation by UV-inactivated-HSV-pulsed dendritic
cells. The results, expressed as SFC/106 cells, are means
of four replicates from three separate experiments. DLN cells from the
mice (n = 3) were pooled, while spleen cells from
individual mice were used in each experiment. *, P < 0.05 (two-tailed t test).
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FIG. 8.
Cervical and mandibular DLN and splenic cells were
obtained from mice infected with 105 PFU of HSV-RE on their
scarified corneas at day 18 postinfection. (Top row) Cells were
restimulated in vitro with UV-inactivated HSV-1 RE at an MOI of 1.5 and
incubated for 72 h at 37°C. The supernatant from each of the
groups was collected and analyzed by ELISA for cytokine production as
described in Materials and Methods. ConA-stimulated (5 µg/106 cells/ml) and unstimulated cells were used as
positive and negative controls, respectively. The results are means of
triplicates from three separate experiments. DLN cells from the mice
(n = 3) were pooled, while spleen cells from individual
mice were used in each experiment. The values are expressed in
picograms per milliliter. SFC, spot-forming cells; UD, undetectable;
*, P < 0.05. (Bottom row) Cells (2 × 105) in 100 µl per well were restimulated in vitro for 4 days with either irradiated enriched dendritic cells that were pulsed
with UV-inactivated HSV-1 RE or irradiated naïve enriched
dendritic cells at stimulator-to-responder ratios of 1:50, 1:25, and
1:12.5. Frequencies of cytokine SFC were measured by ELISPOT assay as
described in Materials and Methods. The number of SFC after
naïve-dendritic-cell stimulation were substracted from the
values of stimulation by UV-inactivated HSV-pulsed dendritic cells. The
results, expressed as SFC/106 cells, are means of four
replicates from three separate experiments. DLN cells from the mice
(n = 3) were pooled, while spleen cells from individual
mice were used in each experiment. *, P < 0.05
(two-tailed t test).
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DISCUSSION |
HSV infection of the eye may result in a blinding
immunoinflammatory lesion which is orchestrated by CD4+ T
lymphocytes (10, 33, 34). In this report, we demonstrate that mice lacking B cells due to deletion of the Ig µ chain (µK/O) are more susceptible to HSV infection and develop lesions of HSK at
infecting doses of virus well below those necessary to induce HSK in
immunocompetent mice. At infecting doses required to induce HSK in
immunocompetent mice, most µK/O mice succumbed to herpes encephalitis. The reason for the greater susceptibility of µK/O mice
was assumed to be at least twofold. First, in the absence of antibody
production, virus persisted for longer periods in the eye and
disseminated to tissues such as the corneal stroma, the site of
inflammation. Second, the T-cell response necessary for both protection
and the mediation of lesions was delayed and changed in cytokine
balance in µK/O mice compared to immunocompetent animals. The
compromised T-cell response combined with the absence of antibody might
explain the spread of virus to the brain and death from encephalitis.
The change in the Th1-Th2 subset balance could account for the lesion
severity in µK/O mice. Thus, such animals developed diminished Th2
responses known to downregulate Th1-mediated anti-HSV
immunoinflammatory reactions (5, 8, 35). Consequently, our
studies indicate a role for B-cell-mediated functions following ocular
infection by HSV.
The protective role for antibody in HSV infections may relate to its
function of containing or neutralizing virus and preventing its spread
to the central nervous system (9, 22, 28). Consequently, early (day 0 to day 3) administration of immune serum following ocular
infection of immunocompetent mice leads to virus neutralization and
complete amelioration of HSK (30). Here, we report that antibody is also involved in limiting the replication of virus and
preventing its dissemination to surrounding sites, such as the corneal
stroma. Thus, in immunocompetent individuals, the severity of lesions
may be minimized as a consequence of limiting virus replication to the
corneal epithelium. Strikingly, in the µK/O mice the virus persisted
in the cornea for prolonged periods and spread from the epithelium to
the stroma, the site of the inflammatory reaction. Of interest, if the
µK/O mice were given antibody 5 days postinfection, such spread to
the stroma failed to occur and the treated mice expressed only mild
lesions. Accordingly, in the absence of early antibody or perhaps
natural antibody production in µK/O mice, a mechanism of
immunopathology may come into play that represents only a minor
component of HSK in immunocompetent mice. This additional mechanism is
termed bystander activation and was observed to account for HSK lesions
in T-cell receptor transgenic mice on a SCID or RAG background
(12, 13). Such mice possessed CD4+ T cells, but
the cells were unable to recognize HSV antigens. Bystander activation
as a mechanism of tissue pathology has also been observed in some other
model systems (3, 15, 27). We contend that the severe
lesions evident in µK/O mice may largely represent bystander
activation reactions. They occur because the persistence of virus in
the stroma drives proinflammatory cytokines and chemokines at the site.
Such mediators in turn drive arriving CD4+ T cells (likely
largely non-HSV specific) to orchestrate the HSK lesions. Accordingly,
whereas it may appear that HSK lesions in immunocompetent and µK/O
mice are identical, the pathological mechanisms at play for their
expression may be different. Further experiments are ongoing to verify
these ideas.
An additional process to account for the heightened susceptibility to
HSV infection in the µK/O mice must also be considered. Thus, B cells
could play a role in anti-HSV immune defense other than by functioning
as antibody producers (2). Such cells may act as
antigen-presenting cells for the induction of T-cell-mediated immunity,
although whether this occurs during primary T-cell induction remains in
dispute (6, 7, 11, 24, 26). Some reports show that B cells
play a significant role in inducing CD4+ T cells of the Th2
cytokine-producing profile against protein antigen (4, 7, 20, 29,
32). In consequence, the absence of B cells may result in
impaired Th2 induction. This may result in a failure to modulate Th1
T-cell-mediated immunoinflammatory lesions, which in consequence become
more severe and prolonged. Such a situation was described previously
for experimental allergic encephalomyelitis (29, 37) and in
addition may at least partially explain our findings. Thus, we observed
that the balance of T-cell responsiveness to HSV was changed in µK/O
mice compared to immunocompetent controls. In fact, the µK/O mice
made an almost exclusively Th1 CD4+-T-cell response. Such
cells were shown by our group as well as others to act as the main
orchestrators of HSK lesions (14, 34). However, it is well
known that the potency of Th1 cells in mediating pathology or immunity
can be modulated by cytokines generated by Th2 cells. Our previous
studies showed modulation effects on HSK and cutaneous inflammatory
lesions of transforming growth factor , IL-4, and IL-10, all
products of Th2 T cells or B cells (5, 19).
In conclusion, B cells influence the pathogenesis of HSV infection. It
appears likely that B cells are involved in multiple events, which
include antibody production as well as antigen-presenting-cell activity
for regulatory subsets of T cells. The antibody likely functions
principally to limit the extent of virus spread to critical sites, such
as the corneal stroma and the central nervous system. The former, if it
occurs, may result in the immunoinflammatory lesions of HSK, and the
latter may cause a lethal viral encephalitis.
| |
ACKNOWLEDGMENTS |
We are grateful to W. Gerhard (Wistar Institute, Philadelphia,
Pa.) for providing the µK/O mice.
This work was supported by National Institutes of Health grant EY 05093.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology, M409, Walters Life Science Building, University of
Tennessee, Knoxville, TN 37996-0845. Phone: (423) 974-4026. Fax: (423)
974-4007. E-mail: btr{at}utk.edu.
| |
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Journal of Virology, April 2000, p. 3517-3524, Vol. 74, No. 8
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Abstract
Introduction
