Abstract
purpose. The object of this study was to evaluate improvement of lacrimal gland
(LG) function after topical cyclosporin A (CyA).
methods. Topical CyA (0.01% and 0.1%) was applied to two mouse models of
Sjögren’s syndrome, the NFS/sld after thymectomy and
the nonobese diabetic (NOD) mouse, and the functional integrity of the
lacrimal gland was evaluated by measuring basal and stimulated tear
secretion and its histologic integrity by examining it for apoptosis
and lymphocyte invasion.
results. After treatment with CyA at 0.1% in the NFS/sld mice, tear
function increased, and there was a decrease in lymphocyte infiltration
of the LG and a decrease in apoptotic figures among the acinar cells.
In the NOD mice, tear function also improved, but there was no
associated decrease in lymphocyte infiltration. However, the expression
of Fas ligand (FasL) in NOD mice by infiltrating lymphocytes was
suppressed with 0.1% CyA eye drops.
conclusions. CyA appears to improve tear secretion in mouse models of
Sjögren’s syndrome by preventing lymphocyte-induced apoptosis of
acinar cells. In one model this was achieved by preventing lymphocyte
infiltration and in the other by reducing expression of FasL expression
on infiltrating lymphocytes.
Sjögren’s syndrome (SS) is characterized by three
symptoms: dry eye, dry mouth, and arthritis, as originally described by
Sjögren in 1933.
1 Lymphocytes infiltrate the
lacrimal gland (LG) and salivary gland (SG) in SS, and the lymphocyte
infiltration is associated with destruction and dysfunction of the
glands.
2 3 The destruction of the glands is the primary
cause of the severe dry eye and dry mouth that are patients’ major
symptoms.
4 Because the LGs are seriously affected,
patients cannot produce reflex tears, resulting in severe squamous
metaplasia of the ocular surface epithelium.
5 6 Although
the mechanism of destruction of the glands is unclear, a contribution
by lymphocytes is highly suspected. We have reported increased
expression of Fas, Fas ligand (FasL), granzyme A, and perforin in LGs
of patients with SS.
7 8 9 FasL is a member of the TNF
family and is expressed on activated lymphocytes. FasL induces target
cells to undergo apoptosis.
10 These findings, suggest that
the infiltrating lymphocytes may induce apoptosis of duct and acinar
cells in SS through a Fas–FasL interaction.
Although topical cyclosporin A (CyA) has long been discussed for the
treatment of dry eye in the field of ophthalmology, and clinical
application is now under serious consideration,
11 12 13 there is no definite evidence that CyA can improve dry eye. More
specifically, tear production by patients with dry eye, as measured by
the Schirmer test, has failed to show any increase in response to
CyA.
14 15 Nevertheless, CyA has been shown to have a
therapeutic effect in a dog model of dry eye,
11 and we
recently reported that topical CyA prevented lymphocyte infiltration in
the NFS/
sld SS mouse model.
16 The degree to
which lymphocyte infiltration is responsible for lacrimal gland
dysfunction is still unclear, because gland dysfunction has been shown
in diabetes in the absence of lymphocyte
infiltration.
17 18
There is still controversy about which animal model of SS is optimal in
exhibiting the characteristics of human SS, such as decreased tears,
lymphocyte infiltration of the LGs, and ocular surface squamous
metaplasia. We have reported that topical CyA can prevent lymphocyte
infiltration of the LG in NFS/
sld mice after thymectomy at 3
days after birth.
16 We used this animal model because it
is associated with lymphocyte infiltration of only the salivary and
lacrimal glands, which causes dry eye and dry mouth. Haneji et
al.
19 isolated the autoantigen from this mouse model, and
the autoantibody has been detected in patients with SS as well as in
animals. Because autoantibodies are thought to be important in the
pathogenesis of SS,
20 this animal model is considered a
good model of SS. Thus, in our previous study we showed that CyA can
prevent lymphocyte infiltration in one mouse model of SS. However, the
question remains whether CyA can effectively improve and lead to
functional improvement of the glands after massive lymphocyte
infiltration. Furthermore, it remains unknown whether this effect of
CyA is specific to NFS/
sld mice alone. We therefore decided
to use both the nonobese diabetic (NOD) mouse and the
NFS/
sld mouse in this experiment. The NOD mouse was
originally considered a model of nonobese diabetes and has recently
been extensively used to study pancreatic islet B-cell destruction and
of exocrine autoimmune disorders.
21 22 23 24 Although diabetes
developed only in the females, lymphocyte infiltration of the LG
developed in the male mice.
25 26 27 We have confirmed that
the NOD mouse also exhibits decreased tear production.
28
The present study showed that an increase in tear production
(functional improvement) was obtained by application of 0.1% and
0.01% CyA eyedrops three times a day even after massive lymphocytic
infiltration had developed. Different findings were observed in regard
to lymphocyte infiltration in the two different SS models:
NFS/sld mice and NOD mice. In NFS/sld mice the
lymphocyte infiltration improved after topical CyA, whereas it
persisted in NOD mice. Nevertheless, topical CyA prevented acinar cell
apoptosis in both animal models, which may be the reason for the
functional improvement. We also investigated the possible mechanism of
the effect of CyA and found that it suppressed lymphocyte adhesion to
cultured LGs from the NFS/sld mouse and that it suppressed
FasL expression on infiltrating lymphocytes in the LGs of NOD mice. The
results of our study clearly suggest the therapeutic potential of CyA
for the treatment of dry eye associated with SS.
Basal tear secretion in mice anesthetized with pentobarbital
sodium (65 mg/kg; Abbott Laboratories, North Chicago, IL) was measured
by the cotton thread test (Showa, Tokyo, Japan). Cotton thread was
placed under the lower lid of each eye near the medial canthus for 5
minutes, and the length of wet thread was measured. The measurements of
tear volume were performed four times during the 30-minute period of
anesthesia from two data points in each animal. Basal secretion was
calculated as mean tear volume/mean body weight. Weight was shown not
to vary between the groups (P > 0.1).
We developed a reliable method of measuring tear production in mice
with commercially available cotton thread. We measured tear production
over 30 minutes and calculated the mean value as basal tearing. Because
stimulated tearing is also an important function of the LGs, we caused
stimulated tear production by injecting pilocarpine and measured the
response by the cotton thread test, as described. To measure
pilocarpine-stimulated tear secretion, animals were intraperitoneally
injected with 0.05 mg of pilocarpine (Wako, Osaka, Japan) in saline per
100 g body weight under pentobarbital sodium anesthesia (65
mg/kg). Stimulated tearing started within 5 minutes after stimulation
and peaked between 10 and 20 minutes. We used the value between 10 and
20 minutes as the measurement of reflex tearing. Stimulated tear
production was measured in the same manner as basal secretion, and the
average of the second and third measurements (10 minutes after
application of pilocarpine and 20 minutes after application) was
divided by body weight and calculated as stimulated tear secretion.
Data are expressed as means ± SEM of 6 to 12 eyes.
The ocular surface was evaluated 1 day before measuring tear
secretion. Under pentobarbital sodium anesthesia (35 mg/kg), 1 ml of
1.0% sodium fluorescein in saline was applied to the eyes, followed by
washing with saline. The cornea was then examined for fluorescein
staining under slit lamp and scored on the following scale: 0, no
staining; 0.5, slight punctate staining; 1, punctate staining of more
than one quarter of the cornea; 2, presence of a corneal epithelial
defect; 3, corneal epithelial defect covering more than one eighth of
its surface area. Data are expressed as means ± SEM of 6 to 12
eyes.
In the topical application study, CyA dissolved in 2 μl of
ophthalmic solution (0.01% and 0.1% CyA eye drops; Santen, Osaka,
Japan) or vehicle only was applied 3 times a day to both eyes with a
micropipette. We had already confirmed that topical CyA could reach the
LG and was effective for prevention of the disease when administered to
NFS/
sld mice at the age of 4 weeks, before lymphocyte
infiltration occurred.
16 To investigate its therapeutic
effect, we initiated CyA therapy at a later stage. Because massive
lymphocyte infiltration becomes established at approximately 8 weeks
after birth, application was begun 6 days a week in NFS/
sld mice at 10 weeks of age. Animals were killed at age 16 weeks (after 6
weeks of application:
n = 6 for vehicle, 0.01%, and
0.1%), at age 20 weeks (10 weeks of application:
n = 6 for
vehicle, 0.01%, and 0.1%), and at age 24 weeks (14 weeks of
application:
n = 6 for vehicle, 0.01%, and 0.1%).
NFS/
sld mice (
n = 6) were used as starting point
control animals and killed at the age of 10 weeks.
CyA was applied to NOD mice in the same manner, beginning at 10 weeks
of age when the LG infiltration was already severe. Animals were killed
at age 14 weeks (after 4 weeks of application: n = 6 for
vehicle, 0.01%, and 0.1%), at age 18 weeks (after 8 weeks of
application: n = 6 for vehicle, 0.01%, and 0.1%) and at
age 22 weeks (after 12 weeks of application: n = 6 for
vehicle, 0.01%, and 0.1%). The NOD mice (n = 6) were used
as starting point control animals and killed at the age of 10 weeks.
We performed in situ DNA nick-end labeling to detect apoptotic
cells.
32 Paraffin-embedded tissue sections (4 μm) were
deparaffinized by 3 washes in xylene (Koso, Tokyo, Japan), followed by
3 minutes of successive washes in 100%, 90%, and 70% ethanol and
distilled water. Slides were equilibrated in PBS before
deproteinization with proteinase K for 30 minutes at 37°C. DNA
fragmentation was detected by using a kit (Mebstain; MBL, Nagoya,
Japan) that incorporates biotin-conjugated dUTP into DNA by TdT.
The reaction was allowed to continue at 37°C for 1 hour. Sections
were covered with avidin-conjugated fluorescein for 30 minutes at
37°C and then counterstained by 0.5 μg/ml propidium iodide (Wako)
for 15 minutes at 4°C. Negative controls consisted of tissue sections
incubated as described earlier but without addition of TdT. The thymus
of BALB/c mice was used as a positive control.
TUNEL staining of NFS/sld mice of the LG was performed at
the age of 24 weeks (after 14 weeks of application, six animals) and of
the NOD mice at the age of 18 weeks (after 8 weeks of application,
three to four animals). One tissue section per animal was used.
The thyroid, pancreas, bronchus, lung, kidney, and liver were
examined histologically for lymphocyte infiltration and possible side
effects of topical use of CyA. Lymphocyte infiltration was studied, and
the general condition of the animals was carefully monitored.
No increased lymphocyte infiltration was detected in the thyroid,
pancreas, bronchi, lung, kidney, or liver of either NFS/sld or NOD mice treated with CyA. No systemic side effects were observed in
either NFS/sld or NOD mice, except for the ex-pected
lymphocyte infiltration of other organs in the NOD mice.
It was very important to confirm increased tear secretion in
response to CyA, because lymphocyte infiltration does not necessarily
correlate with LG dysfunction.
17 18 Acinar cells can be
abnormal without lymphocyte infiltration in certain mouse models of
autoimmune diseases, including NOD and NFS/
sld mice.
19 36 In this study we showed that tear secretion
increased in both NOD and NFS/
sld mice after topical use of
CyA, confirming that CyA can lead to functional improvement in these
animal models. However, there was no functional improvement in
stimulated secretion in 22-week-old NOD mice
(Fig. 2B) , suggesting that
the effect of CyA may be limited when the disease has progressed. This
should be further investigated in future experiments.
Lymphocyte infiltration in NFS/
sld mice was reduced by
topical CyA which was started after the establishment of lymphocyte
infiltration. Thus, CyA can be used to treat as well as prevent the
disease. We showed that CyA could decrease lymphocyte adhesion to LG
cells in vitro, suggesting a possible mechanism of action of CyA. CyA
inhibits expression of intercellular adhesion molecule (ICAM)-1 in
skin.
37
The drawback to our study is that we did not investigate the adhesion
molecule of NOD mice and FasL expression of lymphocytes in
NFS/sld mice. Without these controls, we cannot say
definitively that the two mechanisms are present in both animals. There
may be some overlapping mechanism for the improvement of tear function.
However, it is our observation that FasL expression is suppressed in
lymphocyte infiltration after CyA treatment in NOD mice.
It was surprising that although CyA improved LG function in NOD mice,
there was no decrease in lymphocyte infiltration. This resembles
Mikulicz’s disease, in which lacrimal secretion is unaffected despite
the massive lymphocyte infiltration.
8 In SS, the acinar
cells undergo apoptosis and stop functioning, whereas in Mikulicz’s
disease they do not. The LGs of NOD mice treated with CyA were similar
to the LGs in Mikulicz’s disease. We have demonstrated by TUNEL
staining that the acinar cells of the LGs of both NFS/
sld and NOD mice show decreased apoptosis. CyA is known to inactivate T
cells and suppress FasL expression.
38 Our study showed
that FasL expression is suppressed in lymphocytes infiltrating the LG
after CyA treatment. Thus, the mechanism of CyA action may be
prevention of apoptosis by suppression of expression of FasL, even
though the lymphocyte infiltration itself was not prevented. This
resembles insulitis without diabetes in MRL-
lpr/lpr animals,
in which the Fas–FasL system does not function.
39
It is interesting that CyA prevents lymphocyte infiltration in one
animal model of SS (NFS/
sld) and suppresses FasL expression
by infiltrating lymphocytes in the other model (NOD). Because both
animals showed functional improvement, CyA may be indicated for the
clinical treatment of dry eye. However, our observations provide an
important warning for human clinical application of CyA. Although the
fundamental mechanism of action of CyA is T-cell suppression, the
outcome is not always similar. When CyA was given to NFS/
sld mice systemically, lymphocyte infiltration in the LGs and SGs was
aggravated, and there was increased lymphocyte infiltration of the
lung, kidney, and pancreas.
16 Thus, CyA may have a
negative effect at certain concentrations in certain animals because of
different mechanisms. This possibility is particularly important
because CyA may be used for long periods of time.
In summary, functional improvement of the LG was achieved by the
topical application of 0.1% CyA in two mouse models. The mechanism of
action of CyA seems to be prevention of acinar cell apoptosis through
either prevention of lymphocyte infiltration or suppression of FasL
expression on infiltrating lymphocytes. The mechanism of CyA’s effects
should be investigated before clinical application of CyA, with careful
attention to unexpected side effects.
Supported by grants from Oral Health Science Center, Tokyo Dental College; Santen Pharmaceutical Co., Ltd.; and the Medical School Faculty and Alumni Grants of Keio University Medical Science Fund.
Submitted for publication November 30, 1999; revised May 16 and September 20, 2000; accepted September 29, 2000.
Commercial relationships policy: F (KT, HF); N (all others).
Corresponding author: Kazuo Tsubota, Department of Ophthalmology, Tokyo Dental College, 5-11-13 Sugano, Ichikawa-shi, Chiba 272-8513, Japan.
[email protected]
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