 |
 Previous Article | Next Article 
The Journal of Neuroscience, December 15, 2002, 22(24):10781-10789
Involvement of Tissue Plasminogen Activator in Onset and Effector
Phases of Experimental Allergic Encephalomyelitis
Weiquan
Lu1,
Madhuri
Bhasin2, and
Stella E.
Tsirka1, 2
Programs in 1 Pharmacology and 2 Genetics,
Department of Pharmacological Sciences, University Medical Center at
Stony Brook, Stony Brook, New York 11794-8651
 |
ABSTRACT |
Inflammation, demyelination, and neurodegeneration are
pathological features of multiple sclerosis (MS). In the brains of MS patients, tissue plasminogen activator (tPA) mRNA and protein are
upregulated, and changes in the levels of tPA correlate with progression of the disease. However, the role of tPA in MS is as yet
unknown. tPA functions in the CNS in neuronal plasticity and cell
death. tPA also mediates the activation of microglia, the CNS "immune
cells." In this study, we establish that tPA activity increases
during major oligodendrocyte glycoprotein-induced experimental allergic
encephalomyelitis (EAE) in normal mice. To explore the role of tPA in
this disease as a model for MS, we have examined the EAE course and
expression of histopathological markers in mice lacking tPA
(tPA /). We find that tPA/
mice have a delayed onset of EAE but then exhibit increased severity and delayed recovery from the neurological dysfunction. Demyelination and axon degeneration are delayed, microglial activation is attenuated, and the production of chemokines is decreased. Our results suggest that
tPA and activated microglia have complex roles in MS/EAE, and that
these roles are harmful during the onset of the disease but beneficial
in the recovery phase. A temporally restricted attenuation of tPA
activity could have therapeutic potential in the management of MS.
Key words:
proteolysis; multiple sclerosis; microglia; mice; plasmin; cytokine
| |
INTRODUCTION |
Multiple sclerosis (MS) is an
autoimmune disease of the CNS. It results in neurological impairments
that range from sensory defects to difficulties in movement and
paralysis. The cause of MS remains unknown, although viral,
environmental, and genetic factors have been proposed to contribute to
its development (Martin et al., 1992 ). Several animal models have been
developed to explore causes of and treatments for MS. One of these is
experimental allergic encephalomyelitis (EAE), which is characterized
by paralysis, weight loss, and mononuclear cell infiltration in the
CNS. The pathology of MS is similar and includes multicentric
inflammation and demyelination (Opdenakker and Damme, 1994; Steinman,
1996). Despite anti-inflammatory and immunosuppressive therapy, most patients exhibit progressive neurological deterioration. Several groups
have now shown that MS is more than just a demyelinating disease;
axonal degeneration has been shown to be present throughout active
lesions even early in the course of the disease and at the active
borders of less acute lesions (Trapp et al., 1998; Waxman, 1998). These
findings indicate that axonal loss, in addition to demyelination,
occurs early and may also contribute to the development of MS.
Therefore, therapeutic modalities aimed at conferring protection to
axons in early stages of the disease could reduce the irreversible
neurological deficits. Recent reports support this possibility; the
AMPA/kainate antagonist
2,3-dihydroxy-6-nitro-7-sulfonyl-benzo[f]quinoxaline (NBQX) protected against oligodendroglial and axonal damage and ameliorated EAE symptoms (Pitt et al., 2000; Smith et al., 2000). Therefore, the degenerative pathway may involve excitotoxicity, although it is not clear whether the NBQX benefit comes from a direct
effect on neurons or whether it protects oligodendrocytes and myelin.
In the CSF of MS patients, tissue plasminogen activator (tPA) activity
is increased >10-fold compared with reference subjects. Moreover, the
increase in tPA activity correlates with the disease progression
(Akenami et al., 1997). tPA is also detected in macrophages of
inflammatory cuffs in the spinal cord of EAE rats and in degenerating axons during the third relapse of symptoms (Kreutzberg, 1995). tPA mRNA
and protein expression are upregulated, and at least some of the
increase takes place specifically in neurons (Cuzner et al., 1996;
Akenami et al., 1999). tPA is a serine protease that converts the
zymogen plasminogen (plg) to the active protease plasmin and thus
initiates a potent proteolytic cascade. Mice lacking functional tPA
(Carmeliet et al., 1994) are resistant to excitotoxin-induced
neurodegeneration (Tsirka et al., 1995). tPA also plays a role in the
CNS in neuronal plasticity and reorganization (Seeds et al., 1995; Wu
et al., 2000).
Neurons and microglia in the CNS express tPA. Microglia are phagocytic
brain cells that resemble tissue-specific macrophages and are
considered to be the "immune" cells of the CNS. When microglia sense injury to the brain, they migrate to the wound site, proliferate locally, and undergo a series of changes that characterize their activation (Kreutzberg, 1995). Activated microglia are inextricably linked to neurodegeneration. They are present around the lesions of
many neuropathologies and are participants in many experimental models
of CNS injury, including excitotoxin injection, ischemia, and
autoimmune inflammation (Dickson et al., 1993; London et al., 1996).
To investigate the role of tPA and activated microglia in MS, we used
the myelin oligodendrocyte glycoprotein (MOG)-induced EAE model in
tPA-deficient (tPA/) mice. Our results
indicate that tPA affects both the onset of and recovery from acute
EAE. We find that tPA contributes to neuronal degeneration at the early
stages of EAE, and that its absence causes a delay in the onset of EAE.
However, at later stages of EAE, the presence of tPA may be beneficial
in neuronal regeneration, because tPA/
mice exhibit sustained symptoms.
| |
MATERIALS AND METHODS |
Mice. C57BL/6(H-2b),
C57BL/6-tPA+/, and
C57BL/6-tPA/ mice were bred in-house
under specific pathogen-free conditions [Division of Laboratory Animal
Resources at the State University of New York (SUNY) Stony
Brook], controlled for temperature (21°C), and maintained with a
daily light period of 12 hr. Adult (6- to 8-week-old) female mice were
used in all experiments.
MOG peptide. MOG35-55 peptide
(MEVGWYRSPFSRVVHLYRNGK) was synthesized by Quality Controlled
Biochemicals and purified using reverse-phase (C18) HPLC.
Induction of EAE with MOG35-55
peptide. EAE was induced actively, as described previously
(Bernard et al., 1997), by subcutaneous injection in the flank on day 0 with 300 µg of MOG35-55 peptide thoroughly
emulsified in complete Freund's adjuvant (CFA) containing 500 µg of
heat-inactivated Mycobacterium tuberculosis (Difco, Detroit,
MI). One week later (day 7), mice were boosted with 300 µg of
MOG35-55 peptide subcutaneously in the other flank. Pertussis toxin (500 ng; List Biologicals, Campbell, CA) in 200 µl of PBS was injected intraperitoneally on days 0 and 2.
Evaluation of the EAE clinical course. After immunization
with MOG, mice were observed and weighed daily. The disease severity was scored on a scale of 0-5 with graduations of 0.5 for intermediate clinical signs. The score is designated as follows (Hjelmstrom et al.,
1998): 0, no detectable clinical signs; 1, weakness of the tail; 2, hindlimb weakness or abnormal gait; 3, complete paralysis of the
hindlimbs; 4, complete hindlimb paralysis with forelimb weakness or
paralysis; 5, moribund or death. Half-scores were assigned when disease
signs were intermediate. Paralyzed mice were given easy access to food
and hand watered at least twice daily. A mean clinical score was
assigned to each group using this scale.
Immunohistochemistry. At different time points during the
course of EAE, the mice were killed, and the spinal cords were removed. The dissected spinal cords were embedded in Tissue-Tek (Miles, Elkhart,
IN) optimal cutting temperature compound, frozen on dry ice, and stored
at  80°C until use. Cross sections (10 µm) were cut on a cryostat
(Leica, Nussloch, Germany) at 20°C. Sections were processed for
detection of multiple markers to compare the differences between
wild-type (wt) and tPA/ EAE mice.
Primary antibodies were chosen that detect axonal damage [amyloid
precursor protein (APP), a gift from Dr. W. van Nostrand, SUNY Stony
Brook], myelin [myelin basic protein (MBP); Roche Products, Hertforshire, UK], activated macrophage/microglia (F4/80; Serotec, Indianapolis, IN), and activated microglia (5-D-4; Seikagaku Kogyo, Tokyo, Japan) (Ferguson et al., 1997; Kennedy et al., 1998; Kiefer et
al., 1998; Wilms et al., 1999). To perform immunohistochemistry, sections were fixed with 4% paraformaldehyde in PBS, washed in 0.3%
H2O2 to block endogenous
peroxidase, and then incubated overnight at 4°C in primary antibodies
at the appropriate concentrations. After washing in PBS, sections were
incubated with biotinylated secondary antibodies (Vector Laboratories,
Burlingame, CA). The avidin-biotin complex was visualized with
diaminobenzidine and H2O2
(Vector Laboratories), as described previously (Tsirka et al.,
1997).
Quantitative Western blot analysis. Spinal cord extracts
were prepared in 0.25% Triton X-100 in PBS. Cell debris was removed by
centrifugation, and total protein concentration was measured using the
Bio-Rad (Richmond, CA) Bradford Dc assay. Twenty-five micrograms of
protein was separated by 12% SDS-PAGE and transferred on a
polyvinylidene difluoride membrane. Membranes were blocked using 5%
nonfat dry milk in PBS containing 0.05% Tween 20 and incubated
overnight at 4°C with sheep anti-goat plasminogen activator inhibitor
(PAI)-1 antibody (1:1000; American Diagnostic); goat polyclonal
monocyte chemotactic protein (MCP)-1 antibody; goat polyclonal
regulated on activation, normal T cell expressed and secreted (RANTES)
antibody (1:500); monoclonal mouse anti-human B cell/CD22 antibody
(1:500; Dako, Carpinteria, CA); monoclonal rat anti-human T cell/CD3
antibody (1:500; Serotec); or monoclonal mouse anti-rat osteopontin
(OPN) (1:500; obtained from Developmental Studies Hybridoma Bank,
University of Iowa, Iowa City, IA). Then the immunocomplex was detected
with biotinylated anti-rabbit IgG (Vector Laboratories). For
quantification of the bands, the biotinylated secondary antibody was
detected using FITC-labeled ExtrAvidin (1:200; Sigma, St. Louis, MO).
Emitted fluorescence was visualized by FluorImager (Molecular Devices,
Palo Alto, CA), which has an extended dynamic linear range, and
quantified using ImageQuant software. Sample loading was visualized by
Ponceau S red staining.
Amidolytic assay for tPA activity. For the quantitative
determination of tPA activity, amidolytic assays were performed as described previously (Andrade-Gordon and Strickland, 1986). Briefly, spinal cord was lysed in 0.25% Triton X-100 and incubated in a mix
containing either 0.3 mM S-2251 and 0.42 µM plg or 0.3 mM S-2288
(which is specific for tPA) in 0.1 M Tris
HCl, pH 8.1, 0.1% Tween 80. The samples were incubated at 25°C. The
change in absorbency ( A) at 405 nm was measured at different time
points. Known concentrations of recombinant tPA were used as controls. tPA activity was calculated from the initial rates in the amidolytic assay. Total protein content in the aliquots of each sample was determined using the Bio-Rad Bradford Dc assay. These concentrations were used to normalize the amount of tPA in each sample. The
measurements were performed in triplicate.
RNA isolation and reverse transcriptase-PCR. Mice were
killed at different time points during the course of EAE, and the
lumbar spinal cords were removed immediately. Total RNA was extracted using the TriPure isolation reagent (Boehringer Mannheim, Indianapolis, IN) according to the manufacturer's instructions. The concentration of
RNA was determined by UV spectroscopy at 260 nm. From each sample, 5 µg of RNA was used for synthesis of the first oligo-dT-primed cDNA
strand with Moloney murine leukemia virus reverse transcriptase (RT; Invitrogen, San Diego, CA). cDNA (50 ng) from each spinal cord was
then used for PCR in a final volume of 50 µl using the primers for
mouse CD8 , tumor necrosis factor- (TNF-), inducible nitric
oxide synthase (iNOS), or  -actin. The cDNA templates were denatured for 5 min at 94°C and then amplified using 35 cycles of
denaturing (94°C, 30 sec), annealing (60-65°C, 30 sec), and extension (74°C, 45 sec). The final step was incubation for 7 min at
42°C. Each sample was amplified using a FastStart DNA Master SYBR Green I kit in a real-time LightCycler system (Roche
Products). The level of each specific cDNA was quantified in the
exponential phase of PCR product accumulation and normalized by the
level of actin expression in each individual sample. Primers used for PCR amplification are listed in Table
1.
| |
RESULTS |
Levels of tPA activity reflect the clinical course of EAE in
wt mice
The spinal cords from MOG-induced EAE mice were removed at
different time points. As shown in Figure
1A, the level of tPA activity increased up to fourfold by day 20 (3.2 ng of tPA per microgram of protein vs 0.8 for the control mice). The tPA activity was
increased during the period that the EAE mice were observed to be
symptomatic (see below) but returned almost to control levels after
recovery (1.2 ng of tPA per microgram of protein). Increases in tPA
release are generally accompanied by release in parallel of its
inhibitors (PAIs) to ensure stringent regulation of potentially deleterious proteolytic activity. In situ upregulation of
tPA and PAI-1 and elevated tPA and PAI-1 antigen levels in the CSF of
MS patients have been reported previously (Akenami et al., 1996, 1997,
1999). Accordingly, we assessed whether PAI-1 expression was altered
during the clinical course of EAE. As shown in Figure 1B, the level of PAI-1 expression was increased
during the period of EAE clinical symptoms and returned almost to
normal levels after recovery. However, PAI-1 expression increased more
slowly and to a lesser extent than was observed for the increase in tPA activity. Given the stoichiometric interaction between tPA and PAI-1
(Kiefer et al., 1998), the increase in tPA would appear to be
prevalent, further suggesting that (nonsequestered) tPA activity
increases in vivo during EAE.
View larger version (18K):
[in this window]
[in a new window]
|
Figure 1.
Levels of tPA activity increase during the
clinical course of MOG-induced EAE in wt mice. Lumbar spinal cord
lysates were prepared from wt EAE mice at different time points after
MOG injection. Uninjected adult female mice were used as controls.
Top, To quantitatively determine tPA activity,
amidolytic assays were performed as described in Materials and Methods.
Total protein content in aliquots of each sample was determined using
the Bradford assay. Note that tPA activity significantly increased
during the disease but returned to near normal levels after recovery.
Although this assay does not discriminate between uPA and tPA activity,
uPA is unlikely to have contributed to the increased activity observed
for two reasons: (1) previous reports (Akenami et al., 1996; Cuzner et
al., 1996) using tPA-specific assays have demonstrated that it is the
activity of tPA rather than uPA that becomes upregulated, and (2) we
performed in situ zymographic assays on spinal cord
sections in the presence or absence of amiloride, a specific uPA
inhibitor, and observed no differences in activity (data not shown).
This result is consistent with our previous report that uPA mRNA and
protein are not detected in the mouse CNS (Tsirka et al., 1997).
Bottom, PAI-1 expression was determined by Western
blotting. FluorImager was used for the quantification of the bands.
Note that the level of PAI-1 expression also increased during this
period, although less quickly or dramatically than tPA, and returned to
baseline levels after recovery. The data are presented as mean ± SEM (n = 3 mice). *p < 0.05;
Student's t test.
|
|
Altered progression of EAE in tPA/ mice
To evaluate the role of tPA in EAE, the clinical course of
MOG-induced EAE was assessed in tPA/
mice. C57BL/6(H-2b) wt mice exhibited
signs of disease on average at day 7.8 ± 0.5 after immunization
and developed a chronic course (Fig. 2)
that was accompanied by histopathological hallmarks of EAE, such as spinal cord inflammation and demyelination (Fig.
3), in agreement with the literature
(Suen et al., 1997). By day 40, the clinical score observed for wt mice
was 1 (flaccid tail) (Fig. 2), and they exhibited no other motor
dysfunction. In contrast, the tPA/
mice, which otherwise were genetically quite similar to the wt mice
because they had been back crossed for 10 generations to the C57BL/6
background, showed a significant delay in disease onset (day 11.5 ± 0.6). However, they exhibited more severe symptoms at later time
points (e.g., day 50) (Table 2). The
tPA-deficient mice had a much slower recovery; their neurological and
motor dysfunction continued over extended periods of time,  100 d
after immunization (data not shown). To evaluate whether the altered progression of EAE was subject to a dosage effect, we subjected heterozygous (tPA+/) animals to EAE.
These mice exhibited clinical symptoms at approximately day 8, which
was similar to wt mice, and the subsequent clinical symptomatology of
the disease also followed the wt time course (data not shown).
Accordingly, a 50% reduction in the amount of tPA present does not
suffice to alter the progression of EAE; instead, a more dramatic
reduction is required. This result is in agreement with data obtained
from other experimental paradigms (Dickson et al., 1993; London
et al., 1996). The altered progression (delay in onset) of EAE in
tPA/ mice indicates that tPA
contributes to neuronal degeneration during the early stage of EAE. At
later stages of EAE, however, tPA appears be beneficial in neuronal
regeneration, because the tPA/ mice
exhibited slower recovery and more severe and sustained symptoms.
View larger version (17K):
[in this window]
[in a new window]
|
Figure 2.
Altered progression of EAE in
tPA/ mice. The wt and
tPA/ mice were injected with
MOG35-55 peptide in CFA and pertussis toxin
(PT) to induce EAE. The disease severity was
scored on a clinical scale from 0 to 5 as described in Materials and
Methods. The average score for each day was calculated by averaging the
clinical score for that day for each mouse in the group
(n = 12 mice for each group).
tPA/ mice showed a significant delay in the
onset of EAE, followed by a delay in recovery. Table 2 presents the
statistical significance in the day of onset, average maximum clinical
score, and score at day 50.
|
|
View larger version (113K):
[in this window]
[in a new window]
|
Figure 3.
Delayed demyelination in
tPA/ mice during EAE. Frozen cross sections of
spinal cords from wt and tPA/ mice at different
time points during the EAE course were stained with LFB and Nuclear Red
(A). Note the extensive demyelination and
infiltration of inflammatory cells evident in sections of wt
mice at day 15 and in sections of tPA/ mice
until day 100. The dashed line demarcates the border of
the dorsal horn (as denoted by asterisks), where
demyelination is observed. B, Immunohistochemistry using
an antibody to visualize MBP revealed similar patterns of demyelination
(600× magnification).
|
|
Delayed demyelination in tPA/ EAE mice
Inflammation and demyelination are two well defined
characteristics of EAE. Luxol Fast Blue (LFB) histological stain was
used to stain for myelin, and Nuclear Red was used to show influx of inflammatory cells. Myelination was examined at the dorsal horn of the
spinal cord (to which the myelinated axons normally extend). At days 0 and 10, there were no significant differences between wt and
tPA/ mice. In contrast, severe
demyelination was detected in wt but not in
tPA/ EAE mice at day 15. As shown in
Figure 3, a significant decrease in LFB intensity staining (indicating
demyelination) is obvious in the dorsal horn (as indicated by
asterisks) of the spinal cord of wt mice, but only minimal
demyelination is seen in tPA/ animals.
Both strains exhibited extensive inflammatory cell infiltrates. By day
100, the clinical symptoms of EAE were no longer evident in the wt
mice, and they appeared to have recovered from the inflammation and
demyelination. However, the clinical symptoms and inflammatory pathology were still quite severe in the
tPA/ EAE mice. Demyelination was also
evaluated by MBP immunohistochemistry (Fig. 3B); extensive
demyelination was observed at early time points in the wt mice (day
15), whereas for the tPA/ mice, the
onset of demyelination was again observed to be delayed (minimal
demyelination was observed at day 15) but then continued beyond day 100.
Delayed axonal damage in tPA/ mice
during EAE
Early neuronal degeneration is a newly identified pathological
characteristic of MS. Using histopathological markers that specifically
detect damaged axons, axonal degeneration has been shown to occur
throughout active lesions even early in the course of the disease and
to be present at the active borders of less acute lesions (McDonald et
al., 1992; Ferguson et al., 1997; Trapp et al., 1998; Waxman, 1998). An
antibody to APP was used to detect axonal damage in EAE. APP is
normally expressed in neurons but only at low levels that are not
detectable by standard immunocytochemistry. Its detection at sites of
axonal injury is thought to represent accumulation attributable
to failure of axonal transport (Ferguson et al., 1997; Bitsch et
al., 2000; Bjartmar and Trapp, 2001). We found that in EAE wt mice, APP
could be detected on day 10, had reached its peak at day 15, and
decreased to negligible levels by day 100. In contrast, however, in EAE
tPA/ mice, APP was not observed until
day 15, and then it continued to be detectable through day 100 (Fig.
4). At day 0, there was no difference in
APP immunoreactivity between wt and
tPA/ animals, indicating that there
are no intrinsic differences between the two genotypes.
View larger version (98K):
[in this window]
[in a new window]
|
Figure 4.
Delayed axonal damage in
tPA/ mice during EAE. Using an antibody directed
against APP, neuronal degeneration was detected in the white matter of
spinal cord sections from wt mice as early as day 10 and more strongly
at day 15. For the tPA/ mice, in contrast, only
minimal APP was detected, and even that was not observed until day 15 (600× magnification).
|
|
Attenuated microglial activation in tPA/
mice during the course of EAE
Activated microglia accumulate and presumably play a role in
MS/EAE (Benveniste, 1997; Diemel et al., 1998). In the kainic acid-induced excitotoxic neurodegeneration model, tPA has been shown to
mediate microglial activation (microglial activation in
tPA/ mice is attenuated) (Tsirka et
al., 1995; Rogove et al., 1999; Siao and Tsirka, 2002). We evaluated
the levels of microglial activation at different time points (days 0, 10, 15, and 100) during EAE, using antibodies either to the mature
macrophage/microglial-specific antigen F4/80 or to the microglial
surface antigen 5-D-4 (Fig. 5).
Microglial activation, assessed by immunohistochemistry for both
markers of microglia/macrophages, was not detectable at day 0 and was
very limited at day 10 (data not shown) in both wt and tPA/ animals. Highly activated
macrophage/microglial cells were found in wt mice at day 15, and this
activation persisted through day 100 (Fig. 5, arrows). In
contrast, microglial activation in
tPA/ EAE mice was delayed and
attenuated, with minimal presence of F4/80+ and
5-D-4+ cells (and decreased intensity of
staining for the two markers) at day 15. At day 100, activated
macrophages/microglia were present in
tPA/ mice, but even then the cells
were not fully activated judging from the lack of extensive branching
of their processes and amoeboid morphology. These results suggest a
possible mechanism of action through which altering the levels of tPA
might affect EAE progression (i.e., through interference with
microglial activation).
View larger version (63K):
[in this window]
[in a new window]
|
Figure 5.
Attenuated microglial activation in
tPA/ mice during the course of EAE. Frozen cross
sections of spinal cords from wt and tPA/ mice
at different time points of EAE were probed using antibodies directed
against either the mature macrophage/microglia-specific antigen F4/80
or the microglial-specific cell surface antigen 5-D-4. Highly activated
microglial cells were found in wt mice at day 15. In contrast, only
attenuated microglial activation was noted in
tPA/ mice, and even that was only seen at day
100. Arrows point to individual activated
macrophage/microglial cells (600× magnification).
|
|
Alteration in cytokine/chemokine expression in
tPA/ mice during EAE
Members of the CC chemokine family have been implicated in the
immunopathology of EAE (Kuchroo et al., 1993). Moreover, the production
of MCP-1 and RANTES in the CNS has been associated with disease
symptoms in EAE models (Hulkower et al., 1993; Godiska et al., 1995;
Kennedy et al., 1998; Asensio et al., 1999). Lysates of spinal cords
from wt and tPA/ mice collected at
different time points during the course of EAE (days 0, 10, 15, 24, and
45) were prepared and used to perform quantitative Western blotting
analysis. As shown in Figure
6A, delayed expression
of MCP-1 was found in the tPA/ EAE
mice. From days 10 to 15, MCP-1 expression increased twofold in wt
mice. The increase was less dramatic in
tPA/ mice. However, from days 15 to
24, MCP-1 expression was still increasing (more than twofold) in
tPA/ mice but had already decreased in
wt mice. The increase in RANTES expression (Fig. 6A)
was not as robust as that of MCP-1, but the trend was similar.
View larger version (30K):
[in this window]
[in a new window]
|
Figure 6.
Altered expression of chemokines and cytokines in
tPA/ mice during the course of EAE.
A, Quantitative Western blotting analysis for chemokines
was performed using spinal cord lysates from wt and
tPA/ mice at days 0, 10, 15, 24, and 45 of EAE,
using either anti-MCP-1 antibody, anti-RANTES antibody, or anti-OPN.
Note the delayed expression of all three chemokines and persistent
expression of MCP-1 and OPN in the tPA/ mice
during the course of EAE. B, Quantitative RT-PCR
analysis for TNF- and iNOS. RNA from lumbar spinal cords of wt and
tPA/ mice at days 0, 10, 24, and 45 after MOG
injection was used to perform RT-PCR in a real-time LightCycler system.
Specific primer sets were designed to detect the cytokines iNOS and
TNF- (described in Table 1). The level of specific mRNAs was
quantified in the exponential phase of PCR product accumulation and
normalized by comparison with standard curves obtained from serial
dilutions of plasmids encoding cDNAs for each gene.
|
|
OPN, also called early T cell activator gene-1, costimulates T cell
proliferation and is classified as a T helper cell-1 (Th1) cytokine. It
was reported very recently that OPN transcripts are elevated in EAE,
and that OPN-deficient mice are resistant to EAE (Chabas et al., 2001).
Accordingly, we performed a Western blotting analysis to evaluate the
OPN expression level in both wt and
tPA/ mice. In wt mice, the level of
OPN increased by day 15 and then returned to control levels (Fig.
6A). In tPA/ mice,
the OPN expression level peaked at day 24 and remained high at day 45. Because interleukin-10 production is upregulated by OPN and has been
associated with remission from EAE, the sustained OPN expression in
tPA/ EAE mice may partly explain the
sustained symptoms in the later stages of EAE.
The levels of TNF- and iNOS, other cytokines known to be upregulated
during EAE, were evaluated using quantitative RT-PCR. Rapid and
dramatic upregulation of both TNF- and iNOS was observed at days 10, 24, and 45 in wt mice (Fig. 6B). In the
tPA/ mice, in contrast, the expression
of the two cytokines did increase, but more slowly and to a
significantly lesser degree. Because both cytokines are synthesized and
secreted primarily by activated microglia (Kreutzberg, 1996), these
data are in agreement with the observation (Fig. 5) that microglial
activation is attenuated in tPA/ mice.
Alteration of a T cell proliferation/activation marker but not a B
cell marker in tPA/ mice during EAE
EAE is a T cell-mediated autoimmune disease. Therefore, we set out
to assess whether possible differences in the
tPA/ immune response could account for
the altered disease progression. CD3 and CD22 were used as markers for
T and B cells, respectively. Using quantitative Western blotting
analysis, T cell proliferation during EAE was found to occur but to be
delayed in tPA/ mice (Fig.
7A). However, no significant
difference was detected for the B cell marker (Fig. 7A).
This observation supports the notion that T cells play a very important
role in this disease, and that this role is affected in the absence of
tPA. The expression levels of CD3 and CD22 did not differ between
tPA/ and wt mice at days 0 and 10, suggesting that there are not obvious baseline differences in the
tPA/ immune system. We also assessed
the levels of expression of CD8 (as a marker for cytotoxic T cells).
Quantitative RT-PCR was used to determine these levels. As shown in
Figure 7B, the expression of CD8 is very low in
tPA/ animals compared with wt ones,
possibly leading to lower levels of neurodegeneration in the
tPA/ mice (Fig. 4).
View larger version (19K):
[in this window]
[in a new window]
|
Figure 7.
Alteration of a T cell proliferation/activation
marker but not a B cell marker in tPA/ mice
during EAE. A, Quantitative Western blotting analysis
was performed using spinal cord lysates from wt and
tPA/ mice at days 0, 10, 15, 24, and 45 of EAE,
using either anti-T cell/CD3 or anti-B cell/CD22. Note that the
expression of the T cell marker (but not that of the B cell marker)
showed a delayed rise in tPA/ mice during EAE.
No differences in marker expression were observed at day 0. B, Quantitative RT-PCR analysis of CD8, a marker for
cytotoxic T cells. RNA from lumbar spinal cords of wt and
tPA/ mice at days 0, 10, 24, and 45 after MOG
injection was used to perform RT-PCR in a real-time LightCycler system.
Specific primer sets were designed as described in Table 1. The level
of specific mRNAs was quantified in the exponential phase of PCR
product accumulation and normalized by comparison with standard curves
obtained from serial dilutions of a plasmid containing the CD8
cDNA.
|
|
| |
DISCUSSION |
In this study, using mice lacking tPA, we examined changes in the
clinical course and histopathology of
MOG35-55-induced EAE, an animal model for MS. We
found that tPA/ mice exhibit (1)
altered EAE progression characterized by delayed onset but then
increased severity at later time points, resulting in delayed recovery
of neurological and motor dysfunction; (2) delayed demyelination, which
then persists >100 d after the EAE onset; (3) attenuated microglial
activation; (4) delayed axonal degeneration; and (5) delayed expression
of chemokines and altered/reduced expression of cytokines. We also
found that levels of tPA activity increase during the clinical course
of EAE in wt mice.
Our data indicate that tPA is involved in the pathogenesis of EAE.
Reviewing the literature, several possible mechanisms through which tPA
may be acting can be proposed. First, tPA may promote demyelination,
because plasmin (which is generated by the action of tPA on
plasminogen) can directly degrade MBP (Cammer et al., 1978). In
addition, plasmin is the key initiator of the matrix metalloproteinase
(MMP) activation cascade. MMP activity has been documented to have an
important role in the breakdown of myelin membranes (Cuzner and
Opdenakker, 1999). Second, tPA may alter inflammatory reactions in the
CNS by increasing the permeability of the blood-brain barrier
(Paterson et al., 1987). Third, because tPA can promote excitotoxic
cell death, tPA may also play a role in the early stages of MS by
contributing to glutamate-induced oligodendrocyte injury and neuronal
death (Pitt et al., 2000; Smith et al., 2000). Fourth, tPA may help
neuronal regeneration by reducing local fibrin deposition (Herbert et
al., 1996; Akassoglou et al., 2000) or by promoting migration of
oligodendrocyte progenitors through the extracellular matrix (Uhm et
al., 1998). It is probable that tPA plays both harmful and beneficial
roles in MS, and that its involvement is complex.
There is precedent for the involvement of tPA, and plasminogen
activators in general, in different autoimmune diseases. In rheumatoid
arthritis, elimination of tPA or urokinase plasminogen activator (uPA)
results in exacerbation of the disease and very severe clinical
symptoms (Yang et al., 2001). In other studies, this finding has been
attributed to disease-specific conformational changes of its remaining
assembled substrate, plasminogen, on cell or fibrin surfaces, which
results in the presentation of new epitopes recognized by
autoantibodies (Dominguez et al., 2001). Furthermore, in patients with
systemic lupus erythematosus, decreased levels of tPA have been
measured along with increases in the levels of PAI-1. The changes in
the levels of tPA were shown to be caused by the presence of
auto-antibodies to fibrin-bound tPA (Salazar-Paramo et al., 1996).
Changes in the levels of tPA and tPA activity have also been observed
in antiphospholipid syndrome (Ieko et al., 2000), a disease that
occasionally is indistinguishable from MS (Cuadrado et al., 2000). Such
fluctuations in the expression of plasminogen activators are thought to
be the primary reason for the frequent incidence of thromboses observed
in these diseases (Satoh et al., 1998; Munoz-Rodriguez et al.,
2000).
More interestingly, activated microglia also appear to play complex
roles in MS/EAE. Microglia, the immunocompetent cells of the CNS
(Kreutzberg, 1996), are thought to contribute to MS/EAE through several
mechanisms, including production of proinflammatory cytokines,
proteases, and free radicals (Benveniste, 1997). However, microglia may
also potentially contribute to recovery from MS/EAE by expressing a
wide variety of growth factors and cytokines. These include several
that directly affect oligodendrocyte survival, proliferation, and
differentiation, such as insulin-like growth factor-1, platelet-derived
growth factor, and fibroblast growth factor (Diemel et al., 1998). The
microglia also express immunosuppressive TGF-1, which may promote
MS/EAE remission (Kiefer et al., 1998). We assessed the expression of
TGF-1 during MOG35-55-induced EAE; in wt
mice, TGF-1 is expressed as reported previously (Kiefer et al.,
1998) (i.e., it was increased late in the course of EAE). In contrast,
decreased expression was found in the
tPA/ EAE mice (data not shown).
Consistent with this, delayed and decreased microglial activation was
noted in tPA/ EAE mice.
The activation/proliferation of T cells and the infiltration of
cytotoxic T cells (which is evident by the increased expression of
CD8) were delayed in tPA/ EAE mice.
However, whether this is the cause of the delayed onset and recovery or
just a component or consequence of the clinical course will need to be
addressed. Apoptosis of T lymphocytes is thought to be a key element in
the downregulation of autoimmune CNS inflammation. This apoptosis
affects both autoreactive T-cell populations and secondarily recruited
lymphocytes. Elimination of T cells may depend at least in part on
intact Fas-Fas ligand (FasL) signaling (Bauer et al., 1998). In
the CNS, Fas+ T cells and
FasL+ microglial cells and macrophages
have been found in the brains of MS patients, suggesting that
Fas-induced apoptosis of T cells by microglial cells may occur. In our
quantitative Western blot analysis, CD3 was expressed at higher levels
in tPA/ mice at unexpectedly late time
points (days 24 and 45), possibly suggesting a defect in T cell
apoptosis. Intriguingly, we have observed that in a different model of
apoptosis (in the spontaneous neurodegeneration- and premature
apoptosis-prone lurcher mouse), tPA does mediate the c-JunP, caspase-8
apoptotic pathway (Lu and Tsirka, 2002). This pathway is initiated via
Fas-FasL interactions and signaling. It is therefore possible that the
persistence of T cells and deficient T cell elimination in
tPA/ mice is a potential cause or
primary component of the prolonged EAE clinical symptoms and inflammation.
The pattern of delay/failure of the tPA-deficient animals with regard
to recovery from acute MOG-induced EAE is very reminiscent of the EAE
progression pattern in interferon- knock-out mice primed with
MOG35-55, for which the disease appears to be mediated by Th2 (Chu et al., 2000). The decreased expression of TNF-
in the tPA/ animals would also suggest
that this disease may be Th2 in nature (Fig. 6B).
It is probable that tPA and microglia play both harmful and beneficial
roles in MS/EAE, and that there is a balance between injury and
recovery. This balance may be regulated via the expression and
secretion of cytokines and proteolytic enzymes. Our results suggest
that attenuation of tPA activity in a temporally restricted manner
could prove beneficial in combination with the existing therapeutic
management of MS.
| |
FOOTNOTES |
Received Sept. 9, 2002; revised Sept. 30, 2002; accepted Oct. 1, 2002.
This work was supported by a grant from the National Institutes of
Health, a research grant from the Wadsworth Foundation, and a Targeted
Research Opportunities award (S.E.T.). We thank Drs. K. Akassoglou and M. Frohman for advice and critical reading of this
manuscript. We also thank members of the Tsirka laboratory for helpful suggestions.
Correspondence should be addressed to Dr. Stella Tsirka, Department of
Pharmacological Sciences, University Medical Center at Stony Brook,
Stony Brook, NY 11794-8651. E-mail: stella{at}pharm.sunysb.edu.
| |
REFERENCES |
-
Akassoglou K,
Kombrinck K,
Degen J,
Strickland S
(2000)
Tissue plasminogen activator-mediated fibrinolysis protects against axonal degeneration and demyelination after sciatic nerve injury.
J Cell Biol
149:1157-1166[Abstract/Free Full Text].
-
Akenami F,
Sirén V,
Koskiniemi M,
Siimes M,
Teräväinen H,
Vaheri A
(1996)
Cerebrospinal fluid activity of tissue plasminogen activator in patients with neurological diseases.
J Clin Pathol
49:577-580[Abstract/Free Full Text].
-
Akenami F,
Koskiniemi M,
Mustjoki S,
Siren V,
Farkkila M,
Vaheri A
(1997)
Plasma and cerebrospinal fluid activities of tissue plasminogen activator and urokinase in multiple sclerosis.
Fibrinolysis Proteolysis
11:109-113.
-
Akenami F,
Siren V,
Wessman M,
Koskiniemi M,
Vaheri A
(1999)
Tissue plasminogen activator gene expression in multiple sclerosis brain tissue.
J Neurol Sci
165:71-76[ISI][Medline].
-
Andrade-Gordon P,
Strickland S
(1986)
Interaction of heparin with plasminogen activators and plasminogen: effects on the activation of plasminogen.
Biochemistry
25:4033-4040[Medline].
-
Asensio VC,
Lassmann S,
Pagenstecher A,
Steffensen SC,
Henriksen SJ,
Campbell IL
(1999)
C10 is a novel chemokine expressed in experimental inflammatory demyelinating disorders that promotes recruitment of macrophages to the central nervous system.
Am J Pathol
154:1181-1191[Abstract/Free Full Text].
-
Bauer J,
Bradl M,
Hickey W,
Forss-Peter S,
Breitschopf H,
Linington C,
Wekerle H,
Lassmann H
(1998)
T cell apoptosis in acute inflammatory lesions.
Am J Pathol
153:715-724[Abstract/Free Full Text].
-
Benveniste E
(1997)
Role of macrophages/microglia in multiple sclerosis and experimental allergic encephalomyelitis.
J Mol Med
75:165-173[ISI][Medline].
-
Bernard CC,
Johns TG,
Slavin A,
Ichikawa M,
Ewing C,
Liu J,
Bettadapura J
(1997)
Myelin oligodendrocyte glycoprotein: a novel candidate autoantigen in multiple sclerosis.
J Mol Med
75:77-88[ISI][Medline].
-
Bitsch A,
Schuchardt J,
Bunkowski S,
Kuhlmann T,
Bruck W
(2000)
Acute axonal injury in multiple sclerosis. Correlation with demyelination and inflammation.
Brain
123:1174-1183[Abstract/Free Full Text].
-
Bjartmar C,
Trapp B
(2001)
Axonal and neuronal degeneration in multiple sclerosis: mechanisms and functional consequences.
Curr Opin Neurol
14:271-278[ISI][Medline].
-
Cammer W,
Bloom BR,
Norton WT,
Gordon S
(1978)
Degradation of basic protein in myelin by neutral proteases secreted by stimulated macrophages: a possible mechanism of inflammatory demyelination.
Proc Natl Acad Sci USA
75:1554-1558[Abstract/Free Full Text].
-
Carmeliet P,
Schoonjans L,
Kieckens L,
Ream B,
Degen J,
Bronson R,
De Vos R,
van den Oord J,
Collen D,
Mulligan R
(1994)
Physiological consequences of loss of plasminogen activator gene function in mice.
Nature
368:419-424[Medline].
-
Chabas D,
Baranzini SE,
Mitchell D,
Bernard CCA,
Rittling SR,
Denhardt DT,
Sobel RA,
Lock C,
Karpuj M,
Pedotti R,
Heller R,
Oksenberg JR,
Steinman L
(2001)
The influence of the proinflammatory cytokine, osteopontin, on autoimmune demyelinating disease.
Science
294:1731-1735[Abstract/Free Full Text].
-
Chu CQ,
Wittmer S,
Dalton DK
(2000)
Failure to suppress the expansion of the activated CD4 T cell population in interferon gamma-deficient mice leads to exacerbation of experimental autoimmune encephalomyelitis.
J Exp Med
192:123-128[Abstract/Free Full Text].
-
Cuadrado MJ,
Khamashta MA,
Ballesteros A,
Godfrey T,
Simon MJ,
Hughes GR
(2000)
Can neurologic manifestations of Hughes (antiphospholipid) syndrome be distinguished from multiple sclerosis? Analysis of 27 patients and review of the literature.
Medicine (Baltimore)
79:57-68[Medline].
-
Cuzner ML,
Opdenakker G
(1999)
Plasminogen activators and matrix metalloproteases, mediators of extracellular proteolysis in inflammatory demyelination of the central nervous system.
J Neuroimmunol
94:1-14[ISI][Medline].
-
Cuzner M,
Gveric D,
Strand C,
Loughlin A,
Paemen L,
Opdenakker G,
Newcombe J
(1996)
The expression of tissue-type plasminogen activator, matrix metalloproteases and endogenous inhibitors in the central nervous system in multiple sclerosis: comparison of stages in lesion evolution.
J Neuropathol Exp Neurol
55:1194-1204[ISI][Medline].
-
Dickson D,
Lee S,
Mattiace L,
Yen S,
Brosnan C
(1993)
Microglia and cytokines in neurological disease, with special reference to AIDS and Alzheimer's disease.
Glia
7:75-83[ISI][Medline].
-
Diemel LT,
Copelman CA,
Cuzner ML
(1998)
Macrophages in CNS remyelination: friend or foe?
Neurochemical Res
23:341-347[ISI][Medline].
-
Dominguez M,
Cacoub P,
Garcia de la Torre I,
Piette TJ,
Salazar-Paramo M,
Godeau P,
Anglees-Cano E
(2001)
Autoantibodies to receptor induced neoepitopes of fibrinolytic proteins in rheumatic and vascular diseases.
J Rheumatol
28:302-308[Medline].
-
Ferguson B,
Matyszak M,
Esiri M,
Perry V
(1997)
Axonal damage in acute multiple sclerosis lesions.
Brain
120:393-399[Abstract/Free Full Text].
-
Godiska R,
Chantry D,
Dietsch GN,
Gray PW
(1995)
Chemokine expression in murine experimental allergic encephalomyelitis.
J Neuroimmunol
58:167-176[ISI][Medline].
-
Herbert CB,
Bittner GD,
Hubbell JA
(1996)
Effects of fibrinolysis on neurite growth from dorsal root ganglia cultured in two- and three-dimensional fibrin gels.
J Comp Neurol
365:380-391[Medline].
-
Hjelmstrom P,
Juedes AE,
Fjell J,
Ruddle NH
(1998)
B-cell-deficient mice develop experimental allergic encephalomyelitis with demyelination after myelin oligodendrocyte glycoprotein sensitization.
J Immunol
161:4480-4483[Abstract/Free Full Text].
-
Hulkower K,
Brosnan CF,
Aquino DA,
Cammer W,
Kulshretha S,
Guida MP,
Rapoport DA,
Berman JW
(1993)
Expression of CSF-1, c-fms, and MCP-1 in the central nervous system of rats with experimental allergic encephalomyelitis.
J Immunol
150:2525-2533[Abstract].
-
Ieko M,
Ichikawa K,
Atsumi T,
Takeuchi R,
Sawada KI,
Yasukouchi T,
Koike T
(2000)
Effects of 2-glycoprotein I and monoclonal anticardiolipin antibodies on extrinsic fibrinolysis.
Semin Thromb Hemost
26:85-90[ISI][Medline].
-
Kennedy KJ,
Strieter RM,
Kunkel SL,
Lukacs NW,
Karpus W
(1998)
Acute and relapsing experimental autoimmune encephalomyelitis are regulated by differential expression of the CC chemokines macrophage inflammatory protein-1a and monocyte chemotactic protein-1.
J Neuroimmunol
92:98-108[ISI][Medline].
-
Kiefer R,
Schweitzer T,
Jung S,
Toyka K,
Hartung H-P
(1998)
Sequential expression of transforming factor-b1 by T-cells, macrophages, and microglia in rat spinal cord during autoimmune inflammation.
J Neuropathol Exp Neurol
57:385-395[Medline].
-
Kreutzberg G
(1995)
Microglia, the first line of defense in brain pathologies.
Arzneimittelforschung
45:357-360[Medline].
-
Kreutzberg G
(1996)
Microglia: a sensor for pathological events in the CNS.
Trends Neurosci
19:312-318[ISI][Medline].
-
Kuchroo VK,
Martin CA,
Greer JM,
Ju S-T,
Sobel RA,
Dorf ME
(1993)
Cytokines and adhesion molecules contribute to the ability of myelin proteolipid protein-specific T cell clones to mediate experimental allergic encephalomyelitis.
J Immunol
151:4371-4382[Abstract].
-
London J,
Biegel D,
Pachter J
(1996)
Neurocytopathic effects of -amyloid-stimulated monocytes: a potential mechanism for central nervous system damage in Alzheimer's disease.
Proc Natl Acad Sci USA
93:4147-4152[Abstract/Free Full Text].
-
Lu W,
Tsirka S
(2002)
Partial rescue of neural apoptosis in the Lurcher mutant mouse through elimination of tissue plasminogen activator.
Development
129:2043-2050[Abstract/Free Full Text].
-
Martin R,
McFarland HF,
McFarlin DE
(1992)
Immunological aspects of demyelinating diseases.
Annu Rev Immunol
10:153-187[ISI][Medline].
-
McDonald W,
Miller D,
Barners D
(1992)
The pathological evolution of multiple sclerosis.
Neuropathol Appl Neurobiol
18:319-334[ISI][Medline].
-
Munoz-Rodriguez FJ,
Reverter JC,
Font J,
Tassies D,
Cervera R,
Espinosa G,
Carmona F,
Balasch J,
Ordinas A,
Ingelmo M
(2000)
Prevalence and clinical significance of antiprothrombin antibodies in patients with systemic lupus erythematosus or with primary antiphospholipid syndrome.
Haematologica
85:632-637[ISI][Medline].
-
Opdenakker G,
Damme J
(1994)
Cytokine-regulated proteases in autoimmune disease.
Immunol Today
15:103-107[ISI][Medline].
-
Paterson PY,
Koh C-S,
Kwaan HC
(1987)
Role of the clotting system in the pathogenesis of neuroimmunologic disease.
Fed Proc
46:91-96[ISI][Medline].
-
Pitt D,
Werner P,
Raine C
(2000)
Glutamate excitotoxicity in a model of multiple sclerosis.
Nat Med
6:67-70[ISI][Medline].
-
Rogove A,
Siao C-J,
Keyt B,
Strickland S,
Tsirka S
(1999)
Activation of microglia reveals a non-proteolytic cytokine function for tissue plasminogen activator in the central nervous system.
J Cell Sci
112:4007-4016[Abstract].
-
Salazar-Paramo M,
Garcia de la Torre I,
Fritzler MJ,
Loyau S,
Angles-Cano E
(1996)
Antibodies to fibrin-bound tissue-type plasminogen activator in systemic lupus erythematosus are associated with Raynaud's phenomenon and thrombosis.
Lupus
5:275-278[Abstract/Free Full Text].
-
Satoh N,
Abe T,
Nakajima A,
Ohkoshi M,
Koizumi T,
Tamada H,
Sakuragi S
(1998)
Analysis of uveitogenic sites in phosducin molecule.
Curr Eye Res
17:677-686[ISI][Medline].
-
Seeds N,
Williams B,
Bickford P
(1995)
Tissue plasminogen activator induction in Purkinje neurons after cerebellar motor learning.
Science
270:1992-1994[Abstract/Free Full Text].
-
Siao C-J,
Tsirka S
(2002)
Tissue plasminogen activator mediates microglial activation via its finger domain through annexin II.
J Neurosci
22:3352-3358[Abstract/Free Full Text].
-
Smith T,
Groom A,
Zhu B,
Turski L
(2000)
Autoimmune encephalomyelitis ameliorated by AMPA antagonists.
Nat Med
6:62-66[ISI][Medline].
-
Steinman L
(1996)
Multiple sclerosis: a coordinated immunological attack against myelin in the central nervous system.
Cell
85:299-302[ISI][Medline].
-
Suen W,
Bergman C,
Hjelmstroem P,
Ruddle N
(1997)
A critical role for lymphotoxin in experimental allergic encephalomyelitis.
J Exp Med
186:1233-1240[Abstract/Free Full Text].
-
Trapp B,
Peterson J,
Ransohoff R,
Rudick R,
Mork S,
Bo L
(1998)
Axonal transection in the lesions of multiple sclerosis.
N Engl J Med
338:278-285[Abstract/Free Full Text].
-
Tsirka S,
Gualandris A,
Amaral D,
Strickland S
(1995)
Excitotoxin induced neuronal degeneration and seizure are mediated by tissue-type plasminogen activator.
Nature
377:340-344[Medline].
-
Tsirka S,
Rogove A,
Bugge T,
Degen J,
Strickland S
(1997)
An extracellular proteolytic cascade promotes neuronal degeneration in the mouse hippocampus.
J Neurosci
17:543-552[Abstract/Free Full Text].
-
Uhm J,
Dooley N,
Oh L,
Yong V
(1998)
Oligodendrocytes utilize a matrix metalloproteinase, MMP-9, to extend processes along an astrocyte extracellular matrix.
Glia
22:53-63[ISI][Medline].
-
Waxman S
(1998)
Demyelinating disease-new pathological insights, new therapeutic targets.
N Engl J Med
338:323-325[Free Full Text].
-
Wilms H,
Wollmerb M,
Sievers J
(1999)
In vitro-staining specificity of the antibody 5-D-4 for microglia but not for monocytes and macrophages indicates that microglia are a unique subgroup of the myelomonocytic lineage.
J Neuroimmunol
98:89-95[ISI][Medline].
-
Wu Y-P,
Siao C-J,
Lu W,
Sung T-C,
Frohman M,
Milev P,
Bugge T,
Degen J,
Levine J,
Margolis R,
Tsirka S
(2000)
The tPA/plasmin extracellular proteolytic system regulates seizure-induced hippocampal mossy fiber outgrowth through a proteoglycan substrate.
J Cell Biol
148:1295-1304[Abstract/Free Full Text].
-
Yang YH,
Carmeliet P,
Hamilton JA
(2001)
Tissue-type plasminogen activator deficiency exacerbates arthritis.
J Immunol
167:1047-1052[Abstract/Free Full Text].
Copyright © 2002 Society for Neuroscience 0270-6474/02/222410781-09$05.00/0
This article has been cited by other articles:
|
|
|
|
 
A. Reijerkerk, G. Kooij, S. M. A. van der Pol, T. Leyen, B. van het Hof, P.-O. Couraud, D. Vivien, C. D. Dijkstra, and H. E. de Vries
Tissue-Type Plasminogen Activator Is a Regulator of Monocyte Diapedesis through the Brain Endothelial Barrier
J. Immunol.,
September 1, 2008;
181(5):
3567 - 3574.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
TOP
ABSTRACT
INTRODUCTION
