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The Journal of Neuroscience, April 15, 2001, 21(8):2669-2677
Coexpression of Microsomal-Type Prostaglandin E Synthase with
Cyclooxygenase-2 in Brain Endothelial Cells of Rats during
Endotoxin-Induced Fever
Kanato
Yamagata1,
Kiyoshi
Matsumura2,
Wataru
Inoue2,
Takuma
Shiraki2,
Kyoko
Suzuki1,
Shin
Yasuda1,
Hiroko
Sugiura1,
Chunyu
Cao3,
Yasuyoshi
Watanabe3, and
Shigeo
Kobayashi2
1 Department of Neuropharmacology, Tokyo Metropolitan
Institute for Neuroscience, Fuchu 183-8526, Japan,
2 Department of Intelligence Science and Technology,
Graduate School of Informatics, Kyoto University, Sakyo-ku, Kyoto
606-8501, Japan, and 3 Department of Neuroscience, Osaka
Bioscience Institute, Suita, Osaka 565-0874, Japan
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ABSTRACT |
Fever is triggered by an elevation of prostaglandin E2
(PGE2) in the brain. However, the mechanism of its
elevation remains unanswered. We herein cloned the rat
glutathione-dependent microsomal prostaglandin E synthase (mPGES), the
terminal enzyme for PGE2 biosynthesis, and examined its
induction in the rat brain after intraperitoneal injection of pyrogen
lipopolysaccharide (LPS). In Northern blot analysis, mPGES
mRNA was weakly expressed in the brain under the normal conditions but
was markedly induced between 2 and 4 hr after the LPS injection.
In situ hybridization study revealed that LPS-induced
mPGES mRNA signals were mainly associated with brain blood
vessels, especially vein or venular-type ones, in the whole brain area.
Immunohistochemical study demonstrated that mPGES-like immunoreactivity
was expressed in the perinuclear region of brain endothelial cells,
which were identified as von Willebrand factor-positive cells.
Furthermore, in the perinuclear region of the endothelial cells, mPGES
was colocalized with cyclooxygenase-2 (COX-2), which is the enzyme
essential for the production of the mPGES substrate
PGH2. Inhibition of cyclooxygenase-2 activity resulted in
suppression of both PGE2 level in the CSF and fever (Cao et al., 1997 ), suggesting that the two enzymes were functionally linked and that this link is essential for fever. These results demonstrate that brain endothelial cells play an essential role in the
PGE2 production during fever by expressing COX-2 and mPGES.
Key words:
prostaglandin E synthase; cyclooxygenase-2; endothelial
cell; fever; prostaglandin E2; brain
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INTRODUCTION |
Fever has been recognized as a
common sign of various diseases, and its proper management is still an
important issue in modern medicine. Fever is phylogenically old, at
least found among lower vertebrates, and seems to have some protective
values against pathogens (Kluger, 1991). Studies during the last three
decades provided three essential findings about the mechanism of fever (Dinarello et al., 1988; Kluger, 1991; Rothwell, 1997; Dinarello, 1999). First, fever is an elevation in body temperature controlled by
the CNS. Second, the CNS activity toward fever is triggered by
an elevation of a lipid mediator, prostaglandin
E2 (PGE2), in the brain.
Third, the elevation of PGE2 in the brain is
brought about by the actions of proinflammatory cytokines, including
interleukin-1- / (IL-1-/), IL-6, tumor necrosis
factor , and interferons, which are all produced by activated
immune cells in the periphery and in some cases in the brain. There
still remains a question, however, as to how brain
PGE2 is elevated by the cytokines during fever because these cytokines with molecular weights over 15 kDa unlikely penetrate the blood-brain barrier to act on brain cells directly.
This question may be answered by histochemical localization of either
PGE2 itself or
PGE2-synthesizing enzymes in the brain during
fever. PGE2 is biosynthesized through the
following three enzymatic steps (Smith et al., 1991): first,
phospholipase A2 (PLA2) acts on the membrane phospholipids to cleave
arachidonic acid; second, cyclooxygenase (COX) converts arachidonic
acid to PGH2; and finally, PGE synthase (PGES)
converts PGH2 to PGE2. Among these enzymes, we previously demonstrated a strong induction of
inducible-type of COX (COX-2) in a subset, but not all, of the brain
endothelial cells or perivascular cells in response to various
fever-inducing agents (Cao et al., 1995, 1996, 1998; Breder and Saper,
1996; Elmquist et al., 1997; Lacroix and Rivest, 1998; Matsumura et
al., 1998; Quan et al., 1998; Laflamme et al., 1999). Although this
fact led us to hypothesize that brain endothelial cells are the sites
of PGE2 production during fever, the final conclusion was hampered by the lack of evidence that PGES is also expressed in the brain endothelial cells. In this study, to test a
hypothesis that PGES is induced in brain endothelial cells along with
COX-2, we cloned the rat homolog of human microsomal
glutathione-dependent PGES (mPGES) (Jakobsson et al., 1999) from a rat
testis cDNA library and examined histochemically the expressions of its
mRNA and protein in the brain after systemic challenge with
lipopolysaccharide (LPS), a potent exogenous pyrogen derived from the
cell wall of Gram-negative bacteria. The results provided conclusive
evidence that brain endothelial cells are the sites of
PGE2 production in response to a peripheral
pyrogenic challenge and, hence, play the central role in evoking fever.
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MATERIALS AND METHODS |
Materials. Male Wistar rats of 8 weeks of age were
purchased from Shizuoka Laboratory Animal Cooperative (Shizuoka,
Japan). They were housed four or five to a cage in the room at 26 ± 2°C with a standard 12 hr light/dark cycle. Other materials and
their sources are as follows: lipopolysaccharide of Escherichia
coli 026:B6 (Sigma, St. Louis, MO); NS-398, a
COX-2-specific inhibitor (a generous gift from Dr. S. Higuchi of Taisho
Pharmaceutical, Tokyo, Japan); rabbit polyclonal antibody against human
mPGES (Cayman Chemical, Ann Arbor, MI); goat polyclonal antibody
against rat COX-2 (Santa Cruz Biotechnology, Santa Cruz, CA); sheep
polyclonal antibody against rat von Willebrand factor (Affinity
Biologicals, Ontario, Canada); TO-PRO3 (Molecular Probes,
Eugene, OR); multiple-labeling grade secondary antibodies (Jackson
ImmunoResearch, West Grove, PA); and PGE2 monoclonal enzyme
immunoassay (EIA) kit (Cayman Chemical).
Cloning of rat mPGES cDNA. To clone rat mPGES
cDNA, we first amplified human mPGES cDNA from a human brain
cDNA library (Clontech, Cambridge, UK) by using PCR with two
mPGES-specific primers (5'-ATG CCT GCC CAC AGC CTG GTG ATG
A-3' and 5'-TCA CAG GTG GCG GGC CGC TTC CC-3') (Jakobsson et al.,
1999). The amplified DNA fragments were directly sequenced in both
directions. Then we screened a rat testis cDNA library (Stratagene, La
Jolla, CA) with human mPGES cDNA probe according to standard
procedures (Sambrook et al., 1989). Briefly, ~5 × 105 phages of the rat testis cDNA library
were plated on the bacterial host XL1-Blue. Plaques were lifted onto
Hybond-N membranes (Amersham Pharmacia Biotech, Uppsala,
Sweden), and phage DNAs were denatured, neutralized, and cross-linked
to the membranes. Human mPGES cDNA was labeled with
[-32P]dCTP using the Random Primer
DNA Labeling kit (TaKaRa, Tokyo, Japan). Membranes were hybridized with
the radiolabeled human mPGES probe at 65°C for 18 hr in a
solution of 6× SSC, 0.5% SDS, 5× Denhardt's reagent, and 0.1 mg/ml
denatured salmon sperm DNA and finally washed in a solution of 2× SSC
and 0.5% SDS at 50°C for 1 hr. Seven positive plaques were isolated,
of which two containing the largest inserts were purified and cloned
into pBluescript (pBS) using the Stratagene in vivo
excision protocol. These two largest clones were sequenced in both directions.
Northern analysis. This procedure was performed as described
previously (Linzer and Nathans, 1983) with 30 µg of total RNA per
lane. The probe used for Northern analysis was a 1.5 kb pair fragment
of rat mPGES cDNA. The cDNA fragment was labeled by the random priming technique using
[-32P]dCTP.
In situ hybridization. Distribution of mPGES mRNA
in the rat brain was examined at 2, 4, and 12 hr after intraperitoneal
injection of LPS (0.4 mg/kg in 0.5 ml of saline). At each time point,
three rats were anesthetized with diethylether and perfused via the left ventricle with 50 ml of ice-cold saline followed by 200 ml of 4%
paraformaldehyde solution in 0.1 M phosphate
buffer, pH 7.4. The brains were put in a solution containing 20%
sucrose and 4% paraformaldehyde overnight and then frozen in dry-ice
powder. The brain sections of 16 µm thickness were made in a cryostat at  25°C and mounted on 3-aminopropyltriethoxysilane-coated
glass slides and stored at 80°C until hybridized with riboprobes.
35S-labeled rat mPGES antisense
riboprobe was prepared from an appropriately restricted pBS plasmid
containing nearly full-length rat mPGES cDNA. A sense strand
35S-labeled rat mPGES probe of
identical length was also made in a similar way and used for a
negative-control experiment. The cryostat sections were fixed with 1%
paraformaldehyde in PBS, pH 7.4, for 5 min, treated with 0.001%
proteinase K, acetylated, dehydrated in an ascending ethanol series,
and air-dried. The sections were hybridized overnight (16-18 hr) at
55°C in a humidified chamber with hybridization buffer (50%
formamide, 0.3 M NaCl, 10 mM Tris-HCl, pH 8.0, 1 mM
EDTA, 1× Denhardt's solution, 10% dextran sulfate, 10 mM dithiothreitol, and 0.5 mg/ml yeast RNA) containing 2 × 107 cpm/ml
35S-labeled riboprobe. After
hybridization, the sections were washed, treated with RNase A,
dehydrated in an ascending ethanol series, and air-dried. The sections
were then exposed to Hyperfilm- max (Amersham Pharmacia Biotech) at
20°C for 1 week. For microautoradiography, the sections were dipped
in NTB2 emulsion (Eastman Kodak, Rochester, NY) diluted 1:1 with
distilled water and exposed for 2 weeks at 4°C. The films and
sections on the glass slides were developed in Kodak D-19 at room
temperature and fixed with Fuji Fix (Fujifilm, Tokyo, Japan). The
sections were further lightly counterstained with 1% toluidine blue,
dehydrated in an ascending ethanol series, and coverslipped.
Immunohistochemistry. For immunohistochemical detection of
mPGES protein, rats were killed 5 hr after intraperitoneal
injection of LPS (0.1 or 0.4 mg/kg in 0.5 ml of saline). This time
point was selected because mPGES mRNA peaked at 4 hr after
the LPS treatment. Under anesthesia, the rats were perfused via the
left ventricle with 50 ml of ice-cold PBS (20 mM), pH 7.4. The brains were freshly frozen in
dry-ice powder, cut at a thickness of 14 µm in a cryostat, and
thaw-mounted on glass slides. After having been air-dried at room
temperature for 10 min, the sections were treated with 0.02% sodium
metaperiodate followed by 2% paraformaldehyde for 10 min each. The
brain sections were treated with 10% normal donkey serum (NDS) for 1 hr and then incubated with anti-PGES (1:500 dilution) overnight at room
temperature. After removal of the primary antibody, the sections were
incubated with Cy3-labled anti-rabbit IgG (1:500 dilution) for 90 min.
The anti-PGES antibody had been raised in rabbits against a peptide
corresponding to amino acids 59-75 of human mPGES. With this antibody,
Western blot analysis of sheep seminal vesicle and rat kidney was
performed as described previously (Matsumura et al., 1998). The
antibody (1:1000 dilution) properly recognized a 16 kDa protein band
corresponding to mPGES (see Fig. 5j). The specificity of the
staining was confirmed with antibody preabsorbed with the antigen
peptide (1 µM) overnight at 4°C. For
visualization of the blood vessels, some of these sections were further
incubated with sheep anti-von Willebrand factor IgG (1:3000 dilution)
for 1 hr, followed by FITC-labeled anti-sheep IgG for 1 hr. The
specificity of the double-immunostaining was confirmed by incubating
the sections, which had been stained for mPGES, with sheep nonimmunized
IgG instead of sheep anti-von Willebrand factor IgG.
In the case of double-immunostaining of mPGES and COX-2, rabbit
anti-mPGES and goat-anti COX-2 were premixed so that their final
dilutions became 1:500 and 1:2000, respectively. After overnight incubation of brain sections with the mixed antibodies at room temperature, one of the primary antibodies was visualized with a
Cy3-labeled secondary antibody, and the other one with a biotin-labeled secondary antibody followed by FITC-avidin D. These secondary antibodies were of multiple-labeling grade (Jackson ImmunoResearch). Control experiments for the double-immunostaining of mPGES and COX-2
were done in two ways. First, the staining was done in the same way
except that the primary antibody mixture was preabsorbed with either
mPGES antigen peptide (1 µg/ml) or COX-2 antigen peptide (1 µg/ml).
Second, the staining was done with a primary antibody mixture in which
either mPGES or COX-2 was substituted with nonimmunized rabbit IgG or
nonimmunized goat IgG, respectively. In both cases, inappropriate
cross-reactions were negligible. In some cases, the sections were
further counter-stained for nuclear DNA with TO-PRO3. All antibodies
were diluted with 10% NDS in 0.1 M PBS, and all other
chemicals were dissolved in 0.1 M PBS. Fluorescent images
were captured by a three-laser confocal microscope (Radiance 2000;
Bio-Rad, Hercules, CA).
Enzyme immunoassay for PGE2 in the
CSF. Rats were injected with a COX-2 inhibitor, NS398, (4 mg/kg,
i.p.) or its vehicle [500 µl of 50% dimethylsulfoxide in saline] 1 hr before the injection of LPS (0.1 mg/kg in 0.5 ml of saline) or
saline. Five hours after the LPS or saline injection, the animals were
anesthetized with pentobarbital, and their heads were fixed in a
stereotaxic apparatus. CSF was sampled from the cisterna magna with a
27 gauge needle connected to a microsyringe (0.25 ml) via PE20 tubing.
The sampled CSF was immediately frozen in liquid nitrogen and stored at
80°C. On the day of assay for PGE2, the
samples were thawed on ice, and PGE2 was
extracted with organic solvent (ethylacetate). The extracted samples
were assayed for PGE2 with an EIA kit (Cayman Chemical) according to the manufacturer's instruction. Values were
presented as the means ± SEM. ANOVA followed by
Scheffe's post hoc test was performed for the statistical analysis.
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RESULTS |
Cloning of rat mPGES cDNA
We have cloned a rat cDNA that was highly homologous to human
mPGES by screening a rat testis library with human
mPGES cDNA as a probe. This rat cDNA encoded a single open
reading frame of 153 amino acids (Fig.
1A). Its nucleotide
sequence was 84% identical to that of human mPGES cDNA
(data not shown) (Jakobsson et al., 1999). Moreover, the amino acid
sequence of the protein encoded by this cDNA was 79.7% identical to
that of human mPGES (Fig. 1B). Its high
homology to human PGES indicated that this novel gene
encodes rat prostaglandin E synthase. The rat mPGES polypeptide
contained one amino acid insertion near the N terminus (Glu at position
9).
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Figure 1.
A, Nucleotide sequence of rat
mPGES cDNA and its predicted amino acid sequence. Numbering
for nucleotides, on the right, is from the start site of
the largest cDNA. Two independent cDNAs were sequenced on opposite
strands and yielded identical sequences. B, Comparison
of the deduced amino acid sequences of rat (rPGES) and
human (hPGES) PGES. Conserved amino acids between rat
and human PGES are boxed.
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Tissue distribution and LPS induction of PGES mRNA
The expression of rat mPGES mRNA was investigated in
various tissues by Northern blot analysis using rat mPGES
cDNA as a probe (Fig.
2A). Under the normal
conditions, rat mPGES mRNA was ~1.5 kb in size and was
highly expressed in the kidney and testis. In the brain, the
mPGES mRNA was weakly expressed in the cerebrum, cerebellum,
and brainstem. These results are consistent with the expression pattern
of human mPGES (Jakobsson et al., 1999), indicating that rat
mPGES mRNA is expressed in the same kinds of tissues as the
human.
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Figure 2.
Expression and regulation of rat mPGES
mRNA. Northern blot analysis of 30 µg of total RNA per lane prepared
from brain and peripheral tissues. A, Tissue
distribution analysis shows that mPGES mRNA expression is
enriched in the testis and kidney, with a low level of expression
detected in the brain regions. B, Forebrain RNA at
different time points (0, 1, 2, 4, and 12 hr) after LPS injection (0.4 mg/kg, i.p.) reveal that LPS induced a transient increase in
mPGES mRNA that peaked at 4 hr and persisted through 8 hr.
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To clarify whether mPGES gene expression is regulated in the
brain by peripheral immunological stimuli, we assayed mPGES
mRNA level in the rat brain by Northern analysis at different time points after the intraperitoneal injection of LPS (Fig.
2B). mPGES mRNA was hardly seen in the
control brain in this case. This was because the exposure time was
shorter than that in Figure 2A. The 1.5 kb
mPGES mRNA was induced between 2 and 4 hr and remained elevated for as long as 12 hr after the injection.
Brain localization of LPS-induced PGES mRNA
Figure 3 shows macroautoradiographic
images of the distribution of mPGES mRNA in the rat brain
after the intraperitoneal injection of LPS. By 2 hr after the
injection, spot-like mRNA signals appeared in the brain parenchyma and
on the brain surface (Fig. 3a,b). This type of
signal was observed in the entire brain and spinal cord (data not
shown). By 4 hr after the injection, the mRNA signals had increased in
both number and intensity (Fig. 3c,d). By 12 hr
after the injection, the mRNA signals had been reduced in intensity but
still existed (Fig. 3e,f). No such
spot-like signals were observed in the brains of untreated rat (data
not shown) or saline-treated ones (Fig. 3g). Neither were
such signals observed when the brain sections of LPS-treated rats were
hybridized with the sense cRNA probe (Fig. 3h).
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Figure 3.
Macroautoradiographic images of mPGES
mRNA signals in coronal sections of the rat brain. By 2 hr after LPS
injection (a, b), the spot-like
mPGES mRNA signals appeared in the brain parenchyma and
subarachnoidal space. By 4 hr after the injection (c,
d), the spot-like mPGES mRNA signals markedly
increased in both number and intensity. At 12 hr after LPS injection
(e, f), the mRNA signals were
reduced in intensity but still existed. mPGES mRNA signals
were not detectable in the brain section obtained 4 hr after saline
injection (g). Hybridization with the sense cRNA
probe did not show the spot-like signals in a brain section obtained 4 hr after LPS injection (h). The coronal planes in
the left panels and h contained cerebral
cortex (ctx), striatum (str), preoptic
area (po), and optic chiasma (ox).
Those in b, d, and f
contained more caudal brain regions, including hippocampus
(hipp), amygdala (amy), and mediobasal
hypothalamus (mbh). Arrowheads in
e and g indicate nonspecific signals
occasionally seen in the white matter at the edge of sections.
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Figure 4a-d shows light
microscopic views of mPGES mRNA signals in the rostroventral
part of the preoptic area, the area assumed to be the site of
PGE2 action to evoke fever. In line with the macroscopic observation, the mRNA signals appeared by 2 hr after the
LPS injection (Fig. 4b), further increased by 4 hr (Fig.
4c), and became reduced by 12 hr (Fig. 4d). No
such signals were observed in the same brain region 4 hr after the
intraperitoneal injection of saline (Fig. 4a). In most
cases, the LPS-induced mPGES mRNA signals were found in a
cluster of cells associated with blood vessels (Fig.
4b,c, arrows). In a cross-section of a
large blood vessel (Fig. 4e), the mRNA spots were aligned at
a regular interval along the luminal side of the vessel wall. Figure
4f shows another large blood vessel, which was axially
sectioned, and, hence, its luminal surface was seen in the microscopic
section. The luminal surface was tightly tiled with a number of
mPGES mRNA-positive cells. Thus, it seems very likely that
induction of mPGES mRNA occurred mainly in blood vessel
endothelial cells in the brain. It should be noted that not all the
blood vessels became positive for mPGES mRNA after the LPS
challenge. Figure 4g shows a blood vessel without the mRNA
signals in a sample taken 4 hr after the LPS injection. Figure
4h shows a section of cerebral cortex taken 2 hr after the
LPS injection. There were three blood vessels seen in the section, but
two of them were negative for the mRNA (indicated by
arrowheads). Figure 4i shows two large blood
vessels in the subarachnoidal space, but only one of them was positive
for the mRNA. In all cases described above, there was a common feature to the mPGES mRNA-negative blood vessels in that they
possessed an apparent smooth muscle layer, which was identified by the
sphincter muscle with the cellular nucleus being elongated in a
direction perpendicular to the vessel axis (Fig.
4g,h) or by the thickened vessel wall (Fig.
4i). Thus, PGES mRNA seemed to be induced by LPS
preferentially in the veins rather than in the arteries. It was hard to
determine in the emulsion-coated autoradiography whether the
capillaries also expressed mPGES mRNA. Even if they did so, however, the expression would not be so intense as that in the veins.
In addition to its inducing effect on blood vessels, the LPS stimulus
also induced mPGES mRNA expression in a certain type of cell
in the brain parenchyma (Fig. 4j, arrows) and in
the choroid plexus (Fig. 4k), although the signals were not
so intense as those in the blood vessels. Such parenchymal cells with
weak mPGES mRNA signals were seen in any brain regions after
the LPS stimulus. The identity of these cells is not clear at
present.
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Figure 4.
Light microscopic views of localization of
mPGES mRNA. a-d, mPGES mRNA
signals in the rostral part of the preoptic area 4 hr after
saline injection (a), and 2 (b), 4 (c), and 12 (d) hr after the LPS injection.
3v, The third ventricle; ox, optic
chiasma. Arrows in b and c
indicate mPGES mRNA-positive cells associated with
blood vessels. Most other mPGES mRNA-positive cells not
denoted by arrows were also associated with blood
vessels when examined under higher magnification. e-k,
mPGES mRNA signals in brain parenchyma
(e-h, j), subarachnoidal
space (i), and choroid plexus (k) 4 hr after the
LPS injection, except for h, which was sampled at 2 hr
after the injection. Note that the artery-like blood vessels
(arrowheads in h and i)
were devoid of the mRNA signals. j, Less intense
mPGES mRNA signals (arrows) were occasionally
seen in unidentified cells in the brain parenchyma along with intense
mRNA signals associated with blood vessels (arrowheads).
dg, Dentate gyrus of the hippocampus. k,
mPGES mRNA signals were also expressed in the choroid plexus
(arrows) and associated blood vessels
(asterisk). Scale bar (in d):
a-d, k, 100 µm; e-j,
50 µm.
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LPS-induced PGES-like immunoreactivity in brain blood vessels
Under the normal conditions, no mPGES-like immunoreactive
(mPGES-IR) cells were found in the rat brain. After LPS
challenge, mPGES-IR cells started to appear by 2 hr and reached their
highest level by 5 hr. The LPS-induced mPGES-IR structures were round or oval in shape (Fig.
5a1,b) and aligned
along the vessel wall, as shown by double-immunostaining with von
Willebrand factor, an endothelial marker (Fig. 5a2).
Specificities of the staining of mPGES and von Willebrand factor were
confirmed with preabsorbed anti-mPGES antibody (Fig. 5a3)
and nonimmunized sheep IgG in substitution for anti-von Willebrand
factor (Fig. 5a3, inset), respectively. Figure 5,
b and c1, shows laser confocal microscopic images
of mPGES-like immunoreactivity (red) and nuclear DNA
(blue). mPGES-like immunoreactivity was most densely
expressed in the perinuclear region. This perinuclear mPGES-IR
structure was surrounded by von Willebrand factor (an
endothelium-specific protein)-like immunoreactivity (Fig.
5c2, green). Thus, mPGES-like immunoreactivity
was expressed in the perinuclear region of a subset of brain
endothelial cells after the LPS challenge. Consistent with the in
situ hybridization study, endothelial cells of arteries did not
express mPGES-IR signals (Fig. 5d).
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Figure 5.
Immunostaining of mPGES, von Willebrand factor,
and COX-2 in the rat brain 5 hr after LPS injection. In all
panels, red and blue
indicate mPGES-like immunoreactivity and nuclear DNA staining,
respectively. a1, mPGES staining is seen along the
vessel wall. a2, mPGES staining is overlaid with von
Willebrand factor staining (green) in the
same brain section as in a1. a3,
Incubation with preabsorbed anti-mPGES eliminated the staining in
the same blood vessel seen in the adjacent section. a3,
Inset, Control experiment for the double-immunostaining
of mPGES and von Willebrand factor. Incubation of mPGES-stained section
with nonimmunized sheep IgG instead of anti-von Willebrand factor
resulted in virtually no staining of endothelial cytosol.
b, mPGES-positive cells are seen along an axially cut
blood vessel. c1, Magnified view of mPGES-positive cells
with nuclear DNA staining. c2, von Willebrand factor
staining (green) is overlaid on mPGES and nuclear
staining in c1. d, mPGES is negative in a
large artery (asterisk) but is positive in small blood
vessels nearby. mPGES staining (e1, f1,
g1) is overlaid with COX-2 immunostaining
(e2, f2, g2) and further
with nuclear staining (e3, f3,
g3). f1-f3, Perinuclear colocalization
of mPGES and COX-2 is confirmed in enlarged views.
g1-g3, mPGES and COX-2 are colocalized only in
endothelial cells but not in cortical neurons (arrow),
in which only COX-2 is expressed. h1, h2,
i1, i2, Double-immunostaining of mPGES
(h1, i1) and COX-2 (h2,
i2) was performed using either the ordinary antibody
mixture (h1, h2) or the mixture
preabsorbed with COX-2 antigen peptide (i1,
i2). Note that only COX-2 staining was eliminated after
preabsorption with COX-2 antigen peptide. j,
Western blot analysis of rat kidney revealed that the antibody used for
immunohistochemistry properly recognized rat mPGES. Scale bars:
a1-a3, 50 µm; b, 20 µm;
c1, c2, 5 µm; d,
e1-e3, g1-g3, h1,
h2, i1, i2, 10 µm; and
f1-f3, 2 µm.
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Colocalization of PGES and COX-2
It was shown previously that LPS induced COX-2 expression in the
perinuclear region of brain endothelial cells (Matsumura et al., 1998).
Therefore, coexpression of mPGES and COX-2 was examined in
double-immunostained brain sections. As shown in Figure 5e1-e3, these two enzymes were coexpressed in a
subset of endothelial cells. Among 109 endothelial cells
positive for either mPGES or COX-2, the majority (96%) were
double-positive for mPGES and COX-2, and only 1 and 3%
were single-positive for mPGES and COX-2, respectively. Furthermore,
their subcellular localizations almost overlapped in the perinuclear
region (Fig. 5f1-f3). On the other hand, a subset of
telencephalic neurons that constitutively expressed COX-2-like
immunoreactivity did not show any mPGES-like immunoreactivity under
both the control and LPS-challenged conditions, although endothelial
cells nearby were positive for both (Fig. 5g1-g3). Figure
5, h1 and h2, shows double-immunostaining for
mPGES (h1, red) and COX-2 (h2,
green) using the ordinary antibody mixture of anti-mPGES and
anit-COX-2. In Figure 5, i1 and i2, the adjacent section was incubated with the primary antibody mixture preabsorbed with COX-2 antigen peptide and visualized in the same way as in Figure
5h. Only staining for COX-2 was eliminated (Fig.
5i2), indicating that the anti-goat IgG antibody did not
cross-react with rabbit anti-mPGES IgG. In a similar way, preabsorption
of the primary antibody mixture with mPGES antigen peptide specifically eliminated mPGES staining but not COX-2 staining, indicating that the
anti-rabbit IgG antibody did not cross-react with goat anti-COX-2 IgG
(data not shown). The distinct staining pattern between neurons and
endothelial cells in Figure 5, g1 and g2, also
exclude the possibility that the anti-rabbit IgG antibody cross-reacted
with goat anti-COX-2 IgG. Western blot analysis of rat kidney revealed that the antibody used for immunohistochemistry properly recognized rat
mPGES (Fig. 5j).
Functional link of PGES with COX-2 and its relevance to fever
Coexpression of COX-2 and mPGES in the perinuclear region of brain
endothelial cells led us to examine whether the two enzymes are
functionally linked. The PGE2 level in the CSF
was elevated 5 hr after the LPS challenge (Fig.
6). This increase was completely suppressed when the rats had been pretreated with a COX-2-specific inhibitor, NS-398. This result indicates that mPGES is supplied with
its substrate, PGH2, primarily through COX-2
after LPS challenge. Thus, mPGES and COX-2 are functionally linked
under such a pathological condition. It is highly likely that this link
takes place in brain endothelial cells, because they are the only cell
group expressing both enzymes in the brain after the LPS challenge. The
pretreatment with NS-398 also suppressed febrile response to LPS as
reported previously (Cao et al., 1997). These results strongly suggest that brain endothelial cells are the primary source of the
PGE2 that is essential for the fever
response.
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|
Figure 6.
PGE2 level in the CSF 5 hr LPS
injection and effect of a COX-2-specific inhibitor.
Numbers in the parentheses indicate the
number of animals examined. *p < 0.0001
|
|
| |
DISCUSSION |
It is well established that PGE2 in the
brain triggers a variety of CNS-mediated pathological responses
associated with infectious or inflammatory diseases (Milton, 1982;
Dinarello et al., 1988; Blalock, 1989). These responses, generally
called "acute-phase response," include fever, hyperalgesia, and the
activation of the hypothalamo-pituitary-adrenal axis (Kent et al.,
1992). It was not fully clarified, however, where and how
PGE2 is biosynthesized in the brain under such
pathological conditions. This information would be of importance
when fever and other symptoms should be controlled to avoid their
adverse effects. To answer the question, we have been studying the
brain expressions of enzymes responsible for PGE2
synthesis in animal models of infection. As discussed below, the
present study strongly indicates that fever is evoked by
PGE2 that is biosynthesized in the brain
endothelial cells through COX-2 and mPGES enzymatic actions.
COX-2 was identified in 1991 as an inducible isoform of COX (Kujubu et
al., 1991; Xie et al., 1991). It catalyzes the reaction from
arachidonic acid to PGH2, a common substrate for
several types of PG synthase, including PGES. A large number of studies during the last decade demonstrated that COX-2 is inducible by cytokines, viral infection, and mitogens, and plays pivotal roles in
the development of inflammatory symptoms, cancer, and, possibly neurodegenerative diseases (Goppelt-Struebe, 1995; Herschman, 1996). We and others demonstrated that various pyrogenic stimuli induced COX-2 expression in brain blood vessels (Cao et al., 1995, 1996, 1998; Breder and Saper, 1996; Elmquist et al., 1997; Lacroix and
Rivest, 1998; Matsumura et al., 1998; Quan et al., 1998; Laflamme et
al., 1999), although there was controversy as to the type of cells that
expressed COX-2, either endothelial cells (Matsumura et al., 1998) or
perivascular microglia (Elmquist et al., 1997). Fevers evoked by
various inflammatory agents were all suppressed by a COX-2-specific
inhibitor (Futaki et al., 1993; Cao et al., 1997, 1999) or by
COX-2 gene disruption (Li et al., 1999) and were always
associated with a concomitant expression of COX-2 in brain endothelial
cells (Cao et al., 1997, 1999). These findings led us to hypothesize
that brain endothelial cells are the sites of
PGE2 production during fever, but at that moment,
evidence was still lacking for the presence of PGES in the same
endothelial cells expressing COX-2.
PGES activity, which catalyzes the conversion of
PGH2 to PGE2, has long been
recognized in various tissues. Partial purification of PGES activity
indicated that there existed multiple isoforms of PGES (Urade et al.,
1995; Watanabe et al., 1997, 1999), although they were not molecularly
identified until recently. In 1999, Jakobsson et al. for the first time
identified a human microsomal protein (designated as mPGES) that
possessed glutathione-dependent PGES activity (Jakobsson et al., 1999).
It should be particularly noted that mPGES was inducible by IL-1, an
inflammatory cytokine, in a human macrophage cell line, suggesting the
involvement of mPGES in inflammation and in the acute-phase response
(Jakobsson et al., 1999; Forsberg et al., 2000). The present study for
the first time revealed histochemically that mPGES was minimally
expressed in the brain under the normal conditions but was induced in
the brain endothelial cells after intraperitoneal injection of LPS. Recently, another PGES was molecularly identified (Tanioka et al.,
2000). It is a cytosolic PGES (cPGES), which requires glutathione for
the enzymatic activity and is constitutively expressed in various
tissues. Its cellular localization in the brain remains to be studied.
COX-2 and mPGES were coexpressed in brain endothelial cells in a
temporally and spatially similar manner, suggesting that they were
functionally linked. The occurrence of this link in endothelial cells
was evidenced by the facts that the inhibition of COX-2 activity
resulted in a suppression of the PGE2 level in
the CSF, and no other brain cells coexpressed both of these enzymes
during fever. Preferential coupling of COX-2 and mPGES was demonstrated
recently in an in vitro experiment under a better-controlled experimental condition, in which a cell line was transfected with mPGES gene with either the COX-1 or
COX-2 gene (Murakami et al., 2000). In this experiment, the
cells transfected with mPGES and COX-2 produced
PGE2 from much lower concentrations of
arachidonic acid in the medium compared with those transfected with
mPGES and COX-1. On the other hand, the same
research group demonstrated that cPGES is functionally linked with
COX-1 in a marked preference rather than to COX-2 (Tanioka et al.,
2000). Thus, although cPGES is expressed in some brain cells, its
contribution to COX-2-mediated responses, such as LPS-induced
PGE2 production and fever, would seem to be
small, if any. The above three lines of evidence, that (1) fever and
PGE2 elevation in the CSF are both COX-2-mediated responses, (2) COX-2 and mPGES are coexpressed only in the endothelial cells as far as the brain is concerned, and (3) COX-2 is preferentially coupled with mPGES rather than with cPGES, led us to finally conclude that brain endothelial cells are the major source of
PGE2 during fever.
It is generally assumed that PGI2 rather than
PGE2 is the major prostanoid in the vascular
system, and PGI2 plays an essential role in the
regulation of vascular tone by acting on the arterioles. Although this
is certainly true under the normal conditions, brain endothelial cells
seem to markedly enhance their ability to produce PGE2 under immunologically stimulated conditions.
This is in line with previous reports that PGE2
was secreted from cultured brain endothelial cells in a higher amount
than PGI2 in response to LPS or cytokine stimuli
(de Vries et al., 1995) and that PGE2-like immunoreactivity was detected in vivo in brain
microvasculature after systemic LPS or cytokine administration (Van Dam
et al., 1993, 1996). Of interest, the present study showed that the
endothelial response to LPS seems to occur mainly in veins or venules,
which have little smooth muscle in their walls. Therefore,
PGE2 produced in these vessels should have little
impact on the vascular tone. Rather, PGE2
elaboration seems to be one of the early events in brain during
immunological insults. The mechanism of vessel-type specific inductions
of mPGES and COX-2 is unclear at present.
Figure 7 illustrates our current view on
the signaling pathway to fever. Circulating LPS and/or inflammatory
cytokines derived from LPS-stimulated blood cells do not enter the
brain because of the tight junction between the endothelial
cells. Rather, they activate the corresponding receptors on the luminal
surface of the endothelial cells in the brain. Activation of these
receptors leads to transcription and translation of COX-2
and mPGES genes, as shown in the present study, and also to
translocation of cytosolic PLA2 (cPLA2) to the nuclear envelope (Glover
et al., 1995). Translocated cPLA2 cleaves nuclear membrane
phospholipids to release arachidonic acid. Arachidonic acid is then
converted to PGH2 by COX-2 and finally to
PGE2 by mPGES, because both enzymes are located
near the nuclear membrane, as shown in the present study.
PGE2 is then released into the brain and acts on
the neurons possessing the EP3 subtype of
PGE2 receptor (Ushikubi et al., 1998). This
neuronal activation switches on the neuronal circuit to increase heat
production and suppress heat loss, and as a consequence, the body
temperature elevates.
View larger version (35K):
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|
Figure 7.
Our current hypothesis on the signaling cascade
leading to fever in which brain endothelial cells play a pivotal role.
See Discussion for the details. Dashed arrow
indicates translocation of cPLA2. Other arrows indicate
the flow of either molecules or signals
|
|
There has been a long discussion as to how the immune system
communicates with the CNS (Rothwell and Hopkins, 1995; Watkins et al.,
1995; Blatteis and Sehic, 1997; Rothwell, 1997). The present study
strongly indicates that, at least under the present experimental conditions, brain endothelial cells constitute one of the routes for
immune-CNS communication, in which the endothelial cells transform the
blood-borne immune signal into a PGE2 signal,
which in turn acts on the CNS neurons to evoke fever and other
acute-phase responses. Thus, brain endothelial cells are not merely a
physical barrier between blood and brain but also act as a signal
transducer between the immune system and the nervous system.
| |
FOOTNOTES |
Received Sept. 25, 2000; revised Dec. 27, 2000; accepted Jan. 24, 2001.
This work was supported by grants from the program Grants-in-Aid for
Scientific Research (C) of the Japan Society for the Promotion
of Science (to K.Y. and K.M.) and by grants from the Ministry of
Education, Science, Sports, and Culture of Japan, the Japan Epilepsy
Research Foundation, the Pharmacopsychiatry Research Foundation (to
K.Y.), the Special Coordination Funds for Promoting Science and
Technology from the Science and Technology Agency, Japan, and the Naito
Foundation (to K.M.).
K.Y. and K.M. contributed equally to this study.
Correspondence should be addressed to Dr. Kanato Yamagata, Department
of Neuropharmacology, Tokyo Metropolitan Institute for Neuroscience,
2-6 Musashidai, Fuchu 183-8526, Japan. E-mail: kyamagat{at}tmin.ac.jp.
| |
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TOP
ABSTRACT
INTRODUCTION
Compound via MeSH
