 |
 Previous Article | Next Article 
The Journal of Neuroscience, October 1, 1999, 19(19):8244-8251
Knock-Out of the Neural Death Effector Domain Protein PEA-15
Demonstrates That Its Expression Protects Astrocytes from
TNF -Induced Apoptosis
Daniel
Kitsberg4,
Etienne
Formstecher1,
Mireille
Fauquet1,
Miroslav
Kubes1, 2,
Jocelyne
Cordier1,
Brigitte
Canton1,
GuoHua
Pan3,
Malvyne
Rolli1,
Jacques
Glowinski1, and
Hervé
Chneiweiss1
1 Institut National de la Santé et de la
Recherche Médicale U114, Chaire de Neuropharmacologie,
Collège de France, 75231 Paris cedex 05, France
2 Institute of Virology, Slovak Academy of Sciences, 842 46 Bratislava, Slovakia, 3 Department of Pathology, University
of Michigan Medical School, Ann Arbor, Michigan 48109, and
4 Harvard Medical School, Boston, Massachusetts 02115
 |
ABSTRACT |
Apoptosis is a very general phenomenon, but only a few reports
concern astrocytes. Indeed, astrocytes express receptors for tumor
necrosis factor (TNF)  , a cytokine demonstrated on many cells and
tissues to mediate apoptosis after recruitment of adaptor proteins
containing a death effector domain (DED). PEA-15 is a DED-containing
protein prominently expressed in the CNS and particularly abundant in astrocytes. This led us to investigate if PEA-15 expression could be involved in astrocytic protection against deleterious effects
of TNF. In vitro assays evidence that PEA-15 may bind to
DED-containing protein FADD and caspase-8 known to be apical adaptors of the TNF apoptotic signaling. After generation of PEA-15 null mutant mice, our results demonstrate that PEA-15 expression increases astrocyte survival after exposure to TNF.
Key words:
astrocytes; TNF; apoptosis; death effector domain; PEA-15; FADD; caspase
| |
INTRODUCTION |
Programmed cell death is extensively
reported in the CNS for neurons and oligodendrocytes in several
pathological conditions, but not for astrocytes. Inflammation and
trauma of the adult CNS result in the production of several cytokines,
among which tumor necrosis factor (TNF) seems to play a major role
(St. Pierre et al., 1996 ). Astrocytes produce TNF and express
apoptosis-inducing receptors belonging to the TNF receptor superfamily,
such as TNFR1 or Fas (Dopp et al., 1997; Becher et al., 1998), but are
not susceptible for example to Fas-mediated cytotoxicity (Becher et
al., 1998), suggesting a self-protective mechanism.
Apoptosis results from an orderly cascade of cellular events. It
involves the sequential activation of aspartate-specific cysteine
proteases named caspases (Alnemri et al., 1996). Extracellular signals
such as FasL or TNF are well known to trigger such cascades. After
binding to their respective ligands, Fas and TNFR1 receptors initiate
apoptosis by recruiting the cytosolic adaptor molecule FADD/MORT
(FADD) to the plasma membrane (Fraser and Evans, 1996). The N-terminal
part of FADD contains a death effector domain (DED) that binds to
homologous domains located in the N-terminal part of caspase-8 (FLICE,
MACH, Mch5), allowing the autocleavage of the latter and its activation
(Boldin et al., 1996; Muzio et al., 1996). DEDs also exist in another
procaspase, caspase-10 (Mch4, FLICE2), where they might play the same
protein-binding function (Vincenz and Dixit, 1997). Mutants of FADD
lacking DED or mutants of caspase-8 with only its DEDs can act as
dominant-negative inhibitors, suggesting that endogenous inhibitors of
early steps of apoptosis could exist. Indeed, a family of
DED-containing proteins expressed by  -type herpes virus was
characterized and shown to block the cascade after binding to either
FADD or caspase-8 (Bertin et al., 1997; Thome et al., 1997). A
mammalian homolog of these proteins (CASH/CASPER/CLARP/FLAME1/FLIP/I-FLICE/MRIT/Usurpin) (Golstev et
al., 1997; Han et al., 1997; Hu et al., 1997; Inohara et al., 1997;
Irmler et al., 1997; Shu et al., 1997; Srinivasula et al., 1997;
Wallach, 1997b) is also recruited as FADD and caspase-8 in the
death-inducing signaling complex and could modulate its efficacy
(Scaffidi et al., 1999).
The prominently brain-expressed protein PEA-15 also contains a DED
domain. PEA-15 was first characterized because of its enrichment in
astrocytes, but it can be detected at lower levels in other cell types
and out of the CNS (Danziger et al., 1995; Condorelli et al., 1998).
This protein is phosphorylated on two different seryl residues, Ser104
being identified as a site of regulation for protein kinase C (PKC)
(Araujo et al., 1993; Estelles et al., 1996), whereas Ser116 is
regulated by calcium-calmodulin kinase II (CaMKII) (Kubes et al.,
1998). PEA-15 is particularly abundant in astrocytes (Danziger et al.,
1995), raising the hypothesis that it could play a role against
cytokine-triggered apoptosis. Indeed, we demonstrate here that PEA-15
interacts in vitro with two other DED domain-containing
proteins, FADD and caspase-8. Its function was further investigated
in vivo in astrocytes from wild-type versus PEA-15 null
mutant mice. Expression of PEA-15 protects astrocytes from TNF-induced apoptosis.
| |
MATERIALS AND METHODS |
Glial primary cultures. Glial cultures were prepared
as previously described (Araujo et al., 1993). Briefly, 16 mm wells or 100 mm dishes were coated with poly(L-ornithine) (1.5 µg/ml; Mr 40,000). Striatal cells from 16-d-old
wild-type (WT) or PEA-15-null (KO) mouse embryos were dissociated and
plated (80,000 cells per well) in a culture medium (Life Technologies,
Gaithersburg, MD) consisting of a 1:1 mixture of MEM and F-12
nutrient supplemented with glucose (33 mM), glutamine (2 mM), sodium bicarbonate (3 mM), and 10%
Nu-Serum (Collaborative Research, Bedford, MA). The culture medium was
changed every 3 d for 3 weeks until glial elements had formed a
confluent monolayer devoid of neuronal cells. As previously described,
using morphological and immunohistochemical criteria, cells were shown
to be virtually mature astrocytes (Birman et al., 1989).
cDNA constructs. Coding region of PEA-15 was cloned into
pGEX-4T1 (Pharmacia Biotech) at EcoRI-SalI sites
or into pcDNA3 (Invitrogen, San Diego, CA) tagged with a FLAG epitope
at its C terminus at KpnI-BamHI sites. PEA-15
ORF was cloned into pEGFP-C1 (Clontech, Cambridge, UK). A
PCR-generated fragment corresponding to the DED of PEA-15 (amino acids
1-79) was obtained using the following primers containing
EcoRI and SalI sites, respectively: DEDPE, 5'-CGAGGAATTCGGCGGAATGG-CAGAGTACGGAACT-3' and DDPEs,
5'-CGGCGTCGACTCAAACCACCATAGTG-AGGAG-3'. The PCR product was cloned into
pGEX-4T1 or pEGFP-C1 vectors.
Glutathione S-transferase pull-down assay. Using
a TNT-coupled reticulocyte lysate system (Promega, Madison, WI),
PEA-15, FADD, and caspase-8 (Casp8) were translated in vitro
in the presence of 35S-methionine. Five
microliters of the reaction product were incubated with 5 µg of GST
fusion proteins coupled to glutathione Sepharose beads in the following
buffer: Tris 10 mM, pH 7.5, MgCl2 1 mM, Triton X-100
1%, NaCl 50 mM, and bovine serum albumin (BSA)
0.1% for 1.5 hr at room temperature. Beads were then washed twice in the same buffer and once in this buffer without BSA. Associated proteins were analyzed by a 4-20% SDS-PAGE followed by transfer on a
nitrocellulose membrane and analysis in an Instantimager (Packard).
Deletion of PEA-15 gene. A full-length PEA-15 cDNA clone was
used to screen a mouse SV129 genomic library (Stratagene, La Jolla,
CA). Two overlapping phage clones were isolated, which were recloned
into a bluescript vector, and restriction mapping was performed. A
targeting vector was constructed by deleting a 4.5 kb
BamHI-EcoRI genomic fragment that contains the
entire PEA-15 gene. This was performed using a pPNT vector (Tybulewicz et al., 1991). A 10 kb BamHI genomic fragment was cloned 5'
of the PGKneo cassette, and a 4 kb
EcoRI-BglII genomic fragment was inserted 3' to
the PGKneo cassette and 5' of the PGK-TK cassette.
Homologous recombination in embryonic stem cells. A newly
established embryonic stem (ES) cell line (derived from a
129/SvEvTacfBR mouse), TC1, was transfected with the targeting vector
linearized with NotI and selected with G418 and FIAU. The
cell culture, electroporation, and selection procedures were performed
essentially as previously described (Deng et al., 1994). ES colonies
that were resistant to both FIAU and G418 were isolated, expanded, and
genomic DNA was prepared for Southern blot analysis to identify clones
that had undergone homologous recombination. Genomic DNA was digested with DraIII, run on a 0.7% agarose gel, blotted onto
Genescreen plus nylon membrane (NEN) and probed with a 1.3 kb
BglII-DraIII fragment isolated from the genomic
clone. The probe hybridized with a 15 kb wild-type band. However, DNA
of cells in which homologous recombination had occurred demonstrated
both a 15 kb wild-type band and an 8 kb mutated band. ES cells
heterozygous for the targeted mutation were microinjected into C57BL/6J
blastocysts to obtain germline transmission. The injected blastocysts
were implanted into the uteri of pseudopregant Swiss Webster (Taconic,
Germantown, NY) foster mothers and were allowed to develop to term.
Male chimeras were identified on the basis of their agouti coat color
and were mated with National Institutes of Health Black Swiss females
(Taconic). Germ line transmission was confirmed by agouti coat color in
the F1 animals, and all agouti mice were tested for the presence of the
mutated PEA-15 allele by Southern blot analysis using the same
conditions as those used for the detection of the homologous recombination event in ES cells. Mice carrying the heterozygote mutation were crossed to obtain homozygote mice, and genotypes were
determined by Southern blotting.
Northern blot analysis. Total RNA was extracted from
cultured astrocytes from WT or KO mice. RNA samples were
electrophoresed though 1% agarose (Appligene, Heidelberg, Germany)
gels following standard procedures (Ausubel et al., 1992) and
transferred to Hybond-N membranes (Amersham, Arlington Heights, IL). A
specific probe for the PEA-15 coding region (ATG to TGA) was
synthesized using PCR (Estelles et al., 1996) and was labeled with
-32P-dCTP using the RadPrime DNA
labeling kit (Life Technologies). Specific binding was analyzed and
quantified in a Packard InstantImager.
Western blots. Electrotransfer of gels on Hybond C-Super
nitrocellulose membrane was performed with a Bio-Rad (Hercules, CA) semidry blotting apparatus (15 V, 1 hr). Nitrocellulose blots were
fixed and stained with Ponceau Red (0.2% in 1% acetic acid) and
blocked with 2.5% casein for 1 hr (20°C). After overnight incubation
at 4°C with antiserum diluted in 2.5% casein, bound antibodies
(Danziger et al., 1995) were detected by anti-rabbit IgG coupled to
horseradish peroxidase and revealed by chemiluminescence (Renaissance
kit; DuPont, Billerica, MA).
32P labeling of astrocytes.
Labeling was performed by preincubating cells for 4 hr with
32PO43
(0.15 mCi) in 250 µl of phosphate-free medium. Labeling was stopped as previously described (Araujo et al., 1993), and samples were prepared for two-dimensional PAGE electrophoresis according to Garrels
(1979) with a few modifications (Araujo et al., 1993). Isoelectric
focusing gels contained 2% total ampholines, pH 4-6.5 (Pharmacia,
Piscataway, NJ). The second dimension was performed on 13%
polyacrylamide gels according to Laemmli (1970). To detect proteins,
gels were silver-stained, dried, exposed for autoradiography (1-3 d)
with Kodak (Eastman Kodak, Rochester, NY) XAR-5 films, and counted and
digitalized in an InstantImager (Packard).
In vitro analysis of genomic DNA fragmentation. After
TNF treatment, cells were pelleted and incubated in 350 µl of a
lysis buffer (Tris 100 mM, NaCl 100 mM, EDTA 50 mM, SDS 1%, proteinase K 1 mg/ml, pH 7.8) for 2 hr at
55°C. DNA was then extracted with phenol-chloroform as previously
described (Moyse and Michel, 1996). DNAs (1 µg for each sample) were
32P-end-labeled for 10 min at room
temperature using Kleenow polymerase (5 U) as previously described
(Rösl, 1992). One-tenth of the sample was then electrophoresed on
a 1.8% agarose gel for 2 hr at 100 V. After drying, the gel was
analyzed in InstantImager.
Cell death assay. Astrocytes were replated
(2000/cm2) on cover glass slides coated
with polyornithine and allowed to recover for 4 d. After 2 hr in
the presence of actinomycin D (10 µg/ml), TNF [recombinant human
TNF (Calbiochem, La Jolla, CA), 300 U/16 mm dish, 5 × 107 U/mg] was added for the indicated
time. Cells were then stained with annexin V using a kit (Bender
Medsystems), and/or fixed and stained with DAPI, and/or labeled
with a terminal deoxynucleotidyl transferase-mediated biotinylated UTP
nick end labeling (TUNEL) assay kit (Biovation), according to each
manufacturer's protocol with a few modifications.
Using a polyethylenimine (PEI)-based protocol, astrocytes cultured from
KO mice were transiently transfected with pCMV-GFP in the presence of a
fourfold excess of pcDNA3 expression constructs encoding PEA-15 or with
the pEGFP-PEA-15 construct. Forty-eight hours after transfection, cells
were treated with TNF, and apoptosis was evaluated using the same tests
as above. The data (mean ± SEM) shown are the percentage of green
fluorescent apoptotic cells among the total number of green cells.
| |
RESULTS |
Previous studies have shown that DED domains mediate the binding
of the adaptor molecule FADD to the effector protease caspase-8 (Boldin
et al., 1996; Muzio et al., 1996). Because PEA-15 is also a protein
with a DED domain (Fig. 1), we
investigated the ability of PEA-15 to interact with FADD and/ or
caspase-8 using in vitro binding assays.
35S-radiolabeled FADD, caspase-8, or
PEA-15 was precipitated with PEA-15 (Fig.
2A) or FADD (Fig.
2B) GST fusion proteins immobilized on
glutathione-Sepharose beads. FADD and caspase-8 associated specifically with GST-PEA-15, although the interactions of FADD and
caspase-8 with GST-PEA-15 were weaker than those observed with
GST-FADD. As PEA-15 bound, to some extent, to GST alone, no specific
binding was observed with GST-PEA-15, suggesting that PEA-15 did not
associate with itself. Simultaneous addition of FADD and caspase-8
neither prevented nor enhanced their interaction with PEA-15 (Fig.
2A). In addition, GST-DED-PEA15 was also able to
coprecipitate with FADD and caspase-8 but to a lower extent than the
whole PEA-15 protein (data not shown). These results demonstrated that
PEA-15 may interact with several DED domain-containing molecules and
led us to further investigate the role of PEA-15 in cytokine-induced
apoptosis in astrocytes.
View larger version (61K):
[in this window]
[in a new window]
|
Figure 1.
Schematic representation of PEA-15 and comparison
of death effector domains. A, The two identified sites
of phosphorylation, Ser104 for PKC and Ser116 for CaMKII, are located
outside of DED. B, Alignment of DEDs (sequence-based).
Hydrophobic residues known in FADD to contribute to its structure
(arrangement of six helices 1-6, see Eberstadt et al., 1998) are
shown in bold and are shaded. The
boxed and asterisked area is the F25
reported as critical for the proapoptotic function of FADD. Mouse
PEA-15 (GenBank accession number X86804); mouse FADD (GenBank accession
number U43184); human caspase-8 (GenBank accession number U60520);
human caspase-10 (GenBank accession number 1498324); cFLIP (GenBank
accession number U97076); and equine herpes virus-2 E8 protein (GenBank
accession number U20824).
|
|
View larger version (36K):
[in this window]
[in a new window]
|
Figure 2.
In vitro interactions of PEA-15.
The indicated in vitro translated
35S-labeled proteins were precipitated with GST
(A, B, lanes
1), GST-PEA-15 (A, lanes
2), or GST-FADD (B, lanes 2) fusion proteins
immobilized on glutathione-Sepharose beads. The bound proteins were
then analyzed by SDS-PAGE, visualized, and counted in a Packard
InstantImager. Data presented are taken from one individual experiment
of three or more giving similar results.
|
|
For this purpose, using homologous recombination, PEA-15 null mutant
mice were created to investigate apoptosis in astrocytes that no longer
express PEA-15. We designed a targeting vector that replaced a 4.5 kb
BamHI-EcoRI genomic fragment containing the
entire coding region of the PEA-15 gene with the neomycin resistance
gene (neo) (Fig. 3A). The
correct homologous event in ES cells was confirmed by Southern blotting
(Fig. 3B), and mice were genotyped by the same procedure
(Fig. 3B). The absence of PEA-15 expression in homozygous
animals was analyzed by Northern and Western blotting (Fig.
3C,D) and further confirmed by
32P labeling of astrocytes grown in
primary culture followed by two-dimensional PAGE and
autoradiography (Fig. 3E). Heterozygous mutant mice
(PEA-15+/ ) were healthy and normal in size as were the homozygous
PEA-15/. Body weight was decreased in PEA-15/ animals in
comparison with their wild-type littermates, but brain sizes were
similar in wild-type, heterozygous, and homozygous animals. Gross
examination of brain sections from 2-month-old animals revealed no
difference between WT PEA-15+/+ and KO PEA-15/ mice. Because PEA-15
is highly expressed in astrocytes, GFAP labeling that indicated no
obvious difference between WT and KO in the number, morphology, and
organization of glial cells (Fig. 4) was performed. All subsequent experiments were performed on astrocytes grown in primary culture.
View larger version (31K):
[in this window]
[in a new window]
|
Figure 3.
Generation of PEA-15 mutant mice by
gene targeting. A, A schematic diagram of the PEA-15
locus, the targeting vector, and the targeted allele. Restriction
enzyme sites are indicated as R, EcoRI;
B, BamHI; D, DraIII;
G, BglII; and X, XhoI. The entire PEA15
gene lies within a 4.5 kb BamHI-EcoRI
fragment. In the targeting construct, this fragment is deleted and is
replaced by the neomycin gene driven by the PGK promoter (neo). A 10 kb
BamHI fragment flanks one side of the neo gene, and a 3 kb EcoRI-BglII fragment flanks the other
side. On the other side of this fragment lies the thymidine kinase gene
also driven by the PGK promoter (TK). Homologous
recombination results in the disrupted allele as shown. Fragment A
represents the 1.3 kb DraIII-BglII
fragment that was used as a probe to differentiate between the
wild-type and the disrupted alleles. The arrows mark the
direction of transcription of the various genes. B,
Southern blot analysis of DraIII digested DNA isolated
from the parental ES cells (WT) as compared with
DNA from an ES cell clone that had undergone homologous recombination
(KO). Using a 1.3 kb
DraIII-BglII probe, a shift down from a
15 kb wild-type band to an 8 kb mutated band is observed.
C, Southern blot analysis of DNA isolated from the tails
of a litter of pups born from a heterozygote × heterozygote
mating. As predicted by Mendelian genetics, two wild-type mice, two
homozygotes, and four heterozygotes are observed with the expected band
pattern following DraIII digestion and hybridization
with the 1 kb DraIII-BglII probe.
D, Northern (RNA) blot demonstrating the absence of
PEA-15 messages in / mutant astrocytes derived from these mice.
E, Western blot demonstrating the absence of PEA-15
protein in the brains of / mice and in cultured astrocytes from
these mice. F, Details of two-dimensional PAGE
autoradiograms performed after 32P-labeling of cultured
astrocytes and demonstrating the absence of PEA-15 in / mice.
|
|
View larger version (121K):
[in this window]
[in a new window]
|
Figure 4.
Astrocytes from mice lacking PEA-15 seem normal in
their number and morphology. Staining with an anti-GFAP antibody
demonstrate similar population of astrocytes in hippocampal sections
from PEA-15 null mutants (KO) and their wild-type
littermates (WT). Original magnification 200×
(top figures, scale bar, 300 µm) and 400×
(bottom figures).
|
|
Under usual primary culture conditions, no difference was observed
between WT and KO cells with respect to their growth rate and
differentiation, i.e., GFAP expression. In both cell types, TNF
stimulated proliferation as observed after
[3H]thymidine incorporation (128 ± 6 and 135 ± 8% stimulation over control for WT and KO astrocytes
respectively; 24 hr; n = 3).
However, differences were observed between WT and KO cells after TNF
treatment in the presence of the transcription inhibitor actinomycin D. Astrocytes not expressing PEA-15 began to retract after a few hours,
and many cells died within the first 24 hr. In contrast, no major
morphological changes could be observed under the same conditions in WT
cells (Fig. 5A ). The cell
death observed in KO cells was further analyzed by several classical apoptotic tests. The TUNEL assay using fluorescent D-UTP,
clearly labeled KO cell nuclei after 6 hr of treatment with TNF. After 24 hr of TNF treatment, >60% of the KO nuclei were labeled compared with <20% of nuclei from WT cells (Fig. 5B,D). In KO
cells, a rapid labeling could be observed with Annexin V, already
maximal at 6 hr. This was correlated with the typical condensation and fragmentation alterations of the nuclei of the corresponding cells as
observed with DAPI staining (Fig. 5C,D). Finally, after DNA extraction, an in vitro 32P-labeling
assay allowed the identification of ladders corresponding to DNA
fragmentation in KO cells treated with TNF, whereas a minor effect
could be observed in WT astrocytes (Fig. 5E). These data clearly demonstrated that PEA-15 KO cells were more sensitive to
TNF-induced apoptosis than WT astrocytes.
View larger version (99K):
[in this window]
[in a new window]
|
Figure 5.
Increased susceptibility to TNF-induced apoptosis
of cultured astrocytes from / PEA-15 mice. A, Phase
contrast analysis of astrocytes grown for 3 weeks in primary culture
without or with a 24 hr treatment of TNF (300 U/well). KO = PEA/ cells, WT = PEA+/+ cells. B, KO or WT
astrocytes were incubated with TNF for 6 or 24 hr and analyzed by
in situ polymerase assay (TUNEL) using D-UTP
coupled to fluorescein. C, TNF-treated KO or WT cells
were stained an annexin V labeling kit associated with nucleus staining
with DAPI. AnnexinV-positive cells also present nucleus condensation
and fragmentation usually observed during apoptosis. D,
Quantification of results obtained with the different staining methods:
DAPI, Annexin V, and TUNEL. Data are from four or more independent
experiments. Statistically significant at **p < 0.01 versus control according to Student's t test.
E, After a 24 hr incubation with TNF, astrocytes were
harvested, and their DNA was extracted and analyzed on a 1.8% agarose
gels directly or after in vitro end labeling
as described in Materials and Methods.
|
|
To confirm that increased susceptibility to TNF-induced apoptosis in KO
astrocytes was a direct consequence of the lack of expression of
PEA-15, cells were transiently transfected with vector pcDNA3-PEA-15
tagged with a FLAG epitope and with pcDNA3-GFP in a 4:1 ratio. After 48 hr, the expression of the transfected protein was checked by Western
blotting with an anti-FLAG antibody. Cells were then treated with TNF
and apoptosis assayed by Annexin V and DAPI staining. GFP expression
alone did not promote apoptosis neither did it protect cells from the
effects of TNF. In contrast, after cotransfection with PEA-15,
expressing cells exhibited no labeling with annexin V, and their nuclei
appeared normal after DAPI staining, indicating that PEA-15 expression
protected the cell from TNF (Fig. 6).
Similar results were obtained using a single vector pEGFP.C1 where
PEA-15 was fused at the C terminus of GFP.
View larger version (26K):
[in this window]
[in a new window]
|
Figure 6.
Expression of PEA-15 in KO cells
protects them from TNF-induced apoptosis. PEA-15/ astrocytes were
transiently transfected with pcDNA3-GFP alone or pcDNA3-PEA-15-FLAG
associated with pcDNA3-GFP in a 4:1 ratio. After 48 hr, expression of
GFP +/ PEA-15 transfected cells was checked by immunocytochemistry
and immunoblotting against the flag epitope (data not shown).
Transfection protocol resulted in 4-15% of cultured astrocytes
expressing GFP (n = 5). Cells were then treated for
24 hr with TNF. A, Expression of GFP alone does not
protect astrocytes from TNF-induced apoptosis as evidenced by Annexin V
labeling and DAPI staining (left panels). In contrast,
after cotransfection of GFP and PEA-15 fluorescent cells are not
labeled by Annexin V, and their nuclei appear normal after DAPI
staining (right panels). B, Annexin V and
DAPI staining were used to measure the percentage of apoptotic cells.
Results are from five independent experiments, and significant at
**p < 0.01 using Student's t
test.
|
|
| |
DISCUSSION |
Proteins containing a DED, such as FADD and caspase-8, occupy an
apical position in the apoptosis cascade triggered by TNF. We
demonstrate that the astrocytic DED-containing protein PEA-15 interacts
in vitro with FADD and caspase-8, and that its expression decreases astrocyte susceptibility to TNF-induced cell death.
In vitro interaction of PEA-15 with FADD appeared weaker
than that observed between FADD and caspase 8. This could suggest that
post-translational modifications not occurring during bacterial expression of the protein are important. Indeed, in astrocytes PEA-15
was always essentially observed under its phosphorylated forms (Araujo
et al., 1993; Danziger et al., 1995). On the other hand, a low affinity
for interaction could also explain the high level of PEA-15 expression
in glial cells, whereas FADD or caspase-8 are expressed at very low
levels (data not shown).
TNF triggers both cytotoxic and protective mechanisms, respectively
independent and dependent on protein synthesis: whereas it hardly
affects viability of normal cells, TNF destroys diseased cells, such as
virus-infected or transformed cells, and cells treated with inhibitors
of transcription or of protein synthesis (Wallach, 1997a). To balance
these effects, several gamma-type herpes viruses express DED proteins
demonstrated to bind FADD and/or caspase-8 and act as dominant negative
effectors of cytokine-induced apoptosis (Bertin et al., 1997; Thome et
al., 1997). I-FLICE, presenting essentially two DEDs and no caspase
domain, was also shown to bind FADD and/or caspase-8 and/or caspase-10,
and to inhibit apoptosis through a potential dominant negative
mechanism. However I-FLICE did not seem sufficient to block apoptosis
(Scaffidi et al., 1999), and even amplified cell death in other reports (Wallach, 1997b). It would be of interest to see if PEA-15 could also
bind I-FLICE and enhance its efficacy to protect cells. In addition, a
novel DED-containing molecule, DEDD, was proposed to transduce the
death signaling from FADD to the nucleolus (Stegh et al., 1998). PEA-15
is a cytosolic protein, and does not translocate to the nucleus. It
would be of interest to see if PEA-15 binds DEDD and prevents it to
contribute its part in the apoptotic process initiated by CD95.
Among the specific features of the PEA-15 DED is a serine residue found
at position 25, whereas the recently reported three-dimensional structure of the DED domain of FADD suggests a critical proapoptotic function for a phenylalanine at this position, an amino acid conserved in the DEDs of caspase-8 and caspase-10 as well as in viral and mammalian I-FLICE and in DEDD (Eberstadt et al., 1998). This may confer
novel properties for the DED of PEA-15, in addition to an
oligomerization with other DEDs. Indeed, this domain was recently demonstrated necessary for a newly discovered function of the protein,
the reversal of the inhibitory effect of H-Ras on integrin signaling
(Ramos et al., 1998). Work in progress in our group, based on a yeast
two-hybrid screen of a brain and an astrocytic cDNA library will
unravel specific partners of PEA-15 and allow the mapping of
interacting regions.
Why should PEA-15 protect astrocytes from apoptosis? Programmed cell
death is a very general phenomenon, but only a few reports concern
astrocytes. Astrocytes grown in primary cultures were shown to undergo
apoptosis under pharmacological treatments such as staurosporine or
ceramide, a process involving the activation of caspase-3 (Keane et
al., 1997). However, astrocytes seem rather protected in several
pathological situations such as glutamate-triggered excitotoxicity
(Choi, 1988) or calcium overload (Rzigalinski et al., 1997). Neuronal
apoptosis is well documented in CNS damage resulting from trauma or
ischemia, but in these situations astrocytes seem to be essentially
involved in repair and regeneration at the site of injury. In response
to a brain lesion or infection, glial cells have been demonstrated to
secrete and respond to numerous cytokines (Merrill and Benveniste,
1996). Astrocytes produce TNF and express TNF receptors triggering
several responses after TNF stimulation: cell proliferation,
upregulation of TNF mRNAs, production of interleukin 8, macrophage-,
granulocyte-, and granulocyte-macrophage colony stimulating factors
(St. Pierre et al., 1996). In addition, TNF primes astrocytes to render
them immunocompetent through the induction of the expression of several
surface molecules, including MHC class II molecules, ICAM-1,
VLA-1, and VLA-2, allowing recruitment of lymphocytes and
monocytes (Merrill and Benveniste, 1996). Considering the time course
of these events, astrocytes need to be protected against apoptosis that
TNF could also trigger, and PEA-15 seems to play an important role in
this process.
| |
FOOTNOTES |
Received April 8, 1999; revised July 6, 1999; accepted July 16, 1999.
This work was supported by funds from the Institut National de la
Santé et de la Recherche Médicale, European Science
Foundation/European Neuroscience Program European research Grant 245, and VEGA Grant 2/5098/98. Requests concerning the PEA-15
knock-out mice should be submitted directly to Prof. Leder at Harvard
Medical School. We thank Dr. E. Moyse for his help, Prof. Philip Leder
for his encouragement at early steps of this project and for constant support, and Dr. Chris Henderson for critical reading of this manuscript and helpful suggestions.
Drs. Kitsberg and Formstecher contributed equally to this work.
Correspondence should be addressed to Dr. Hervé Chneiweiss,
Institut National de la Santé et de la Recherche Médicale
U114, Chaire de Neuropharmacologie, Collège de France, 11 Place
M. Berthelot 75231 Paris cedex 05, France.
Dr. Pan's present address: Genentech, South San Franscisco, CA
94080-4990.
Dr. Kitsberg's present address: Alamone Laboratories, Jerusalem, Israel.
| |
REFERENCES |
-
Alnemri ES,
Livingston DJ,
Nicholson DW,
Salvesen G,
Thornberry NA,
Wong WW,
Yuan J
(1996)
Human ICE/CED-3 protease nomenclature.
Cell
87:171[ISI][Medline].
-
Araujo H,
Danzinger N,
Cordier J,
Glowinski J,
Chneiweiss H
(1993)
Characterization of PEA-15, a major substrate for protein kinase C in astrocytes.
J Biol Chem
268:5911-5920[Abstract/Free Full Text].
-
Ausubel FM,
Brent R,
Kingston RE,
Moore DD,
Seidman JG,
Smith JA,
Struhl K
(1992)
In: Short Protocols in Molecular Biology. New York: Greene and Wiley.
-
Becher B,
D'Souza SD,
Troutt AB,
Antel JP
(1998)
Fas expression on human fetal astrocytes without susceptibility to fas-mediated cytotoxicity.
Neuroscience
84:627-634[ISI][Medline].
-
Bertin J,
Armstrong RC,
Ottilie S,
Martin DA,
Wang Y,
Banks S,
Wang G-H,
Senkevich TG,
Alnemri ES,
Moss B,
Lenardo MJ,
Tomaselli KJ,
Cohen JI
(1997)
Death effector domain-containing herpesvirus and poxvirus proteins inhibit both Fas- and TNFR1-induced apoptosis.
Proc Natl Acad Sci USA
94:1172-1176[Abstract/Free Full Text].
-
Birman S,
Cordier J,
Glowinski J,
Chneiweiss H
(1989)
CyclicAMP dependent protein kinase in mouse striatal neurones and astrocytes in primary culture: development, subcellular distribution and stimulation of endogenous phosphorylation.
Neurochem Int
14:25-34.
-
Boldin M,
Goncharov TM,
Goltsev YV,
Wallach D
(1996)
Involvement of MACH, a novel MORT1/FADD-interacting protease, in Fas/APO1- and TNF receptor-induced cell death.
Cell
85:803-815[ISI][Medline].
-
Choi DW
(1988)
Glutamate neurotoxicity and diseases of the nervous system.
Neuron
1:623-634[ISI][Medline].
-
Condorelli G,
Vigliotta G,
Iavarone C,
Crauso M,
Tocchetti CG,
Andreozzi F,
Cafieri A,
Tecce MF,
Formisano P,
Beguinot L,
Beguinot F
(1998)
PED/PEA-15 gene controls glucose transport and is overexpressed in type 2 diabetes mellitus.
EMBO J
17:3858-3866[ISI][Medline].
-
Danziger N,
Yokoyama M,
Jay T,
Cordier J,
Glowinski J,
Chneiweiss H
(1995)
Cellular expression, developmental regulation, and phylogenic conservation of PEA15: the major substrate for protein kinase C in astrocytes.
J Neurochem
64:1016-1025[Medline].
-
Deng CX,
Wynshaw-Boris A,
Shen MM,
Daugherty C,
Ornitz DM,
Leder P
(1994)
Murine FGFR-1 is required for early postimplantation growth and axial organization.
Genes Dev
8:3045-3057[Abstract/Free Full Text].
-
Dopp J,
Mackenzie-Graham A,
Otero G,
Merrill J
(1997)
Differential expression, cytokine modulation and specific functions of type-1 and type-2 tumor necrosis factor receptors in rat glia.
J Neuroimmunol
75:104-112[ISI][Medline].
-
Eberstadt M,
Huang B,
Chen Z,
Meadows RP,
Ng S-C,
Zheng L,
Lenardo MJ,
Fesik SW
(1998)
NMR structure and mutagenesis of the FADD(Mort1) death-effector domain.
Nature
392:941-945[Medline].
-
Estelles A,
Yokoyama M,
Nothias F,
Vincent J,
Glowinski J,
Vernier P,
Chneiweiss H
(1996)
The major astrocytic phosphoprotein PEA-15 is encoded by two mRNAs conserved on their full length in mouse and human.
J Biol Chem
271:14800-14806[Abstract/Free Full Text].
-
Fraser A,
Evans G
(1996)
A license to kill.
Cell
85:781-784[ISI][Medline].
-
Garrels JI
(1979)
Two-dimensional gel electrophoresis and computer analysis of proteins synthesized by clonal cell lines.
J Biol Chem
254:7961-7977[Abstract/Free Full Text].
-
Golstev YV,
Kovalenko AV,
Arnold E,
Varfoloveev EE,
Brodianski VM,
Wallach D
(1997)
CASH, a novel caspase homologue with death effector domains.
J Biol Chem
272:19641-19644[Abstract/Free Full Text].
-
Han DKM,
Chaudhary PM,
Wright M,
Friedman C,
Trask B,
Riedel RT,
Baskin DG,
Schwartz ST,
Hood L
(1997)
MRIT, a novel death-effector domain-containing protein, interacts with caspases and BclXL, and initiates cell death.
Proc Natl Acad Sci USA
94:11333-11338[Abstract/Free Full Text].
-
Hu S,
Vincenz C,
Ni J,
Gentz R,
Dixit V
(1997)
I-FLICE, a novel inhibitor of tumor necrosis factor-1 and CD-95-induced apoptosis.
J Biol Chem
272:17255-17257[Abstract/Free Full Text].
-
Inohara N,
Koseki T,
Hu Y,
Chen S,
Nunez G
(1997)
CLARP, a death effector domain-containing protein interacts with caspase-8 and regulates apoptosis.
Proc Natl Acad Sci USA
94:10717-10722[Abstract/Free Full Text].
-
Irmler M,
Thome M,
Hahme M,
Schneider P,
Hofman K,
Steiner V,
Bodmer J-L,
Schöter M,
Burns K,
Mattman C,
Rimoldi D,
French LE,
Tschopp J
(1997)
Inhibition of death receptor signals by cellular FLIP.
Nature
388:190-195[Medline].
-
Keane RW,
Srinivasan A,
Foster LM,
Testa M-P,
Ord T,
Nonner D,
Wang H-G,
Reed JC,
Bredesen DE,
Kayalar C
(1997)
Activation of CPP32 during apoptosis of neurons and astrocytes.
J Neurosci Res
48:168-180[ISI][Medline].
-
Kubes M,
Cordier J,
Glowinski J,
Girault J-A,
Chneiweiss H
(1998)
Endothelin induces a calcium-dependent phosphorylation of PEA-15 in intact astrocytes.
J Neurochem
71:1307-1314[ISI][Medline].
-
Laemmli UK
(1970)
Cleavage of structural proteins during the assembly of the head of the bacteriophage T4.
Nature
227:680-685[Medline].
-
Merrill JE,
Benveniste ET
(1996)
Cytokines in inflammatory brain lesions: helpful and harmful.
Trends Neurosci
19:331-338[ISI][Medline].
-
Moyse E,
Michel D
(1996)
Analyses of apoptosis-associated DNA fragmentation in vivo during neurodegeneration in the peripheral olfactory system in adult mammals.
In: Neuromethods: apoptosis (Poirier J,
ed), pp 135-161. Totowa, NJ: Humana.
-
Muzio M,
Chinnaiyan AM,
Kischkel FC,
O'Rourke K,
Shevchenko A,
Ni J,
Scaffidi C,
Bretz JD,
Zhang M,
Gentz R,
Mann M,
Krammer PH,
Peter M,
Dixit VM
(1996)
FLICE, a novel FADD-homologous ICE/Ced3-like protease, is recruited to the CD95 (Fas/APO1) death-inducing signaling complex.
Cell
85:817-827[ISI][Medline].
-
Ramos J,
Kojima TJ,
Hughues PE,
Fenczik CA,
Ginsberg M
(1998)
The death effector domain of PEA-15 is involved in its regulation of integrin activation.
J Biol Chem
273:33897-33900[Abstract/Free Full Text].
-
Rzigalinski BA,
Liang S,
McKinney JS,
Willoughby KA,
Ellis EF
(1997)
Effect of Ca2+ on in vitro astrocyte injury.
J Neurochem
68:289-296[ISI][Medline].
-
Rösl F
(1992)
A simple and rapid method for detection of apoptosis in human cells.
Nucleic Acids Res
20:5243[Free Full Text].
-
Scaffidi C,
Schmitz I,
Krammer PH,
Peter ME
(1999)
The role of c-FLIP in modulation of the CD95-induced apoptosis.
J Biol Chem
274:1541-1548[Abstract/Free Full Text].
-
Shu HB,
Halpin DR,
Goeddel D
(1997)
Casper is a FADD- and caspase-related inducer of apoptosis.
Immunity
6:751-763[ISI][Medline].
-
Srinivasula SM,
Ahamad M,
Ottilie S,
Bullrich F,
Banks S,
Wang Y,
Fernandez-Alnemri T,
Croce CM,
Litwak G,
Tomaselli KJ,
Alnemri A
(1997)
FLAME-1, a novel FADD-like anti-apoptotic molecule that regulates Fas/TNFR1-induced apoptosis.
J Biol Chem
272:18542-18545[Abstract/Free Full Text].
-
St. Pierre BA,
Merrill JE,
Dopp JM
(1996)
Effects of cytokines on CNS cells: glia.
In: Cytokines and the CNS (Merrill R,
Benveniste E,
eds), pp 151-168. Boca Raton: CRC.
-
Stegh AH,
Schickling O,
Ehret A,
Scaffidi C,
Peterhänsel C,
Hofmann TG,
Grummt I,
Kramer PH,
Peter ME
(1998)
DEDD, a novel death effector domain-containing protein, targeted to the nucleolus.
EMBO J
17:5974-5986[ISI][Medline].
-
Thome M,
Schneider P,
Hofman K,
Fickenscher H,
Meinl E,
Neipel F,
Mattman C,
Burns K,
Bodmer J-L,
Schöter M,
Scaffidi C,
Krammer PH,
Peter ME,
Tschopp J
(1997)
Viral FLICE-inhibitory proteins (FLIPs) prevent apoptosis induced by death receptors.
Nature
386:517-521[Medline].
-
Tybulewicz VL,
Crawford CE,
Jackson PK,
Bronson RT,
Mulligan RC
(1991)
Neonatal lethality and lymphopenia in mice with a homozygous disruption of the c-abl proto-oncogene.
Cell
65:1153-1163[ISI][Medline].
-
Vincenz C,
Dixit V
(1997)
Fas-associated death domain protein interleukin-1
 -converting enzyme 2 (FLICE2), an ICE/Ced3 homologue, is proximally involved in CD95- and p55-mediated death signaling.
J Biol Chem
272:6578-6583[Abstract/Free Full Text]. -
Wallach D
(1997a)
Cell death induction by TNF: a matter of self control.
Trends Biochem Sci
22:107-109[ISI][Medline].
-
Wallach D
(1997b)
Placing death under control.
Nature
388:123-126[Medline].
Copyright © 1999 Society for Neuroscience 0270-6474/99/19198244-08$05.00/0
This article has been cited by other articles:
|
|
|
|
 
H. Vaidyanathan, J. Opoku-Ansah, S. Pastorino, H. Renganathan, M. L. Matter, and J. W. Ramos
ERK MAP kinase is targeted to RSK2 by the phosphoprotein PEA-15
PNAS,
December 11, 2007;
104(50):
19837 - 19842.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S C Mizrak, F Renault-Mihara, M Parraga, J Bogerd, H J G van de Kant, P P Lopez-Casas, M Paz, J del Mazo, and D G de Rooij
Phosphoprotein enriched in astrocytes-15 is expressed in mouse testis and protects spermatocytes from apoptosis
Reproduction,
April 1, 2007;
133(4):
743 - 751.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Miele, G. A. Raciti, A. Cassese, C. Romano, F. Giacco, F. Oriente, F. Paturzo, F. Andreozzi, A. Zabatta, G. Troncone, et al.
PED/PEA-15 Regulates Glucose-Induced Insulin Secretion by Restraining Potassium Channel Expression in Pancreatic {beta}-Cells
Diabetes,
March 1, 2007;
56(3):
622 - 633.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Glading, J. A. Koziol, J. Krueger, and M. H. Ginsberg
PEA-15 Inhibits Tumor Cell Invasion by Binding to Extracellular Signal-Regulated Kinase 1/2
Cancer Res.,
February 15, 2007;
67(4):
1536 - 1544.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F. Renault-Mihara, F. Beuvon, X. Iturrioz, B. Canton, S. De Bouard, N. Leonard, S. Mouhamad, A. Sharif, J. W. Ramos, M.-P. Junier, et al.
Phosphoprotein Enriched in Astrocytes-15 kDa Expression Inhibits Astrocyte Migration by a Protein Kinase C{delta}-dependent Mechanism
Mol. Biol. Cell,
December 1, 2006;
17(12):
5141 - 5152.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Gervais, C. Dugourd, L. Muller, C. Ardidie, B. Canton, L. Loviconi, P. Corvol, H. Chneiweiss, and C. Monnot
Akt Down-Regulates ERK1/2 Nuclear Localization and Angiotensin II-induced Cell Proliferation through PEA-15
Mol. Biol. Cell,
September 1, 2006;
17(9):
3940 - 3951.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. Stassi, M. Garofalo, M. Zerilli, L. Ricci-Vitiani, C. Zanca, M. Todaro, F. Aragona, G. Limite, G. Petrella, and G. Condorelli
PED Mediates AKT-Dependent Chemoresistance in Human Breast Cancer Cells
Cancer Res.,
August 1, 2005;
65(15):
6668 - 6675.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Krueger, F.-L. Chou, A. Glading, E. Schaefer, and M. H. Ginsberg
Phosphorylation of Phosphoprotein Enriched in Astrocytes (PEA-15) Regulates Extracellular Signal-regulated Kinase-dependent Transcription and Cell Proliferation
Mol. Biol. Cell,
August 1, 2005;
16(8):
3552 - 3561.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F. B. Engel, M. Schebesta, M. T. Duong, G. Lu, S. Ren, J. B. Madwed, H. Jiang, Y. Wang, and M. T. Keating
p38 MAP kinase inhibition enables proliferation of adult mammalian cardiomyocytes
Genes & Dev.,
May 15, 2005;
19(10):
1175 - 1187.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Trencia, F. Fiory, M. A. Maitan, P. Vito, A. P. M. Barbagallo, A. Perfetti, C. Miele, P. Ungaro, F. Oriente, L. Cilenti, et al.
Omi/HtrA2 Promotes Cell Death by Binding and Degrading the Anti-apoptotic Protein ped/pea-15
J. Biol. Chem.,
November 5, 2004;
279(45):
46566 - 46572.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Zhao, A. Chow, J. Powers, G. Fajardo, and D. Bernstein
Microarray analysis of gene expression after transverse aortic constriction in mice
Physiol Genomics,
September 16, 2004;
19(1):
93 - 105.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. W. Whitehurst, F. L. Robinson, M. S. Moore, and M. H. Cobb
The Death Effector Domain Protein PEA-15 Prevents Nuclear Entry of ERK2 by Inhibiting Required Interactions
J. Biol. Chem.,
March 26, 2004;
279(13):
12840 - 12847.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. A. Albrecht, A. M. Chinnaiyan, S. Varambally, C. Kumar-Sinha, T. R. Barrette, J. V. Sarma, and P. A. Ward
C5a-Induced Gene Expression in Human Umbilical Vein Endothelial Cells
Am. J. Pathol.,
March 1, 2004;
164(3):
849 - 859.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F.-L. Chou, J. M. Hill, J.-C. Hsieh, J. Pouyssegur, A. Brunet, A. Glading, F. Uberall, J. W. Ramos, M. H. Werner, and M. H. Ginsberg
PEA-15 Binding to ERK1/2 MAPKs Is Required for Its Modulation of Integrin Activation
J. Biol. Chem.,
December 26, 2003;
278(52):
52587 - 52597.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Vaidyanathan and J. W. Ramos
RSK2 Activity Is Regulated by Its Interaction with PEA-15
J. Biol. Chem.,
August 22, 2003;
278(34):
32367 - 32372.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Trencia, A. Perfetti, A. Cassese, G. Vigliotta, C. Miele, F. Oriente, S. Santopietro, F. Giacco, G. Condorelli, P. Formisano, et al.
Protein Kinase B/Akt Binds and Phosphorylates PED/PEA-15, Stabilizing Its Antiapoptotic Action
Mol. Cell. Biol.,
July 1, 2003;
23(13):
4511 - 4521.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Xiao, B. F. Yang, N. Asadi, F. Beguinot, and C. Hao
Tumor Necrosis Factor-related Apoptosis-inducing Ligand-induced Death-inducing Signaling Complex and Its Modulation by c-FLIP and PED/PEA-15 in Glioma Cells
J. Biol. Chem.,
July 5, 2002;
277(28):
25020 - 25025.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
TOP
ABSTRACT
INTRODUCTION
