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The Journal of Neuroscience, March 15, 2002, 22(6):2035-2043
The Neuronal Apoptosis Inhibitory Protein Is a Direct Inhibitor
of Caspases 3 and 7
Johannes K. X.
Maier1, 2,
Zahia
Lahoua1,
Nathalie H.
Gendron1,
Raouf
Fetni1,
Anne
Johnston1,
Jamshid
Davoodi1,
Dita
Rasper4,
Sophie
Roy4,
Ruth S.
Slack3,
Donald W.
Nicholson4, and
Alex E.
MacKenzie1, 2, 5
1 Solange Gauthier Karsh Laboratory, Children's
Hospital of Eastern Ontario Research Institute, Ottawa, Ontario, Canada
K1H 8L1, 2 Department of Biochemistry, Microbiology, and
Immunology, and 3 Neuroscience Research Institute,
University of Ottawa, Ottawa, Ontario, Canada K1H 8M5,
4 Merck Frosst Canada Inc., Kirkland, Quebec, Canada H9H
3L1, and 5 Aegera Therapeutics Inc., Ottawa, Ontario,
Canada K1H 8M5
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ABSTRACT |
The neuronal apoptosis inhibitory protein (NAIP) was identified as
a candidate gene for the inherited neurodegenerative disorder spinal
muscular atrophy. NAIP is the founding member of a human protein family
that is characterized by highly conserved N-terminal motifs
called baculovirus inhibitor of apoptosis repeats (BIR). Five members
of the human family of inhibitor of apoptosis proteins including NAIP
have been shown to be antiapoptotic in various systems. To date, a
mechanism for the antiapoptotic effect of NAIP has not been elucidated.
To investigate NAIP function, we found cytoprotection of
NAIP-expressing primary cortical neurons treated to undergo
caspase-3-dependent apoptosis. The additional treatment of these
neurons with the pancaspase inhibitor
boc-aspartyl(OMe)-fluoromethylketone did not result in increased
survival. Similar cytoprotective effects were obtained using HeLa cells
transiently transfected with a NAIP N-terminal construct and treated to
undergo a caspase-3-dependent cell death. To examine whether NAIP
inhibits caspases directly, recombinant N-terminal NAIP protein
containing BIR domains was overexpressed, purified, and tested for
caspase inhibition potential. Our results demonstrate that inhibition
of caspases is selective and restricted to the effector group of
caspases, with Ki values as low as ~14
nM for caspase-3 and ~45 nM for caspase-7.
Additional investigations with NAIP fragments containing either one or
two NAIP BIRs revealed that the second BIR and to a lesser extent the
third BIR alone are sufficient to mediate full caspase inhibition.
Key words:
BIR domains; NAIP; caspase inhibition; neuronal
apoptosis; inhibitor of apoptosis protein family; cytoprotection
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INTRODUCTION |
With the discovery of biochemical
and histological hallmarks of apoptosis, it has become increasingly
evident that the intrinsic cellular suicide program is not only
required for normal CNS development (Oppenheim, 1991 ) but also, if
executed inappropriately, contributes to the pathology of
neurodegenerative disorders such as Alzheimer's disease (Cotman,
1998), Parkinson's disease (Hartmann et al., 2000), or the childhood
spinal muscular atrophy (SMA; Morrison, 1996). The defining
characteristic of SMA is a progressive loss of motor neurons leading to
wasting of the voluntary muscles. SMA patients are clinically
heterogeneous and are classified into three types (types I-III) on the
basis of age of onset, severity, and clinical progression (Morrison,
1996). The combined frequency for all three types of SMA is
~1:10,000, making it one of the most common inherited
neurodegenerative diseases (Emery, 1991). Analysis of the complex SMA
locus that maps to chromosome 5q13 has led to the discovery of two
candidate genes for SMA, the SMA-causing gene survival motor neuron
(SMN) and the potential modifier neuronal apoptosis inhibitory protein
(NAIP; Lefebvre et al., 1995; Roy et al., 1995). The NAIP gene coding
region spans 4212 nucleotides encoding a 1403-amino acid 156 kDa
protein with strong homology to the baculoviral inhibitor of apoptosis
proteins (IAPs) Cp-IAP and Op-IAP. NAIP is the founding member of the
human IAP protein family (Roy et al., 1995), which typically express
one to three motifs in the N-terminal region termed baculovirus
inhibitor of apoptosis repeat (BIR) domains that are defined by a
CX2CX16HX6-8C consensus sequence (Uren et al., 1998).
Recent studies examining neuronal cell death indicate a key role for
caspase-3 in the apoptotic process. For example, it has been shown that
caspase-3 knock-out mice show severe alterations of brain structures in
regions where neuronal apoptosis is predominantly believed to occur.
The changes include an overall brain mass increase, disorganized cell
deployment, and duplicated brain structures (Kuida et al., 1996). In
addition, upregulation and activation of caspase-3 or a caspase-3-like
protease has been shown to be a key mediator of neuronal death in
neurons after excitotoxic and hypoxic injuries, as well as in the
hippocampal CA1 sector after transient global ischemia (Yakovlev et
al., 1997; Chen et al., 1998; Namura et al., 1998; Ni et al.,
1998).
An antiapoptotic effect of NAIP and other members of the human IAP
family has been shown in cell culture systems (Liston et al., 1996;
Deveraux and Reed, 1999). Apoptotic hippocampal neurons can be rescued
by stereotactic microinjection of NAIP-expressing adenovirus in the CA1
region, suggesting that the antiapoptotic activity of NAIP shown
in vitro extends to the in vivo situation (Xu et
al., 1997). Recent evidence suggests that in addition to supraphysiologic levels of NAIP conferring neuronal protection, the
loss of endogenous NAIP results in enhanced neuronal vulnerability (Holcik et al., 2000), indicating that NAIP plays an important role in
regulation of neuronal apoptosis. However, a mechanism for
antiapoptotic function of NAIP has not yet been identified. Although
other IAP family members have been shown to inhibit caspases directly
(Deveraux et al., 1997; Roy et al., 1997; Tamm et al., 1998), a similar
interaction could not be demonstrated for NAIP (Roy et al., 1997),
suggesting an alternate mechanism in mediating cytoprotection. The
present study demonstrates the direct inhibition of effector caspases
by NAIP BIR domains and thus provides a mechanistic explanation for the
cytoprotective effect of NAIP and its function as an important
regulator protein for neuronal apoptosis.
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MATERIALS AND METHODS |
Generation and cloning of NAIP BIR constructs. NAIP
constructs encompassing one to three BIR domains (see Fig.
2A) were generated by PCR using the following primer
pairs: B123xt, 5' forward primer GGATCC ATG GCC ACC CAG CAG AAA
GCC and 3' reverse primer CTCGAG CCA GAT GCC CAC AGA AAA GCT AT; B1, 5'
forward primer GGATCC GCA GTT CAG TTG GCA AGG and 3' reverse primer
CTCGAG CTC AGC CTG CTC TTC AGA TT; B2, 5' forward primer GGATCC AGC AGG
CTG AGA GAG GT and 3' reverse primer CTCGAG GTA ATT TCC TCT GAG GAT
TTC; B3, 5' forward primer GGATCC TCC TCA GAG GAA ATT ACC and 3'
reverse primer CTCGAG ATA GGA CCA ACT GCA TTG AA; B12, 5' forward
primer GGATCC GCA GTT CAG TTG GCA AGG and 3' reverse primer CTCGAG GTA ATT TCC TCT GAG GAT TTC; B23, 5' forward primer GGATCC AGC AGG CTG AGA
GAG GT and 3' reverse primer CTCGAG ATA GGA CCA ACT GCA TTG AA; B2A, 5'
forward primer GGATCC GCA TCC TTC AGG AAC TGG and 3' reverse primer
CTCGAG TAT GTC AAC AAA TCC C; B2B, 5' forward primer GGATCC ATG AGG TAC
CAA GAA GAGG and 3' reverse primer CTCGAG GGG AAC CAT TTG GCA TG; and
B2C, 5' forward primer GGATCC GGG ATA TCC CCT TGT GTG CTC and 3'
reverse primer CTCGAG ATC ATC TCC TTC TTC CCA. The PCR product
was subcloned in pCR2.1 vector using the Invitrogen TOPO cloning
kit (Invitrogen Canada Inc., Burlington, Ontario, Canada) according to
the manufacturer's instructions. After sequencing, the constructs were
digested with BamHI and XhoI restriction enzymes
and subcloned in pGEX-4T3 and pcDNA3.0-myc vectors.
Overexpression and purification of NAIP BIR proteins. The
recombinant glutathione S-transferase (GST)-NAIP proteins
were overexpressed in Escherichia coli strain BL21 (Novagen
Inc., Madison, WI). Briefly, overnight bacterial cultures were diluted
1:10 in Luria-Bertani medium. The culture was incubated at 30°C to
an OD600 of 1.8, followed by
isopropyl- -D-thiogalactopyranoside induction
(final concentration, 0.1 mM; B2, 0.5 mM). One hour after induction, the cells were
harvested, and the pellets were resuspended in sodium Tris EDTA
buffer [10 mM Tris-Cl, pH 8.0, 150 mM NaCl, 1 mM EDTA, 0.1%
3-[(3-cholamidopropyl)-dimethylammonio]-2-hydroxy-1-propanesulfonic acid (CHAPS), and 5 mM dithiothreitol (DTT)].
Purification was performed by adding glutathione-Sephadex 4B beads
(Amersham Biosciences, Piscataway, NJ) to the soluble fraction,
followed by washing in protein wash buffer (1× PBS, pH 8.0, containing
5 mM DTT and 0.1% CHAPS). The proteins were then
eluted (50 mM Tris-Cl, pH 9.5, 15 mM reduced glutathione, and 0.1% CHAPS). Protein
concentrations were measured using a protein assay (Bio-Rad, Hercules,
CA) according to the manufacturer's protocol. The purity of the
obtained protein was determined by SDS PAGE and was generally
>90%.
Reversible caspase inhibition assay. The reversible caspase
inhibition assay was performed as described previously (Thornberry et
al., 1992; Nicholson et al., 1995) The inhibitory constants were
derived by steady-state velocities of enzyme inhibitor complexes generated with a range of inhibitor (NAIP) concentrations and maintaining constant levels of both enzyme (caspase) and substrate (fluorogenic tetrapeptide) with the concentrations of the caspase and
tetrapeptide in the range of the known
Km for the caspase-tetrapeptide interaction with the following modifications. Ac-YVAD-AMC (Biomol, Plymouth Meeting, PA) was used as the substrate for caspase-1 and
Ac-DEVD-AMC for caspase-3, caspase-7, and caspase-8. Before reading,
the IAP protein was diluted 1:20 in assay buffer followed by serial
dilution before addition of substrate (10 µM
final) and enzyme (50 pM for caspase-3, 2.25 nM for caspase-8, 1.4 nM for caspase-7, and 1 nM for caspase-1; all final
concentrations; final assay volume, 200 µl). The assays were
performed in 96-well microtiter plates at room temperature in
continuous readings for 30 min [five readings per minute; Cytofluor
II; PerkinElmer Life Sciences, Emeryville, CA;  excitation (ex), 380 nm; emission (em), 460 nm]. IC50 values were
calculated using the curve-fitting program PROFIT 5.5 for MacIntosh
(QuantumSoft Inc., Zurich, Switzerland); Ki values were calculated according to
the formula developed by Cheng and Prusoff (1973). This formula is
valid when the binding is competitive and reversible; we know that this
is the case for capase-3 and XIAP given the recently published
structural analyses of IAP and caspases (Chai et al., 2001; Huang et
al., 2001; Riedl et al., 2001). Because substrate concentration and
Km were kept constant in the assay
(both at 10 µM), the
Ki should approximate half of the
obtained IC50 value.
Ki values were also calculated from
the steady-state velocities of the enzyme inhibitor complexes using the
equations developed by Morrison and Walsh (1988) for the analysis of
slow and tight binding inhibitors. This was done in the event that the
binding had a marked time dependence and was not wholly competitive and
reversible, in which case the Cheng and Prusoff (1973) equation would
not obtain. The fact that equivalent results were obtained by both
statistical methods supports the accuracy of the inhibitory constants.
Culture and survival of primary cortical neurons. Mouse
cortical neurons (CD1) were cultured from embryonic day 16 (E16) and grown in defined serum-free medium as described previously (Keramaris et al., 2000). For optimal infection of neurons with minimal
cytotoxicity, recombinant adenoviral vectors (carrying lacZ,
NAIP, or XIAP), at a multiplicity of infection
(MOI) of 10 or 20 pfu/cell, were added to cell suspensions immediately
before plating. Neurons were cultured up to day 3 and subsequently
treated either with camptothecin (10 µM) alone
or with camptothecin and boc-aspartyl(OMe)-fluoromethylketone (BAF; 100 µM). Cell survival was assessed by using the
colorimetric (3-(4,5-dimethylthiazol-2-yl)-2,5 diphenyltetrazolium
bromide (MTT) survival assay (Cell Titer Kit; Promega, Madison, WI),
which measures the conversion by mitochondrial enzymes of the
tetrazolium salt to a blue formizan salt 24 hr after treatment in an
adaptation of the method of Keramaris et al. (2000).
Cell culture and transfection. HeLa cells (CCL2; American
Type Culture Collection, Manassas, VA) were grown in DMEM with 4.5 mg/ml D-glucose and pyridoxine hydrochloride (Invitrogen)
containing 10% heat-inactivated fetal bovine serum, 2 mM
L-glutamine, 100 U/ml penicillin G, and 100 µg/ml
streptomycin. Twenty-four hours before transfection, cells were plated
at a density of 2 × 105 cells/well
in 60 mm six-well culture dishes. Cells were transfected by applying
the LipofectAMINE Plus system (Invitrogen) using 0.8 µg of each
plasmid construct and 0.4 µg of pEGFP-N1 plasmid [expressing green
fluorescent protein (GFP)] according to the manufacturer's protocol.
HeLa cell death assay. Twenty-four hours after transfection,
the cells were treated with 100 µM etoposide in
dimethylsulfoxide (DMSO) or with DMSO (control) for 8 hr before being
returned to complete media. Seventy-two hours after treatment, the
supernatant was removed and centrifuged to collect floating cells. The
adherent cells were trypsinized and then combined with the floating
cells by centrifugation and washed with cold PBS. After a second
centrifugation, the cells were resuspended in 500 µl of cold PBS.
Five minutes before flow cytometry analysis, 5 µl of 1 mg/ml
propidium iodide (PI) was added to the cells. Flow cytometry was
performed using an EPICS XL flow cytometry system (Beckman-Coulter
Inc., Fullerton, CA), and analysis of cell viability was performed
using the software WinMDI 2.8 (http://facs.scripps.edu). GFP- and
PI-positive cells were counted in control and etoposide-treated cells
transfected with the same construct. Specific apoptosis was calculated
in an adaptation of the method of Scaffidi et al. (1998).
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RESULTS |
NAIP protects primary cortical neurons undergoing
caspase-3-dependent apoptotic death
To elucidate the antiapoptotic mechanism mediated by NAIP, we
sought to study its action in a physiologically relevant context. Previous work has shown that the genotoxic agent camptothecin evokes
apoptotic death of cultured embryonic (E16) mouse cortical neurons
through activation of caspase-3 (Stefanis et al., 1999; Keramaris et
al., 2000). To clarify whether the chief means of neuroprotection by
NAIP is mediated through a caspase-dependent or -independent mechanism,
as suggested by the results of a previous in vitro study
(Roy et al., 1997), an adenoviral vector was used to deliver
full-length NAIP to cortical neurons undergoing apoptosis induced by
the DNA-damaging agent camptothecin. The effect of NAIP in this system
was compared with the IAP family member XIAP, shown previously to
inhibit effector caspases directly (Deveraux et al., 1997), as well as
with an adenovector carrying the lacZ gene
(Ad-lacZ) used as a vector control. Cultured neuronal cells, infected with lacZ at an MOI of 20, exhibit 36.8 ± 2.3% survival 24 hr after treatment with camptothecin, as determined
by MTT assay (Fig. 1). In contrast,
neurons expressing NAIP exhibited a significantly prolonged survival in
an MOI dose-dependent manner (Fig. 1); e.g., a significant delay in
cell death was obtained with 44.6 ± 2.6% survival of these
neurons when an MOI of 10 was used (Fig. 1) and 49.7 ± 3.8% with
an MOI of 20 (Fig. 1). Comparable results were obtained with the
caspase inhibitor XIAP (44.7 ± 2.8% at MOI 10 and 51.2 ± 3.5% at MOI 20) (Fig. 1). To establish whether the neuroprotective
effect observed with NAIP is attributable to inhibition of caspases
alone or via a caspase-independent mechanism, the identical experiments
were conducted in the presence of the general caspase inhibitor BAF.
The application of BAF (100 µM) alone to
camptothecin-treated neurons expressing LacZ resulted in prolonged
survival (45.8 ± 2.2% with an MOI of 20) (Fig. 1). However, when
neurons were infected with Ad-NAIP at an MOI of 10 in
addition to BAF, a small but significant (p < 0.05, Student's t test) increase in cell survival was
observed (49.5 ± 3.2%) (Fig. 1). When Ad-NAIP was
used at an MOI of 20, the addition of BAF resulted in no significant
increase in cell survival (50.6 ± 2.7% with BAF treatment
compared with 49.7 ± 3.8% without) (Fig. 1). Similar results
were obtained when Ad-XIAP was used under identical conditions (Fig. 1). Together, the results of these studies indicate that NAIP expression can protect cortical neurons primarily through either direct inhibition of caspases or a caspase-dependent
pathway.
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Figure 1.
Cytoprotection of Ad-NAIP in
primary cortical neurons treated to undergo caspase-3-dependent cell
death. The neurons were infected with Ad-lacZ,
Ad-NAIP, or Ad-XIAP at the MOI indicated
at the bottom. After 3 d of culture, the cells were
treated with camptothecin alone (10 µM) or with addition
of the pancaspase inhibitor BAF (100 µM). Control samples
were kept untreated. A neuronal survival assay (MTT) was assessed 24 hr
later. Data are expressed as number of surviving cells treated with
camptothecin alone or with BAF versus nontreated cells (taken as
100%), and are the mean ± SEM of six independent experiments.
*p < 0.05; **p < 0.01;
Student's t test.
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The N terminus of NAIP can protect HeLa cells undergoing
caspase-3-dependent apoptosis
In view of the above findings, additional experiments to establish
the results in an alternate cellular system were undertaken. When
treated with the topoisomerase II inhibitor etoposide, HeLa cells are
reported to undergo apoptosis characterized by elevated levels of
caspase-3 (Liu, 1989; Mizukami et al., 1999). In these studies, we used
a N-terminal construct of NAIP encompassing the three BIR domains (Fig.
2A, B123xt),
shown previously to be sufficient to mediate an antiapoptotic effect
(Liston et al., 1996). HeLa cells were transiently transfected with
pcDNA3.0-myc B123xt and treated with etoposide. The effect was compared
with cells transfected with pcDNA3.0-myc-XIAP or pcDNA3.0-myc-Survivin,
IAP family members shown previously to confer cytoprotection in a
similar system by inhibiting caspase-3 and caspase-7 (Tamm et al.,
1998). Cotransfection with pEGFP-N1 (expressing GFP) allows the
identification of transfected cells. After an incubation period of 72 hr, cell viability for GFP-positive cells was determined by flow
cytometry. The results of four experiments revealed significant
cytoprotection by all IAP constructs applied in comparison with the
samples transfected with the empty vector (63.3 ± 6.3%) (Fig.
3), with the NAIP B123xt construct
exhibiting the most profound cytoprotective effect (89.8 ± 0.4%), followed by Survivin (78.2 ± 6.3%) and XIAP (73.8 ± 3.2%) (all Fig. 3). Together, these results support the finding
that expression of NAIP is cytoprotective when cells undergo
caspase-dependent apoptosis and that this effect is mediated via its
BIR domains.
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Figure 2.
A, Illustration of the NAIP
deletion constructs generated for caspase inhibition and cell death
assays. B, Amino acid sequence alignment of BIR domains
of human IAP family members known to have an antiapoptotic effect. The
alignment was generated with the program CLUSTALW 1.8 (Thompson et al.,
1994) with default settings (http://workbench.sdsc.edu/). The
black regions in highlight amino acids
conserved in BIR motifs across species as determined by Uren et al.
(1998); the gray regions indicate identity with NAIP
BIR2 domain. The sequences of NAIP BIR2 deletion constructs
(B2A, B2B, B2C) are
illustrated above the NAIP BIR2 sequence. C,
Phylogenetic tree diagram (rooted) of the BIR sequences aligned in
B generated with the program DRAWGRAM (Inference
Package, version 3.5; Department of Genetics, University of Washington,
Seattle, WA) using NAIP B2 as the leader sequence.
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Figure 3.
Cytoprotection assay of apoptotic HeLa cells
transfected with IAP constructs. HeLa cells were transiently
cotransfected with the pEGFP-N1 vector and either pcDNA3.0-myc vector
alone (control) or pcDNA3.0-myc containing B123xt, XIAP, or Survivin
(Surv) and treated with the topoisomerase II inhibitor
etoposide for 8 hr (control samples were kept untreated). Seventy-two
hours after treatment, cell death was assessed in GFP-positive cells by
flow cytometry. Results (mean ± SEM) of four independently
performed experiments are shown. Cell survival was calculated in an
adaptation of the method of Scaffidi et al. (1998).
*p < 0.05; **p < 0.01;
***p < 0.001; Student's t
test.
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Recombinant N-terminal NAIP protein selectively inhibits
caspase-3 and caspase-7
We then overexpressed and purified a recombinant GST-NAIP fusion
protein encompassing the three BIR domains (Fig. 2A,
B123xt) to evaluate the possibility that NAIP directly
inhibits caspases. Peptide aldehydes that reversibly bind and suppress
caspase activity with high potency (Garcia-Calvo et al., 1998) as well
as a recombinant GST-XIAP protein were used as enzyme inhibition
controls. The GST-XIAP protein was purified and treated under
conditions identical to those used for the NAIP B123xt protein.
On the basis of the classification of caspases (Thornberry et al.,
1997), caspase-1 (interleukin-1 converting enzyme) was selected
as a representative of group I caspases (caspase-1, caspase-4, and
caspase-5) and tested for direct inhibition by purified GST-B123xt. This enzyme could not be inhibited by NAIP or XIAP, even when high
concentrations of protein (NAIP, 3 µM; and XIAP, 5 µM) were used (Fig.
4A). The same result
was obtained when NAIP and XIAP were tested against caspase-8, a
representative member of the group III caspases (Fig.
4B). However, very potent and specific inhibition was
obtained when NAIP was tested against members of the group II caspases,
also termed effector caspases, because of the multitude of cellular and
structural proteins that serve as their substrates (Nicholson, 1999).
Figure 5A depicts the specific inhibition of caspase-7 by NAIP (Ki,
50 nM), identical to that observed for XIAP
(Ki, 49 nM).
Additional assays were then conducted to evaluate the potential for
inhibition of the most prominent member of group II caspases,
caspase-3. Figure 5B represents a typical experiment
(n = 6) of caspase-3 inhibition by NAIP. As is the case
for caspase-7, B123xt is able to inhibit caspase-3 but with a much
higher affinity. The Ki values of
several independent experiments conducted to substantiate the potency
of B123xt for caspase-3 inhibition ranged from 7 to 21 nM (14 ± 5 nM; Table 1). Control proteins such as GST and SMN
as well as the elution buffer itself showed no inhibitory effect on
caspases (data not shown).
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Figure 4.
Caspase inhibition assay, group I and III
caspases. A, Inhibition of caspase-1, a representative
member of the group I caspases. The tetrapeptide Ac-YVAD-AMC (10 µM) served as the substrate. Enzyme concentration was
held constant at 1 nM. The peptide aldehyde
Ac-YVAD-CHO was used as control for enzyme inhibition at
an initial concentration of 10 µM. Continuous readings
(ex, 380 nm; em, 460 nm) were performed for 30 min at room
temperature. The IC50 of the control inhibitor
Ac-YVAD-CHO was 74 nM. B,
Inhibition of caspase-8, a representative member of group III
caspases. The assay was performed as described above with a substrate
concentration (Ac-DEVD-AMC) of 10 µM and an enzyme
concentration of 2.25 nM. The peptide aldehyde
Ac-DEVD-CHO was applied as inhibition control,
inhibiting the enzyme with an IC50 of 18 nM.
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Figure 5.
Caspase inhibition assay, group II caspases.
A, Representative illustration of caspase-7 inhibition.
The IC50 of NAIP (B123xt) was 101 nM in this experiment; XIAP was 99 nM; and
Ac-DEVD-CHO was 39 nM. The enzyme
concentration in this experiment was 1.4 nM.
B, Representative experiment of caspase-3 inhibition by
NAIP (B123xt). The assay was performed as described
above using caspase-3 at 50 pM. The IC50 values
obtained from this experiment were 23 nM for
XIAP, 28 nM for NAIP
(B123xt), and 4 nM for the control inhibitor
Ac-DEVD-CHO.
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A single NAIP BIR domain is sufficient for
caspase-3 inhibition
To investigate which BIR domains in combination or isolation
inhibit caspase-3, NAIP deletion constructs comprising either single or
dual BIR (Fig. 2A) were cloned into bacterial
expression vectors, overexpressed as GST fusion proteins, purified, and
tested for potential caspase-3 inhibition. In Figure
6A, a representative result for caspase-3 inhibition using proteins containing two NAIP BIR
domains in relation to control inhibitors, peptide aldehyde, or
GST-XIAP is shown. The B12 protein shows no significant enzyme inhibition, whereas B23 inhibits caspase-3 with a low potency in
comparison with full-length XIAP and B123xt. The
IC50 value obtained from this experiment was 614 nM for B23, corresponding to a
Ki of 307 nM.
When proteins comprising single NAIP BIR motifs were tested in
inhibition assays, a wide range of inhibition potencies was
observed. The GST-BIR1 (B1) protein did not inhibit caspase-3 activity (Fig. 6B) in contrast to GST fusion
proteins containing either the BIR3 or BIR2 domain. GST-B3 shows a
weaker inhibition profile, similar to that observed with the B23
protein (Ki, 195 and 276 nM, respectively). Potent inhibition of caspase-3
was observed with the BIR2 construct
(Ki, 9) (Fig. 6B),
similar to that seen for the protein containing all three BIR domains
(Fig. 5B, B123xt). The profound inhibitory effect
of the BIR2 protein was substantiated in additional experiments
yielding Ki values of 5 and 21 nM (10 ± 6 nM; Table
1), demonstrating that a single BIR domain of NAIP is sufficient to
fully mediate the inhibitory effect. On the basis of these findings, we
tested additional truncations of the BIR2 domain to delineate the
minimum requirement for caspase-3 inhibition. Three constructs were
generated (Fig, 2B, B2A, B2B, B2C) with deletions of amino acids highly conserved within
all known BIR motifs (Uren et al., 1998) (Fig. 2B).
None of these BIR2 deletion proteins was able to inhibit caspase-3
(data not shown).
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Figure 6.
Caspase-3 inhibition assay, NAIP BIR deletion
proteins. A, Caspase-3 inhibition assays of NAIP BIR
deletion constructs using NAIP proteins with two BIR domains. The NAIP
B12 protein does not inhibit caspase-3,
B23, with an IC50 of 614 nM,
~20-fold lower than XIAP, with an IC50 of 32 nM. B, Typical experiment of caspase-3
inhibition by NAIP proteins containing a single BIR domain. The
experimental procedure is described above and revealed IC50
values for B3 of 348 nM and for
B2 of 17 nM; values of control inhibitors
are as in A.
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NAIP BIR deletion constructs show inhibition in cell
death assays
After the demonstration that a single BIR domain is sufficient to
inhibit caspases, a correlation between the in vitro
BIR-mediated caspase inhibition and cytoprotection was sought. The BIR
deletion constructs were subcloned in a pcDNA3.0-myc vector and
transiently transfected along with pEGFP-N1 into HeLa cells, applying
the conditions described above. Expression of NAIP deletion proteins was confirmed by Western blot analysis using an anti-myc antibody (data
not shown). The results of four experiments are illustrated in Figure
7 and reveal cytoprotection by all NAIP
BIR constructs used when compared with the control sample (63.3 ± 3.2%) (Fig. 7), with B3 showing the most profound cytoprotective
effect (91.3 ± 3.4%), followed by B2 (82.8 ± 3.6%) and B1
(73.8 ± 5%). The proteins containing two BIR domains also
conferred significant protection, with 71.2 ± 4% for B12 and
81.9 ± 1.7% for B23 (Fig. 7). These results show that NAIP
proteins with the greatest capability for caspase inhibition
in vitro (B123xt, B3, B2, and B23) conferred the
greatest cytoprotection in the HeLa cell death assays, consistent with
a causal link between caspase inhibition and cellular survival.
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Figure 7.
Cytoprotection assay of apoptotic HeLa cells
transfected with NAIP BIR deletion constructs. Description and
procedure are as described in Figure 3. Surv,
Survivin.
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DISCUSSION |
The first human IAP family member, NAIP, was cloned in 1995 as the
result of a search for the genetic cause of the neurodegenerative disorder SMA. A number of laboratories have shown that NAIP is antiapoptotic and cytoprotective in a variety of cellular and in
vivo models (Liston et al., 1996; Xu et al., 1997; Perrelet et
al., 2000), suggesting that NAIP is an important regulator of neuronal
apoptosis. However, a mechanism of NAIP action has not yet been
described. In this report, we demonstrate that the BIR domains of NAIP
are potent inhibitors of effector caspases, suggesting a mechanism for
the antiapoptotic effect of NAIP.
Analysis of representative enzymes of all three groups of caspases
demonstrate an inhibition of caspases that is apparently selective and
restricted to group II caspases, with
Ki values as low as ~15
nM for caspase-3 and ~45
nM for caspase-7 (Fig. 5, Tables 1,
2). The comparison of
Ki values obtained from our experiments reveals no difference between the caspase inhibitory properties of NAIP and XIAP (Figs. 4-6), an IAP family member shown previously to inhibit caspases (Deveraux et al., 1997). A previously published study assaying for an in vitro recombinant NAIP
and caspase interaction failed to detect any binding to caspase (Roy et
al., 1997) for reasons that are unclear. The N-terminal NAIP construct
used in our study included the putative ATP and GTP binding site
downstream from the third BIR (Fig. 2A,
B123xt), adding 160 amino acids to the protein used in the
previous study (Roy et al., 1997). The inclusion of these amino acids
may permit proper protein folding. Generally, a strong tendency of NAIP
BIR proteins toward oligomerization and precipitation was observed during the course of purification, especially with highly soluble proteins such as B23 and B3. The BIR-BIR interaction revealed in x-ray
crystallographic analysis of the IAP family member Survivin (Verdecia
et al., 2000) is consistent with a model of NAIP BIR domain self
association.
The effect of NAIP as a specific and potent inhibitor of group II
caspases was also assessed in a context of greater physiological relevance. In view of the pivotal role of caspase-3 in mediating neuronal apoptosis, we investigated the effect of NAIP and caspase inhibition in apoptotic neuronal cells. When exposed to the
DNA-damaging agent camptothecin, primary cortical neurons show
characteristic features of apoptosis and elevated levels of caspase-3
(Stefanis et al., 1999; Keramaris et al., 2000). As shown in Figure 1,
infection of camptothecin-treated neurons with an adenovirus expressing either NAIP or XIAP led to similar levels of survival of these neurons.
This effect was dose-dependent, because the application of an MOI of 20 resulted in a higher protection than seen with an MOI of 10 (Fig. 1).
The additional treatment of NAIP-expressing neurons with the pancaspase
inhibitor BAF led to increased survival only when a low MOI was used
(Fig. 1). The lack of an additional cytoprotective effect with BAF at a
high MOI (Fig. 1) strongly suggests that a caspase-3-dependent
apoptotic pathway is inhibited by NAIP. The results obtained are in
accordance with cytoprotection studies using cerebellar granule neurons
deprived of K+ and infected with identical
adenoviral constructs (Simons et al., 1999). This previous study also
showed caspase-3-dependent cell death inhibited by expression of NAIP
or XIAP (Simons et al., 1999). These results, together with the
inhibition data obtained from our in vitro assays, strongly
suggest that the neuroprotective effect is mediated either in part or
wholly as a consequence of direct inhibition of effector caspases by NAIP.
To define the motif(s) that are necessary and sufficient for caspase
inhibition, constructs encompassing either single or dual BIR were
generated. The purified recombinant GST fusion proteins were tested for
caspase-3 inhibition. The experiments clearly demonstrate that the
caspase-inhibiting domain can be reduced to the second or third BIR
domain of NAIP or both. With B2, Ki values were almost equal to those documented with the N-terminal NAIP
protein B123xt and full-length XIAP, ranging from 5 to 21 nM (Fig. 6, Tables 1, 2). Therefore, the second
BIR domain is sufficient to mediate the full inhibitory effect of NAIP
on group II caspases. Deletions of highly conserved amino acids within this critical BIR (as shown in Fig. 2B) resulted in
proteins unable to inhibit caspase-3 (data not shown), suggesting that
the intact BIR motif is necessary to mediate the caspase inhibitory
effect. A full potential for caspase-3 inhibition is also reported for the second BIR domain of XIAP (Takahashi et al., 1998), underlining the
importance of this BIR in mediating an apoptotic resistance. However,
recent publications revealing the structure of the XIAP complexed with
caspase-3 and caspase-7 showed binding to effector caspases with the
XIAP BIR1/2 linker region (Chai et al., 2001; Huang et al., 2001; Riedl
et al., 2001). It is important to note that this caspase binding motif
is not conserved among IAPs as is the BIR domain (Fig.
2B,C); it will be of interest to delineate the
caspase binding motif of the NAIP B2 protein. A study addressing the
inhibition kinetics of linker region and BIR2 domain on caspase-3 is
currently under way and shall hopefully shed more light on this issue.
The recent crystallographic structural analyses have revealed
unexpected details of the XIAP-caspase interaction. A DISD
tetrapeptide lying outside and ~11 amino acids upstream of the NH2
border of the XIAP BIR2 domain has been found to be critical for the
interaction of both caspase-3 and caspase-7, binding to the catalytic
groove of both proteases (Sun et al., 1999; Chai et al. 2001;
Huang et al., 2001; Suzuki et al., 2001). This is the same groove to
which the tetrapeptide DEVD caspase inhibitor binds. A scan of the NAIP
sequence for a similar tetrapeptide mapping upstream of any of the
three BIRs, assuming a similar mechanism of binding and inhibitory
action, reveals a DIRV motif that maps 15 amino acids upstream of the
BIR2. This domain, which binds most avidly to caspase 3, is included in
all the BIR2-containing polypeptides used in this study. Thus it may be
that the motif contributes to the caspase binding and inhibition of
BIR2. The difference in the size and polarity of arginine (bulky and
positive) from that of serine (small and uncharged) and charge
dissimilarity between valine (uncharged) and aspartate (negative) makes
such a possibility somewhat less likely, but such binding is currently being assessed.
The potency of NAIP B2 protein in inhibiting effector caspases
correlates in its ability to protect cells from undergoing apoptosis.
When HeLa cells are treated with the anticancer drug etoposide,
apoptosis and elevated levels of activated caspase-3 are observed (Yang
et al., 1997; Mizukami et al., 1999). Transfection of a single NAIP
BIR2 construct in HeLa cells resulted in significant cytoprotection,
with 83% cell survival compared with ~60% of cells transfected with
the control plasmid (Fig. 7). In Figure 2, B and
C, sequence alignment of the BIR domains of human IAPs is illustrated, showing a close sequence identity between the second and
third BIRs of NAIP. In this context, it might be expected that
recombinant B3 protein would also inhibit caspase-3 strongly; however,
the Ki values obtained from our
in vitro experiments are ~20- to 30-fold lower than for
the B2 protein (Fig. 6). In the cell death assays, B3 shows
significantly higher protection than B2 (91 vs 83%; p = 0.0434) (Fig. 7). When evaluating the subcellular localization of B2
and B3 in transfected HeLa cells, we find a predominant staining of the
hydrophobic B2 protein localizing to the membrane in contrast to the
cytoplasmic and nuclear staining seen with B3 (data not shown). It may
be that this membrane association impairs the ability of B2 to inhibit
caspase activity when compared with the more soluble and accessible B3.
Thus, cellular sublocalization in addition to caspase affinity appears
to be an important factor in the cytoprotective potency of a given
protein. Less cytoprotection was observed for the B12 and B1 proteins,
correlating with their weaker caspase inhibition. Nonetheless, the
cytoprotective effect of these constructs is significant (Fig. 7).
Given the strong cytoprotective effects of BIR constructs that inhibit
caspase-3 directly, such as B123xt, B23, B2, and B3 (Figs. 5, 6), we
assume that the recombinant proteins (B1 and B12) used were misfolded but retain reduced capability for caspase inhibition when expressed in cells.
Together, the results from our study provide strong support for a model
in which NAIP, more specifically the BIR2 domain, is playing a critical
role in regulation of neuronal apoptosis by directly inhibiting
effector caspases. It is perhaps of significance that two-thirds of SMA
type I and a smaller fraction of type II and III patients have
homozygous deletions in exons 5 and 6 of the NAIP gene (Roy et al.,
1995) (Fig. 2A). Deletions of these exons would
result in either the complete absence of NAIP or the generation of a
protein lacking BIR2 domain (Fig. 2A). This could potentially result in an impaired or abolished ability to inhibit the
effector caspases, resulting in enhanced levels of death in the
SMN-deficient motor neurons, thus exacerbating the clinical severity of SMA.
| |
FOOTNOTES |
Received May 18, 2001; revised Oct. 30, 2001; accepted Nov. 6, 2001.
This work was supported by grants from the Canadian Institutes of
Health Research, the Muscular Dystrophy Association of Canada, and Aegera Therapeutics Inc. A.E.M. is a Burroughs-Wellcome clinical translation awardee.
Correspondence should be addressed to Dr. Alex E. MacKenzie,
Children's Hospital of Eastern Ontario Research Institute, 401 Smyth
Road, Ottawa, Ontario, Canada K1H 8L1. E-mail:
alex{at}mgcheo.med.uottawa.ca.
| |
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TOP
ABSTRACT
INTRODUCTION
