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Molecular and Cellular Biology, July 2001, p. 4292-4301, Vol. 21, No. 13
Metabolism Branch, Division of Clinical Sciences, National
Cancer Institute,1 and Surgical
Neurology Branch, National Institute of Neurological Disorders and
Stroke,3 National Institutes of Health,
Bethesda, and National Cancer Institute
Received 21 December 2000/Returned for modification 12 February
2001/Accepted 2 April 2001
Inhibitor of apoptosis protein (IAP)-like protein-1 (ILP-1) (also
known as X-linked IAP [XIAP] and mammalian IAP homolog A [MIHA]) is
a potent inhibitor of apoptosis and exerts its effects, at least in
part, by the direct association with and inhibition of specific
caspases. Here, we describe the molecular cloning and characterization
of a human gene related to ILP-1, termed ILP-2.
Despite high homology to ILP-1, ILP-2 is encoded by a distinct gene,
which in normal tissues is expressed solely in testis. In contrast to
ILP-1, overexpression of ILP-2 had no protective effect on apoptosis
mediated by Fas (also known as CD95) or tumor necrosis factor. However,
ILP-2 potently inhibited apoptosis induced by overexpression of Bax or
by coexpression of caspase 9 with Apaf-1, and preincubation of
cytosolic extracts with ILP-2 abrogated caspase activation in vitro. A
processed form of caspase 9 could be coprecipitated with ILP-2 from
cells, suggesting a physical interaction between ILP-2 and caspase 9. Thus, ILP-2 is a novel IAP family member with restricted specificity
for caspase 9.
Apoptosis is a genetically
determined, biochemically ordered process in which cells are induced to
initiate a cellular suicide program in response to physiologic signals,
cellular damage, or virus infection (24, 46, 47). The
principal effectors are a family of cysteine proteases known as
caspases (35, 42). These proteases, which cleave with a
high degree of specificity after aspartate residues, are initially
produced in the cell as inactive precursors whose activation is
controlled by a variety of regulatory factors and events. Numerous
regulators of apoptosis have been identified and have been shown to
exert their effects ultimately by affecting levels of caspase activity.
For example, the Bcl-2 family of proteins regulates apoptosis through
the control of mitochondrial integrity. Proapoptotic signals have been
shown to result in the release of cytochrome c from the
mitochondria into the cytosol (4, 6, 14, 25, 34, 44, 48).
Released cytochrome c is thought to stimulate the formation
of an active holoenzyme containing the CED-4-like protein Apaf-1
together with caspase 9 (1, 5, 31), and this holoenzyme
induces the activation of the downstream effector caspase, caspase 3. Overexpression of prosurvival members of the Bcl-2 family has been
shown to maintain mitochondrial membrane integrity, preventing
cytochrome c release and thereby inhibiting formation
of the Apaf-1:caspase 9 holoenzyme (21).
In contrast to the mechanisms employed by Bcl-2-related proteins,
several members of the inhibitor of apoptosis (IAP) family of proteins
are thought to bind directly to caspases and inhibit their enzymatic
activity (10, 11). Three IAPs, ILP-1 (also known as
X-linked IAP [XIAP] and MIHA), c-IAP1, and c-IAP2, are widely
expressed in mammalian tissues and are broad inhibitors of apoptosis
(15, 26, 32, 43). Their predicted open reading frames
share several common features: all three IAPs have three tandem repeats
of an approximately 70-residue domain known as the BIR (baculovirus
iap repeat), followed by an amphipathic spacer region of
unknown function and a single carboxy-terminal RING finger domain
(2, 22). In vitro evidence suggests that c-IAP1, c-IAP2,
and ILP-1 inhibit cell death by interacting with and inhibiting specific caspases, namely caspases 3, 7, and 9 (11, 12,
33). Studies of individual BIRs suggest that these are the
domains responsible for caspase interaction and inhibition (40,
41). The RING finger domain of the IAPs has recently been shown
to play a role in regulating their signal-induced autoubiquitination and resulting degradation (49).
Here, we report the identification of ILP-2, a novel member of the IAP
family that is most closely related in sequence to ILP-1.
ILP-2 encodes a single amino-terminal BIR domain followed by
a spacer region and a carboxy-terminal RING finger domain. In normal
tissues, expression of the ILP-2 gene was detected only in
testis, but ILP-2 was also detected in lymphoblastoid cells. Human
ILP-2 potently inhibited apoptosis induced by overexpression of Bax or
by caspase 9 and Apaf-1, but unlike ILP-1, ILP-2 had no protective
effect on apoptosis mediated by Fas (also known as CD95). In a
cell-free system utilizing cytosolic extracts, ATP-dependent caspase
activation was abrogated when recombinant ILP-2 protein was added prior
to ATP. However, once active, caspases in the cell-free system were not
inhibited by ILP-2. In contrast, ILP-1 blocked both caspase activation
and activity in the cell-free system. In transient-transfection
studies, a processed form of caspase 9 was coprecipitated with ILP-2,
suggesting a direct physical interaction between ILP-2 and caspase 9. Thus, ILP-2 is a novel member of the IAP family with restricted
apoptotic inhibitory functions.
Molecular cloning and characterization of ILP-2.
Combinations of oligonucleotides which collectively span the
ILP-1 gene were tested in PCRs using human genomic DNA and
cDNA prepared from peripheral blood leukocyte RNA. A PCR product was obtained from genomic DNA with two primers,
5'-CCTGGCGCGAAAAGGTGGACAAGTC-3' and
5'-TGTTCACATCACACATTCAATCAGGG-3', and using the following PCR conditions: 45 s at 94°C, 45 s at 60°C, and 120 s at
72°C for 30 cycles. This product was found to encode a previously
unidentified sequence, which was designated ILP-2.
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.13.4292-4301.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Molecular Cloning of ILP-2, a Novel
Member of the Inhibitor of Apoptosis Protein Family
Frederick Cancer
Research and Development Center, National Institutes of Health,
Frederick,5 Maryland, and Istituto
Tecnologie Biomediche Avanzate, Milan,2 and
Department of Pediatrics, University of Brescia,
Brescia,4 Italy
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
RT-PCR expression analysis. Reverse transcriptase-PCR (RT-PCR) was performed on total RNA of testis, heart, and lung (Clontech, Palo Alto, Calif.) as follows. RNase-free DNase I (1 µl; Promega) was added to 4 µl of total RNA and was incubated at 37°C for 30 min and then at 75°C for 5 min. RT-PCR was performed according to the manufacturers' instructions using a cDNA cycle kit (Invitrogen) and Advantage polymerase (Clontech). Controls without reverse transcriptase were included in every reaction. The human ILP-2-specific PCR primers (5'-ACTTGAGGGAGCTCTGGTACAAAC-3' and 5'-AGTGACCAGATGTCCACAAGG-3') were used for detection of ILP-2 transcripts. For internal controls, GAPDH-specific primers 5'-ACCACCATGGAGAAGGCTGG-3' and 5'-CTCAGTGTAGCCCAGGATGC-3' were used in parallel reactions that produced a 500-bp product.
Plasmids.
The pEBB expression vector and the pEBG mammalian
glutathione S-transferase (GST) expression vector were
kindly provided by B. Mayer. The pEBB-FLAG-ILP-1 and pEBG-ILP-1
plasmids have been described previously (14). The Apaf-1
expression vector was a gift of R. Armstrong. The P1 artificial
chromosome (PAC) genomic clone of ILP-1 was a gift of the Sanger Centre
(library RPCI6, clone dA30A23). The Bax expression vector was kindly
provided by S. Korsmeyer. The Fas expression vector was a kind gift of R. Siegel. Expression vectors encoding wild-type and dominant-negative caspase 9 (20, 25) were kindly provided by C. Zacharchuk. Site-directed mutagenesis (QuikChange; Stratagene, La Jolla, Calif.) was performed on the caspase 9 plasmid to generate two mutations: Asp-315 to an Ala codon and Asp-315 to the TGA stop codon. The pEBG-ILP-1 (
2BIR) vector encodes residues 262 to 497 of ILP-1.
Southern and Northern blot analyses. BAC and PAC DNA (5 ng) and genomic DNA (10 µg) were digested overnight with EcoRI (New England Biolabs, Beverly, Mass.). For Southern blot analysis, the restriction fragments were separated by 1% agarose gel electrophoresis at 40 V, transferred to a Hybond-N+ nylon membrane (Amersham Pharmacia), and immobilized by UV cross-linking. The DNA probe was obtained by isolating a fragment of human ILP-2 from a cDNA expression vector using the restriction enzymes BamHI and HindIII. 32P-labeling was performed as described (19) using Klenow enzyme (New England Biolabs). The DNA probe was separated from unincorporated nucleotides on a G-25 spin column (Amersham Pharmacia). Hybridization and washing were performed with Hybrisol II (Intergen, Gaithersburg, Md.) according to the manufacturer's instructions.
Northern blot hybridization was performed similarly using Human Multiple Tissue Northern blots (Clontech), and a 32P-labeled DNA fragment from ILP-2 spanning the entire open reading frame was prepared exactly as described above. Blots were washed at high stringency following the manufacturer's instructions.Cells, transfections, and viability assays. Human embryonic kidney 293 cells were maintained in Dulbecco's modified Eagle's medium with 10% fetal bovine serum and 2 mM glutamine at 37°C in 5% CO2. Six-well plates were seeded with 2 × 105 cells per well in 2 ml of medium. Cells were transfected the following day by the calcium phosphate procedure as described previously (13). For viability experiments, 293 cells were transfected with 0.5 µg of green fluorescent protein (GFP) (pEGFP-N1; Clontech) together with plasmids encoding Bax, Fas, caspase 9, and Apaf-1 as indicated in the text. Cells were stained with 4',6'-diamidino-2-phenylindole (DAPI; Molecular Probes, Eugene, Oreg.) 24 h after transfection and were examined for apoptosis by fluorescence microscopy as previously described (16).
Protein expression and purification.
pGEX-CD1
(29), pGEX-ILP-1, or pGEX-ILP-2 was expressed in
BL-21(DE3) E. coli cells (Stratagene). Bacterial cultures
(500 ml) were grown overnight at 37°C before induction with 1 mM
isopropyl-1-
-D-thiogalactopyranoside (IPTG) at 30°C
for 3 h and then were purified by standard glutathione-Sepharose affinity purification methods. Briefly, bacteria were lysed in 50 ml of
GST lysis buffer (50 mM Tris, pH 7.5, 1 mM EDTA, 100 mM NaCl, 1%
Triton X-100), sonicated five times for 10 s, and centrifuged for 15 min at 10,000 × g at 4°C. The supernatant was applied to a column containing 1 ml of a 50% slurry of
glutathione-Sepharose (Amersham Pharmacia) and washed with 10 ml of GST
lysis buffer. Protein fractions were eluted with elution buffer (10 mM
glutathione and 100 mM Tris, pH 7.5) and dialyzed against
phosphate-buffered saline. Expression of proteins was analyzed by
gradient sodium dodecyl sulfate (SDS)-4 to 12% polyacrylamide gel
electrophoresis (PAGE; Invitrogen) followed by Coomassie blue staining,
and protein concentrations were measured by the method described by
Bradford (3) using a commercial kit (Bio-Rad, Hercules,
Calif.).
Extract preparation and caspase assays. Cytosolic extracts from 293 cells were prepared essentially as previously described (17). Cells were washed and the pellet was resuspended in 10 volumes of extract preparation buffer (50 mM PIPES [piperazine-N,N'-bis(2-ethanesulfonic acid)] at pH 7.0, 50 mM KCl, 5 mM EGTA, 2mM MgCl2, 1 mM dithiothreitol [DTT]) supplemented with 10 µg of cytochalasin B/ml and protease inhibitor cocktail (0.1 mM phenylmethylsulfonyl fluoride and 2 µg [each] of chymostatin, pepstatin, leupeptin, and antipain/ml; Sigma, St. Louis, Mo.). Cells were immediately pelleted and lysed by three cycles of freezing and thawing. The lysate was centrifuged at 100,000 × g for 1 h to produce the cell extract. The final concentration of extract was adjusted to 15 µg/µl in modified extract preparation buffer containing 10 mM KCl.
Recombinant GST, GST-ILP-1 or GST-ILP-2 (100 ng each) was added to 293 cytosolic extract (150 µg) either before or after extract activation with ATP, in a total volume of 20 µl, as detailed in the text. Following incubation for the indicated periods of time at 37°C, 2 µl of the reaction mixture was incubated with 200 µl of assay buffer (50 mM PIPES at pH 7.0, 0.1 mM EDTA, 10% glycerol, 1 mM DTT) containing 20 µM Ac-DEVD-AFC (N-acetyl-Asp-Glu-Val-Asp-AFC [7-amino-4-trifluoromethylcoumarin]) or 50 µM Ac-LEHD-AFC (N-acetyl-Leu-Glu-His-Asp-AFC) (Biomol Research Laboratories, Plymouth Meeting, Pa.) for 10 min. The release of free AFC was measured with a Cytofluor 4000 fluorescence plate reader (Perseptive Biosystems, Framingham, Mass.).Coprecipitation and immunoblot analysis. Human embryonic kidney 293 cells were transiently transfected in six-well plates with the indicated plasmids. After 15 h, cells were washed once with phosphate-buffered saline and lysed for 15 min in 0.3 ml of 1% Triton X-100 buffer containing 25 mM HEPES (pH 7.9), 100 mM NaCl, 1 mM EDTA, 10% glycerol, 1 mM phenylmethyl sulfonyl fluoride 1 mM DTT, and 1 protease inhibitor cocktail tablet (Roche Diagnostics, Indianapolis, Ind.) per 10 ml of lysis buffer. For coprecipitation, 150-µl aliquots of lysates were incubated with 20 µl of glutathione-Sepharose beads (Amersham Pharmacia) at 4°C for 1 h. Beads were washed four times with 1 ml of lysis buffer. The bead-associated proteins along with aliquots of total lysates were resolved by a 4 to 12% gradient SDS-PAGE (Invitrogen) and transferred to nitrocellulose membranes (Invitrogen). After blocking the membranes in 5% dry milk in Tris-buffered saline with 0.2% Tween, the membranes were incubated with either anti-GST antibody (Santa Cruz Laboratories, Santa Cruz, Calif.), anti-Apaf-1 antibody (a kind gift of Y. Lazebnik, Cold Spring Harbor, N.Y.), or anti-caspase 9 antibodies (Pharmingen, San Diego, Calif. or Upstate Biotechnology, Lake Placid, N.Y.) as indicated in the figure legends and were visualized by enhanced chemiluminescence (ECL; Amersham Pharmacia).
Gel filtration chromatography. Chromatography was carried out using an ÄKTA fast-performance liquid chromatograph (FPLC) (Amersham Pharmacia) at 4°C. Samples (0.2 ml, 1.5 mg of protein) were applied to an HR 10/30 Superose 6 column (Amersham Pharmacia) equilibrated in 25 mM HEPES (pH 7.0), 10 mM KCl, 50 mM NaCl, 5 mM EGTA, 1 mM MgCl2, 5% sucrose, 0.1% CHAPS {3-[(3-cholamidopropyl)-dimethylammonio]-1-propane-sulfonate}, and 1 mM DTT. Proteins were eluted at 0.3 ml/min, and 0.5-ml fractions were collected. An aliquot of each fraction was immediately assayed for caspase activity or snap frozen for later analysis by immunoblotting. The Superose 6 column had previously been calibrated using blue dextran, thyroglobulin, ferritin, catalase, bovine serum albumin, and ovalbumin as standards (Amersham Pharmacia).
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Cloning and genetic analysis of human ILP-2.
To search for
human homologs of ILP-1, combinations of PCR primers which
spanned the entire open reading frame of human ILP were
designed. Human genomic DNA and cDNA prepared from peripheral blood
leukocyte RNA were used as templates for PCR. Sequencing of the PCR
products revealed novel ILP-related sequences in addition to
that of ILP-1. The full-length genomic clone of one of these sequences was isolated and termed ILP-2. The predicted open
reading frame of ILP-2 lacks the first two BIR domains and is comprised of a single amino-terminal BIR followed by a spacer domain and a
carboxy-terminal RING domain (Fig. 1A).
The coding sequence of ILP-2 is very similar to that
of ILP-1, with 80% identity (95% homology) at the amino acid level to
the corresponding region of ILP-1 (Fig. 1B).
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ILP-2 is conserved in primates. To determine whether ILP-2 has been conserved throughout evolution, the ILP-2 genes of several primates were characterized. The open reading frame of ILP-2 in both chimpanzee and gorilla was conserved (Fig. 1B), suggesting that the selective pressure on ILP-2 has been retained. Interestingly, no ILP-2 sequences could be isolated from any species other than primates. ILP-2 was detected only in humans and great apes (chimpanzee and gorilla; Fig. 1B) and could not be isolated from genomic DNA prepared from Old World monkeys (baboon, cynomolgus monkey, and rhesus monkey). This observation was examined further by performing Southern analysis of genomic DNA from primates as well as mouse by using a radiolabeled probe prepared from ILP-2 but which identifies both ILP-1 and ILP-2. The human genomic clones of ILP-1 and ILP-2 were included in order to identify bands seen in primate samples. Analysis revealed a similar pattern of bands present in genomic DNA from the Old World monkeys (Fig. 1C). Consistent with results obtained by PCR experiments, this pattern is more complex in genomic DNA from the great apes, suggesting the presence of additional ILP-1-related genes that are not present in Old World monkeys. Bands in genomic DNA from great apes, but not that from Old World monkeys, migrated closely with the two major bands representing the human genomic clone of ILP-2, suggesting that ILP-2 emerged after their divergence. The pattern of bands seen in genomic DNA from primates was not present in mouse genomic DNA. These data suggest that the retrotransposition event which gave rise to ILP-2 occurred during the evolution of great apes.
Expression of ILP-2.
The expression pattern of
ILP-2 was examined by Northern analysis of both fetal and
adult human tissues, as well as of a panel of transformed cell types.
In primary cells, a ~2-kb transcript in human testis was detected
with a radiolabeled ILP-2 fragment (Fig.
2A), indicating a testis-restricted
pattern of expression. In the Northern blot panel of selected tumor
lines (Fig. 2A), a band of the same size was also detected in the Raji
B-lymphoblastoid cell line, suggesting that deregulated expression of
ILP-2 might occur in a subset of transformed cells.
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ILP-2 inhibits apoptosis induced by Bax or coexpression of caspase
9 and Apaf-1.
Since ILP-2 is highly homologous to ILP-1, the two
proteins were compared for their ability to regulate apoptosis.
Expression vectors encoding several proapoptotic stimuli were
coexpressed in 293 cells with vectors encoding ILP-1, ILP-2, or control
vectors (Fig. 3). Apoptosis induced by
ectopic expression of Bax was profoundly inhibited by ILP-2 at levels
which were essentially identical to those observed with ILP-1 (Fig.
3A). However, expression of ILP-2 had no inhibitory effect on apoptosis
induced by Fas (Fig. 3B). Induction of apoptosis by Bax is thought to
occur through the insertion of Bax into the mitochondrial outer
membrane. This event is then followed by perturbation of the integrity
of the mitochondrial membrane, the release of cytochrome c,
and the activation of a complex which contains the apoptosis activating
factor Apaf-1 and caspase 9 (4, 31). In contrast, the
induction of apoptosis by overexpression of Fas in 293 cells occurs
through a caspase 9-independent pathway (9), since it is
not inhibited by dominant-negative caspase 9 (Fig. 3B). These data
suggested that ILP-2 might inhibit Bax-induced death by suppression of
caspase 9 activity. Therefore, the ability of ILP-2 to inhibit caspase
9-induced death was assessed. Consistent with previous reports
(7), ectopic expression of caspase 9 alone did not induce
apoptosis of 293 cells, although coexpression of caspase 9 with Apaf-1
strongly induced the apoptosis of transfected cells (Fig. 3C). ILP-2
potently inhibited cell death induced by caspase 9 plus Apaf-1 (Fig.
3C), suggesting that ILP-2 suppresses Bax-induced apoptosis
through inhibition of caspase 9-Apaf-1 activity.
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ILP-2 binds caspase 9.
To examine whether ILP-2 interacts with
caspase 9 in cells, mammalian expression vectors encoding ILP-1 or
ILP-2 fused to GST were cotransfected with a caspase 9 expression
vector into 293 cells. Cell lysates were precipitated with
glutathione-Sepharose beads and analyzed with an anti-caspase 9 antibody. A processed form of caspase 9 was found to coprecipitate with
ILP-2 but not with ILP-1 (Fig. 5A)
with an approximate molecular mass of 35 kDa.
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Cleaved ILP-1 interacts with processed caspase 9 in cells.
Recent in vitro studies suggest that ILP-1 is cleaved by caspase 9 at
Asp-242 (9). This cleavage event generates a form of ILP-1
which lacks its first two BIR domains (2BIR) and is therefore
analogous to ILP-2. To determine whether cleaved ILP-1 interacts with
caspase 9 in cells, a GST-tagged deletion construct of ILP-1 was
generated (2BIR) which consists of the third BIR, spacer, and RING
domains of ILP-1. Expression vectors encoding ILP-1, ILP-1 (2BIR),
or ILP-2 were cotransfected with a caspase 9 expression vector into 293 cells. Cell lysates were precipitated with glutathione-Sepharose beads
and analyzed with a caspase 9 antibody. Processed caspase 9 was found
to coprecipitate with ILP-1 (2BIR) as well as ILP-2 but not with
full-length ILP-1 (Fig. 5C). These studies suggest that cleaved but not
full-length ILP-1 interacts with processed caspase 9 in cells.
ILP-2 inhibits processing of caspase 9 in cell-free system.
The data shown in Fig. 4 and 5 suggest that the ability of ILP-2 to
impede the activation of caspase 3 is indirect, perhaps functioning at
the level of caspase 9. While the coprecipitation studies shown in Fig.
5 revealed that ILP-2 can coassociate with processed caspase 9, the
possibility remained that ILP-2 might also function to impair either
holoenzyme formation or the processing of full-length caspase 9. To
test this possibility, cytosolic extracts from 293 cells were
preincubated with recombinant, purified GST-ILP-1, GST-ILP-2, or
control GST proteins prior to the addition of ATP and were subsequently
resolved by gel filtration chromatography using a Superose 6 column.
Fractions eluted from the column were evaluated for DEVDase activity,
which measures downstream caspase 3 activity, and in parallel, aliquots
were immunoblotted and probed with antibodies to Apaf-1, caspase 9, and
caspase 3 (Fig. 6). No
significant DEVDase activity was detected in higher-molecular-mass fractions corresponding to the predicted molecular mass (~700 to
1,400 kDa) of the apoptosome (5). However, oligomeric
Apaf-1, necessary for the formation of the holoenzymatic complex, was detected and was slightly inhibited in extracts incubated with GST-ILP-1 or GST-ILP-2 (Fig. 6A). In GST-incubated extracts,
processed caspase 9 was faintly detected in a high-molecular-weight
fraction (fraction 14) which presumably corresponds to the
Apaf-1:caspase 9 holoenzyme, while full-length caspase 9 was detected
in the equivalent fraction in ILP-1-incubated extracts. Caspase 9 was not detected in the corresponding fraction in ILP-2-incubated extracts
(Fig. 6B). Caspases 3 and 9 could readily be detected in fractions
which, by comparison with molecular mass standards, would be predicted
to be uncomplexed with Apaf-1 (Fig. 6B and C). The fractions containing
these free caspases corresponded exactly to the fractions with the peak
enzymatic activity, as measured by the DEVDase assay (Fig. 6D). As
expected, the DEVDase activities of corresponding fractions from
extracts preincubated with either GST-ILP-1 or GST-ILP-2 were greatly
reduced. These fractions from GST-ILP-1 and GST-ILP-2-incubated
extracts were found to contain caspase 3 predominantly in its
full-length form. Also as predicted, the majority of caspase 3 in the
GST-incubated extracts was found to be in the active p19/17 form (Fig.
6C). In the case of ILP-2, this is presumably due to the suppression of
caspase 9 activity, thereby impeding the ability of caspase 9 to cleave
full-length caspase 9. Surprisingly, however, immunoblot analysis of
fractions from the ILP-2-incubated extracts revealed that a large
proportion of caspase 9 was also found in its full-length form.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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ILP-1 is a potent inhibitor of apoptosis which exerts its effects, at least in part, through the direct binding and inhibition of specific caspases. For example, ILP-1 can bind active caspase 3 with nanomolar affinity and is a powerful inhibitor of its enzymatic activity (10). Interestingly, ILP-1 is able to bind only the active, heterotetrameric form of caspase 3 and does not associate with its inactive precursor (12). An important consequence of the high affinity of ILP-1 for caspase 3 is that ILP-1 is capable of suppressing a wide variety of apoptotic signals, including signaling through death receptors as well as DNA-damaging agents, such as irradiation and chemotoxic drugs. While these stimuli have been shown to initiate distinct apoptotic pathways involving the sequential activation of different caspases, they are thought to converge at the downstream effector caspases, particularly caspase 3, and this is thought to account for the wide-ranging protective effects of ILP-1 (10).
In this report, we describe the cloning and characterization of a novel IAP gene, ILP-2. Examination of the genomic structure of the ILP-2 locus revealed the absence of introns as well as an autosomal location. Most gene families are thought to have arisen during evolution by duplication of an ancestral gene, often followed by sequence divergence and ultimately to distinct biological functions. In this case, the general intron-exon structure of the gene family should be conserved. The lack of introns in ILP-2 strongly suggests that it was generated by a retroprocessing event (45), that is, by the integration into the genome of a fully spliced ILP-1 cDNA generated by reverse transcription. In some cases, retrotransposons have been found to encode functional proteins (28). One example, which has striking similarity to the situation of ILP-1 and ILP-2, is that of the X-linked gene XAP-5 and its autosomal retrotransposon-derived counterpart, X5L (36). Like ILP-2, X5L has an intronless open reading frame which is highly conserved, encodes a functional protein, and is preferentially expressed in testis. While the functions of XAP-5 and X5L are unknown, it has been proposed that the testis-specific expression of X5L serves to compensate for the absence of XAP-5 in the Y-containing gamete during spermatogenesis (36). In this regard, ILP-2 is highly analogous to X5L, since it is autosomal (Mir and Duckett, unpublished) and has a conserved open reading frame and in primary tissues is expressed exclusively in the testis (Fig. 2). However, the retroposition event which resulted in ILP-2 most likely occurred relatively recently in primate evolution, while the X5L retroposition is thought to have taken place before the radiation of eutherian mammals (36, 39). The human ILP-1 and ILP-2 DNA sequences are significantly closer to each other than they are to murine Xiap. This, combined with Southern blot analysis data (Fig. 1C), suggests that a murine counterpart of ILP-2 might not exist, and therefore a direct test of the biological significance of ILP-2 by gene disruption cannot be performed. However, since ILP-1 can be proteolytically processed to a form which closely resembles ILP-2, it will be of particular interest to examine the tissue expression and functional properties of processed ILP-1.
Analysis of the ILP-2 open reading frame reveals a close similarity to ILP-1. The most significant difference between ILP-2 and ILP-1 is that ILP-2 lacks the two amino-terminal BIR domains which are present in ILP-1. Given the high primary sequence homology between the two proteins, it is more likely that this major structural difference, rather than the small degree of sequence variation, is the main determinant of the differences in biological activity between the two proteins. In support of this hypothesis, two recent reports have described the existence of a proteolytically processed form of ILP-1 (9, 23) which shares many structural and functional properties with ILP-2.
Despite its similarity to ILP-1, ILP-2 was found to function in a far more restricted manner. Overexpression of ILP-2 failed to inhibit apoptosis induced by signals through death domain-containing receptors but potently suppressed apoptosis induced by Bax or by ectopic expression of Apaf-1 and caspase 9. In addition, cytosolic extracts preincubated with either recombinant ILP-1 or ILP-2 before activation with ATP were found to suppress caspase activity. However, ILP-2 was unable to inhibit caspase activity when added after the extracts had been activated with ATP, while ILP-1 retained its inhibitory function under these conditions.
In many respects, the properties of ILP-2 appear to be very similar to a recently described cleaved form of ILP-1 which lacks the first two amino-terminal BIR domains (9, 23). Both proteins were capable of suppressing apoptosis induced by Bax or by Apaf-1 and caspase 9, and neither ILP-2 nor the equivalent version of ILP-1 was able to inhibit Fas-mediated apoptosis. However, in transfected cells, processed caspase 9, but not full-length caspase 9, was found to coprecipitate with ILP-2 or its ILP-1 equivalent, and in contrast to a previous report (11), caspase 9 did not coprecipitate with full-length ILP-1. A recent study by Datta et al. (8) reported that ILP-1/XIAP could coprecipitate from cells with processed caspase 9, but not full-length caspase 9, and this would appear to be consistent with our data. One possibility is that different forms of ILP-1 and caspase 9 may exist in distinct cellular compartments. For example, processed caspase 9 of the form observed in Fig. 6 is thought to be generated in the Apaf-1-containing apoptosome (1, 31, 34), and so it is formally possible that, in a cell, ILP-1 and ILP-2 might specifically be targeted to this enzyme complex.
Of particular interest was the observation that preincubation of extracts with GST-ILP-2 resulted in fractions containing a large proportion of full-length caspase 9 (Fig. 6B), while in cotransfection studies, processed caspase 9, but not full-length caspase 9, coprecipitated with ILP-2 (Fig. 5A). While we currently have no definitive explanation for these apparently contradictory findings, one possibility that would reconcile the data would be if Apaf-1, following caspase 9 recruitment, processing, and release, could recruit further full-length caspase 9 molecules. If ILP-2 were targeted to the Apaf-1-containing apoptosome, its binding to processed caspase 9 might affect the release of processed caspase 9 from Apaf-1 and the subsequent recruitment of other caspase 9 molecules. Thus, the observed result would be an abundance of full-length caspase 9, even though ILP-2 was functioning specifically on processed caspase 9, and this is consistent with our findings. While this is an attractive possibility, other models can be proposed, and further studies will be required to determine the precise mode of ILP-2 action.
These studies reinforce the notion that IAP proteins can function to suppress apoptosis at multiple points in the cell death pathway. The high degree of specificity of ILP-2 may be very useful in better understanding the apoptotic machinery, and this may also be important as other Apaf-1-independent pathways are identified. Finally, ILP-2 or the equivalent ILP-1 fragment may represent a novel therapeutic target, since disruption of these proteins from the holoenzyme would be predicted to specifically sensitize tumor cells to chemotherapy-induced apoptosis.
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ACKNOWLEDGMENTS |
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Bettina W. M. Richter and Samy S. Mir contributed equally to this study.
We thank R. Armstrong, B. Mayer, S. Korsmeyer, R. Siegel, and C. Zacharchuk for plasmids, Y. Lazebnik for Apaf-1 antibody, the Sanger Centre for the PAC genomic clone of ILP-1, and J. Ashwell for helpful advice and critical reading of the manuscript. S.S.M. is an HHMI-NIH Research Scholar.
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FOOTNOTES |
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* Corresponding author. Mailing address: Metabolism Branch, Division of Clinical Sciences, National Cancer Institute, National Institutes of Health, 10 Center Dr., Room 6B-05, Bethesda, MD 20892-1578. Phone: (301) 594-1127. Fax: (301) 480-9195. E-mail: duckettc{at}helix.nih.gov.
This paper is dedicated to the memory of Lois K. Miller. This is
manuscript no. 45 of the Genoma 2000/ITBA Project funded by Cariplo.
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REFERENCES |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Molecular and Cellular Biology, July 2001, p. 4292-4301, Vol. 21, No. 13
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.13.4292-4301.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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