From the Department of Biochemistry, The Cancer
Institute, Tokyo, Japanese Foundation for Cancer Research and Research
for the Future Program, Japan Society for the Promotion of Science,
1-37-1 Kami-Ikebukuro, Toshima-ku, Tokyo 170-8455, Japan and the
§ Third Department of Internal Medicine, Yamaguchi
University School of Medicine, 1144 Kogushi, Ube,
Yamaguchi 755-8505,Japan
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ABSTRACT |
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Decapentaplegic (Dpp) is a Drosophila
member of bone morphogenetic proteins, which belong to the transforming
growth factor- superfamily. Members of this family regulate a
variety of biological processes such as cell proliferation,
morphogenesis, immune response, and apoptosis. Dpp plays a critical
role in many aspects of Drosophila development. Members of
the transforming growth factor-
superfamily bind to two different
types of serine/threonine kinase receptors, termed type I and type II.
Type I receptors act as downstream components of type II receptors in
the receptor complexes. Therefore, intracellular proteins that interact
with the type I receptors are likely to play important roles in
signaling. Several proteins have been identified through
protein-protein interaction screenings. We identified
Drosophila inhibitor of apoptosis (DIAP) 1 as an interacting protein of a Dpp type I receptor, Thick veins (Tkv). DIAP1
associates with Tkv in vivo. The binding region in DIAP1 is
mapped to its C-terminal RING finger region. DIAP2, another Drosophila member of the inhibitor of apoptosis protein
family, also interacts with Tkv in vivo. These data suggest
that DIAP1 and DIAP2 may be involved, possibly as negative regulators,
in the Dpp signaling pathway, which leads to cell apoptosis.
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INTRODUCTION |
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Transforming growth factor-s
(TGF-
s),1 bone
morphogenetic proteins (BMPs), and activins belong to a large family of
cytokines that regulate a variety of biological processes such as cell
proliferation, morphogenesis, immune response, and apoptosis (1, 2).
Ligands of this superfamily have been identified in organisms from
invertebrates to vertebrates. In Drosophila, three factors,
Decapentaplegic (Dpp), 60A, and Screw, have been isolated, and all of
them belong to the BMP subfamily (3, 4). Dpp plays an important role during Drosophila development. Dpp acts as a morphogen to
establish the patterning of the dorsal ectoderm. Dpp also regulates gut morphogenesis and growth of imaginal discs such as wings and eyes.
Dpp has been an ideal molecule for studying the signaling
mechanism of the TGF- superfamily, because a wide range of genetic approaches are applicable in Drosophila. Mothers against dpp
(Mad) was identified as a genetic enhancer of the dpp
phenotypes (5). Maternally, Mad mutations exacerbated the
embryonal leathality caused by dpp mutations. Mad
mutations also enhanced various dpp phenotypes associated
with appendages such as wings, eyes, and claws in zygotes. Sma proteins
in Caenorhabditis elegans are structurally similar to Mad
(6). An increasing number of vertebrate homologs of Mad and Sma have
been identified and are now generically denoted Smad. Eight different
Smads (Smad1-Smad8) have been identified in mammals, and they are
biochemically demonstrated to mediate signals of the TGF-
superfamily proteins (2, 4, 7).
Signals of TGF- are transduced into the cell by two types of
serine/threonine kinase receptors (1, 2). The type II TGF-
receptor
(T
R-II) is a constitutively active kinase. Upon ligand binding,
T
R-II recruits and phosphorylates the type I TGF-
receptor
(T
R-I). Phosphorylation of T
R-I occurs mainly at the GS domain, a
glycine-serine-rich region highly conserved among the type I receptors.
Mutation of threonine 204 in the GS domain to aspartic acid resulted in
constitutive activation of T
R-I (8). This demonstrates that T
R-I
is the effector kinase that phosphorylates cytoplasmic substrates, now
revealed as Smad2 and Smad3 (2). Upon phosphorylation by T
R-I, Smad2
and Smad3 form a complex with Smad4 and translocate into the nucleus
where they activate transcription of the target genes.
Yeast two-hybrid screenings using the cytoplasmic region of TR-I or
T
R-II as a bait have led to the identification of various proteins
such as FKBP12 (9-13), farnesyl-protein transferase-
(14-16),
TRIP-1 (17), and apolipoprotein J (18). Although farnesyl transferase-
is phosphorylated both in vitro and in
vivo by T
R-I, little is known about its role in TGF-
signaling. FKBP12 binds to the juxtamembrane region of T
R-I. FKBP12
has been shown to prevent spontaneous activation of T
R-I by T
R-II
(13). TRIP-1 and apolipoprotein J interact with T
R-II, but their
functions in signal transduction of TGF-
remain to be
determined.
We employed the two-hybrid system to identify proteins that interact with the cytoplasmic region of Thick veins (Tkv), one of the type I receptors for Dpp (4). One positive clone encoded Drosophila inhibitor of apoptosis 1 (DIAP1), which is structurally similar to baculovirus inhibitor of apoptosis protein (IAP) (19). Moreover, we show that Tkv interacts with DIAP1 in vivo. DIAP2, another Drosophila member of the IAP family (19), also interacts with Tkv.
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EXPERIMENTAL PROCEDURES |
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Plasmid Construction--
The bait plasmid, pEG-Tkv, encoding
the fusion protein of the LexA DNA-binding domain and the cytoplasmic
region of Tkv was constructed as follows. The cytoplasmic region of Tkv
was amplified by polymerase chain reaction (PCR) from the full-length
clone, Brk25D2 (20), and inserted between the EcoRI and
XhoI sites of pEG202 (21). The prey plasmid of Tkv, pJG-Tkv,
was constructed by inserting the EcoRI-XhoI
fragment into pJG4-5 (21). Tkv mutants were constructed by
site-directed mutagenesis using the Chameleon mutagenesis kit
(Stratagene). Tkv (JM) lacks the juxtamembrane region (amino acids
205-254) of the wild type Tkv. Tkv (Q253D) and Tkv (K281R) have
aspartic acid instead of glutamine 253 and arginine instead of lysine
281, respectively. pcDNA3-HA was made by inserting an annealed
oligonucleotide between the XhoI and XbaI sites
of pcDNA3 (Invitrogen). pcDNA3-FLAG was described (11). The
whole coding region of Tkv was amplified by PCR with an
EcoRI and an XhoI site added before the starting
codon and in place of the stop codon, respectively, followed by
insertion between the EcoRI and XhoI sites of
pcDNA3-HA. The internal EcoRI site of Tkv was removed by
site-directed mutagenesis. The yeast expression plasmids of DIAP1 were
made by subcloning the EcoRI-XhoI fragment amplified by PCR into pEG202 and pJG4-5. The coding region of DIAP1
without the stop codon was subcloned between the EcoRI and XhoI sites of pcDNA3-FLAG, yielding FLAG-tagged DIAP1.
The DIAP2 plasmids were constructed in a similar manner to DIAP1. The
details of the plasmid construction including the oligonucleotide
sequences are available upon request. All of the PCR products were
sequenced.
Screening and Interaction Assay--
A Drosophila
imaginal disc cDNA expression library (gift of R. Brent) was
screened using the interaction trap (21) exactly as described (14).
Briefly, the yeast strain, EGY48, was transformed with the reporter,
pSH18-34 (21), and pEG-Tkv. The cDNA library was then introduced
into EGY48. The transformants were grown on appropriate selection
medium, and positive clones were selected depending on
-galactosidase activity and leucine prototrophy. Library plasmids
were rescued from EGY48, amplified in bacteria, and sequenced.
Interaction assays using the interaction trap were done as described
before (14).
Cloning of the Full-length DIAP1-- One of the positive clones contained a partial C-terminal region of DIAP1 (see Fig. 1A). PCR was performed under a standard condition to amplify the missing N-terminal region from a Drosophila 4-8-h-old embryo cDNA library in the pNB40 vector (gift of Y. Nishida). The full coding region of DIAP1 was made by ligating the EcoRI-BanII fragment obtained from PCR and the BanII-XhoI fragment obtained from the interaction trap screen.
Protein Interaction in Vivo-- COS-7 cells were maintained in Dulbecco's modified Eagle's medium containing 10% fetal bovine serum, 100 units/ml penicillin, and 4.5 g/liter glucose. Cells were transiently transfected using DMRIE-C (Life Technologies, Inc.) with 10 µg of plasmids. After 2 days, cells were labeled with 22.8 mCi/ml [35S]methionine and cysteine mixture (Amersham Pharmacia Biotech) for 5 h and lysed in 150 mM NaCl, 20 mM Tris-HCl, pH 7.5, and 1% Triton X-100 containing 1.5% of aprotinin. Cleared lysates were divided into two tubes and incubated with anti-FLAG M2 (Eastman Kodak) or anti-HA 12CA5 (Boehringer Mannheim) monoclonal antibodies. Immune complexes were bound to protein G-Sepharose (Amersham Pharmacia Biotech) or protein A-Sepharose (Amersham Pharmacia Biotech). The precipitates were washed and subjected to SDS-polyacrylamide gel electrophoresis (PAGE) (8.5% or 10% gel) and analyzed with Fuji BAS 2000 Bio-Imaging Analyzer (Fuji Photo Film).
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RESULTS |
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To search for proteins that interact with Tkv, we employed the
interaction trap screen developed by Brent and co-workers (21). A
Drosophila imaginal disc cDNA library was screened with
the cytoplasmic region of Tkv as a bait. 160,000 transformants were screened. Finally, four positive clones were isolated. One clone encoded Drosophila FKBP12, a homolog of human FKBP12 that is
known as a binding protein for mammalian type I receptors, including TR-I (9, 11, 13) (data not shown). One of the other clones, termed
PC1, encoded a partial C-terminal region of DIAP1 (Fig. 1A), which is a homolog of
baculovirus IAP (19). The remaining two positive clones were not
analyzed. PCR using a Drosophila 4-8-h-old embryo cDNA
library was performed to obtain the missing N-terminal region.
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We then examined the interaction of the full-length DIAP1 with Tkv
using the interaction trap (Fig. 1B). DIAP1 strongly
interacted with the wild type Tkv, although its interaction was
slightly weaker than that of the partial clone, PC1. Mutants of Tkv
with different signaling activities were also tested for the
interaction with DIAP1. One Tkv mutant replacing glutamine 253 with
aspartic acid (QD), reported to have a constitutively kinase activity
(22), showed strong interaction with DIAP1 as well as with PC1. Another mutant replacing lysine 281 with arginine (KR), which is expected to
lack the kinase activity (8), showed weak interaction with DIAP1 and
PC1. We also tested a deletion mutant lacking the juxtamembrane region
(amino acids 205-254) where probable transphosphorylation sites by the
type II receptor exist (8). The mutant, Tkv (JM), did not interact
with PC1 or DIAP1. Contrary to Tkv, Saxophone (Sax), another Dpp type I
receptor (20, 23-25) or Punt, a type II receptor for Dpp (26-28), did
not interact with PC1 or DIAP1. Thus, DIAP1 specifically interacted
with Tkv in the yeast system.
In Drosophila, two types of IAP are known (19). DIAP2, another Drosophila inhibitor of apoptosis, has three baculovirus IAP repeat (BIR) domains, whereas DIAP1 has two BIR domains (Fig. 1A). We tested whether DIAP2 interacts with Tkv. DIAP2 did not show interaction with the wild type or mutants of Tkv, Sax, or Punt in the yeast system (Fig. 1B). To identify the interacting region of DIAP1 with Tkv, we constructed various truncated forms (TF) of DIAP1 (Fig. 1A). The wild type Tkv showed interaction with TF4 that has only the RING finger domain but not with the other truncated forms (Fig. 1C). Thus, the interacting region in DIAP1 is mapped to the RING finger domain. Sax and Punt did not interact with TF4.
We next examined the interaction between DIAP1 and Tkv in
vivo. DIAP1 was epitope-tagged with FLAG at the C terminus
(DIAP1-FLAG). HA-tagged Tkv and/or DIAP1-FLAG were transiently
expressed in COS-7 cells. Labeled lysates were immunoprecipitated with
anti-HA or anti-FLAG monoclonal antibodies and then subjected to
SDS-PAGE (Fig. 2A). Each
antibody specifically recognized Tkv-HA and DIAP1-FLAG, respectively
(Fig. 2A, fourth and seventh lanes
from the left). Anti-FLAG antibody coprecipitated Tkv only
when DIAP1 was expressed, demonstrating that DIAP1 interacts with Tkv
in vivo (Fig. 2A, ninth lane from the
left). Both constitutively active (QD) and kinase-inactive
(KR) mutants interacted with DIAP1 as efficiently as the wild type Tkv
(Fig. 2A, eleventh and thirteenth
lanes from the left). The reason for the difference
between this result in COS-7 cells and that in the yeast assay (Fig.
1B) is not known, but the difference in mammalian cells and
in yeast was also observed in the interaction of FKBP12 with TR-I
(11).
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We also tested the interaction of DIAP2 with Tkv in vivo. Tkv-HA and/or DIAP2-FLAG were transiently transfected in COS-7 cells (Fig. 2B). Although the interaction of DIAP2 with Tkv was not detected in the yeast assay (Fig. 1B), DIAP2 coprecipitated not only with the wild type Tkv but also with the QD and KR mutants in vivo.
To determine the region of DIAP1 required for the interaction with Tkv in vivo, expression plasmids of the BIR domain (BIR-FLAG) and C-terminal region of DIAP1 (PC1-FLAG) were constructed (Fig. 3A). Tkv-HA was coexpressed with BIR-FLAG or PC1-FLAG (Fig. 3B). Tkv-HA was detected in a stable complex only with PC1-FLAG but not with BIR-FLAG (Fig. 3B, eleventh and thirteenth lanes from the left). These results indicate that the interaction region of DIAP1 is the C terminus, which contains the RING finger domain, consistent with the results in the yeast assay. TF4-FLAG that has only the RING finger domain was tested, but the expression level was too low to detect interaction (data not shown).
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DISCUSSION |
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Members of the TGF- superfamily regulate growth,
differentiation, and apoptosis of various cell types. Recent data have
clearly shown that Smad proteins transduce signals for the TGF-
superfamily proteins; however, it is likely that other signaling
pathways may exist for the TGF-
superfamily. BMPs and TGF-
have
been reported to induce apoptosis both in vitro and in
vivo (29, 30). More recently, caspase family proteases, such as
interleukin-1
converting enzyme (ICE), are involved in the apoptosis
signals for the TGF-
superfamily (30). However, it is not yet known whether Smads are involved in the apoptosis pathway.
DIAP1 is a homolog of the baculovirus IAP that prevents cell apoptosis when virus infects cells. Recently, an increasing number of IAPs have been reported in virus (OpIAP, CpIAP) (31, 32), Drosophila (DIAP1, DIAP2/DIAP/DIHA/dILP) (33-35), mouse (MIHA, mc-IAP-1) (34, 36), and human (XIAP/hILP, MIHB/c-IAP1/hIAP2, MIHC/c-IAP2/hIAP1, neuronal apoptosis inhibitory protein) (33-35). IAPs share conserved regions, i.e. two or three BIR domains at the N-terminal region and one RING finger domain at the C-terminal region, with an exception of neuronal apoptosis inhibitory protein that has three BIR domains but not the RING finger domain. It has been reported that IAPs are able to prevent cell apoptosis induced by ICE (34, 35, 37), although direct interaction of IAPs with ICE has not been shown.
Because IAPs prevent apoptosis of the cells, proteins that interact with IAPs seem to play important roles for cell death signals. Tumor necrosis factor receptor-associated factor 1 and 2 (36), and tumor necrosis factor receptor-1-associated death domain protein, a 34-kDa cytoplasmic protein containing a C-terminal death domain (38) were shown to associate with mammalian IAPs. Drosophila Doom, which induces apoptosis in insect cells, interacts with viral IAPs (39). Reaper is a small polypeptide with 65 amino acids that induces apoptosis in Drosophila. DIAP2 prevents Reaper-induced cell death by binding to it (40). All of the five proteins above bind to IAPs through the BIR domains, whereas Tkv associates with DIAP1 through the RING finger domain.
Mutations of DIAP1 enhanced apoptosis caused by Reaper, whereas overexpression of DIAPs in Drosophila eyes suppressed normally occurring cell death, causing rough eye phenotype (19). Tkv QD mutant induces rough eye (22), suggesting a possible involvement of Tkv in the apoptosis signal pathway. Our results suggest that Tkv may induce apoptosis by suppressing the DIAP1 function. Future studies will be directed to investigate how the interaction between Tkv and DIAP1 is regulated, which molecules are targets of Tkv-DIAP1 pathway, and whether Smad proteins are linked to the signaling activity of DIAP1.
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ACKNOWLEDGEMENTS |
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We thank R. Brent for reagents of the interaction trap and the cDNA library, M. Hoffmann for Tkv and Sax cDNAs, K. Basler for Punt cDNA, Y. Nishida for a Drosophila cDNA library, G. Rubin for DIAP2 cDNA, and Y. Inada for excellent technical assistance.
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FOOTNOTES |
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* This work was supported by grants-in-aid for scientific research from the Ministry of Education, Science and Culture of Japan and special coordination funds for promoting science and technology from the Science and Technology Agency.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
¶ Supported by the Toray Scientific Foundation and Uehara Memorial Foundation.
To whom correspondence should be addressed. Tel.:
81-3-5394-3866; Fax: 81-3-3918-0342; E-mail:
mkawabat-ind{at}umin.u-tokyo.ac.jp.
1
The abbreviations used are: TGF, transforming
growth factor; BMP, bone morphogenetic protein; TR, TGF-
receptor; IAP, inhibitor of apoptosis; DIAP, Drosophila IAP;
BIR, baculovirus IAP repeat; ICE, interleukin-1
converting enzyme;
PCR, polymerase chain reaction; PAGE, polyacrylamide gel
electrophoresis; HA, hemagglutinin.
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REFERENCES |
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