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Molecular and Cellular Biology, May 2000, p. 3015-3026, Vol. 20, No. 9
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
TAK1 Participates in c-Jun N-Terminal Kinase
Signaling during Drosophila Development
Yoshihiro
Takatsu,1,2
Makoto
Nakamura,1,*
Mark
Stapleton,3
Maria C.
Danos,3
Kunihiro
Matsumoto,4
Michael B.
O'Connor,3
Hiroshi
Shibuya,1,5 and
Naoto
Ueno1,6
Division of Morphogenesis, Department of Developmental
Biology, National Institute for Basic Biology,1
and Department of Molecular Biomechanics, School of Life
Science, The Graduate University for Advanced
Studies,6 Okazaki 444-8585, Department of Molecular Biology, Faculty of Pharmaceutical
Science, Hokkaido University, Sapporo 060,2
Department of Molecular Biology, Faculty of Science, Nagoya
University, Nagoya 464-01,4 and
Precursory Research for Embryonic Science and Technology, Japan
Science and Technology Corporation, Kyoto
619-02,5 Japan, and Howard Hughes
Medical Institute, Department of Genetics, Cell Biology and
Development, University of Minnesota, Minneapolis, Minnesota
554553
Received 17 May 1999/Returned for modification 30 June
1999/Accepted 27 January 2000
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ABSTRACT |
Transforming growth factor 
(TGF-)-activated kinase 1 (TAK1)
is a member of the MAPKKK superfamily and has been characterized as a
component of the TGF-/bone morphogenetic protein signaling pathway.
TAK1 function has been extensively studied in cultured cells, but its
in vivo function is not fully understood. In this study, we isolated a
Drosophila homolog of TAK1 (dTAK1)
which contains an extensively conserved NH2-terminal kinase
domain and a partially conserved COOH-terminal domain. To learn about
possible endogenous roles of TAK1 during animal development, we
generated transgenic flies which express dTAK1 or the mouse
TAK1 (mTAK1) gene in the fly visual system.
Ectopic activation of TAK1 signaling leads to a small eye phenotype,
and genetic analysis reveals that this phenotype is a result of
ectopically induced apoptosis. Genetic and biochemical analyses also
indicate that the c-Jun amino-terminal kinase (JNK) signaling pathway
is specifically activated by TAK1 signaling. Expression of a dominant
negative form of dTAK during embryonic development resulted in various
embryonic cuticle defects including dorsal open phenotypes. Our results
strongly suggest that in Drosophila melanogaster, TAK1
functions as a MAPKKK in the JNK signaling pathway and participates in
such diverse roles as control of cell shape and regulation of apoptosis.
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INTRODUCTION |
During the development of
multicellular organisms, cells receive various extracellular stimuli.
These signals are propagated from the cell surface to the nucleus via
specific sets of intracellular signaling molecules. Mitogen-activated
protein kinase (MAPK) is one of the intracellular signaling molecules
commonly activated by various stimuli and plays a crucial role in cell
proliferation, differentiation, and regulation of early development
(41, 53, 65). MAPK is activated by a sequential cascade of
protein kinases; MAPK is activated by dual phosphorylation catalyzed by
MAPK kinase (MAPKK), which is itself phosphorylated and activated by a
MAPKK kinase (MAPKKK) (41, 47). At least three MAPK modules,
the MAPK/extracellular signal-regulated kinase (ERK) pathway, the c-Jun
amino-terminal kinase (JNK)/stress-activated protein kinase (SAPK)
pathway, and the p38 MAPK pathway, participate in distinct (but
sometimes partially overlapping) functions in various biological processes (9, 11, 67).
Transforming growth factor (TGF-)-activated kinase 1 (TAK1) is a
member of the MAPKKK superfamily (71). The function of TAK1
has been extensively studied in transient transfection assays using
cultured cells (44, 52, 54-56, 71). These studies have revealed that TAK1 can function in a signal transduction pathway that
is triggered by the TGF- superfamily of ligands. Stimulation of
cells with TGF- or bone morphogenetic protein 4 (BMP4) activates TAK1 activity in cultured cells and, in the case of TGF-, leads to
induction of plasminogen activator inhibitor 1 (PAI-1), a TGF--responsive gene (71). In
addition, it has been shown that TAK1 has a role in a
TGF--independent signaling pathway. Ceramide is thought to be a
second messenger molecule which has been implicated in a variety of
biological processes (28, 38). Ceramide stimulates the
kinase activity of TAK1, and ceramide-induced JNK/SAPK activation can
be blocked by expression of a dominant negative form of TAK1 (56). In addition, biochemical studies have revealed that
MAPKK4 and MAPKK3/MAPKK6 are substrates of TAK1 (44, 56,
66), indicating that TAK1 can activate the JNK pathway and/or the
p38 MAPK pathway in cultured cells.
Despite these extensive biochemical studies of TAK1 in cultured cells,
the in vivo function of TAK1 is not fully understood. Overexpression of
Xenopus TAK1 (xTAK1) and an upstream activator called TAB1
(TAK1 binding protein 1) can induce ventral mesoderm and inhibit neural
differentiation. Overexpression epistasis experiments using activated
and dominant negative forms of TAK1 and BMP or activin receptors place
the activity of TAK1 downstream of the BMP2/4 receptors. Furthermore,
TAK1 has been shown to act downstream or in parallel to Smad1 and Smad4
(71). In addition to its role in BMP signaling, ectopic
expression of xTAK1 in early Xenopus embryos also induced
apoptosis. This finding suggests that TAK1 may mediate a number of
different processes (54).
To further address the in vivo function of TAK1, we took a transgenic
approach in the Drosophila model system. There are several advantages to using Drosophila melanogaster as a functional
assay system. First, transgenic flies obtained using P-element-mediated germ line transformation (58) can be used for genetic
interaction studies to screen for downstream or upstream signaling
components (6, 63). Second, expression of exogenous genes
can be temporally and spatially controlled using either tissue-specific
promoters or the GAL4 upstream activation sequence (UAS) system
(5, 6, 16, 45, 64). Third, basic MAPK cascades are conserved
between vertebrates and Drosophila. For example, the
Drosophila MAPK/ERK cascade consists of D-raf, Dsor1, and
Rolled, which correspond to Raf, MAPK/ERK kinase (MEK), and ERK,
respectively, in vertebrates (15). The Drosophila
JNK pathway consists of Basket (Bsk) and Hemipterous (Hep),
corresponding to JNK and MKK7, respectively, in vertebrates (21,
26, 35, 49, 51, 57). In addition, two Drosophila p38
(D-p38) homologs and a Drosophila MKK3 have recently been
cloned (1, 25, 26, 61).
In this report, we describe the effects of overexpressing mouse TAK1
(mTAK1) and a newly discovered Drosophila homolog (dTAK1) in
developing eyes and embryos. The results indicate that TAK1 can
specifically activate the JNK pathway in vivo and mediate both cell
shape and apoptotic responses in Drosophila.
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MATERIALS AND METHODS |
Identification of a Drosophila TAK1-like
sequence.
A 1.9-kb SalI-SpeI fragment
containing most of the mTAK1 open reading frame (71) was
random prime labeled with 32P and used to probe a
Drosophila genomic library (Stratagene) under low-stringency
conditions (46). Several positive plaques were picked and
purified. A 2.0-kb genomic SalI/EcoRI fragment which showed the strongest hybridization to mTAK1 was subcloned into
pBluescript KS+ and partially sequenced. This sequence
confirmed that the 2.0-kb fragment contained an open reading frame with
similarity to mTAK1. The 2.0-kb genomic fragment was labeled and used
to probe a directional Drosophila lambda GT22a ovarian cDNA
library (59). Positive plaques were purified and grown up as
phage, and DNA inserts were excised as SalI/NotI
fragments. Two cDNAs of 2.2 and 3.4 kb were subcloned into pBluescript
KS+. The 3.4-kb subcloned fragment was sequenced by primer
walking using a U.S. Biochemicals cycle sequencing kit. A search of the Drosophila expressed sequence tag (EST) database identified
three dTAK1 EST clones, GM05307, GM05309, and GM09711 (Berkeley
Drosophila Genome Project).
Plasmid construction and generation of transgenic flies.
Ectopic expression of the mTAK1 and human TAB1
(hTAB1) constructs were achieved using GAL4 /UAS system
(6) and an eye-specific expression vector, pGMR
(31). The full-length mTAK1 cDNA was cloned as a
EcoRI-XhoI fragment from pEF-mTAK1
(71) into EcoRI-XhoI-digested pUAST
(6) and as an EcoRI-KpnI fragment into
EcoRI-KpnI-digested pGMR (31). The
mTAK1
N cDNA, which encodes an activated form of mTAK1, a
truncation lacking the NH2-terminal 22 amino acids, was
cloned as an EcoRI-XbaI fragment from
pEF-mTAK1N (71) into EcoRI-XbaI-digested pUAST and as an
EcoRI-synthesized blunt end of a XbaI cleavage
site fragment into EcoRI-StuI-digested pGMR. The
mTAK1-K63W cDNA, which encodes a dominant negative form of mTAK1 (54, 71) in which lysine 63 was replaced by
tryptophan, was cloned as an EcoRI-DraI fragment
from pBS-mTAK1-K63W (71) into
EcoRI-StuI-digested pGMR. The hTAB1
cDNA was cloned as an EcoRI-SmaI fragment from
pBS-hTAB1 (55) into
EcoRI-HpaI-digested pGMR. dTAK1 was
also subcloned into pUAST. The full-length dTAK1 cDNA was cloned as an
EcoRI-NotI fragment from pBS-dTAK1
into EcoRI-NotI-digested pUAST. The
dTAK1-K46R cDNA, which encodes a dominant negative form of
dTAK1 in which lysine 46 was replaced by arginine, was cloned as an
EcoRI-NotI fragment from
pBS-dTAK1-K46R into
EcoRI-NotI-digested pUAST. Flies bearing
transgenes were generated by P-element-mediated germ line
transformation (58). At least five independent transformant
lines were obtained for each transgenic construct. Two copies of the
transgenes (pGMR-mTAK1-K63W and UAS-dTAK1-K46R)
were required to reveal the dominant negative phenotype. Most of the
flies expressing dTAK1, GMR-GAL4;
UAS-dTAK1 died at early pupal stages at 25°C, presumably
due to leaky GAL4 expression. To circumvent the lethality,
we cultured these flies at 18°C.
Fly strains.
Drosophila cultures and crosses were
carried out by standard procedures at 25°C. To test for modification
of the TAK1 phenotype, each mutant was crossed with three different
pGMR-mTAK1N lines which show similar but different
extents of the small eye phenotypes. Interaction with the TAK1
phenotype was scored as positive only if a similar effect was observed
with all three pGMR-mTAK1N lines. The following mutant
strains were used for the genetic interaction assay:
tldE4, tld15,
tldB4, dppd6,
dppd12, scwE2,
Mad12, Med4,
tkv5, tkv7,
tkv8, sax1,
put135, put10460,
shn1, shn04738,
omb3198, N55e11,
DlRF, argos257,
spi1, sev14,
EgfrE3, flbf6,
Sos34Ea-7, SosJC2,
Gap1B2, Ras1e2F,
phl1, Dsor1Su1,
Dsor1r2, Dsor1LH110,
rlsem, hep1,
hepr75, bsk1,
bsk2, and flp147E strains. We also
tested three transgenic strains, pGMR-p35,
pGMR-DIAP1, and pGMR-DIAP2 strains (30,
31). Df(3L)H99 was described previously
(23). We also preformed the genetic interaction assay using
GMR-GAL4/UAS-dTAK1 and obtained results similar to
that seen for pGMR-mTAK1N lines (only the data for GMR-GAL4/UAS-dTAK1 crosses are shown in the figures).
Targeted expression of UAS-driven transgenes (6) was induced
using the GAL4 lines Dll-GAL4,
elav-GAL4, hs-GAL4, en-GAL4,
GMR-GAL4, and pnr-Gal4. hepr75 is a
lethal allele of the hep mutants; however, some escapers of
the hemizygous males survive during the pupal stage. The pupal eyes of
the hepr75 males were subjected to cobalt
sulfide staining to detect the loss-of-JNK signaling phenotype.
Histology.
Flies were prepared for scanning electron
micrographs as described by Kimmel et al. (36). Adult eyes
were prepared for tangential histological sections. Adult heads were
fixed at 4°C overnight in a mixture of 2.5% glutaraldehyde and 3.7%
paraformaldehyde in 0.1 M phosphate buffer (pH 7.0). After a buffer
wash, the heads were dehydrated through a graded acetone series. After
dehydration, the heads were transferred into 60% LR white resin
(Polysciences) in acetone at 4°C for 1.5 h. Then the heads were
replaced with pure resin for 8 h and polymerized at 55°C
overnight. Embedded heads were sectioned on an ultramicrotome and
viewed under phase-contrast optics. Cobalt sulfide staining of pupal
retinas was done as described by Wolff and Ready (70).
Staging was carried out by aging white prepupae at 25°C. Acridine
orange staining was performed by the method of Wolff and Ready
(70). For
5-bromo-4-chloro-3-indolyl--D-galactopyranoside (X-Gal)
staining, embryos were collected and stained for -galactosidase activity according to standard protocols (2). In situ
hybridization to whole-mount eye discs was carried out as described
previously (62). Riboprobes of rpr,
hid, and dpp were made by using a DIG RNA
labeling kit (Boehringer Mannheim) and hybridized at 55°C. The probes
were detected with a monoclonal antibody against digoxigenin coupled to
alkaline phosphatase and BM purple as a substrate (Boehringer Mannheim). Cuticle preparation was performed according to a standard protocol (2) except that embryos were not fixed before mounting.
Phosphorylation analysis.
Anti-JNK1 antibody (Santa Cruz),
anti-phospho-JNK (p-JNK) antibody (Promega), anti-D-p38b antibody (a
gift from T. Adachi-Yamada [1]), and anti-phospho-p38
(p-p38) antibody (Santa Cruz) were used. Flies of genotypes
UAS-dTAK1; hs-GAL4 and hs-GAL4 (as a wild-type control) were subjected to heat shock (twice at 37°C for 30 min with a 30-min interval). Flies at the third larval stage were
collected (just before or 5 h after the heat shock) and
homogenized. Their extracts were immunoblotted with one of the
antibodies described above after separation in a sodium dodecyl sulfate-polyacrylamide gel.
Nucleotide sequence accession number.
The GenBank accession
number for the dTAK1 cDNA reported here is AF199466.
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RESULTS |
Ectopic expression of mTAK1 affects eye formation.
To study
the in vivo function of TAK1, we generated transgenic flies carrying
the wild-type mouse TAK1 (UAS-mTAK1) or a
truncated, constitutively active form of mTAK1
(UAS-mTAK1N). Ectopic expression of the wild-type
mTAK1 showed various defects in different adult tissues. For
example, UAS-mTAK1/Dll-GAL4 flies were lacking the distal
parts of legs and antenna, whereas UAS-mTAK1/elav-GAL4 flies
showed a rough eye phenotype (data not shown). Ectopic expression of
the activated form of mTAK1 (mTAK11N) resulted
in lethality in early developmental stages. To circumvent the early
lethality, we ectopically expressed mTAK1 and
mTAK1N in the adult eye using an eye-specific expression
vector, pGMR. pGMR contains multimerized Glass-binding sites and
promotes gene expression in all cells in and posterior to the
morphogenetic furrow in the larval eye disc (16, 45).
Eye-specific expression of the TAK1 transgenes induced
specific defects in the visual system. pGMR-mTAK1 transgenic flies showed relatively weak defects in the compound eyes. The phenotype varied among transgenic strains: 6 out of 11 transgenic strains revealed a rough eye phenotype and a reduction in size of the
compound eye. Figure 1D shows the eye
phenotype of a medium-strength pGMR-mTAK1 line. The eye size
is reduced to about 70% of the wild-type eye size. Many ommatidia,
typically located in the medial region, were fused to each other (Fig.
1D). Electron micrographs of ommatidial cross sections of this mutant
revealed that some ommatidia were missing photoreceptors, while others
showed disrupted rows of pigment granules (Fig. 1E). In the pupal eye
disc, a wild-type ommatidium contains four cone cells, two primary
pigment cells, which are surrounded by six secondary pigment cells,
three tertiary pigment cells, and three sensory bristles (Fig. 1C). In
ommatidia from mTAK1 overexpression lines, only two to three
cone cells were observed. The number of primary pigment cells was
relatively normal, but occasionally one of the primary pigment cells
was also missing (Fig. 1F). Secondary and tertiary pigment cells seemed to be heavily affected by mTAK1 expression, as these cells
were rarely observed in the mutant retina (Fig. 1F).
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FIG. 1.
Phenotypes induced by ectopic TAK1 signaling. Scanning
electron micrographs of the compound eye (A, D, G, J, K, and L),
tangential histological sections (B, E, and H), and pupal eyes (at
40 h after puparium formation) stained with cobalt sulfide (C, F,
and I) are shown. (A to C) Canton-S. (A) The wild-type eye
is composed of a regular array of about 800 ommatidia. (B) Each
ommatidium contains six outer photoreceptor cells and an inner
photoreceptor cell, R7 (R1 to R7 are indicated with numbers). (C)
Cobalt sulfide staining shows the apical profile of cells in the
epithelium. Each ommatidium contains four cone cells (indicated with
"c") and two primary pigment cells ("1"), surrounded by six
secondary pigment cells ("2"), three tertiary pigment cells
("3"), and three interommatidial bristles ("b"). (D to F)
pGMR-mTAK overexpression. (E) Most of the ommatidia contain
only five to six photoreceptors (arrow), and visual pigments are also
disrupted at many positions (arrowheads). (F) In the pupal eye, most of
the ommatidia contain only two or three cone cells (arrows) and
occasionally are also missing primary pigment cells (arrowhead).
Numerous numbers of interommatidial cells are also missing in this
mutant. (G to I) pGMR-mTAK1N overexpression. (G)
Expression of mTAK1N in the developing eye results in a
severe decrease in size of the compound eyes. (H and I) Ommatidial
structures are totally disrupted and hard to discriminate in the adult
head section and pupal eye disc. (J) pGMR-hTAB1. Expression
of hTAB1 alone in the eye has no effect on eye development.
(K) Weak pGMR-mTAK1 overexpression phenotype. (L)
Coexpression of hTAB1 and mTAK1 (weak line as
shown in panel K) causes a phenotype as severe as
pGMR-mTAK1N overexpression, as shown in panel G. All
pictures are shown with anterior to the left and dorsal up.
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mTAK1N was also expressed using the pGMR vector. In
contrast to the
pGMR-mTAK1 transgenic line, all
pGMR-mTAK1N transgenic
files (eight independent
transgenic lines) displayed severe eye
phenotypes. In the weakest line
(Fig.
1G), eye size was less than
30% of the wild type and ommatidial
units were rarely identified.
In addition, photoreceptor cells and
pigment granules were difficult
to recognize (Fig.
1H). In the mutant
pupal eye disc, cone cells,
primary pigment cells, and accessory cells
existed in a disorganized
array (Fig.
1I). The results suggest that the
strength of signaling
activity of mTAK1
N is stronger than that of
intact mTAK1 in
Drosophila.
Shibuya et al. have also
reported that TAB1 activates TAK1 signaling
activity in cultured cells
and
Xenopus (
54,
55). If TAK1 is
activated by
TAB1 in
Drosophila, the
pGMR-mTAK1 phenotype
should
be enhanced by the coexpression of
TAB1. Expression
of
hTAB1 alone
did not lead to any defect in the eye (Fig.
1J). However, when
hTAB1 was coexpressed with
mTAK1, the reduced eye phenotype was
dramatically enhanced
(Fig.
1L), consistent with the observations
from the cultured cell and
Xenopus (
54,
55).
Isolation of dTAK1.
The results of the ectopic
mTAK1 and hTAB1 expression indirectly suggest
that a TAK1 homolog is likely to exist in Drosophila. To
examine this issue further, we searched for a Drosophila
homolog of TAK1, using the mTAK1 cDNA as a probe on a
Drosophila genomic library under low-stringency conditions.
A 2.0-kb genomic fragment was obtained and confirmed by sequencing to
be related to vertebrate TAK1. A Drosophila ovarian cDNA
library was then screened using the 2.0-kb genomic fragment as a probe.
Two cDNAs of 2.2 and 3.4 kb were isolated and sequenced. The 3.4-kb
clone contained a full-length cDNA encoding a 678-amino-acid protein
which we refer to as dTAK1 (Fig. 2A). The
overall protein appeared similar to the vertebrate TAK1s, containing an NH2-terminal protein kinase domain as
well as a long COOH-terminal domain (Fig. 2A). The kinase domain showed 56% identity and 73% similarity with the amino acid sequences of
mTAK1 (Fig. 2A). Phylogenetic analysis of the catalytic domain of dTAK1
with those of other Drosophila and vertebrate MAPKKK proteins indicated that its closest relatives are the vertebrate TAK1s
(Fig. 2B). In the COOH-terminal region, dTAK1 is less well conserved
with its vertebrate homologs. However, there is a stretch of 65 amino
acids that is relatively well conserved between Drosophila and vertebrates (37% identity and 57% similarity to mTAK1 [Fig. 2A]). Interestingly, this region is almost completely missing in one
of the alternative spliced forms of the human TAK1 (hTAK1c) (52). Shibuya et al. have reported that TAB2 binds directly to the COOH-terminal region of mTAK1 (55). The functional
significance the TAB2-TAK1 interaction is not known; however, it seems
likely that the COOH-terminal region of TAK1, perhaps through this
conserved 65-amino-acid stretch, may help regulate TAK1 kinase activity and/or provide signaling specificity through physical interactions with
other signaling molecule(s).
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FIG. 2.
Primary structure of dTAK1. (A) The dTAK1 primary
sequence is compared with that of xTAK1, one of the three alternative
splicing forms of hTAK1 (hTAK1b), and mTAK1. The protein sequences are
presented in single-letter code. Gaps ( ) were introduced to optimize
the alignment. Identical residues are indicated with periods. The
protein kinase domain sequence is shown by overline, and sequences
corresponding to conserved kinase subdomains I to XI (27)
are indicated by roman numerals. The 65-residue stretch of amino acids
in the COOH-terminal domain that is conserved between TAK1s is boxed.
(B) Relationship between catalytic domains of members of the vertebrate
and Drosophila MAPKKK group, presented as a dendrogram
created using the Gene Works program (version 2.0; IntelliGenetics).
The figure presents the analysis of the human MAPKKKs RAF-1, KSR1,
MLK1, MOS, and ASK1 (3, 14, 34, 63, 68), the mouse MAPKKKs
TAK1 and MEKK1 (40, 71), and the Drosophila
MAPKKKs DRAF-1, DKSR (48, 63), and dTAK1.
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dTAK1 behaves similarly to mTAK1 and facilitates apoptosis in the
eyes.
To test whether dTAK1 is a true functional ortholog of
mTAK1, we overexpressed dTAK1 under the control of the
GMR-GAL4 driver. A small eye phenotype similar to that
produced by pGMR-mTAK1N (activated form) was obtained
(Fig. 3A and B). The difference in the
strength of dTAK1 enzymatic activity compared to the nonactivated mTAK1
might be explained by the difference in the NH2-terminal structures of these proteins. mTAK1 contains a serine-rich
NH2-terminal domain which has been shown to down regulate
mTAK1 kinase activity (71). Interestingly, dTAK1 lacks this
domain, suggesting that dTAK1 may have a higher basal level of activity
in the absence of an activator protein(s), such as TAB1, than does the
vertebrate gene product (54, 55).
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FIG. 3.
Ectopic TAK1 signaling induces apoptosis in the
developing eye. (A) GMR-GAL4/UAS-dTAK1(strong); (B)
GMR-GAL4/UAS-dTAK1(weak); (C)
GMR-GAL4/UAS-dTAK1(weak); pGMR-p35; (D)
GMR-GAL4/UAS-dTAK1(weak); Df(3L)H99/+. The
deficiency of Df(3L)H99 uncovers three proapoptotic genes,
rpr, hid, and grim. The reduced eye
phenotype of GMR-GAL4/UAS-dTAK1(weak) (B) is rescued either
by coexpression of p35 (C) or by a heterozygous mutant
background which removes the proapoptotic genes (D). (E and F) Acridine
orange staining of eye discs at late third-instar larval stage of
Canton-S (E) and GMR-GAL4/UAS-dTAK1 (F) flies.
Acridine orange-positive cells are rare in the wild-type eye disc (E)
but abundant in dTAK1 overexpression eye discs predominantly
posterior to the morphogenetic furrow (F). (G) Eye discs from wild-type
flies (left two discs) or GMR-GAL4/UAS-dTAK1 flies (right)
were labeled with an rpr antisense riboprobe (top) or a
hid antisense riboprobe (bottom). rpr and
hid expression is not evident in the wild-type eye disc.
dTAK1 expression induces rpr and hid
most significantly in regions posterior to the morphogenetic furrow.
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Next, we further analyzed the cause of the small eye phenotype induced
by ectopic TAK1 signaling. Acridine orange staining,
which identifies
dying cells (
70), was used to examine the extent
of cell
death in larval eye discs of
dTAK1-overexpressing flies.
This study revealed that dying cells increased dramatically in
regions
posterior to the morphogenetic furrow (Fig.
3F), suggesting
that cell
death occurred rapidly after
dTAK1 induction. There
are
several possibilities that might account for the induction
of cell
death in the eye disc in response to ectopic TAK1 signaling.
One
possibility is that TAK1 signaling might directly activate
a cell death
signaling pathway leading to apoptosis. Alternatively,
overpression of
TAK1 leads to necrosis as the result of abnormal
cell fate
specification. To distinguish between these possibilities,
we examined
whether the phenotype of flies expressing
dTAK1 could
be
suppressed by specific apoptosis inhibitors. We found that
the reduced
eye phenotype of
dTAK1 overexpression was rescued
by
coexpression of the apoptotic inhibitor protein p35 (
31)
(Fig.
3C). We also found that the
Drosophila inhibitor of
apoptosis
proteins 1 and 2 (DIAP1 and DIAP2) (
30)
effectively rescued
the phenotype (data not shown). Moreover, when we
examined the
effects of introducing the deficiency H99, which uncovers
the
proapoptotic genes
reaper (
rpr),
head
involution defective (
hid),
and
grim
(
10,
23,
69), into a background expressing
dTAK1,
the eye was restored to normal size (Fig.
3D). Figure
3G shows
that the
expression of
rpr and
hid is dramatically induced
in
regions posterior to the morphogenetic furrow in the eye discs
of
GMR-GAL4/UAS-dTAK overexpression lines compared to the wild
type. Since overexpression of
hid in the eye disc does not
induce
rpr and vice versa (data not shown), it is likely
that
rpr and
hid are independently induced by the
TAK1 signal. These data indicate
that the cell death induced by dTAK1
is apoptotic in nature and
that its induction is dependent on
endogenous proapoptotic gene
activity.
We also examined the effect of ectopic TAK1 expression on cell fate
determination of the photoreceptor cells. Sequential recruitment
of the
photoreceptor cells was disrupted in
dTAK1-overexpressing
discs (Fig.
4C and D). Early
photoreceptor cell (R8 and occasionally
R2 and R5) induction appeared
to occur normally. However, later
photoreceptor induction was delayed
or disrupted, and photoreceptor
clustering showed an abnormal and
diffuse pattern even in the
presence of p35 (Fig.
4C to F). This result
indicates that ectopic
TAK1 signaling may also directly or indirectly
affect certain
aspects of cell fate specification. Maybe this abnormal
photoreceptor
induction affects later cell development which includes
cone cell
and pigment cells. However, we found that proper numbers of
the
cone cells and primary pigment cells were induced in the pupal
eye
discs from
pGMR-mTAK1N;
pGMR-p35 (data not
shown). We conclude
that TAK1 induces cell death after proper cell fate
determination
in at least some of the ommatidial cells such as R8.
However,
in other cells, abnormal cell fate determination by the
ectopic
TAK1 signaling may also contribute to induction of cell death
in the TAK1-expressing eye discs.
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FIG. 4.
Effect of dTAK1 expression in photoreceptor cell
induction. Late third-instar eye discs were doubly labeled with
anti-Elav antibody (A, C, E) and for rhomboid lacZ (X81)
expression. Anti-Elav antibody stains all of the photoreceptor cells
(R1 to R8). X81 expresses lacZ strongly in R8 and relatively
weakly in R2 and R5 (19). (A and B) Wild type; (C and D)
GMR-GAL4/UAS-dTAK1; (E and F) GMR-GAL4/UAS-dTAK1;
pGMR-p35. R8 induction occurs normal in
GMR-GAL4/UAS-dTAK1 (D) and GMR-GAL4/UAS-dTAK1;
pGMR-p35 (F) eye discs. R2 and R5 are occasionally induced
in the GMR-GAL4/UAS-dTAK1; pGMR-p35 disc
(indicated with arrows in panel F). Photoreceptor cell markers are
disordered and diffuse in more posterior regions (C to F). This result
indicates that dTAK1 overexpression altered or delayed specification of
the photoreceptor cells, particularly for R3, R4, R1, R6, and R7. All
images are presented with anterior to the left.
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|
We repeated all of the experiments described above using
mTAK1N overexpression strains and obtained similar
results. On this
basis, we conclude that dTAK1 is a functional homolog
of
mTAK1.
TAK1 specifically activates the Hep-Bsk cascade.
To address
which signaling pathway(s) might be activated by TAK1 in vivo, we
tested for genetic interactions between mutants in various signaling
pathways and a TAK1-overexpressing line (either pGMR-mTAK1N or GMR-GAL4/UAS-dTAK1). Included
in this screen were mutations that disrupt BMP signaling, the Raf-MAPK
pathway, and the JNK pathway (see Materials and Methods). Among the
various mutants tested, only alleles of hep and
bsk were found to interact strongly with lines
overexpressing TAK1. In hemizygous hep or heterozygous bsk mutant backgrounds, the reduced size of
compound eyes of GMR-GAL4/UAS-dTAK1 flies was rescued to
that of wild-type flies (Fig. 5A to C).
For comparison, Fig. 5D illustrates an example of noninteraction
between Dsor1, a member of the Rl/MAPK pathway, and
GMR-GAL4/UAS-dTAK1. Overexpression of hep in the
eye resulted in a similar small eye phenotype, and this phenotype was
rescued by the presence of p35 (Fig. 5E and F), confirming that
ectopically activated JNK signaling induces cell death in the
Drosophila eye.
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FIG. 5.
Genetic interaction of pGMR-mTAK1N. (A to
F) Scanning electron micrographs of the compound eye. (A)
GMR-GAL4/UAS-dTAK1(weak); (B) hep1/Y;
GMR-GAL4/UAS-dTAK1(weak); (C)
GMR-GAL4/UAS-dTAK1(weak); bsk2/+; (D)
Dsor1LH110/Y;
GMR-GAL4/UAS-dTAK1(weak) (E) GMR-GAL4/+;
UAS-hep/+; (F) GMR-GAL4/+;
UAS-hep/pGMR-p35. Reduced eye phenotype of
GMR-GAL4/UAS-dTAK1 (A) is suppressed by one copy reduction
of the hep or bsk gene (B and C). In contrast to
this, a mutant which is involved in MAPK/ERK cascade, Dsor1,
does not show any genetic interaction to this phenotype (D). Ectopic
expression of hep also results in the small eye phenotype
(E). This phenotype is suppressed by the presence of p35 (F),
indicating that ectopic activation of the JNK signal induced apoptosis
in the developing eye. GMR-GAL4/UAS-hep flies lost most of
the interommatidial bristles (E). Bristle phenotype is not rescued by
p35 expression (F), suggesting that apoptosis is not a direct cause of
this phenotype. Anterior is to the left, and dorsal is up.
|
|
The Hep-Bsk signaling pathway has been shown to regulate the process of
dorsal closure during the embryonic development (
21,
49,
51,
57). Two genes,
puckered (
puc) and
decapentaplegic (
dpp), are downstream targets of
Hep-Bsk signaling (
21,
22,
42,
49) and are induced in the
leading-edge cells in the embryonic
epidermis during dorsal closure
(Fig.
6A and C). To further examine
whether TAK1 signaling is mediated by Hep and Bsk, we misexpressed
dTAK1 using the
en-GAL4 driver, which promotes
GAL4 expression
in the posterior compartment of the
embryonic ectoderm (
22)
(Fig.
6E). Ectopic
puc
and
dpp expression was observed in
UAS-dTAK1/en-GAL4 embryos in a striped pattern (Fig.
6B and
D). This result indicates
that exogenous
mTAK1 activates the
Hep-Bsk pathway in the embryo
as well as during imaginal disc
development. We also tested whether
dTAK1 expression leads
to Bsk protein phosphorylation.
dTAK1 was
transiently
expressed in the third-instar larva by expressing
UAS-dTAK1
and
hs-GAL4. Strong Bsk phosphorylation was observed
only in
the flies carrying
UAS-dTAK1 after heat shock (Fig.
7A).
Phosphorylation of D-p38 was not
affected by
dTAK1 expression
(Fig.
7B). We conclude that
TAK1 can activate the Hep-Bsk MAPK
cascade in vivo.
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FIG. 6.
Ectopic induction of puc and dpp
by dTAK1 demonstrated by X-Gal staining (A and B) and in situ
hybridization for dpp antisense probe (C and D) of stage 14 embryos. (A) puc-lacZ/+; (B) en-GAL4/UAS-dTAK1;
puc-lacZ/+; (C) wild type; (D) en-GALY/UAS-dTAK1.
puc and dpp expression in the leading-edge cells
is indicated by arrows (A and C, respectively). Ectopic expression of
dTAK1, controlled by en-GAL4, ectopically induces
both puc and dpp in the embryonic ectoderm with a
striped pattern (B and D). (E) en-GAL4/UAS-lacZ. en-GAL4
expression pattern is shown. Anterior is to the left, and dorsal is
up.
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FIG. 7.
In vivo phosphorylation of Bsk and D-p38 by ectopic
dTAK1 expression. Third-instar larva carrying only
hs-GAL4 or both UAS-dTAK1 and hs-GAL4
were collected with or without heat shock treatment. Extracts prepared
from these larva were immunoblotted with either anti-p-JNK or anti-JNK1
antibody (A) and with anti-p-D-p38 or anti-p38 (B). Bsk phosphorylation
is increased dramatically only in UAS-dTAK1-carrying animals
upon heat shock. However, phosphorylation of D-p38 is not induced by
the dTAK1 overexpression.
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|
Expression of the dominant negative dTAK1 in the embryo resulted in
several cuticle defects including a dorsal open phenotype.
A
common feature exhibited by loss-of-function mutations in genes of the
JNK signaling pathway is a failure of proper dorsal closure due to
disruptions in the movement and the ability of cells to change shape in
the leading edge of the lateral epidermis (21, 22, 33, 37, 49-51,
57). Some of these mutants also exhibit defects in head structure
and/or problems with germ band retraction (29, 60). To test
whether dTAK1 also controls dorsal closure signals during normal
development, we overexpressed a kinase-dead form
(dTAK1-K46R) in the embryonic epidermis, using a
pnr-GAL4 driver. Various types of cuticle defects were
observed. The most typical phenotype was a head structure defect in
which mouth hooks were missing (36%, n = 591) (Fig.
8B). A certain fraction of these
defective embryos also exhibited an anterior open phenotype similar to
that exhibited by hep and bsk mutants. In the
most extreme cases, almost the entire dorsal cuticle failed to close (Fig. 8C). Occasionally, we also observed embryos with a U-shaped phenotype presumably due to insufficient germ band retraction (data not
shown). These phenotypes are consistent with the idea that dTAK1
participates in the JNK signaling pathway.
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FIG. 8.
Lateral view of the cuticle phenotypes of dominant
negative dTAK1-expressing embryos of the following
genotypes: (A) +/pannierMD237GAL4, as a
wild-type control; (B and C) UAS-dTAK1-K46R/+;
UAS-dTAK1-K46R/pannierMD237GAL4. (A) Wild-type
cuticle illustrating the regular spacing of the denticle belt on the
ventral side and complete closure of the epidermis on the dorsal side.
(B and C) Expression of dTAK1-K46R (two copies of transgene)
during embryonic development by means of pnr-GAL4
(32) causes various defects. Defects in the anterior
structure, typically loss of the mouth hooks (normal position of the
mouth hooks is indicated with arrows in panels A and B), are seen in
37% of embryos (n = 591). Embryos of this type are
frequently exhibit a small whole in the anterior and dorsal side of the
cuticle (B). In the most extreme cases, the embryo is completely open
dorsally (6%, n = 591) (C). Arrows indicate the edge
of the dorsal hole of the cuticle.
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|
Expression of dominant negative forms of mTAK1 and dTAK1 in the eye
suggest a role of JNK signaling in controlling pigment and bristle cell
shape and position.
Little is known about the role of the JNK
signaling pathway in eye development. Clones of partial
loss-of-function bsk alleles showed no apparent defect in
ommatidial development (49); however, mutations in
disheveled, which appears to play a dual role in Wnt and JNK
signaling pathways, show planar polarity defects in the eye
(4). We wished to examine whether loss of TAK1 activity might affect ommatidial development. To explore this issue, we examined
the outcome of expressing dominant negative forms of mTAK1 and dTAK1 in
the eye disc, using the Glass promoter.
Flies expressing
mTAK1-K63W or
dTAK1-K46R showed
a rough eye phenotype (data not shown), and this phenotype was
sensitive
to gene dosage. Flies expressing one copy of
mTAK1-K63W had an
almost wild-type compound eye, at least in
the outer structure,
while flies carrying two copies of the transgene
displayed a rough
eye phenotype (data not shown). We analyzed these
putative loss-of-function
phenotypes at a cellular level. In an apical
profile of the pupal
eye disc of
pGMR-mTAK1-K63W-expressing
lines (one copy), we noticed
that bristles were mislocalized in the
mutant pupal eye disc (Fig.
9A). In the
wild-type fly, each ommatidium is surrounded by three
bristles (Fig.
1C). These bristles are usually located at the
anterior end of each
horizontal face of the interommatidial space.
In the
pGMR-mTAK1-K63W disc, more than 30% of the bristles were
located on the posterior end (or sometimes in the middle) of the
horizontal face (Fig.
9A). Similar results were seen with
overexpression
of
pGMR-dTAK1-K63R (Fig.
9C). We also
observed abnormalities in
the secondary and tertiary pigment cells.
These two types of pigment
cells lie between ommatidia and are
distinguishable based on positions
and cell shapes. Secondary pigment
cells lie between two ommatidia
and have rectangular shapes. Tertiary
pigment cells are shared
among three ommatidia at a vertex and have
hexagonal cell shapes
(Fig.
1C). In the dominant negative
overexpression discs (Fig.
9B and C), it is obvious that the cell
shapes of the secondary
and tertiary pigment cells are heterogeneous.
For instance, normally
the secondary pigment cells which lie on the
horizontal face are
thicker than those lying on the slanting face (Fig.
1C). The hexagonal
shape of the tertiary pigment cells is also
distorted in the dominant
negative overexpressing discs (Fig.
9B and
C). We also examined
the apical cell profile of
hep
hemizygous mutant eye discs and
found that they too showed mislocation
of bristle cells and alterations
in positions of pigment cells (Fig.
9D). These observations suggest
that the endogenous TAK1 signaling,
likely acting through the
Hep-Bsk pathway, plays an important role in
regulating correct
cell shape changes and/or cell movement in the
secondary and tertiary
pigment cells, as well as in the bristle cells.
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FIG. 9.
Phenotypes induced by the expression of dominant
negative TAK1. Pupal eyes of the following genotypes at
40 h after puparium formation were stained with cobalt sulfide.
(A) pGMR-mTAK1-K63W (one copy). Expression of
mTAK1-K63W, a dominant negative form of mTAK1, at
a lower level results in defective positioning of the interommatidial
bristle (indicated with arrows, compared to the wild-type shown in Fig.
1C). (B) pGMR-mTAK1-K63W (two copies). A higher level of
mTAK1-K63W expression totally disrupts the ommatidial array.
The cell shapes of secondary and tertiary pigment cells are irregular,
and it is hard to discriminate these two cell types by morphology. (C)
GMR-GAL4/UAS-dTAK1-K46R; UAS-dTAK1-K46R/+. A
similar phenotype is observed in a fly expressing dTAK1-K46R (two
copies), a kinase-inactive form of dTAK1. (D)
hepr75/Y. The hep mutant disc also
shows bristle mislocation (indicated with arrows) and abnormal pigment
cell shapes (arrowheads). All images show the phenotype of the center
region of the pupal eye discs (even in the wild-type discs, bristle
mislocation is occasionally observed in the anterior edge region).
Anterior is to the left.
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|
Interestingly, despite the abnormal morphology of the secondary and
tertiary pigment cells in the pupal eye disc of
pGMR-mTAK1-K63W and an allele of the mutant,
hepr75, the total number of secondary and
tertiary pigment cells did
not change (Fig.
9). Since a wave of
apoptosis is known to control
pigment cell number (
8,
70),
this result implies that either
endogenous programmed cell death in the
visual system is independent
of TAK1-JNK signaling or the expression
level of dominant negative
TAK1 is insufficient for inhibiting
endogenous
apoptosis.
| |
DISCUSSION |
TAK1 activates the JNK signaling pathway in Drosophila.
There are many known members of MAPKKK family, including MEKs, germinal
center kinase, mixed-lineage kinases (MLKs), tumor progression locus 2, apoptosis signal-regulating kinase 1 (ASK1) and TAK1. These kinases
have been shown to activate JNK and/or p38 MAPK pathways in cell
culture experiments, but whether they contribute to the function of
these pathways in vivo is unknown (18, 34). In this study we
have shown that TAK1 can activate the JNK signaling cascade in
Drosophila. This conclusion is based on four lines of
evidence. First, ectopic expression of TAK1 induces expression of
dpp and puc, known downstream targets of JNK
signaling in embryonic ectodermal cells (Fig. 6B and D). Second,
ectopic TAK1 expression resulted in the phosphorylation of the Bsk
protein (Fig. 7A). Third, heterozygosity for hep and
bsk mutants is able to dominantly suppress the dTAK1
overexpression phenotype (Fig. 5B and C). Fourth, dominant negative
forms of TAK1 exhibit cuticular phenotypes similar to loss-of-function
phenotypes of bsk and hep alleles (Fig. 8B and
C). Thus, TAK1 is likely to serve as the missing MAPKKK in the JNK
signaling pathway functioning downstream of the misshapen
products, a Drosophila MAPKKKK, and upstream of Hep.
In addition to its role in JNK signaling, previous evidence from cell
culture experiments has implicated TAK1 in p38 MAPK
signaling pathways
(
44,
56,
66,
71). However, we found
no evidence for the
involvement of TAK1 in p38 activation in
Drosophila.
Specifically, the reduced eye phenotype of
pGMR-mTAK1N
overexpression
was not rescued by heterozygosity for a deficiency which
uncovers
one of the D-p38 loci (
D-p38b) (data not shown).
Likewise, expression
of a dominant negative form of
D-p38b,
where Thr-183 of the MAPKK
target site was replaced with Ala, did not
suppress the
pGMR-mTAK1N overexpression phenotype (data
not shown); furthermore, and most
compelling, D-p38 phosphorylation was
not observed in the flies
expressing
dTAK1 (Fig.
7B). Thus,
our data suggest that TAK1 may
specifically activate JNK signaling and
not p38 MAPK signaling
in
Drosophila; however, this
conclusion will need to be tested
further once mutations in D-p38 and
dTAK1 become
available.
Endogenous function of the TAK1 signaling in Drosophila.
Two different biological processes are known to be controlled by the
JNK signaling pathway in Drosophila. One is the movement of
leading-edge cells during the process of embryonic dorsal closure (21, 22, 33, 37, 49-51, 57), and the other is in planar polarity determination of adult tissues (4, 60). In neither case, however, is the role or identity of the putative MAPKKK molecule(s) that might be involved in these processes known. In this
study, gain-of-function experiments revealed that TAK1 could activate
the JNK signaling cascade. Loss-of-function experiments, using dominant
negative dTAK1 and mTAK1, also revealed that TAK1 is likely to be
required for the proper cell movement and/or shape changes in the
embryo and visual system. Indeed, the dorsal open phenotype and head
structure defects observed in the dominant negative dTAK1-expressing
embryos are highly reminiscent of the phenotype produced by JNK pathway
loss-of-function mutants (21, 22, 33, 37, 49-51, 57).
Impaired control of cell shape was also noted in TAK1 gain-of-function
phenotypes obtained by overexpression of dTAK1 in the
presence of p35 (Fig. 4F) and also with dominant negative forms of TAK1
(Fig. 9B and C). The function of JNK signaling in cell movement in the
visual system has been studied only for ommatidial planar polarity
determination (4, 60). Although we did not observe defects
in planar polarity, we do see abnormalities in the positioning and
shape of interommatidial cells in both dominant negative
TAK1-expressing lines and hep mutants (Fig. 9). This result
suggests that the endogenous JNK signaling also participates in the
positioning and shape of the interommatidial cells. Since a true
loss-of-function hep allele also shows this phenotype,
albeit more weakly, it is not likely that the phenotype caused by
overexpression of dominant negative TAK1 is due to a novel neomorphic
property of this protein. The weaker interommatidial phenotype of
hemizygous hepr75 flies compared to that of
pGMR-mTAK1-K63W (two copies) might indicate that there is
some genetic redundancy for this class of kinase in
Drosophila. Likewise, the lack of observable planar polarity
defects in these animals may indicate either a nonrequirement for a
TAK1 kinase in this process or a genetic redundancy for a TAK1-type
kinase, or that this particular phenotype is less sensitive to TAK1
loss-of-function and so is not observable under the conditions used in
this study. Only when clones of true TAK1 loss-of-function alleles are
available will we be able to fully address this issue.
TAK1 function in TGF-/Dpp signaling.
Previous reports have
shown that TAK1 is activated by TGF-/BMP stimuli and that a
kinase-negative form of TAK1 prevents TGF-/BMP signaling in
mammalian cells and in Xenopus (54, 71).
Surprisingly, we did not observe any genetic interactions between
pGMR-mTAK1N overexpression lines and mutations in the Dpp
signaling pathway. We also found that ectopic TAK1 signaling in the
wing disc was unable to induce optomotor blind, a known
downstream target of Dpp signaling (24) and, furthermore,
that ectopic vein formation induced by a constitutively active Dpp
receptor could not be suppressed by overexpression of
dTAK1-K46R expression (Y. Takatsu et al., unpublished data).
These results may indicate that Dpp signaling is not regulated by TAK1
in the visual system and wing or, alternatively, that the effects of
Dpp-induced TAK1 signaling are mild compared to the Mad/Medea pathway
of Dpp signaling and so were not observable with the genetic tests
presently at hand. Once again, the availability of TAK1 mutants will
help clarify this issue.
Apoptosis triggered by the TAK1-JNK signaling pathway.
We have
shown that the ectopic activation of the TAK1 signaling pathway induces
apoptosis in Drosophila. A role for TAK1 in mediating
apoptosis has been previously suggested from overexpression studies in
cell culture (56). For example, in one study, Shirakabe et
al. showed that ceramide, a second messenger molecule that induces
various cellular responses such as cell cycle arrest, differentiation,
and apoptosis (28, 38, 56), activates TAK1 and that
TAK1-K63W blocks ceramide-induced apoptosis (56). The role
of the JNK pathway in stress-induced apoptosis in vertebrates has been
extensively studied. Various environmental stresses, such as UV
irradiation, exposure to toxic agents, osmotic stresses, and heat
shock, all trigger JNK pathway activation and result in apoptosis in
certain cells and tissues (12, 20, 39, 43, 57). We believe
that the TAK1-induced apoptosis that we report here is also likely to
be mediated through the JNK pathway. Consistent with this view, we have
observed that ectopic hep expression using GMR-GAL4 also results in a reduced eye phenotype (Fig. 5E).
Since we have shown that the constitutively active TAK1 phenotype is effectively suppressed by a reduction in gene dosage of the
proapoptotic genes rpr, hid, and grim
or by coexpression of apoptosis inhibitors such as p35 or DIAPs (Fig.
2C) which block the enzymatic activities of caspases (7,
13), we believe that TAK1-JNK function is positioned upstream of
the proapoptotic genes and the caspase cascade. Interestingly, ectopic
TAK1 expression in Xenopus embryos also immediately induces
cell death, yet no vertebrate homologs of the Drosophila
proapoptotic genes have been identified. Recently, however, Evans et
al. reported that overexpression of the Drosophila rpr gene
can induce apoptosis in Xenopus eggs (17). This
may indicate that proapoptotic genes exist in vertebrates and that they
could be targets of TAK1-JNK signaling. Further genetic analysis using
TAK1 transgenic flies should provide a unique opportunity to
identify molecules that help interface JNK activation with the basic
apoptotic machinery.
| |
ACKNOWLEDGMENTS |
Y. Takatsu and M. Nakamura contributed equally to this work.
We are grateful to N. Nakamura and K. Nakagawa for experimental help.
We also thank A. Kreuz and T. Tanimura for comments on the manuscript;
T. Adachi-Yamada and K. Sawamoto for fly stocks and technical advice;
S. Goto for the UAS-hep construct; H. Steller for
rpr and hid cDNAs; N. Patel for Elav antibody; T. Adachi-Yamada for anti-p-D-p38b antibody; and K. Basler, D. Brunner, S. Cohen, M. Freeman, K. Ito, E. Hafen, S. Hayashi, Y. Hiromi, K. Kimura, Y. Nishida, N. Perrimon, G. M. Rubin, L. Raftery, H. Okano, G. Pflugfelder, and the Bloomington Stock Center for fly stocks.
This work was supported by grants-in-aids for scientific research from
the Ministry of Education, Science, and Culture of Japan and the
Research for the Future program of the Japan Society for the Promotion
of Science. M.S. was supported by PHS grant GM47462 to M.B.O.
M.C.D. is a Research Associate of the Howard Hughes Medical Institute.
M.B.O. is an Associate Investigator of the Howard Hughes Medical Institute.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Division of
Morphogenesis, Department of Developmental Biology, National Institute for Basic Biology, Okazaki 444-8585, Japan. Phone: (81)-564-55-7574. Fax: (81)-564-55-7571. E-mail: mack{at}nibb.ac.jp.
| |
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Molecular and Cellular Biology, May 2000, p. 3015-3026, Vol. 20, No. 9
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Abstract
Introduction
