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Molecular and Cellular Biology, February 2000, p. 1044-1054, Vol. 20, No. 3
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Death-Associated Protein Kinase-Related Protein 1, a Novel Serine/Threonine Kinase Involved in Apoptosis
Boaz
Inbal,
Gidi
Shani,
Ofer
Cohen,
Joseph L.
Kissil, and
Adi
Kimchi*
Department of Molecular Genetics, Weizmann
Institute of Science, Rehovot 76100, Israel
Received 18 June 1999/Returned for modification 28 July
1999/Accepted 4 November 1999
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ABSTRACT |
In this study we describe the identification and structure-function
analysis of a novel death-associated protein (DAP) kinase-related protein, DRP-1. DRP-1 is a 42-kDa Ca2+/calmodulin
(CaM)-regulated serine threonine kinase which shows high degree of
homology to DAP kinase. The region of homology spans the catalytic
domain and the CaM-regulatory region, whereas the remaining C-terminal
part of the protein differs completely from DAP kinase and displays no
homology to any known protein. The catalytic domain is also homologous
to the recently identified ZIP kinase and to a lesser extent to the
catalytic domains of DRAK1 and -2. Thus, DAP kinase DRP-1, ZIP kinase,
and DRAK1/2 together form a novel subfamily of serine/threonine
kinases. DRP-1 is localized to the cytoplasm, as shown by
immunostaining and cellular fractionation assays. It binds to CaM,
undergoes autophosphorylation, and phosphorylates an exogenous
substrate, the myosin light chain, in a Ca2+/CaM-dependent
manner. The truncated protein, deleted of the CaM-regulatory domain,
was converted into a constitutively active kinase. Ectopically expressed DRP-1 induced apoptosis in various types of cells. Cell killing by DRP-1 was dependent on two features: the status of the
catalytic activity, and the presence of the C-terminal 40 amino acids
shown to be required for self-dimerization of the kinase.
Interestingly, further deletion of the CaM-regulatory region could
override the indispensable role of the C-terminal tail in apoptosis and
generated a "superkiller" mutant. A dominant negative fragment of
DAP kinase encompassing the death domain was found to block apoptosis
induced by DRP-1. Conversely, a catalytically inactive mutant of DRP-1,
which functioned in a dominant negative manner, was significantly less
effective in blocking cell death induced by DAP kinase. Possible
functional connections between DAP kinase and DRP-1 are discussed.
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INTRODUCTION |
Apoptosis is a genetically
controlled cell death process which is important at various
developmental stages as well as for cell maintenance and tissue
homeostasis (16). During the last few years, many of the key
players in this process, including receptors, adapter proteins,
proteases, and other positive and negative regulators, have been
identified (13, 33). One of the positive mediators of
apoptosis, which was cloned in our laboratory, is death-associated
protein (DAP) kinase (9). This protein was discovered by a
functional approach to gene cloning, based on transfections of
mammalian cells with antisense cDNA libraries and subsequent isolation
of death-protective cDNA fragments (9, 10, 19, 20, 23). The
antisense cDNA of DAP kinase protected HeLa cells from gamma
interferon-induced cell death, and this property served as the basis
for its selection. DAP kinase is a calcium/calmodulin (CaM)-regulated
serine/threonine protein kinase (160 kDa), associated with actin
microfilaments (6, 9). Its structure contains at least two
additional domains that might mediate interactions with other proteins:
ankyrin repeats, and a typical death domain located at the C-terminal
part of the protein (9, 12). Overexpression of DAP kinase in
various cell lines results in cell death, and this death-promoting
effect of DAP kinase depends on at least three features: catalytic
activity, presence of the death domain, and correct intracellular
localization (6, 7). Several independent lines of evidence
proved that DAP kinase is involved in apoptosis triggered by different
external signals including gamma interferon, tumor necrosis factor
alpha (TNF-
), activated Fas receptors, and detachment of cells from the extracellular matrix (6, 7, 9, 15). A tumor-suppressive function was recently attributed to DAP kinase, coupling the control of
apoptosis to metastasis (15).
Recent studies have implicated several serine/threonine kinases in the
regulation of programmed cell death, either as death-promoting or as
death-protecting proteins (1, 3). One such candidate is the
c-Jun N-terminal kinase (JNK)/stress-activated protein kinase (2,
32). In one example it was shown to mediate apoptosis induced by
detachment from extracellular matrix (named anoikis) (4). In
that system, the JNK pathway is activated by MEKK-1, whose kinase
activity is stimulated by caspase cleavage (4). JNK may
antagonize the antiapoptotic activity of Bcl-2 by phosphorylation (24, 27). Another serine/threonine kinase is RIP, which,
like DAP kinase, possesses the death domain. RIP was shown to
positively mediate apoptosis in cell cultures (30). However,
in vivo studies performed in RIP-deficient mice documented another
aspect of its function, i.e., its ability to exert antiapoptotic
effects by mediating the TNF--induced activation of NF-
B
(18). Other RIP members, RIP2 and RIP3, were also recently
identified and shown to possess proapoptotic effects (25, 31,
34). Among the negative regulators of apoptosis is the protein
kinase Akt (protein kinase B). This protein was shown to phosphorylate
BAD, thereby preventing it from dimerizing with and blocking the
antiapoptotic activity of BCL-XL (8, 11). Akt
was also recently shown to phosphorylate procaspase-9, thus blocking
its normal processing and activation (5).
Recently, the isolation and characterization of three novel kinases,
homologous in their catalytic domains to DAP kinase, have been reported
(17, 22, 29). One protein, named ZIP (Dlk) kinase, was found
to be 80% identical to DAP kinase within the kinase domain, yet it
lacks the CaM-regulatory domain and the other domains and motifs
characteristic of DAP kinase. ZIP kinase contains a leucine zipper
domain at the C terminus and is localized to the nucleus (17,
22). The activation of ZIP kinase occurs by a different mechanism
involving homodimerization, mediated by its leucine zipper domain.
Another two novel, closely related proteins, DRAK1 and DRAK2, which
share ~50% identity with the kinase domain of DAP kinase, were also
recently characterized (29). Like ZIP kinase, the DRAK1 and
DRAK2 proteins also lack the CaM-regulatory domain. Ectopic expression
of the three wild-type kinases, but not of their catalytically inactive
mutants, induced morphological changes characteristic of apoptosis
(17, 29). In the case of ZIP kinase, the data on its
death-inducing properties in some cells are still controversial
(22).
Here we report on the cloning and biochemical and functional
characterization of a novel member of the DAP kinase subfamily of
serine/threonine kinases, a 42-kDa protein named DAP kinase-related protein kinase 1 (DRP-1). Unlike ZIP kinase and the DRAK proteins, DRP-1 contains a typical CaM domain resembling that of DAP kinase and
by that mean appears to be the closest homologue to DAP kinase. The
carboxy-terminal tail encompassing the last 40 amino acids has no
homology to other known proteins and was found to be required for
self-dimerization. In vitro kinase assays confirmed the ability of
DRP-1 to undergo autophosphorylation and to phosphorylate an exogenous
substrate, myosin light chain (MLC), in a
Ca2+/CaM-dependent manner. The enzyme became constitutively
active upon deletion of the CaM-regulatory domain. The ectopically
expressed DRP-1 was shown to be localized to the cytoplasm as a
detergent-soluble form, with minor association to matrix-insoluble
elements. Its function was implicated in apoptosis based on the finding
that it induced apoptotic cell death when overexpressed and that a catalytically inactive DRP-1 mutant reduced cell death triggered by the
ectopic expression of p55 TNF receptors (TNFR). The death-promoting effects of DRP-1 depended on the functionality of the catalytic domain
and on the presence of the C-terminal tail, yet further deletion of the
CaM-regulatory domain abrogated the requirement for the C-terminal
tail. Cell death induced by DRP-1 was blocked specifically by the death
domain of DAP kinase, suggesting a possible cross talk between these
two kinases.
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MATERIALS AND METHODS |
cDNA cloning and Northern blotting.
A PCR fragment
of 364 bp was obtained from a 
gt11 human spleen cDNA library
(Clontech), using primers from the deduced DRP-1 sequence
(1047-GGCCGGATGAGGACCTGAGG-1066 and
1411-TCCACACTCCCACCCCAGACTC-1390). To obtain the full-length
cDNA of DRP-1, we screened the same cDNA library with the radiolabeled
PCR product. A 1,742-bp cDNA clone was subcloned into a BlueScript
vector for restriction enzyme mapping and DNA sequencing and into
pcDNA3 (from positions 8 to 1144) for expression in cells. A 580-bp 3'
fragment from the full-length cDNA of DRP-1 subcloned into pT7T3D
vector was generated by HindIII-XhoI digestion (nucleotides 977 to 1557) and used to probe
poly(A)+ RNA prepared by a standard procedure from various
cell lines.
Preparation of anti-DRP-1 antibodies and immunoblot
analysis.
Polyclonal antibodies were generated by injecting
DRP-1-FLAG fusion protein, excised from polyacrylamide gels, into New
Zealand White rabbits. The antibodies were titrated against the
recombinant DRP-1 expressed in 293 cells. Transfections of 293 cells,
cell lysate preparation, and immunoblotting conditions were as
previously described in detail (6).
In vitro transcription and translation assay.
A fragment
starting at a methionine in position 62 and extending to the end of the
cDNA clone was subcloned into the pRSET-C vector and used as a template
for in vitro transcription from the T7 promoter. This RNA was
translated in reticulocyte lysate (TNT T7 Quick Coupled
Transcription/Translation system; Promega) by conventional procedures,
with [35S]methionine (Amersham) as a labeled precursor.
The reaction product was then run on a sodium dodecyl sulfate
(SDS)-12% polyacrylamide gel, followed by sodium salicylate
incubation for signal amplification. The gel was dried and exposed to
X-ray film.
In vitro kinase assay.
293 cells were transfected with
various FLAG or hemagglutinin (HA) epitope-tagged DRP-1 constructs.
Immunoprecipitation of the various ectopically expressed DRP-1 proteins
from 150 µg of total extract was performed with 20 µl of anti-FLAG
M2 gel (IBI, Kodak) in 500 µl of PLB (10 mM
NaH2PO4 [pH 7.5], 100 mM NaCl, 1% Triton
X-100, 0.1% SDS, 0.5% sodium deoxycholate, 5 mM EDTA) supplemented
with protease and phosphatase inhibitors for 2 h at 4°C.
Following three washes with PLB, the immunoprecipitates were washed
once with reaction buffer (50 mM HEPES [pH 7.5], 20 mM
MgCl2, 0.1 mg of bovine serum albumin per ml). The proteins bound to the beads were incubated at 30°C for 15 or 9 min, as indicated, in 50 µl of reaction buffer containing 15 µCi of
[
-32P]ATP (3 pmol), 50 µM ATP, and 5 µg of MLC
(Sigma). In addition, either 1 µM bovine CaM (Sigma) plus 0.5 mM
CaCl2 or 3 mM EGTA was added as indicated. Protein sample
buffer was added to terminate the reaction, and after boiling, the
proteins were analyzed on an SDS-11% polyacrylamide gel. The gel was
blotted onto a nitrocellulose membrane, and 32P-labeled
proteins were visualized by autoradiography.
Immunostaining of cells.
FLAG-DRP-1-transfected or
mock-transfected COS-7 cells were plated on glass coverslips (13-mm
diameter). After 48 h, the cells were fixed and permeabilized by
subsequent incubations in 3% formaldehyde, methanol, and acetone for
5, 5, and 2 min, respectively. The cells were blocked in 10% normal
goat serum for 30 min and incubated with anti-FLAG antibodies (dilution
of 1:100; IBI, Kodak) in 10% NGS for 60 min. Rhodamine-conjugated goat
anti-mouse secondary antibodies (dilution of 1:200; Jackson
ImmunoResearch Laboratories) and the nucleic acid dye Oligreen
(dilution of 1:5,000; Molecular Probes) used for nuclear staining were
then applied. The coverslips were mounted in Mowiol and examined under
a fluorescence microscope.
Detergent extraction assay.
Subconfluent cultures of
transfected COS-7 cells, grown on a 9-cm-diameter plate, were washed
once with phosphate-buffered saline and then with
morpholineethanesulfonic acid (MES) buffer (50 mM MES [pH 6.8], 2.5 mM EGTA, 2.5 mM MgCl2). The cells were extracted for 3 min
with 0.5 ml of 0.5% Triton X-100 in MES buffer supplemented with
protease inhibitors. The supernatant (the soluble fraction) was
collected and centrifuged for 2 min at 16,000 × g at
4°C, and the cleared supernatant was then transferred to new tubes.
Two volumes of cold ethanol was added, and following an overnight
incubation at 
20°C, pellets (10 min at 16,000 × g
at 4°C) were resuspended in 200 µl of 2× protein sample buffer without dye. The detergent-insoluble matrix, remaining on the plate,
was extracted in 200 µl of 2× protein sample buffer and scraped from
the plate with a rubber policeman; 100 µg of protein extracts from
soluble fractions and equivalent volumes of insoluble fractions were
loaded into SDS-10% polyacrylamide gels and resolved by
polyacrylamide gel electrophoresis (PAGE). Western blot analysis was
then performed with monoclonal anti-FLAG antibodies (dilution of 1:200;
IBI, Kodak).
Cell lines, transfections, and apoptotic assays.
All cell
lines were grown in Dulbecco modified Eagle medium (Biological
Industries) supplemented with 10% fetal calf serum (Bio-Lab). For
transient transfection, 105 cells were seeded per well in a
six-well plate a day before transfection. Transfections were done by
the calcium phosphate method or by using SuperFect transfection reagent
(Qiagen). For cell death assays by overexpression, a mixture containing
1.5 µg of cell death-inducing plasmid (pCDNA3 expressing the
different DRP-1 constructs or mutant DAPk 
CaM [see below]) and 0.5 µg of plasmid pEGFP-NI (Clontech) was used. Nuclear staining of 293 cells transfected by the DRP-1 73 mutant was done 60 h after
transfection, using Hoechst dye (2 µg/ml; Molecular Probes). For the
cell death protection assays in Fig. 8B, the mixture consisted of 1.2 µg of DRP-1, 0.5 µg of a plasmid to be tested for cell death
protection (expressing the DAP kinase death domain [DAPk-DD], DN
[dominant negative] FADD, or luciferase as a negative control), and
0.5 µg of plasmid pEGFP-NI. For cell death protection assays in Fig.
8C, the mixture consisted of 1.3 µg of cell death-inducing plasmid
(either DRP-1 or wild-type DAP kinase), 0.75 µg of a plasmid to be
tested for cell death protection (expressing DRP-1 K42A or luciferase
as a negative control), and 0.5 µg of plasmid pEGFP-NI. For cell death protection from p55 TNFR shown in Fig. 8C, the mixture consisted of 0.1 µg of p55 TNFR, 1.6 µg of a plasmid to be tested for cell death protection (expressing DRP-1 K42A, FADD DD, or luciferase), and
0.5 µg of plasmid pEGFP-NI. Cells were counted and photographed 24 h after transfection. For each transfection, at least three fields, each consisting of at least 100 green fluorescent protein (GFP)-positive cells, were scored for apoptotic cells according to
their morphology. When indicated, cell lysates were prepared from the
transient transfection at 24 h for protein analysis. Transfections
of rat embryonic fibroblasts (REFs) and fluorescence-activated cell
sorting (FACS) analysis of transfected fibroblasts for DNA content
distribution were performed as previously described in detail
(21).
Coimmunoprecipitation assays.
293 cells grown in
90-mm-diameter plates (106 cells/plate) were cotransfected
with 5 µg of FLAG-tagged or HA-tagged DRP-1 and 20 µg of HA-tagged
or FLAG-tagged RFX1-SmaI (28) (deleted at amino acids 603 to 913), respectively, or with DRP-1-HA and DRP-1-FLAG (5 µg of
each). Immunoprecipitation of DRP-1 or RFX1-SmaI from 1 mg of total
extract was done with anti-FLAG M2 gel or Protein-G PLUS-agarose (Santa
Cruz Biotechnology) conjugated to anti-HA antibodies. Detection of
bound proteins was performed by Western blot analysis using anti-HA
antibodies (dilution of 1:1,000; BAbCo) or anti-FLAG antibodies. For
the deletion mutant study, 5 µg of FLAG-tagged full-length DRP-1 was
cotransfected with 5 µg of HA-tagged DRP-1 deletion mutants.
Immunoprecipitation of DRP-1 from 1 mg of total extract was performed
with anti-FLAG M2 gel as described above. Detection of
coimmunoprecipitated proteins (mutant or full-length DRP-1) was done
with anti-HA antibodies.
CaM overlay assay.
Transfections with the indicated
HA-tagged proteins into 293 cells, preparation of cell lysates,
immunoprecipitation, and immunoblotting were performed as previously
described in detail (6). The overlay assay was performed as
previously detailed (6). The membranes were preincubated for
1 h in CaM binding buffer (50 mM Tris-HCl [pH 7.5], 150 mM NaCl,
1 mM CaCl2) containing 5% nonfat dry milk powder.
Recombinant 35S-labeled CaM was added, and the membrane was
subjected to gentle shaking at room temperature for 16 h, washed
three times (5 min each) in CaM binding buffer, dried, and exposed to a
phosphorimager. The various proteins were detected with anti-HA
antibodies in a standard Western blot procedure.
Multiple sequence alignments and phylogenetic tree.
The
amino acid sequences were aligned manually according to Hanks and
Quinn's alignment (14), with refinements, using the ClustalX program. The phylogenic tree is based on the neighbor-joining method (paupsearch program; Genetics Computer Group package version 9).
Nucleotide sequence accession numbers.
The nucleotide
sequence reported in this paper has been submitted to the GenBank/EBI
data bank (accession no. AF052941). The murine DRP-1 is also deposited
at the GenBank/EBI Data Bank (accession no. AF052942).
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RESULTS |
Cloning of DRP-1.
To identify proteins that share homologous
sequences with DAP kinase, we searched expressed sequence tag (EST)
databases with the BLASTN program. Two ESTs from human and murine
origin showed remarkable amino acid homology to the catalytic domains
of DAP kinase and the recently identified protein ZIP kinase (79.5 and 80.2% identity, respectively). We performed a second EST search using
the 5' and the 3' ends of the human EST and identified a few more
overlapping ESTs. A putative novel cDNA sequence was generated and used
to design primers for cloning the full-length cDNA. PCR performed on
human spleen cDNA library amplified a 364-bp fragment that was further
used to screen the same library. The full-length cDNA was then
isolated, subcloned into BlueScript vector, and sequenced. The isolated
cDNA is 1,742 bp long, coding for a protein which comprises 360 amino
acids. The deduced amino acid sequence predicted a serine/threonine
kinase domain with all of the 12 characterized subdomains present
(14) (Fig. 1A). Sequence
alignment indicates that the catalytic domain of DRP-1 is 80%
identical to that of DAP kinase and ZIP kinase yet less identical
(50%) to the newly identified DRAK proteins (Fig. 1B). We performed a
multiple sequence alignment of 18 proteins that show high scores of
homology to the DAP kinase catalytic domain (not shown). This alignment
classifies a novel protein subfamily composed of DAP kinase, ZIP
kinase, DRP-1, and the Caenorhabditis elegans DAP kinase
(cDAPk). The DRAK proteins form another closely related group. Local
high-homology segments unique to this subfamily are the SRRGV loop
located between B and C and two amino acids (PR or PH) appearing
in 
8. Phylogenetic analyses, based on the multiple sequence
alignment of the catalytic domains and performed according to the
neighbor-joining (Fig. 1C), maximum-likelihood, and
maximum-parsimony methods (not shown), show that DAP kinase, ZIP
kinase, DRP-1, and cDAPk are indeed grouped into a distinct clade with
high bootstrap probabilities. DRAK1 and DRAK2 form another clade
sharing a putative common ancestor to the other DAP kinase-related
proteins. Similar to DAP kinase and unlike ZIP kinase, DRP-1 carries a
typical CaM-regulatory region adjacent to its catalytic domain
(extending between amino acids 288 and 320) (Fig. 1A and D). Compared
with other kinases such as CaM kinase IIa (CaKIIa) and MLC kinase
(MLCK), DRP-1 has the highest homology to DAP kinase in the
CaM-regulatory region (Fig. 1D). The remaining short stretch of 40 amino acids at the C-terminal part of DRP-1 (amino acids 320 to 360)
displays no homology to any known protein. Thus, beyond the catalytic
domain, DRP-1 differs considerably from DAP kinase. The latter is
longer (1,431 amino acids long) and displays a different multidomain
structure (see also the scheme in Fig. 8A).
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FIG. 1.
Sequence of the DRP-1 cDNA clone and alignments to
related kinases. (A) Nucleotide and deduced amino acid sequences of
human DRP-1. Initiation (ATG) and stop (TAA) codons are boxed. A
polyadenylation signal (ATTAAA) is underlined. The kinase
domain and the CaM-regulatory regions are in bold and underlined by
dashes, respectively. (B) Multiple sequence alignment of the
serine/threonine kinase domains of the related proteins DAP kinase, ZIP
kinase, DRP-1, and DRAK1 and -2. Alignment was done as described by
Hanks and Quinn (14). Identical amino acids are boxed;
homologous amino acids according to PAM250 matrix are shown in grey.
(C) Phylogenic rooted neighbor-joining tree of the 16 catalytic domains
belonging to proteins closely related to DAP kinase. Numbers shown are
bootstrap values. Confidence values lower than 50% are considered
unreliable. CaMKIIa was used as a representative of other CaM kinases
and was outgrouped to root the tree. smMLCK and skMLCK, smooth muscle
and skeletal MLCK, respectively. (D) Multiple sequence alignment of the
CaM-regulatory regions of DAP kinase, DRP-1, smMLCK, CaMKIIa, CaMKI,
and CaMKIV. Alignment was done manually, keeping the conserved (boxed)
regions aligned to each other. The corresponding region of ZIP kinase
which does not contain homology to DAP kinase and DRP-1 CaM-regulatory
regions is given at the bottom.
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Expression of recombinant and endogenous DRP-1.
To check the
mRNA expression of DRP-1, we prepared poly(A)+ RNA from
human cells (MCF-7 breast carcinoma cell line) and hybridized it to a
probe corresponding to the less conserved region of DRP-1 (nucleotides
977 to 1557). Two major mRNA transcripts approximately 1.9 and 3.8 kb
in size were detected (Fig. 2A). The
short mRNA transcript matches in its size to the cloned cDNA [i.e.,
1,742 bp plus the poly(A) tail], whereas the longer mRNA may
correspond to an alternatively spliced transcript or to some other,
unidentified mRNA. PCR analysis of various cDNA libraries and the data
gathered from EST searches indicate that human DRP-1 is widely
expressed and can be detected at least in the spleen, colon, breast,
and leukocytes (not shown).
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FIG. 2.
mRNA and protein expression of DRP-1. (A) Northern blot
analysis of DRP-1 mRNA. A 580-bp 3' fragment from the full-length cDNA
of DRP-1 was used to probe poly(A)+ RNA prepared from MCF-7
cells. (B) In vitro translation of DRP-1. In vitro-transcribed DRP-1
mRNA was programmed in reticulocyte lysate. The translated protein, 42 kDa in size, is shown. (C) Protein expression of recombinant DRP-1 in
HeLa cells. FLAG-tagged DRP-1 cloned in the pCDNA3 vector was
transfected into HeLa cells; 24 h following transfection, cells
were harvested and lysed. Extracted proteins were separated by SDS-PAGE
and then immunoblotted with anti-FLAG antibodies. A protein band at
~42 kDa is shown. (D and E) Expression of endogenous (endo.) DRP-1
protein. (D) Western analysis in which 100 µg of protein lysates of
MCF-7 cells (1) and 30 µg of protein lysates of 293 cells
transfected by DRP-1-FLAG (2) were separated by SDS-PAGE and
immunoblotted with 9% anti-DRP-1 serum. exo., exogenous. (E)
IP/Western analysis in which 3 mg of protein lysates of MCF-7 cells
(1) or 300 µg of protein lysates of 293 cells transfected
by DRP-1-FLAG (2) was immunoprecipitated overnight with (+)
or without () 50 µl of anti DRP-1 serum. The proteins were
separated by SDS-PAGE and immunoblotted with 9% anti-DRP-1 serum.
Arrows indicate positions of the endogenous and exogenous DRP-1 and the
position of immunoglobulin G (IgG) heavy-chain protein.
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In vitro transcription and translation assays, done with reticulocyte
lysates and the cloned DRP-1 cDNA as a template (starting
from the ATG
at positions 62 to 65), generated a single protein
band about 42 kDa in
size, as predicted by its sequence (Fig.
2B). We then cloned a
FLAG-tagged DRP-1 into pCDNA3 vector and
expressed it in HeLa cells. A
single band of about 42 kDa was
evident upon immunoblot analysis of the
cell lysates with anti-FLAG
antibodies (Fig.
2C).
Polyclonal antibodies were raised against the recombinant DRP-1
protein. When reacted with immunoblots containing human cell
lysates,
they recognized a band at the predicted size (it migrated
faster than
the recombinant FLAG-tagged protein; Fig.
2D, compare
lanes 1 to 2).
The other, higher bands, which reacted with the
anti-DRP-1 antibodies,
turned out to be nonspecific, since only
the 42-kDa protein could be
immunoprecipitated by the antibodies
(Fig.
2E, lane
1).
Cellular localization of ectopically expressed DRP-1.
To
determine the cellular localization of the exogenous DRP-1, we
expressed the FLAG-tagged DRP-1 in COS-7 cells. Immunoblot analysis
showed that DRP-1 is expressed in these cells (not shown). For the
immunostaining procedure, nontransfected and DRP-1-transfected COS-7
cells were fixed and reacted both with Oligreen for nuclear staining
and with anti-FLAG antibodies for DRP-1 staining. Specific DRP-1
staining was detected in the cytoplasm of these cells (Fig. 3A). We then performed a gentle cell
extraction with nonionic detergent (0.5% Triton X-100) that removes
lipids and soluble proteins, leaving intact the detergent-insoluble
matrix composed of the nucleus, the cytoskeleton framework, and
cytoskeleton-associated proteins. In contrast to the ectopically
expressed DAP kinase, which is exclusively localized to the
cytoskeleton and hence found only in detergent-insoluble fractions
(6) (Fig. 3B), DRP-1 was preferentially eluted from the
detergent-soluble fraction, with only a small amount remaining in the
insoluble fraction (Fig. 3B). Thus, we conclude that ectopically
expressed DRP-1 is a soluble, cytoplasmic protein with minor
association with insoluble matrix components.
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FIG. 3.
Intracellular localization of DRP-1 in COS-7 cells. (A)
COS-7 cells were transfected by a FLAG-tagged DRP-1 cloned in pCDNA3
vector, fixed and permeabilized in 1% formaldehyde, and treated with
methanol-acetone. Fixed cells were then reacted with Oligreen for
nuclear staining (green) and with anti-FLAG antibodies for DRP-1
detection (red). Cells were visualized under a fluorescence microscope.
(B) Detergent extraction of COS-7 cells. COS-7 cells were transfected
with a pCDNA3 vector expressing either FLAG-tagged DRP-1 or DAP kinase.
The cells were then extracted with 0.5% Triton X-100 to form soluble
fractions (Sol) and insoluble fractions (InSol) as described in
Materials and Methods. The protein extracts were separated by 10%
SDS-PAGE (10% gel) and blotted onto a nitrocellulose membrane. The
membrane was reacted with anti-FLAG antibodies.
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Intrinsic kinase activity of DRP-1.
To test whether DRP-1
functions as a kinase, as predicted from the amino acid sequence, we
performed an in vitro kinase assay using MLC as an exogenous substrate.
This substrate was chosen since it is phosphorylated by DAP kinase
(6). DRP-1 was transfected into human kidney 293 cells,
immunoprecipitated, and incubated with MLC in the presence and absence
of Ca2+ and CaM. Both MLC phosphorylation and DRP-1
autophosphorylation were evident (Fig.
4A). The addition of Ca2+/CaM
to the reaction mixture increased the amount of phosphorylated MLC,
suggesting that the enzyme is regulated by binding to CaM (Fig. 4A and
C). Indeed, the full-length DRP-1 could bind directly CaM, as assessed
by incubating membranes containing the immunoprecipitated protein with
labeled CaM (Fig. 4B). Truncation of the last 73 amino acids, a stretch
which includes the 33 amino acids of the CaM-regulatory domain (73
mutant), abolished CaM binding (Fig. 4B) and converted the enzyme to a
constitutively active form, fully functional in the absence of
externally added Ca2+/CaM and in the presence of EGTA (Fig.
4C). This gain of function in the catalytic activity is in accordance
with the assumption that, like DAP kinase, DRP-1 is negatively
regulated by the autoinhibitory CaM-binding domain and that this
inhibition is removed by the binding of Ca2+/CaM. A
catalytically inactive mutant of DRP-1 (DRP-1 K42A), did not
phosphorylate MLC and failed to undergo autophosphorylation even though
higher amounts of DRP-1 protein were present (Fig. 4A). Thus, DRP-1
functions in vitro as a kinase that is capable of phosphorylating
itself and an external substrate; the latter property is stimulated by
the addition of Ca2+ and CaM.
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FIG. 4.
In vitro kinase activity and CaM binding of DRP-1. (A)
DRP-1-FLAG and DRP-1-FLAG mutant (K42A) proteins were assayed in vitro
for kinase activity in the presence or absence of Ca2+/CaM
as described in Materials and Methods. The proteins were resolved by
SDS-PAGE on an 11% gel and blotted to a nitrocellulose membrane. Top,
autophosphorylation of DRP-1 (42 kDa) and MLC phosphorylation (17 kDa),
respectively, after exposure to X-ray film; bottom, DRP-1 proteins
after incubation of the same blot with anti-FLAG antibodies and ECL
detection. (B) Cell lysates were prepared from 293 cells transfected
with wild-type (WT) DRP-1-HA or DRP-1-HA 73 mutant and separated by
PAGE-SDS on a 12% gel. Blotted proteins were reacted with recombinant
35S-labeled CaM (left); exogenous proteins were detected
with anti-HA antibodies in a standard Western blot procedure (right).
(C) Graph showing the relative amount of MLC phosphorylation by
wild-type DRP-1 or DRP-1 73 mutant in the presence or absence of
Ca2+/CaM. Phosphorylation levels were determined by
phosphorimaging of 32P-labeled MLC bands. Values were
normalized according to the DRP-1 recombinant protein levels used in
each phosphorylation assay. Phosphorylation of MLC by DRP-1 73 in
the absence of Ca2+/CaM was taken as the maximal
phosphorylation activity.
|
|
DRP-1 induces apoptosis in a variety of cell lines.
The high
homology to DAP kinase in the kinase and CaM-binding regions prompted
us to check whether DRP-1 is involved in apoptosis. The wild-type DRP-1
and the catalytic inactive mutant of DRP-1 (DRP-1 K42A), each cloned in
pCDNA3 vector, were transfected into 293 cells. To quantitate the
number of apoptotic cells, we cotransfected these constructs with a
vector expressing GFP. The latter was used as a marker to visualize the
transfected cells and to assess the apoptotic frequency among the
transfectants according to morphological alterations. Apoptotic cells
were scored after 24 h. Overexpression of DRP-1 resulted in
apoptotic cell death (50 to 60%), compared to the basal level of
apoptotic cells caused by transfection of a nonrelevant (luciferase)
gene (Fig. 5A and C). The first and very
prominent morphological changes occurred at the membrane level, since a
major fraction of the GFP-positive green cells showed cytoplasmic
blebbing (26) (Fig. 5A-3). In addition, some of the
transfected cells detached from the plate. DNA staining by Hoechst was
used to monitor the status of the nucleus in the DRP-1-transfected
cells, at 60 h posttransfection. Most of the GFP-positive cells
displayed condensed nuclei; some of the nuclei appeared fragmented
(Fig. 5B). In these experiments, the activated DAP kinase mutant
lacking the autoinhibitory CaM-regulatory region (DAPk CaM) yielded
apoptotic values of 70 to 80% (Fig. 5C). In contrast, when these cells
were transfected with the kinase-inactive mutant of DRP-1 (DRP-1 K42A;
Fig. 5A-4 and C), no apoptosis was observed. Western blot analysis of
transfected cells with anti-FLAG antibodies confirmed the expression of
both the exogenous wild-type and K42A mutant versions of DRP-1 (Fig.
5D). Similar results were observed in human SV-80 fibroblasts (not
shown).
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FIG. 5.
Ectopic expression of DRP-1 induces cell death. (A) 293 cells (105 cells/well) were cotransfected with FLAG-tagged
wild-type DRP-1 or K42A mutant DRP-1 (1.5 µg/well) and GFP (0.5 µg/well). GFP-positive cells were visualized under a fluorescence
microscope and scored for appearance of apoptotic morphology 24 h
after transfection. Apoptotic cells are indicated by arrows. Images 1 to 4 correspond to 293 cells transfected by pCDNA3-luciferase (negative
control), pCDNA3-CaM DAP kinase (positive control), pCDNA3-DRP-1,
and pCDNA3-DRP-1 K42A. (B) Nuclear staining of DRP-1-transfected cells.
Top, GFP staining of 293 cells transfected by DRP-1 73 mutant (1.5 µg/well); bottom, Hoechst nuclear staining of the same cells.
Pictures were taken 60 h posttransfection. Solid arrows, cells
with condensed and fragmented chromatin; dashed arrows, cells with
condensed chromatin. (C) Scores of apoptotic cells. Graphs show the
percentage of apoptotic cells resulting from the above-mentioned
transfections (mean ± standard deviation calculated from
triplicates of 100 cells each). The scores were taken from the same
experiment as shown in panel A. This experiment was repeated six times
with reproducible results. (D) DRP-1 protein expression in transfected
293 cells. Proteins extracted from the transfected cells were separated
by SDS-PAGE on a 10% gel and blotted to a nitrocellulose membrane. The
blot was reacted with anti-FLAG antibodies for DRP-1 detection and
antivinculin antibodies (dilution of 1:300; Sigma) to quantitate the
loaded protein amounts. The proteins were prepared from the same
experiment as shown in panel A.
|
|
The effect of ectopically expressed DRP-1 on the DNA content of primary
REFs was also assessed, as previously described in
detail
(
21). REFs were cotransfected with DRP-1 and a
membrane-bound
form of GFP and after 48 h subjected to FACS
analysis of their
DNA content. A fraction of cells displaying a
sub-G
1 DNA content
(27%), indicative of cells containing
fragmented DNA, appeared
exclusively in the DRP-1-transfected cells,
not in cells transfected
with a control vector (7%) or with the DRP-1
K42A mutant (9%).
No effect on cell cycle distribution of the viable
cells was found
(not
shown).
Deletion of the C-terminal tail of DRP-1 abolishes its apoptotic
activity, while further truncation of the CaM-regulatory region
strongly enhances the apoptotic effect.
To further understand the
mode of DRP-1 action in apoptosis, we generated constructs containing
C-terminal truncations of DRP-1 tagged by HA (Fig.
6A). DRP-1 40 lacks the most
C-terminal part of DRP-1, which displays no homology to any known
protein. DRP-1 73 lacks, in addition to that, the CaM-regulatory
region of DRP-1, and DRP-1 85 contains only the catalytic domain.
The wild-type DRP-1 and the various truncation mutants of DRP-1 were transfected into 293 cells at comparable amounts (see the legend to
Fig. 6). Induction of apoptotic cell death was assessed by scoring
GFP-positive cells. Overexpression of the wild-type DRP-1 in these
experiments resulted in apoptosis (25%), while DRP-1 40 had no
effect in these assays. On the other hand, further truncations of the
CaM-regulatory region yielded mutants (73 and 85) which acted as
"superkillers" (~90% apoptosis) (Fig. 6B and C). Western blot
analysis of transfected cells with anti-HA antibodies confirmed the
expression of all DRP-1 forms (Fig. 6D). These experiments support the
finding that the apoptotic effect of DRP-1 is dependent on its kinase
activity, since as shown in Fig. 4, removal of the autoinhibitory
CaM-regulatory region generates a constitutively active kinase. In
addition, these experiments revealed the existence of a positive module
in the C-terminal region of DRP-1, which is necessary for its
proapoptotic effect, provided that the CaM-regulatory region is still
present. In the absence of the CaM-regulatory region, the C-terminal
tail becomes dispensable.
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FIG. 6.
Ectopic expression of DRP-1 deletion mutants. (A)
Schematic representation of DRP-1 deletion mutants. (B) Scores of
apoptotic cells. Graphs show the percentage of apoptotic cells
resulting from cotransfections of 293 cells with 1.2 µg of HA-tagged
wild-type DRP-1 or various deletion mutants of DRP-1 (mean ± standard deviation calculated from triplicates of 100 cells each). This
experiment was repeated three times with reproducible results. (C)
Pictures were taken from the experiment described above, corresponding
to 293 cells transfected with pCDNA3-luciferase (Luc.; negative
control), pCDNA3-DRP-1, pCDNA3-DRP-1 40, pCDNA3-DRP-1 73, and
pCDNA3-DRP-1 85. (D) DRP-1 protein expression in transfected 293 cells. Proteins extracted from the transfected cells were separated by
SDS-PAGE on a 10% gel and blotted to nitrocellulose membrane. The blot
was reacted with anti-HA antibodies for DRP-1 detection and
antivinculin antibodies to quantitate the loaded protein amounts. The
proteins were prepared from the same experiment as shown in panel B.
|
|
The C-terminal part of DRP-1 functions as a homodimerization
domain.
Western analysis performed on proteins extracted from 293 cells transfected with FLAG-tagged DRP-1 revealed, in some cases, an
additional band of approximately 85 kDa (not shown). This observation led us to test whether DRP-1 can undergo homodimerization. To this end,
we cotransfected two constructs expressing DRP-1 fused to either a FLAG
or an HA tag into 293 cells and performed classical pull-down
experiments with each of the two epitopes. FLAG-tagged DRP-1 was shown
to bind specifically HA-tagged DRP-1 in both immunoprecipitation directions (Fig. 7A, lanes 3 in both IP
panels). No binding of DRP-1-HA to FLAG beads or to the irrelevant
cytoplasmic protein RFX-SmaI (28) could be observed (Fig.
7A, IP anti-FLAG panel, lane 2 or lanes 1 and 2, respectively). Also,
we could not detect nonspecific binding of DRP-1-FLAG to HA beads or to
RFX-SmaI protein (Fig. 7A, IP anti-HA panel, lane 1 or lanes 1 and
2, respectively). Western analysis confirmed the expression of all
proteins in these cell extracts (Fig. 7A, Western panels).
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FIG. 7.
DRP-1 undergoes homodimerization via its C-terminal
tail. (A) Wild-type DRP-1 undergoes specific homodimerization. 293 cells growing in 90-mm-diameter plates were cotransfected with the
following constructs: lane 1, DRP-1-FLAG (5 µg) plus RFX1-SmaI-HA
(20 µg; used as an intrinsic control to rule out nonspecific binding
of DRP-1-FLAG to HA beads or to an irrelevant gene); lane 2, RFX-SmaI-FLAG plus DRP-1-HA (control to rule out nonspecific
attachment of DRP-1-HA to FLAG beads or to an irrelevant gene); lane 3, DRP-1-FLAG plus DRP-1-HA. Cell extracts were immunoprecipitated with
either anti-FLAG antibodies (left) or anti-HA antibodies (right). The
total levels of transfected proteins are shown on immunoblots. (B)
Truncation of C-terminal 40 amino acids of DRP-1 abolishes its
homodimerization. Lanes 1 to 4 correspond to cotransfections (5 µg of
each construct per 90-mm-diameter plate) with DRP-1-FLAG plus DRP-1-HA,
DRP-1-FLAG plus DRP-1-40-HA, DRP-1-FLAG plus DRP-1-73-HA, and
DRP-1-FLAG plus DRP-1-85-HA, respectively. The lower panel
quantitates the immunoprecipitation efficiency of DRP-1-FLAG with the
anti-FLAG antibodies. Solid arrows, immunoprecipitated DRP-1; short
arrow, immunoprecipitated DRP-1 40; arrowhead, RFX-SmaI;
asterisk, nonspecific band.
|
|
Next we tried to map the domain which may be required for the
homodimerization of DRP-1. To this end, DRP-1-FLAG was expressed
in
tandem with the various deletion mutants of DRP-1 tagged by
HA. We
could detect strong binding of DRP-1-FLAG to the wild-type
DRP-1-HA, whereas binding to DRP-1
40,
73, and
85
was minimal
or undetectable (Fig.
7B, upper IP panel, compare lane
1 to lanes
2 to 4). Western analysis confirmed the expression of
wild-type
DRP-1-HA and all other DRP-1-HA deletion mutants in these
transfections
(Fig.
7B, Western panel). The lower IP panel depicts the
presence
of wild-type DRP-1-FLAG in all these immunoprecipitates.
Thus,
we concluded that a region spanning the C-terminal 40 amino
acids
of DRP-1 is required for its homodimerization. This
homodimerization
is probably required for the apoptotic effect of
DRP-1, since
DRP-1-
40 lost the ability to induce apoptosis in 293 cells (Fig.
6B and
C).
DAP kinase death domain protects from DRP-1-induced apoptosis.
The sequence homology between DRP-1 and DAP kinase within the catalytic
domain, the common regulation by Ca2+/calmodulin, and the
finding that both proteins induced apoptosis upon overexpression raised
the possibility that they function along a common apoptotic pathway. To
assess a possible functional cross talk between the two kinases,
dominant negative mutants derived from each of the two kinases were
used. We first tested whether a fragment of DAP kinase encompassing the
death domain (DAPk DD) affected DRP-1-induced cell death. This fragment
of DAP kinase was previously shown to act as a specific dominant negative mutant, negating the effects of the full-length protein when
ectopically expressed (7). Interestingly, we found by cotransfection experiments that DAPk DD protected 293 cells from cell
death induced by DRP-1 (Fig. 8B). A control transfection including
DRP-1 and a nonrelevant luciferase DNA excluded the possibility that
inhibition is simply due to larger amount of DNA used in the
transfection. Moreover, the effect of DAPk DD was specific, since the
death domain of FADD (also named DN FADD) failed to manifest a similar
effect (Fig. 8B). Western blot analysis of transfected cells using anti-FLAG antibodies confirmed the expression of the exogenous DRP-1 in all transfections (Fig. 8B).
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FIG. 8.
Death protection assays. (A) Schematic representation of
DRP-1 and DAP kinase. (B) DAP kinase death domain protects from
DRP-1-induced cell death. Top, 293 cells (105 cells/well)
were cotransfected with FLAG-tagged wild-type DRP-1 and GFP (0.5 µg/well) as described for Fig. 5. To each transfection the indicated
plasmid (DAPk DD, DN FADD, or luciferase [Luc.] in pCDNA3) was also
added (0.5 µg/well). Scores are percentages of apoptotic cells given
as the mean ± standard deviation and calculated from triplicates
of 100 cells each. This experiment was repeated three times with
reproducible results. Bottom, DRP-1 protein expression in transfected
293 cells. Proteins extracted from the transfected cells were separated
by SDS-PAGE on a 10% gel and blotted to a nitrocellulose membrane. The
blot was reacted with anti-FLAG antibodies for DRP-1 detection and
antivinculin antibodies to quantitate the loaded protein amounts. The
proteins were prepared from the same experiment shown in the top part
of panel B. (C) DRP-1 K42A mutant protects from DRP-1 and p55
TNFR-induced cell deaths. Top, 293 cells (105 cells/well)
were cotransfected with HA-tagged wild-type DRP-1 or HA-tagged
wild-type DAP kinase (1.3 µg/well; left) or p55 TNFR (0.1 µg/well;
right) and GFP (0.5 µg/well) as described for Fig. 5. To each
transfection was added: the indicated plasmid DRP-1-FLAG K42A or
luciferase in pCDNA3 (0.75 µg/well; left) or DRP-1-FLAG K42A, FADD
DD, or luciferase in pCDNA3 (1.6 µg/well; right). Scores are the
percentage of apoptotic cells given as the mean ± standard
deviation and calculated from triplicates of 100 cells each. This
experiment was repeated three times with reproducible results. Bottom,
DRP-1-HA, HA-DAP kinase, and DRP-1-FLAG K42A protein expression in 293 transfected cells. The proteins were prepared from the same experiment
as shown in the upper part of panel C.
|
|
In the reciprocal experiment, the catalytically inactive DRP-1 K42A
mutant (FLAG tagged) was assayed in cotransfection experiments,
assuming that it will function in a dominant negative manner.
To test
this possibility, the mutant was first cotransfected with
the wild-type
DRP-1 (HA tagged) and was found to confer protection
against the
apoptotic effects of the wild-type protein without
affecting its
expression levels (Fig.
8C). The latter observation
attributed to this
mutant a moderate yet significant neutralizing
function against
wild-type DRP-1. Nevertheless, when cells were
killed by DAP kinase,
the extent of protection which was conveyed
by DRP-1 K42A was
significantly less despite the fact that the
direct target, i.e., the
endogenous DRP-1, is expressed at lower
levels than the recombinant
DRP-1 in the previous experiments.
In contrast, the same mutant was
effective in protecting 293 cells
from cell death induced by another
stimulus
the ectopically expressed
p55 TNFR (Fig.
8C; the death domain
of FADD, which is a potent
blocker of TNF signaling at the receptor
level, served as a positive
control). Together, the cotransfection
experiments suggest that
in certain genetic constellations, the
death-promoting effects
of DRP-1 may depend on active DAP kinase
whereas a major yet not
exclusive molecular arm emanating from DAP
kinase is refractory
to DRP-1
inactivation.
| |
DISCUSSION |
In this study we describe the cloning and characterization of a
novel serine/threonine kinase with remarkable homology to the catalytic
and CaM-regulatory domains of DAP kinase. This kinase, named DRP-1, is
a 42-kDa cytoplasmic protein which when ectopically expressed exhibits
minor associations with insoluble matrix elements. Another protein, ZIP
kinase, which by virtue of its sequence homology to the kinase domain
of DAP kinase is also a member of the DAP kinase-related protein
subfamily, was recently identified (17, 22). Unlike DAP
kinase and DRP-1, ZIP kinase is a nuclear protein which, instead of
being regulated by a CaM-binding domain, is activated only by
homodimerization via its leucine zipper motifs (17). ZIP
kinase-induced cell death is controlled by its ability to undergo
homodimerization. To this group of kinases, another two less homologous
nuclear proteins, DRAK1 and DRAK2, were recently added (29).
Together they form a novel subfamily of serine/threonine kinases, as is
evident from multiple sequence and phylogenetic analyses.
To check the cellular functions of DRP-1, we overexpressed wild-type
DRP-1 in various cell lines and found that it induced apoptosis as
measured by various parameters. Unlike the wild-type DRP-1, a
kinase-inactive mutant of DRP-1 (DRP-1 K42A) did not induce apoptosis,
although it was expressed at a similar level in the transfected cells.
In vitro kinase assays confirmed that DRP-1 K42A is indeed unable to
phosphorylate the MLC substrate. Such dependence on the catalytic
activity for apoptotic function is apparent also in the other members
of DAP kinase-related proteins (17, 29). In addition, a
truncated form of DRP-1 which lacks the CaM-regulatory region displayed
a constitutively active kinase and induced very high levels of
apoptosis, thus further confirming the dependence of apoptosis on the
overall catalytic activity.
The deletion mutant study presented here confirms the existence of yet
another module responsible for apoptotic induction, which is located at
the C-terminal part of DRP-1. This part of DRP-1 is also essential for
its dimerization. Thus, we can conclude that homodimerization is a
requirement for the functionality of this kinase in apoptosis, although
this property can be completely overridden by a further deletion of the
CaM-regulatory region. It is presently not clear how the dimerization
influences the death-promoting effects of DRP-1 and whether
self-dimerization has an impact on the catalytic activity. Another
challenging question is why the C-terminal tail is functionally
required only when the CaM-regulatory domain is present. So far, the
conventional conditions of in vitro phosphorylation assays have not
resolved the issue (not shown), and it is clear that some fine-tuning
of the biochemical assessments is required.
The high homology in the kinase domains of DAP kinase and DRP-1 and the
finding that they are both localized to the cytoplasm (in either
soluble or insoluble form) imply that they may use the same or closely
related substrates. The phosphorylation sites for these kinases on the
substrate may be either different or identical. Thus, these kinases may
cooperate to induce apoptosis in the same cell type or, alternatively,
may function independently in different cell types, tissues, or organs
in response to different stimuli or in different time frames. Another
possibility is that these kinases act sequentially along the same
signaling pathway to induce apoptosis. Here we provide the first
observations that support the assumption that these kinases may be
functionally linked to each other in some constellations. This is
illustrated by the ability of a dominant negative form of DAP kinase
(DAPk DD) to block apoptosis induced by DRP-1. Also the finding that both, DAP kinase (7) and DRP-1 (Fig. 8C) mediate killing by TNF is consistent with this scenario. These results indicate the need
for a long-term study to establish whether direct or indirect interactions exist between DAP kinase and DRP-1. It should be mentioned
that in the reciprocal approach, the effect of the dominant negative
DRP-1 on DAP kinase was much less pronounced. A simple interpretation
of these data would be to place DRP-1 upstream to DAP kinase; however,
a definitive conclusion still awaits detailed biochemical data on the
nature of the cross talk between these two kinases. Finally, it will be
of interest to study whether DRP-1, like DAP kinase, acts as a tumor
suppressor gene, subjected to loss of function in human tumors.
| |
ACKNOWLEDGMENTS |
The first two authors contributed equally to this work.
We thank D. Wallach for providing the expression vector carrying the
DN-MORT, M. Rubinstein for the Clontech spleen cDNA library, and Y. Shaul for the RFX-SmaI construct. We thank T. Raveh for conducting
the REF death assays.
This work was supported by the Israel Foundation, which is administered
by the Israel Academy of Science and Humanities, and by QBI Ltd. A.K.
is the incumbent of the Helena Rubinstein Chair of Cancer Research.
| |
ADDENDUM IN PROOF |
After the submission of the manuscript, a work describing some
initial characteristics of human and mouse DRP-1 homologues was
published (T. Kawai, F. Nomura, K. Hoshino, N. G. Copeland, D. J. Gilbert, N. A. Jenkins, and S. Akira, Oncogene
18:3471-3480, 1999).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Molecular Genetics Weizmann Institute of Science, Rehovot 76100, Israel. Phone: (972) 8-9342428. Fax: (972) 8-9344108. E-mail:
lvkimchi{at}weizmann.weizmann.ac.il.
| |
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Molecular and Cellular Biology, February 2000, p. 1044-1054, Vol. 20, No. 3
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
