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Mol Cell Biol, August 1998, p. 4863-4871, Vol. 18, No. 8
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Structure-Function Analysis of Qk1: a Lethal Point
Mutation in Mouse quaking Prevents
Homodimerization
Taiping
Chen and
Stéphane
Richard*
Terry Fox Molecular Oncology Group, Lady
Davis Institute for Medical Research, Sir Mortimer B. Davis Jewish
General Hospital, and Departments of Oncology, Medicine, and
Microbiology and Immunology, McGill University, Montréal,
Québec H3T 1E2, Canada
Received 17 February 1998/Returned for modification 24 March
1998/Accepted 18 May 1998
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ABSTRACT |
Qk1 is a member of the KH domain family of proteins that includes
Sam68, GRP33, GLD-1, SF1, and Who/How. These family members are RNA
binding proteins that contain an extended KH domain embedded in a
larger domain called the GSG (for GRP33-Sam68-GLD-1) domain. An
ethylnitrosourea-induced point mutation in the Qk1 GSG domain alters
glutamic acid 48 to a glycine and is known to be embryonically lethal
in mice. The function of Qk1 and the GSG domain as well as the reason
for the lethality are unknown. Here we demonstrate that the Qk1 GSG
domain mediates RNA binding and Qk1 self-association. By using in situ
chemical cross-linking studies, we showed that the Qk1 proteins exist
as homodimers in vivo. The Qk1 self-association region was mapped to
amino acids 18 to 57, a region predicted to form coiled coils.
Alteration of glutamic acid 48 to glycine (E
G) in the Qk1 GSG domain
(producing protein Qk1:EG) abolishes self-association but has no
effect on the RNA binding activity. The expression of Qk1 or Qk1:EG
in NIH 3T3 cells induces cell death by apoptosis. Approximately 90% of
the remaining transfected cells are apoptotic 48 h after
transfection. Qk1:EG was consistently more potent at inducing
apoptosis than was wild-type Qk1. These results suggest that the mouse
quaking lethality (EG) occurs due to the absence of Qk1
self-association mediated by the GSG domain.
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INTRODUCTION |
The mouse quaking gene
encodes the Qk1 RNA binding proteins (11). The type of RNA
binding domain found in Qk1, known as a KH domain, was originally
identified in the heterogeneous nuclear ribonucleoprotein K (hnRNP K
[17, 35]). KH domains are evolutionary conserved
domains that are thought to make direct protein-RNA contacts with a
three-dimensional 
-fold (29). The Qk1 KH
domain is embedded in a larger conserved domain of ~200 amino acids
called the GSG domain. The GSG domain was initially identified by
aligning the first three family members (GRP33, Sam68, and GLD-1
[22]). The boundaries of this new protein module have become clearer with the identification of new family members (1, 11). This domain is also called STAR (for signal transduction and
activator of RNA [39]) and the SGQ (Sam68, GLD-1, and
Qk1 [25]) domain. GSG domain family members include
Artemia salina GRP33 (9), human Sam68
(41), Caenorhabditis elegans GLD-1 (22), human SF1 (1), Drosophila
Who/How (2, 16, 42), Xenopus Xqua
(44), and mouse Qk1 (11). The features of the GSG
domain include a single KH domain that is longer than most other KH
domains (29). In addition to the KH domain, the GSG domain
is composed of ~75 amino acids N-terminal and ~25 amino acids
C-terminal of the KH domain (for a review, see reference 39). These regions in the Qk1 GSG domain are called
QUA1 and QUA2, respectively (11).
GSG proteins share several properties, including RNA binding (1,
8, 25, 41, 44) and self-association (8, 45). With the
exception of the human SF1 protein, which functions as a splicing
factor (1), the roles of the GSG proteins in cellular processes are not known. Genetic studies with GSG domain proteins have
demonstrated the roles of these proteins in development, differentiation, myelination, and tumorigenesis. In C. elegans, GLD-1 is required for germ cell differentiation (14,
15, 22). One class of alleles results in a recessive tumorous
germ line phenotype, suggesting that GLD-1 functions as a tumor
suppressor (22). The Qk1 proteins of Drosophila
melanogaster, Xenopus laevis, and mice have been
characterized. The Drosophila Who/How protein, a Qk1
homolog, has been shown to be critical for skeletal muscle development
since weak alleles result in flies with "held-out" wings (2,
42). One such allele contains a point mutation in loop 4 of the
Who/How KH domain (2). The Xenopus Xqua protein, another Qk1 homolog, has been shown to be necessary for notochord development (45). Mice that are homozygous for the
quaking viable allele have a severe deficiency of myelin
throughout their nervous systems and, as a consequence, develop a
characteristic tremor (34). The genetic lesion in the
quaking viable mouse has been mapped to the qk1
promoter-enhancer region (11). The defect in these mice is
the absence of Qk1-6 and Qk1-7 protein expression from the
myelin-forming oligodendrocytic cells (19). Another class of
mouse quaking mutations is embryonic lethal (7, 23, 33). One such allele, qkkt4, was found to
alter glutamic acid 48 to glycine in the QUA1 region of the Qk1 GSG
domain (11); the cause for the lethality is unknown.
We have characterized the genetic point mutations identified in GLD-1
and Qk1 by using Sam68 (8). Substitution of the
corresponding GLD-1 glycine 227 to aspartic acid in Sam68 abolishes RNA
binding, suggesting that the mutation alters GLD-1 RNA binding in
C. elegans. Substitution of the corresponding GLD-1 glycines
248 and 250 to arginines in Sam68 abolishes self-association,
suggesting that some of the GLD-1 loss-of-function phenotypes observed
in C. elegans may be due to the absence of protein-protein
interactions. However, the replacement of Qk1 glutamic acid 48 by
glycine in Sam68 had no effect on Sam68 RNA binding and oligomerization
(8). Therefore, to better understand Qk1 and its lethal
point mutation, we characterized the properties of these proteins in
vitro and in vivo. Here we report that Qk1 self-associates into dimers
via a GSG domain region predicted to form coiled coils. The
introduction of the Qk1 lethal point mutation altering glutamic acid
48, located in the predicted coiled-coil region, to a glycine (E48G;
resulting protein, Qk1:EG) abolished self-association. We also
demonstrated that the expression of Qk1 and Qk1:EG in NIH 3T3 cells
induces apoptosis. These data implicate GSG domain-mediated
self-association in the normal function of Qk1.
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MATERIALS AND METHODS |
DNA constructions.
The deletion constructs encoding
Qk1:1-205, Qk1:1-180, and Qk1:81-325 were generated by PCR with
myc-Qk1 (8) as a DNA template. The sequences of the
oligonucleotide pairs used are 5'-CTG GAA TTC GGT CGG
GGA AAT GGA AAC GAA GG-3' and 5'-ATG GAA TTC TAT
CTG TAG GTG CCA TTC AG-3' (for Qk1:1-205), 5'-CTG GAA
TTC GGT CGG GGA AAT GGA AAC GAA GG-3' and 5'-TCA
GAA TTC TAT ACC AGT AAC TTC TTC AC-3' (for
Qk1:1-180), and 5'-ACC GAA TTC TCA GTT ACA AGA GAA ACT T-3' and 5'-GCT GAA TTC TAG TCC TTC ATC CAG
CAA GTC-3' (for Qk1:81-325). The amplified DNA fragments were
digested with EcoRI (the restriction sites are underlined)
and subcloned into the EcoRI site of myc-Bluescript KS+
(32) and hemagglutinin (HA)-Bluescript KS (8).
Myc-Qk1:EG was constructed by inverse PCR with myc-Qk1 as a DNA
template and the following oligonucleotides as primers: 5'-GGA ATT AGC AGA GTA CGG AAA GAC-3' and
5'-TTC GTC CAG CAG CCG CTC GAG-3'. HA-Qk1:EG was
generated by subcloning the EcoRI fragment of myc-Qk1:EG
into HA-Bluescript KS. The constructs encoding HA-Qk1, myc-GLD-1,
myc-GRP33, and HA-GRP33 were previously described (8). The
plasmids encoding glutathione S-transferase (GST)-Qk1 and
GST-Qk1:EG fusion proteins were constructed by a two-step subcloning
strategy. The BamHI-XhoI fragment of myc-Qk1 was
first inserted in the corresponding sites of pGEX-KG, generating
pGST-Qk1(BamHI-XhoI). The XhoI
fragments of myc-Qk1 and myc-Qk1:EG were subcloned into the
XhoI site of pGST-Qk1(BamHI-XhoI),
resulting in pGST-Qk1 and pGST-Qk1:EG, respectively. The GST-Qk1
deletion constructs were generated by PCR amplification with myc-Qk1 as
the DNA template. For Qk1:1-80, Qk1:1-57, and Qk1:1-37, the T7
primer was used as the forward primer and the following
oligonucleotides were used as the reverse primers: 5'-CTC
TCT AGA CTA AAC AAT GGG TCC CAC CGC-3' (for
Qk1:1-80), 5'-TAA TCT AGA CTA GTA CAT GTC TTT CCG TAC-3' (for Qk1:1-57), and 5'-GAA TCT AGA TCA
GAA GTT GGG CAG GCT GCT-3' (for Qk1:1-37). The DNA fragments
encoding Qk1:18-57 and Qk1:28-57 were generated by using the reverse
primer employed for Qk1:1-57 and the following forward primers:
5'-CCA GGA TCC TTG ATG CAG CTG ATG AAC-3' (for
Qk1:18-57) and 5'-AAG GGA TCC ATG AGC AGC CTG CCC
AAC-3' (for Qk1:28-57). The oligonucleotides used to generate
Qk1:38-80 were 5'-TGC GGA TCC TTC AAC CAC CTC GAG
CGG-3' and 5'-CTC TCT AGA CTA AAC AAT GGG TCC
CAC CGC-3'. All of the amplified fragments were digested with
BamHI and XbaI (the underlined nucleotide
sequences denote the restriction sites) and subcloned into the
corresponding sites of pGEX-KG. The GST proteins were purified by
affinity chromatography with glutathione beads. The purified GST
proteins were covalently coupled to Affi-Gel 10 (Bio-Rad) as described
previously (32). The green fluorescence protein (GFP) fusion
constructs GFP-Qk1 and GFP-Qk1:EG were generated by subcloning the
EcoRI DNA fragments of myc-Qk1 and myc-Qk1:EG, respectively, into vector pEGFP-C1 (Clontech). pcDNA-Qk1,
pcDNA-Qk1:EG, and pcDNA-GLD-1 were generated by subcloning the
EcoRI fragments of myc-Qk1 and myc-Qk1:EG and the
XhoI fragment of myc-GLD-1, respectively, into the
corresponding sites of myc-pcDNA. myc-pcDNA was constructed by
digesting myc-Bluescript KS+ (32) with BamHI and
XhoI and subcloning the DNA fragment in the corresponding sites of pcDNA1 (Invitrogen). The identities of the plasmid constructs were verified by dideoxynucleotide sequencing with Sequenase (U.S. Biochemical).
Protein expression and analysis.
Proteins were expressed in
HeLa cells, using the vaccinia virus T7 expression system as described
previously (32). The HeLa cells were lysed in lysis buffer
(1% Triton X-100, 150 mM NaCl, 20 mM Tris-HCl [pH 8.0], 50 mM NaF,
100 µM sodium vanadate, 0.01% phenylmethylsulfonyl fluoride, 1 µg
of aprotinin per ml, 1 µg of leupeptin per ml), and the cellular
debris and nuclei were removed by centrifugation. For
immunoprecipitations, cell lysates were incubated on ice with the
appropriate antibody for 1 h; then 20 µl of a 50% protein
A-Sepharose slurry was added, and the mixture was incubated at 4°C
for 30 min with constant end-over-end mixing. The beads were washed
twice with lysis buffer and once with phosphate-buffered saline (PBS).
The samples were analyzed by sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (SDS-PAGE) and transferred to nitrocellulose membranes.
For GST pull-down assays, 20 µl of 50% slurry containing 2 mg of GST
fusion protein, covalently coupled to beads, per ml was incubated with
cell lysate expressing HA-Qk1 for 1 h with constant mixing. The
samples were washed and analyzed as described previously
(32). Immunoblotting was performed with anti-myc 9E10
(12), anti-HA, or anti-Qk1 rabbit polyclonal antibody. The
anti-Qk1 antibody was generated by using GST-Qk1 (81-180) as an
antigen. The designated primary antibody was followed by goat
anti-mouse or goat anti-rabbit antibodies conjugated to horseradish peroxidase (Organon Teknika-Cappel), and chemiluminescence (Dupont) was
used for protein detection.
In situ chemical cross-linking and analysis of Qk1 dimers.
HeLa cells transfected with Qk1 plasmids and rat C6 glioma cells
(American Type Culture Collection) were treated in situ with 1 mM
bis(maleimido)hexane (BMH) and analyzed as described previously (8). Rat astrocytes and oligodendrocytes were prepared by
Guillermina Almazan (McGill University) as described elsewhere
(31). Dimer formation was analyzed in HeLa cells transfected
with myc-Qk1 and HA-Qk1. The transfected cells were treated with BMH in
situ, and the cell lysates were immunoprecipitated with anti-myc
antibody or mouse immunoglobulin G (IgG). The bound proteins as well as the cell lysates were separated by SDS-PAGE, transferred to
nitrocellulose membranes, and immunoblotted with anti-HA antibody.
RNase treatment and RNA binding analysis.
RNase treatment
was carried out by incubating cell lysates at 37°C for 1 h with
RNase A (Boehringer Mannheim) at 1 mg/ml. Incubating the cell lysates
at 37°C without RNase A was considered a mock treatment. RNA binding
studies were carried out by incubating Qk1 immunoprecipitates with
radiolabeled total cellular RNA. To obtain radiolabeled RNA, HeLa cells
were incubated overnight with 50 µCi of
[32P]orthophosphate (Dupont)/ml in phosphate-free
Dulbecco's modified Eagle's medium (ICN). The cells were harvested,
and RNA was extracted by using an RNeasy Mini Kit (Qiagen). myc-Qk1
expressed in HeLa cells was immunoprecipitated with anti-myc antibody
or mouse IgG (control). The immunoprecipitates were incubated at 4°C
for 30 min with 32P-labeled RNA (3 × 106
cpm) in the presence of 2 mg of heparin/ml. The beads were washed extensively, and the bound radioactivity was counted with a liquid scintillation counter. The bound proteins were then dissociated in 1×
Laemmli sample buffer, separated by SDS-PAGE, transferred to
nitrocellulose membranes, and analyzed by immunoblotting with anti-myc
antibodies.
Apoptosis assays.
NIH 3T3 cells were plated 12 h before
transfection, typically at a density of 105
cells/22-mm2 coverslip (Fisher Scientific Co.). Cells were
transfected with DNA constructs encoding GFP alone, GFP-Qk1,
GFP-Qk1:EG, pcDNA-Qk1, pcDNA-Qk1:EG, or pcDNA-GLD-1, using
LipofectAMINE PLUS reagent (Gibco BRL). At 12, 24, 36, or 48 h
after transfection, the cells were fixed with 4% paraformaldehyde in
PBS for 15 min and permeabilized with 1% Triton X-100 in PBS for 5 min. For immunostaining, the fixed cells were incubated with the
anti-myc 9E10 antibody (1:1,000) at room temperature for 1 h and
subsequently with a rhodamine-conjugated goat anti-mouse secondary
antibody (Jackson Laboratories; 1:300) for 30 min. The nuclei were
stained with 3 µg of 4,6-diamidino-2-phenylindole (DAPI)/ml. The
morphology of transfected cells was examined by fluorescence
microscopy, and cells with morphological features such as nuclear
condensation and fragmentation were considered apoptotic. Apoptosis was
also examined by TUNEL (terminal deoxynucleotidyl transferase-mediated
fluorescein-dUTP nick end labeling). The TUNEL reagents were obtained
from Boehringer Mannheim, and the assay was performed as suggested by
the manufacturer.
| |
RESULTS |
The mouse quaking gene products exist as homodimers in
vivo.
The quaking gene encodes three different
alternatively spliced transcripts that generate the Qk1-5, Qk1-6, and
Qk1-7 proteins (11). These Qk1 proteins differ in their
C-terminal 30 amino acids and are predicted to migrate with apparent
molecular masses of 45 to 38 kDa on SDS-polyacrylamide gels
(11). To characterize the endogenous Qk1 proteins, a rabbit
polyclonal antibody against Qk1 amino acids 81 to 180, encompassing the
KH domain, was generated. This region is identical in all Qk1 splice
variants, and therefore the antibody should recognize all three Qk1
isoforms. The specificity of the anti-Qk1 antibody was examined by
using HeLa cells transfected with vector alone, myc epitope-tagged
Qk1-7, or myc-Sam68. The cell lysates from the transfected cells were
resolved by SDS-PAGE, transferred to nitrocellulose membranes, and
immunoblotted with anti-myc (Fig. 1A, lanes 1 to
3), normal rabbit serum (lanes 4 to 6),
anti-Qk1 (lanes 7 to 9), or anti-Qk1 antibodies preabsorbed with the
GST-Qk1 antigen (lanes 10 to 12). The anti-Qk1 antibody recognized the
transfected Qk1 protein but not Sam68 (lanes 8 and 9). Qk1 was not
observed when using normal rabbit serum or anti-Qk1 antibodies
preabsorbed with the antigen (lanes 4 to 6 and 10 to 12, respectively).
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FIG. 1.
Characterization of the anti-Qk1 antibody. (A) Total
cell lysates from HeLa cells transfected with vector (none), myc-Qk1
(Qk1), or myc-Sam68 (Sam68) were separated by SDS-PAGE. The proteins
were transferred to nitrocellulose and immunoblotted with anti-myc,
normal rabbit serum (NRS), anti-Qk1, or anti-Qk1 antibodies preabsorbed
with 1 µg of GST-Qk1KH antigen/ml (anti-Qk1/Qk1 KH). The positions of
Qk1 and Sam68 are shown on the left, and those of molecular mass
markers (in kilodaltons) are on the right. (B) Total cell extracts from
rat C6 glioma cells and rat astrocytes were immunoblotted with
anti-Qk1. The presence of three Qk1-immunoreactive proteins with
approximate molecular masses of 45, 40, and 38 kDa is shown.
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To identify a cell line that contained all three Qk1 splice variants, a
panel of neuronal cell lines was analyzed by immunoblotting
with the
anti-Qk1 antibody. Three major immunoreactive proteins
in the 45- to
38-kDa range were detected in the rat C6 glioma
cell line (Fig.
1B,
lane 1) (
5). Similar patterns of expression
were observed
for purified rat astrocytes (Fig.
1B, lane 2), purified
rat
oligodendrocytes, and whole-brain extracts from BALB/c, heterozygous,
and homozygous
quaking viable mice (data not shown). These
data
are consistent with the recent finding that Qk1-5, Qk1-6, and
Qk1-7 are expressed in different brain cell types of normal and
quaking viable mice (
19), and therefore extracts
from whole
brains should contain all three Qk1 splice variants. Our
results
identify the C6 glioma cell line as a suitable cell system with
which to investigate the properties of the endogenous Qk1 proteins.
Since we have previously shown that the transfected Qk1-7 protein
forms complexes in HeLa cells (
8), we performed chemical
cross-linking studies with C6 glioma cells to determine whether
endogenous Qk1 proteins self-associated into similar complexes.
C6
glioma cells were either left untreated or treated in situ
with BMH, an
irreversible chemical cross-linker, and the cell
lysates were resolved
by SDS-PAGE, transferred to nitrocellulose
membranes, and immunoblotted
with the anti-Qk1 antibody (Fig.
2A). In
addition to the three monomeric Qk1 proteins (lanes 1
and 2), three
distinct cross-linked Qk1 complexes with apparent
molecular masses of
90 to 80 kDa were observed after cross-linking
(lane 2). These data
suggest that the Qk1 proteins exist as dimers.
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FIG. 2.
Qk1 self-associates into homodimers in the absence of
cellular RNA. (A) C6 glioma cells were treated in situ with (+) or
without ( ) BMH. The cells were lysed in sample buffer, and the
proteins were separated by SDS-PAGE. The proteins were transferred to
nitrocellulose and immunoblotted with rabbit anti-Qk1 antibody. The
bands representing the three Qk1 isoforms are shown as monomers, and
the cross-linked complexes are indicated. The positions of molecular
mass markers (in kilodaltons) are indicated on the left. (B) HeLa cells
cotransfected with myc- and HA-Qk1 were treated in situ with BMH. The
cells were lysed, and an aliquot of the total cell lysate (TCL) as well
as anti-myc (myc) and IgG (C) immunoprecipitates were separated by
SDS-PAGE. The proteins were transferred to nitrocellulose and
immunoblotted with anti-HA antibodies. (C) Qk1, unlike GRP33, does not
require cellular RNA for self-association. HeLa cells expressing
myc-Qk1, HA-Qk1, myc-GRP33, or HA-GRP33 were lysed separately, and each
cell lysate was divided into two portions, either treated with RNase A
(+) or not treated (), mixed, and incubated with anti-myc antibodies.
The anti-myc immunoprecipitates (IP) of the mixed lysates were
separated by SDS-PAGE and immunoblotted with anti-HA antibodies.
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To verify that Qk1 cross-linked complexes represented Qk1 dimers, HeLa
cells coexpressing myc- and HA-Qk1 were treated in
situ with BMH, and
the cell lysates were immunoprecipitated with
IgG (Fig.
2B, lane 2) or
anti-myc antibody (lane 3). The immunoprecipitated
proteins as well as
the total cell lysate (lane 1) were analyzed
by immunoblotting with
anti-HA antibodies. BMH treatment of HeLa
cells expressing Qk1 resulted
in a 90-kDa complex, in addition
to the 45-kDa Qk1 monomer (lane 1).
This HA-Qk1-containing complex
was present in anti-myc
immunoprecipitates (lane 3), demonstrating
that HA- and myc-Qk1
proteins dimerized. The presence of HA-Qk1
monomers in anti-myc
immunoprecipitates indicated that not all
complexes were chemically
cross-linked (lane 3).
Since the mouse Qk1-7 protein is an RNA binding protein
(
8), we sought to investigate whether cellular RNA was
required
for Qk1 self-association. myc- and HA-Qk1 were expressed in
HeLa
cells separately, and the cell lysates were or were not treated
with RNase A for 1 h at 37°C and then mixed and
immunoprecipitated
with anti-myc antibodies. The bound proteins were
separated by
SDS-PAGE, transferred to nitrocellulose, and immunoblotted
with
anti-HA antibodies. HA-Qk1 coprecipitated with myc-Qk1 regardless
of whether the lysates were treated with RNase A (Fig.
2C, lanes
1 and
2), indicating that RNase treatment had no effect on the
ability of Qk1
to self-associate. Under similar conditions, we
also tested the ability
of GRP33 to self-associate in the presence
or absence of RNase.
HA-GRP33 was observed in anti-myc immunoprecipitates
when no RNase
treatment was performed (lane 3), but it was not
seen when RNase
treatment was performed (lane 4). These findings
show that unlike GRP33
and Sam68 (
8), Qk1 does not require
RNA for
self-association.
The self-association and RNA binding properties of Qk1 map to the
GSG domain.
The Qk1 GSG domain spans amino acids 9 to 205, and the
embedded KH domain spans amino acids 81 to 180 (Fig.
3A). A deletion analysis was performed to
identify whether the GSG domain and the Qk1 C-terminal region were
necessary and sufficient for Qk1 self-association and RNA binding. The
truncated Qk1 proteins were tested for their ability to associate with
HA-Qk1. HeLa cells were cotransfected with DNAs encoding HA-Qk1 and
with wild-type myc-Qk1 or the truncated myc-Qk1 constructs (Fig. 3A).
The cells were lysed and immunoprecipitated with control or anti-myc
antibodies. The bound proteins were immunoblotted with anti-HA
antibodies for detection of the presence of HA-Qk1. myc
immunoprecipitates of wild-type myc-Qk1 (Fig. 3B, lane 3),
myc-Qk1:1-205 (lane 6), and myc-Qk1:1-180 (lane 9) contained abundant
levels of HA-Qk1. However, Qk1 lacking its N-terminal 80 amino acids,
or the QUA1 region (myc-Qk1:81-325), did not coprecipitate HA-Qk1
(Fig. 3B, lane 12). These data demonstrate that the C-terminal 145 amino acids of Qk1 are dispensable and that the QUA1 region of the GSG domain is required for self-association. The levels of expression of
the myc-Qk1 constructs were equivalent (Fig. 3B, lanes 13 to 16).
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FIG. 3.
Mapping of the Qk1 self-association and RNA binding
regions within the GSG domain. (A) Schematic diagrams of the Qk1
constructs utilized are shown. The black box denotes the KH domain,
whereas the gray boxes represent the QUA1 and QUA2 regions as
indicated. The entire region encompassing QUA1, KH, and QUA2 is the GSG
domain. (B) Truncation of the N-terminal 80 amino acids of Qk1 or QUA1
abolishes self-association. HA-Qk1 was cotransfected in HeLa cells with
various myc-Qk1 deletion constructs as indicated. Total cell lysates
(TCL) as well as anti-myc (myc) and control IgG (C) immunoprecipitates
were analyzed by immunoblotting with anti-HA antibodies. Total cell
lysates of the myc-Qk1 proteins were immunoblotted with anti-myc
antibodies (lanes 13 to 16). (C) The Qk1 GSG domain is required for RNA
binding. HeLa cell lysates containing myc-tagged Qk1 or various
truncated forms of Qk1 were immunoprecipitated with anti-myc antibody
(hatched bars) or control IgG (white bars) and then incubated with
32P-labeled total cellular RNA. Each bar represents the
mean ± standard deviation of data from more than six independent
immunoprecipitations carried out during more than three separate
experiments.
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The RNA binding abilities of wild-type Qk1 and its truncated forms were
compared. Wild-type and the various truncated myc-Qk1
proteins were
expressed in HeLa cells, and the anti-myc and control
IgG
immunoprecipitates were incubated with
32P-labeled RNA in
lysis buffer supplemented with 2 mg of heparin/ml.
The radioactivity in
the bound RNA was counted and expressed in
counts per minute (Fig.
3C).
Anti-myc immunoprecipitates of wild-type
Qk1 bound 20 times more
labeled RNA than did control immunoprecipitates
(Fig.
3C, Qk1). The
deletion of the C-terminal 120 amino acids
had no effect on Qk1 RNA
binding activity (Fig.
3C, Qk1:1-205).
However, the deletion of the
QUA2 region in the Qk1 GSG domain
reduced the bound RNA by more than
half (Fig.
3C, Qk1:1-180).
Furthermore, the deletion of the QUA1
region of the Qk1 GSG domain
completely abolished RNA binding
(Qk1:81-325). These data suggest
that the entire Qk1 GSG domain is
required for optimal RNA binding.
The genetic mutation (E48G) identified in quaking
lethal mice abolishes self-association but not RNA binding.
Our
deletion studies indicated that the QUA1 region of the Qk1 GSG domain
is required for Qk1 self-association and RNA binding. Interestingly,
one ethylnitrosourea-induced point mutation that causes a mouse
quaking lethal phenotype (23) has been identified in this region (11). This amino acid substitution, altering glutamic acid 48 to a glycine, was introduced in the mouse
quaking protein (Qk1:EG) and tested for its effect on
self-association and RNA binding. The abilities of Qk1:EG to
associate with Qk1 and to self-associate were examined (Fig.
4A). HeLa cells were transfected with
combinations of myc- and HA-Qk1 or Qk1:EG as indicated in Fig. 4A.
The cells were lysed and immunoprecipitated with control or anti-myc
antibodies. The proteins were separated by SDS-PAGE and analyzed by
immunoblotting with anti-HA antibodies. HA-Qk1 coimmunoprecipitated
with myc-Qk1 (Fig. 4A, lane 3) but not with myc-Qk1:EG (lane 6).
Moreover, HA-Qk1:EG did not coprecipitate with myc-Qk1 (lane 9) or
myc-Qk1:EG (lane 12), suggesting that the E48G mutation prevents Qk1
self-association. The levels of expression of the myc epitope-tagged
constructs used were equivalent (Fig. 4B).
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FIG. 4.
E48G substitution in Qk1 abolishes homodimerization but
not RNA binding. (A) HeLa cells were transfected with HA- or myc-tagged
Qk1 and/or Qk1:EG as indicated. The total cell lysate (TCL) as well
as anti-myc (myc) and IgG (C) immunoprecipitates were immunoblotted
with anti-HA antibody. The bands representing HA-Qk1 or HA-Qk1:EG
are indicated on the left. The migration of the heavy chain of IgG is
also indicated. (B) Total cell lysates corresponding to those of panel
A were immunoblotted with anti-myc antibodies. (C) Immunoprecipitated
Qk1 or Qk1:EG was incubated with labeled RNA as described in
Materials and Methods.
|
|
The RNA binding properties of Qk1:E
G and Qk1 were investigated. The
Qk1:E
G protein bound RNA to the same extent as the wild-type
Qk1
protein (Fig.
4C), demonstrating that this point mutation
has no effect
on RNA binding. However, we cannot exclude the possibility
that a
difference in RNA binding will be observed once a high-affinity
RNA
target for Qk1 is identified.
We next examined the ability of wild-type and mutated Qk1 to
self-associate in vitro. GST pull-down assays using bacterial
fusion
proteins were performed (Fig.
5A). HeLa
cell lysates containing
HA-Qk1 or HA-Qk1:E
G were incubated with
affinity matrices coupled
with GST alone (lanes 2 and 6), GST-Qk1
(lanes 3 and 7), or GST-Qk1:E
G
(lanes 4 and 8). The proteins that
bound the GST proteins were
separated by SDS-PAGE and analyzed with
anti-HA antibodies. HA-Qk1
bound the GST-Qk1 fusion protein (lane 3),
indicating that Qk1
was able to self-associate in vitro. However,
HA-Qk1 did not associate
with GST-Qk1:E
G (lane 4), and no
interaction between HA-Qk1:E
G
and either GST-Qk1 (lane 7) or
GST-Qk1:E
G (lane 8) was observed.
These results are consistent with
our coimmunoprecipitation data,
confirming that the
quaking
lethal point mutation abolishes Qk1
self-association. These
observations demonstrate that Qk1 containing
the
quaking
lethal point mutation is defective in GSG-mediated
protein-protein
interactions, such as the ability to self-associate.
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|
FIG. 5.
Association of Qk1 in vitro and localization of the
minimal region to amino acids 18 to 57. (A) HA-Qk1 or HA-Qk1:EG was
transfected into HeLa cells. The cells were lysed, and GST pull-down
assays were performed with full-length Qk1 or Qk1:EG expressed as a
GST fusion protein. The bound proteins were separated by SDS-PAGE,
transferred to nitrocellulose, and immunoblotted with anti-HA
antibodies. (B) HA-Qk1 was expressed in HeLa cells and incubated with
various Qk1 GST fusion proteins as indicated. The bound HA-Qk1 was
analyzed as described for panel A. The migration of HA-Qk1 or
HA-Qk1:EG is shown on the left. TCL, total cell lysate.
|
|
The QUA1 region of the GSG domain mediates Qk1
self-association.
The severe effect of the quaking
point mutation on Qk1 self-association suggested that the QUA1 region
of the Qk1 GSG domain is directly involved in Qk1 self-association. To
further delineate the region responsible for self-association, a series
of GST fusion proteins were generated. These fusion proteins were
utilized in GST pull-down assays and tested for their ability to
interact with HA-Qk1 produced in HeLa cells (Fig. 5B). The
GST-Qk1:1-80 and GST-Qk1:1-57 fusion proteins bound HA-Qk1 (lane 3 and 4), but GST-Qk1:1-37 did not (lane 8). Amino-terminal deletions
revealed that Qk1:18-57 was the minimum region capable of binding
HA-Qk1 (lanes 5 to 7).
Qk1 and Qk1:E48G induce apoptosis in fibroblasts.
The
phenotype of the quaking lethal mutation is arrested growth
of an embryo with generalized abnormalities (23), suggesting that Qk1 may play a role in cell proliferation or differentiation. To
determine the role of Qk1 and its lethal mutation, we expressed wild-type Qk1 and Qk1 with the E48G mutation in mouse fibroblast cells
and examined their effects on cell growth. NIH 3T3 cells were
transfected with expression vectors encoding GFP alone, GFP-Qk1, or
GFP-Qk1:EG. Twelve hours after transfection, approximately 25% of
the cells expressed GFP, GFP-Qk1, or GFP-Qk1:EG, as visualized by
fluorescence microscopy. Interestingly, only 6 to 8% of the cells
expressed GFP-Qk1 and GFP-Qk1:EG at 36 h, suggesting that the
cells transfected with wild-type or mutant Qk1 were not surviving (data
not shown). The cells expressing GFP alone appeared normal and healthy
(Fig. 6A, left panels). Cells expressing
GFP-Qk1 or Qk1:EG exhibited morphological changes characteristic of
apoptosis, including cell shrinkage, cytoplasm condensation, and
membrane blebbing (Fig. 6A, middle and right panels). GFP-transfected
cells displayed normal nuclear morphology as visualized by DAPI
staining (GFP panels, lower halves). GFP-Qk1- or
GFP-Qk1:EG-transfected cells had irregular (GFP-Qk1 and
GFP-Qk1:EG panels, 12 h, lower halves), condensed, or
fragmented nuclei (36 h), consistent with apoptotic cell death. Similar
data were obtained in HeLa cells (data not shown). To confirm that the
morphological changes induced by GFP-Qk1 and GFP-Qk1:EG were indeed
associated with apoptosis, we performed the TUNEL assay with
fluoresceinated nucleotides, NIH 3T3 cells were transfected with
myc-Qk1, myc-Qk1:EG, or myc-GLD-1 for 36 h. The cells were
fixed, and the myc epitope-tagged proteins were detected by indirect
immunofluorescence with a rhodamine-conjugated secondary antibody (Fig.
6B, top panels). As observed by TUNEL assay, most of the myc-Qk1- and
myc-Qk1:EG-transfected cells fluoresced green, consistent with
apoptotic cell death. The transfection of another cytoplasmic GSG
protein, myc-GLD-1 (21), did not induce apoptosis and
served as a negative control (Fig. 6B, left panels). All of the cells
that stained in the TUNEL assay contained condensed or fragmented
nuclei as visualized by DAPI staining (Fig. 6B). Therefore, the
presence of nuclear condensation and fragmentation, as detected by DAPI
staining, is a good indication of apoptotic cell death.
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FIG. 6.
Qk1 and Qk1:EG induce apoptosis in NIH 3T3 cells. (A)
NIH 3T3 cells were transfected with an expression vector encoding GFP
alone, GFP-Qk1, or GFP-Qk1:EG. After 12, 24, 36, and 48 h, the
cells were fixed and stained with DAPI to visualize the nuclei. The top
photograph in each pair shows the fluoresceinated cells containing GFP,
and the lower photograph shows the DAPI-stained nuclei. The white
arrowheads were used to align the top and bottom photographs. (B) NIH
3T3 cells were transfected with expression vector encoding myc-GLD-1,
myc-Qk1, or myc-Qk1:EG. The myc epitope-tagged proteins were
visualized by indirect immunofluorescence with a rhodamine-conjugated
secondary antibody (anti-myc). The apoptotic cells were visualized by
TUNEL with fluorescein-containing nucleotides (TUNEL), and the nuclei
were stained with DAPI (DAPI). The three photographs each for
myc-GLD-1, myc-Qk1, and myc-Qk1:EG represent the same field of
cells as visualized with different filters. The white arrowheads were
used to orient the cells in the photographs.
|
|
The levels of apoptosis induced by Qk1 and the Qk1:E
G proteins were
quantitated by randomly counting cells and expressing
the number of
apoptotic cells as a percentage of transfected (green)
cells. NIH 3T3
cells were transfected with plasmids expressing
GFP, GFP-Qk1, or
GFP-Qk1:E
G. A small fraction of GFP-expressing
cells were apoptotic,
and this fraction (~15%) remained steady
for up to 48 h (Fig.
7). The transfection of Qk1 or Qk1:E
G
resulted
in a significant increase in the number of apoptotic cells
with
time. At 48 h posttransfection, ~90% of the remaining
cells were
apoptotic (Fig.
7). Qk1:E
G consistently resulted in a
larger
fraction of apoptotic cells upon transfection than did Qk1. This
difference was more prominent at the early time points. At 12
and
24 h, 36.7 and 68.6% of the Qk1:E
G-transfected cells were
apoptotic. These values are in contrast to 24.4 and 49.0%,
respectively,
for Qk1-transfected cells, and these differences were
statistically
significant as calculated by the
2 test
(
P < 0.01). Since the transfection efficiencies and
levels
of expression of GFP-Qk1 and GFP-Qk1:E
G were similar (data
not
shown), these results suggested that Qk1:E
G is more potent than
Qk1. The majority, ~70%, of the Qk1:E
G-transfected cells were
apoptotic at 24 h, whereas it took GFP-Qk1 36 h to reach a
similar
level of apoptosis. These data suggest that Qk1 induces
apoptosis
and that the E48G mutation in Qk1 contributes to aggravated
apoptotic
cell death.
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|
FIG. 7.
Quantitation of the apoptosis induced by Qk1 and
Qk1:EG. Eight hundred transfected NIH 3T3 cells, in three separate
experiments, were counted and assessed for the presence of apoptotic
nuclei. The presence of apoptotic nuclei was scored as cells undergoing
apoptosis. The white, hatched, and black bars represent GFP, GFP-Qk1,
and GFP-Qk1:EG, respectively.
|
|
| |
DISCUSSION |
We have shown by coimmunoprecipitation and in situ chemical
cross-linking studies that the Qk1 proteins exist as homodimers. The
minimum region required for self-association consists of amino acids 18 to 57, which are located in the QUA1 region of the Qk1 GSG domain. This
region contains several conserved residues, including glutamic acid at
position 48. Alteration of glutamic acid 48 to glycine is thought to be
the cause of the lethality in the qkkt4 mice
(11). We demonstrated that the Qk1 E48G substitution
abolishes self-association. Analysis of the Qk1 protein sequence with
the computer program COILS (26) predicted that amino acids
38 to 57 have a high propensity to form coiled coils, which would be disrupted with the introduction of a glycine at position 48 (Fig. 8, coiled coil no. 1). Thus, it is likely
that Qk1 dimerizes through coiled-coil interactions mediated by the GSG
domain. These data suggest that the failure of Qk1 to dimerize causes
embryonic lethality in the qkkt4 mice and
implicate dimer formation in the normal function of Qk1 proteins. It is
possible that Qk1 associates with other proteins via this region, and
therefore we cannot exclude the possibility that the lethality results
because Qk1 fails to mediate interactions with other proteins.
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|
FIG. 8.
Coiled-coil motif predictions for Qk1 (left) and
Qk1:EG (right). The Qk1 and Qk1:EG protein sequences were
analyzed with the computer program COILS, and the putative coiled-coil
motifs are shown (#1 and #2). The abscissa and ordinate represent amino
acid numbers and the propensity to form coiled coils, respectively. The
structures of the Qk1 proteins are shown below, with hatched and black
boxes representing the GSG and KH domains, respectively. The vertical
line in the GSG domain denotes the location of the quaking
lethal point mutation E48G.
|
|
Mouse Qk1 amino acids 38 to 57, predicted to form coiled-coil no. 1, are conserved in Who/How and Xqua, with 13 of 20 and 19 of 20 identical
residues, respectively (2, 11, 16, 42, 44). This region in
Xqua has a coiled coil prediction similar to that of mouse Qk1 (data
not shown), and since Xqua has been shown to self-associate in vitro
(45), we predict that this region mediates the
self-association. This region in Who/How is also predicted to form
coiled coils, but with a lower propensity (0.15). Both Xqua and Who/How
coiled coils in this region would be disrupted by the introduction of
the corresponding mouse Qk1 E48G mutation. Based on our Qk1 data and
the computer analyses, we predict that the point mutation identified in
Who/How, altering arginine 185 to cysteine (2), should not
alter self-association or RNA binding. Indeed, the introduction of
R185C in Drosophila Who/How did not alter self-association
or RNA binding (10).
The mouse Qk1 sequence is also predicted to form a second coiled coil,
at the C terminus of the KH domain (Fig. 8, coiled coil no. 2).
Although our data suggest that coiled coil no. 2 is not sufficient for
Qk1 self-association (Qk1:81-325), it is most likely involved in
protein-protein interactions other than self-association. Coiled-coil
interactions have been predicted for KH domain proteins FMR1 and FXRs
(36). These proteins have been observed to self-associate as
well as to associate with ribosomes (24, 36). These
interactions were demonstrated to occur outside the KH domains, by
regions predicted to form coiled coils (36). Interestingly,
the KH domains of the FMR1 protein are not predicted to form coiled
coils like the KH domain of Qk1. Analysis of the sequences of GSG
proteins SF1, Who/How, GLD-1, and Xqua demonstrated that they are all
predicted to form coiled coil no. 2 at the C terminus of the KH domain
(data not shown). This may represent one more difference between the KH
domains of GSG proteins and other KH domains. Sam68 and GRP33 are not
predicted to form such coiled coils and may represent a different
subclass of GSG proteins. To this end, both GRP33 and Sam68 require RNA
for self-association (Fig. 2C) (8). For Sam68, we have been
unable to reconstitute the self-association in vitro with recombinant
proteins (data not shown) as we have done with Qk1. Another difference
is the minimum region required for Sam68 self-association, which is
amino acids 103 to 269, the entire GSG domain, and within this region the KH domain loops 1 and 4 are essential (8).
We have mapped the Qk1 RNA binding domain to the N-terminal 205 amino
acids encompassing the entire GSG domain. This demonstrates that the
entire Qk1 GSG domain is sufficient for RNA binding, as has been
previously demonstrated for Sam68 (8, 25). However, this is
in contrast to what has been reported for Xqua by Zorn and Krieg; they
demonstrated that the entire Xqua protein was required for optimal RNA
binding (45). Deletion of the N-terminal GSG amino acids had
only a slight reduction effect on RNA binding, whereas deletion of
amino acids C terminal to the GSG domain (231 to 357) abolished RNA
binding. Since the amino acid sequence identity between mouse, human,
and Xenopus Qk1 proteins is 94% (44), Xqua and
Qk1 are predicted to have similar RNA binding properties. Either the
difference is intrinsic to the proteins or is due to the different
stringencies of the RNA binding assays.
Although the exact function of the GSG domain is unknown, our
observations with Qk1 and Sam68 indicate that the GSG domain is
involved in oligomerization and RNA binding. It is presently unclear
whether the GSG domain mediates protein-protein interactions with
non-GSG family members. The presence of signaling protein motifs in GSG
proteins suggests a role for these proteins in signal transduction (for
a review, see reference 39). Interestingly, these
potential SH2, SH3, and WW domain binding motifs lie outside the GSG
domain, ruling out a direct role for the GSG domain in signal
transduction. Nevertheless, the presence of signaling motifs and the
presence of phosphorylation sites C terminal to the Sam68 GSG domain
(32, 38, 41) suggest that signal transduction pathways may
regulate GSG-mediated interactions. Indeed, we have demonstrated in
previous studies that Sam68 RNA binding and oligomerization are
abolished by the p59fyn tyrosine kinase (8,
40). Moreover, the binding of Sam68 to SH3 domains inhibits RNA
binding in vitro (38). These data demonstrate that Sam68 has
the potential to link signal transduction pathways with RNA metabolism.
Similar data for the other GSG proteins has yet to be obtained. The
absence of known signaling motifs in some GSG family members, such as
GLD-1 (22), demonstrates that not all family members have
the potential to act as signal transduction activators of RNA
metabolism (39), but they may have other functions. It is
possible that the only properties shared by all family members are GSG
domain-mediated RNA binding and self-association.
The quaking genes from X. laevis, D. melanogaster, and mice are involved in a variety of processes,
such as myelination, embryogenesis, muscle development, and notochord
development (2, 7, 16, 20, 23, 33, 34, 42, 45). The
pleiotropic roles and the high level of conservation of this gene
suggest a general function for Qk1 in cellular processes. Our results
suggest that a function of Qk1 might be to act as a regulator or
effector of apoptosis. Since fibroblasts do not express Qk1 (Fig. 1,
lanes 7 to 9), it is likely that the expression of Qk1 leads to
perturbation of normal cellular processes. Qk1-7, the isoform used in
our experiments, is predominantly cytoplasmic (Fig. 6 and data not
shown) (19), and it may induce apoptosis by regulating or
interfering with the translation and/or mRNA stability of apoptotic or
survival proteins. There is a precedent for these mechanisms, since an increase in RNA degradation before the onset of apoptosis has been
observed in T cells (28, 37) and hnRNP K has been shown to
regulate translation (30).
The three mouse Qk1 splice variants have identical GSG domains and
differ in their C termini (11). Qk1-5 is mainly expressed in the nucleus, whereas Qk1-6 and Qk1-7 are mainly expressed in the
cytoplasm, suggesting that the last 30 amino acids determine the
localization (19). The identicalness of the GSG domains suggests that all three Qk1 splice variants are able to associate with
RNA, homodimerize, and heterodimerize. By performing cross-linking studies in C6 glioma cells, we have demonstrated the presence of at
least three cross-linked Qk1 species that may represent homodimers
and/or heterodimers. The presence of multiple Qk1 splice variants in
glial cells and oligodendrocytes (19) suggests an interesting mechanism for the regulation of Qk1 cellular localization. Heterodimers of Qk1-5:Qk1-6 or Qk1-5:Qk1-7 may cause the retention of Qk1-5 in the cytoplasm. Alternatively, Qk1-6 and Qk1-7 might be
dragged into the nucleus as Qk1-5 heterodimers. We speculate that
formation and balance of such dimers are crucial for Qk1 function and
are responsible for the phenotypes observed in the quaking
viable and lethal mice.
The genetic lesion in the quaking viable mouse has been
mapped to the qk1 promoter-enhancer region (11),
and as a result, Qk1-6 and Qk1-7 are not expressed in
oligodendrocytes (19). Oligodendrocytes still express
nuclear Qk1-5. According to our data, Qk1-5 should be unable to form
heterodimers with Qk1-6 or Qk1-7 in oligodendrocytes. This might
interfere with Qk1 function and lead to the myelin dysregulation
observed in the central nervous systems of these animals. The
quaking viable mice have been extensively studied
(20), and several defects in RNA metabolism have been observed. Alterations in the levels of alternatively spliced RNAs and
in the processing and/or turnover of the mRNA transcripts encoding
myelin-associated glycoprotein, myelin basic protein, and proteolipid
protein have been demonstrated (4, 6, 13, 19). A defect in
myelin basic protein mRNA transport has also been observed in the
quaking viable mice (3). The challenge will be to
determine whether Qk1 regulates splicing, RNA transport, mRNA
stability, and/or translation. Since hnRNP K acts as a transcription factor (27) and Sam68 associates with double-stranded DNA
(41), the possibility that nuclear Qk1 also functions as a
transcription factor cannot be excluded.
The ethylnitrosourea-induced quaking alleles are known to be
lethal at around day 9 or 10 of gestation (7, 23, 33). The
only Qk1 isoform expressed in significant amounts at this early time is
Qk1-5 (11). Our data suggest that this point mutation would
be unable to homodimerize, thus possibly altering its function during
embryogenesis. Interestingly, the Qk1:EG protein was significantly more potent than wild-type Qk1 at inducing apoptosis in NIH 3T3 cells.
Since the Qk1 E48G point mutation is lethal in mice, it is tempting to
speculate that unregulated apoptotic cell death occurs due to the
absence of GSG-mediated dimerization. The apoptosis we observe with Qk1
in NIH 3T3 cells may be similar to the poisoning effects observed with
certain GLD-1 point mutations in C. elegans (22).
By using a pan-Qk1 antibody, the C6 glioma cell line was identified to
contain all three Qk1 isoforms. This cell line, which is of rat origin
and is derived from glial cells (5), expresses several
oligodendrocytic markers, such as myelin-associated glycoprotein, proteolipid protein, and 2',3'-cyclic nucleotide 3'-phosphohydrolase (18, 43). Since the C6 glioma cell line expresses all three Qk1 isoforms, it should provide a cell system in which to study the
properties of the Qk1 dimers and some of their biochemical functions.
The expression of Qk1 and Qk1:EG in these cells did not readily
induce apoptosis (data not shown), suggesting that either the
endogenous Qk1 proteins provide a protective effect in these cells or
C6 glioma cells are not a suitable system in which to study apoptosis.
In conclusion, we have defined the Qk1 GSG domain as the region
required for dimerization and RNA binding. Replacement of glutamic acid
48 with a glycine, a mutation known to be lethal in mice, abolished Qk1
self-association but not RNA binding. The expression of Qk1 and
Qk1:EG in fibroblast cells induced apoptotic cell death. Since Qk1
has signaling motifs (11), it will be essential to examine
the potential role of signaling molecules in the regulation of Qk1 RNA
binding, self-association, and apoptosis.
| |
ACKNOWLEDGMENTS |
We thank Guillermina Almazan for purified extracts of rat
astrocytes and oligodendrocytes. We thank Janet Henderson and Antonis Koromilas for critically reading the manuscript and helpful comments. We are grateful to Rongtuan Lin, John Th'ng, and Hans Zingg for providing reagents and to Bassam Damaj for technical assistance with
the rabbit polyclonal antibody.
T.C. is supported by a studentship from the Cancer Research Society of
Canada and funds from Canderel. This work was supported by grants from
the Medical Research Council of Canada, the Cancer Research Society of
Canada, Fonds de la Recherche en Santé du Québec, and the
Multiple Sclerosis Society of Canada. S.R. is a Scholar of the Medical
Research Council of Canada.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Molecular
Oncology Group, Lady Davis Institute, 3755 Côte Ste-Catherine
Rd., Montréal, Québec H3T 1E2, Canada. Phone: (514)
340-8260. Fax: (514) 340-7576. E-mail:
mcrd{at}musica.mcgill.ca.
| |
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Mol Cell Biol, August 1998, p. 4863-4871, Vol. 18, No. 8
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Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
