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J. Biol. Chem., Vol. 275, Issue 41, 31682-31688, October 13, 2000
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From the
Received for publication, December 12, 2000, and in revised form, July 24, 2000
Heat shock protein 90 (hsp90) is a molecular
chaperone responsible for protein folding and maturation in
vivo. Interaction of hsp90 with human glutamyl-prolyl-tRNA
synthetase (EPRS) was found by genetic screening,
co-immunoprecipitation, and in vitro binding experiments.
This interaction was sensitive to the hsp90 inhibitor,
geldanamycin, and also ATP, suggesting that the chaperone activity of hsp90 is required for interaction with EPRS. Interaction of
EPRS with hsp90 was targeted to the region of three tandem repeats
linking the two catalytic domains of EPRS that is also responsible for
the interaction with isoleucyl-tRNA synthetase (IRS). Interaction of
EPRS and IRS also depended on the activity of hsp90, implying that
their association was mediated by hsp90. EPRS and IRS form a
macromolecular protein complex with at least six other tRNA synthetases
and three cofactors. hsp90 preferentially binds to most of the
complex-forming enzymes rather than those that are not found in the
complex. In addition, inactivation of hsp90 interfered with the
in vivo incorporation of the nascent aminoacyl-tRNA
synthetases into the multi-ARS complex. Thus, hsp90 appears to mediate
protein-protein interactions of mammalian tRNA synthetases.
Mammalian aminoacyl-tRNA synthetases
(ARSs)1 are unique in their
formation of a macromolecular complex. This complex consists of at
least eight different ARS polypeptides (1-3) and three auxiliary
protein factors (4-6). Although the existence of this complex has been
known for more than two decades, its assembly process and dynamic
status are not well understood. The structure of the multi-ARS complex
must accommodate their reaction substrates without steric hindrance,
since the component enzymes carry out aminoacylation reactions
simultaneously. Thus, it is intriguing how the components are assembled
and maintained in the complex.
The multi-ARS complex contains three auxiliary proteins, p18, p38, and
p43. Since p38 interacts with most of the ARS components, it was
proposed to be a scaffold for the assembly of the multi-ARS complex
(5). The proposed role of p38 suggests that the formation of the
multi-ARS complex is assisted by nonsynthetase factors, although ARSs
themselves also interact with each other (7). Since assembly of many
functional complexes in the cell is facilitated by their specific
chaperones, we suspected that chaperones might be involved in the
biogenesis of the multi-ARS complex (8-11).
This possibility was first suggested by the results showing the
interaction between heat shock protein 90 (hsp90) and human glutamyl-prolyl-tRNA synthetase (EPRS), a component of the
multi-ARS complex. Although hsp90 is known to protect cellular proteins
from heat denaturation or other proteotoxic stresses (12, 13), it also
plays a role under normal physiological conditions. hsp90 is present as
two highly homologous isoforms, Yeast Two-hybrid Assay--
To identify proteins interacting
with the three repeats of EPRS, the cDNA encoding the peptide from
Val573 to Lys889 of EPRS (EPRS-L) was
subcloned into pLex202 vector using EcoRI and
SalI sites and used as bait to screen a human HeLa cDNA
library expressing B42 fusion proteins (19). The DNA encoding
full-length hsp90 was cleaved from pGEX2T-hsp90 LexA-ARS Construction--
All of the tested genes encoding the
full-length ARSs were isolated from the original clones by polymerase
chain reaction using their specific primers and ligated into the
appropriate LexA fusion vectors. Detailed information for each
construct is available upon request. The original ARS
plasmids, except for those of human valyl-tRNA
synthetase and human tyrosyl-tRNA synthetase, were
kindly provided from Dr. K. Shiba (Cancer Institute, Japan). pG7a-1 for
valyl-tRNA synthetase and pHYTS3-WT for tyrosyl-tRNA synthetase were
obtained from Dr. R. D. Campbell (University of Oxford) (21) and
Dr. E. A. First (Lousiana State University Medical Center) (22),
respectively. Polymerase chain reaction products used for construction
were confirmed by DNA sequencing, and expression of the
LexA-ARS hybrid proteins was determined by immunoblotting with
anti-LexA antibody (data not shown).
Co-immunoprecipitation--
HeLa cells were harvested, and
proteins were extracted by ultrasonication. Endogenous EPRS was
incubated with anti-EPRS rabbit antiserum and precipitated with protein
A-agarose. The precipitated proteins were resolved by SDS gel
electrophoresis, transferred onto Immobilon P membrane (Millipore
Corp.), and immunoblotted with anti-hsp90 antibody (Transduction
Laboratories) and the ECL system following the manufacturer's
instruction (Amersham Pharmacia Biotech). Precipitation of EPRS and
isoleucyl-tRNA synthetase (IRS) was confirmed by immunoblotting with
their respective antibodies.
Preparation of Antibodies--
Polyclonal rabbit antibodies were
raised against EPRS, IRS, LRS, MRS, QRS, RRS, p43, and p38. After
expression as a His tag protein, the full-length MRS, p43, and p38
(denatured), EPRS (the native peptide of three repeats from
Val573 to Lys889), LRS (denatured peptide of
C-terminal 236 amino acids), QRS (native N-terminal 236 amino acids),
and RRS (native N-terminal 72 amino acids) were purified using nickel
affinity chromatography (Invitrogen) and used for antibody preparation
(details will be available upon request). Antibodies were prepared as
described previously (23). The purified anti-IRS rabbit antibody was
obtained from Dr. K. Shiba.
In Vitro Pull-down Assay--
hsp90 Reporter Assay--
Induction of the reporter genes,
Partial Purification of Multi-ARS Complex from Bovine
Liver--
Fresh bovine liver (100 g) was immersed in buffer A (25 mM KPO4, pH 7.5, 10% glycerol, 0.1 mM EDTA, and 10 mM Assay of Multi-ARS Complex Assembly--
Assembly of the
complex-forming ARSs was determined by co-immunoprecipitation of the
components with anti-EPRS antibody. HeLa cells were treated with
different concentrations of GA (from 5 to 20 µM) for
24 h or treated with 20 µM GA for the indicated time
(from 6 to 24 h). Cells were then washed twice with PBS and methionine-free minimal essential medium (Sigma) containing the indicated concentration of GA and incubated for 30 min. Then
[35S]methionine (100 µCi/ml) in 10% serum was added to
the cells for 1 h. Cells were then washed twice with
phosphate-buffered saline, and complete medium (Dulbecco's modified
Eagle's medium) containing 1 mM cold methionine was added
to the medium for 1 h. The cells were then harvested and lysed
with the lysis buffer (50 mM HEPES, pH 7.5, 150 mM NaCl, 10% glycerol, 1 mM EDTA, 1% Nonidet
P-40, 12 mM hsp90 Identified as an EPRS-interacting Protein--
Human EPRS
contains three tandem repeats linking the catalytic domains of the
N-terminal glutamyl- and the C-terminal prolyl-tRNA synthetase (Fig.
1). It has been previously shown that
this peptide region is responsible for the interaction with the
C-terminal tandem repeats of human IRS (26) as well as nucleic
acids (27). We screened a human HeLa cDNA library to test whether
additional proteins could associate with the repeated region of EPRS.
From this screening, human hsp90 Co-immunoprecipitation of hsp90 with EPRS--
hsp90's
interaction with EPRS was further confirmed by co-immunoprecipitation.
HeLa cells were lysed, and endogenous EPRS was immunoprecipitated with
antibody raised against the EPRS peptide. Co-precipitation of hsp90
with EPRS was then determined with anti-hsp90 antibody (Fig.
2A). IRS was previously shown
to interact with EPRS (26, 27) and was also detected in the
immunoprecipitate of EPRS.
To test whether this interaction depends on the activity of hsp90, HeLa
cells were cultivated in the absence and presence of GA, a
specific inhibitor of hsp90 (17, 28), and the effect of GA on the
interaction of EPRS and hsp90 was determined by immunoprecipitation.
While the same level of hsp90 was detected in the whole cell lysates of
the HeLa cells cultured with and without GA, hsp90 was not
co-immunoprecipitated with EPRS in the presence of GA (Fig.
2B). This indicates that the interaction of EPRS and hsp90
depends on the chaperone activity of hsp90.
In Vitro Interaction of EPRS and hsp90--
The interaction of
hsp90 with EPRS was further analyzed by in vitro pull-down
experiments. The EPRS peptide was synthesized by in vitro
translation in the presence of [35S]methionine, and hsp90
was prepared as GST fusion protein. Either GST alone or GST-hsp90 mixed
with the EPRS peptide was affinity-purified using
glutathione-Sepharose, and co-purification of the EPRS peptide was
determined by autoradiography. The EPRS peptide was specifically eluted
as a complex with GST-hsp90 but not with GST alone (Fig. 3).
The binding sites for GA and ATP are both located in the N-terminal
domain of hsp90 that is also responsible for the interaction with EPRS
(Fig. 1). Since our co-immunoprecipitation results indicated that the
interaction of hsp90 and EPRS was sensitive to the presence of GA, we
also tested the effect of these compounds on the interaction of hsp90
and EPRS using an in vitro pull-down assay. EPRS binding to
hsp90 was partially inhibited by the addition of GA or ATP (Fig. 3).
The GA- or ATP-induced dissociation of hsp90 from the bound peptide was
previously reported (29).
Effect of Geldanamycin on the Interaction between EPRS and
IRS--
Chaperones such as hsp 90 play roles in protein folding,
trafficking, degradation, and assembly. EPRS is one of the components for the multi-ARS complex, and previously we have shown that
it interacts with IRS. We hypothesized that hsp90 might facilitate the
interaction between EPRS and IRS; thus, the effect of hsp90 inhibitors
such as GA and RC was tested on the interaction of these two peptides
using the yeast two-hybrid system. Since heat shock proteins are highly
conserved among different organisms and yeast hsp90 homologue is also
sensitive to GA (30, 31), we treated yeast cells with GA or RC to
determine whether these antibiotics affect the interaction between EPRS
and IRS. TSA, which affects transcription by inhibiting histone
deacetylase (24), was also employed as a control. Yeast EGY48 cells
were cultivated in the presence of each of these drugs individually for
48 h to assess whether these drugs affected cell growth. Cell growth was very slightly affected by treatment with these drugs, suggesting that they were not toxic (Fig.
4, right). This result is also
consistent with previous reports (31). The same host cells expressing
both LexA-IRS-C and B42-EPRS-L were grown in yeast synthetic
medium without leucine in the presence of the indicated drug.
Cell growth in the leucine-depleted medium should be affected by
the expression level of leu2 (the reporter gene for the
interaction between EPRS and IRS). The growth of cells treated with GA
or RC was inhibited by about 80% compared with those without drug or
treated with TSA (Fig. 4, left). As a control, the same
cells expressing LexA-IRS-C and B42 were treated with these drugs and
cultivated in the yeast medium with leucine. The growth of these
cells was only slightly affected by the treatment with these drugs
(Fig. 4, middle). These results suggest that the interaction of EPRS
and IRS is specifically affected by the inhibition of hsp90, further
supporting that this interaction is mediated by hsp90. Similar results
were obtained when another reporter gene, Co-elution of hsp90 with Sub-ARS Complex--
Although hsp90 was
co-immunoprecipitated with EPRS (Fig. 2), we do not know whether hsp90
is associated with EPRS in the multi-ARS complex. The presence of hsp90
has not been previously reported in the purified multi-ARS complex,
implying that it either may not be present in or may be weakly
associated with this complex. We thus investigated if hsp90 is present
in the purified multi-ARS complex. To determine whether hsp90 is
present in either the partially purified multi-ARS complex or in its
intermediate subcomplexes, we purified the multi-ARS complex and
evaluated hsp90 association. The complex was enriched by differential
precipitation and by chromatography using several different columns.
Although a majority of hsp90 was removed during purification, a slight
amount of hsp90 co-eluted with the fractions containing the multi-ARS
complex (data not shown). Finally, the proteins in the partially
purified complex were separated using a sizing column, and the elution profile was monitored. A major protein peak was observed in the void
volume indicative of a macromolecular complex, which was also
accompanied by a minor peak (Fig. 5). The
fractions found in these peaks were subjected to SDS gel
electrophoresis, and several components of the complex (EPRS, LRS, MRS,
QRS, RRS, p43, and p38) were identified by immunoblotting with a
mixture of their corresponding antibodies. While the major peak
contained all of these components, the minor peak only showed the
signals for EPRS, QRS, RRS, and p43. The presence of these four
components is consistent with the interaction map determined by genetic
and cross-linking analyses (7, 23, 32). hsp90 was not found in the
major peak containing more components of the multi-ARS complex but was present in the fraction containing the sub-ARS complex. Based on the
molecular weight of hsp90, the free form of hsp90 is not expected to be
present in this fraction. Thus, hsp90 appears to be associated with the
sub-ARS complex but not with the complete multi-ARS complex.
Preferential Interactions of hsp90 with Complex-forming
ARSs--
The results above suggest that hsp90 would be more generally
involved in the molecular interactions of the complex-forming ARSs. We
thus investigated whether there is a distinction between which ARSs
interact with hsp90. Interactions of hsp90 with different ARSs were
tested by yeast two-hybrid assay. A total of 15 full-length human ARSs,
and the nonsynthetase components, p18, p38, and p43, were fused to LexA
and tested for the interaction with B42-hsp90. Among the ARSs tested,
LRS, MRS, QRS, KRS, DRS, and RRS form a complex with
nonsynthetase protein factors, p18, p38, and p43, while the ARSs, CRS,
GRS, HRS, SRS, TRS, VRS, WRS, and YRS have not been found in
this complex (1-3). Among the complex-forming ARSs, hsp90 showed
strong interactions with MRS, QRS, DRS, and p38. In contrast, no
significant interactions were observed with the non-complex-forming
ARSs, although weak interactions were observed with GRS, HRS,
and WRS (Fig. 6). These results suggest that hsp90 interacts preferentially with some of the complex-forming ARSs.
Assembly of Nascent Complex-forming ARSs Is Disrupted by hsp90
Inhibitors--
The experiments above showed that the interaction
between EPRS and IRS was severely affected by the addition of hsp90
inhibitors (Fig. 4). In addition, hsp90 is bound to the sub-ARS complex
but not to the complete multi-ARS complex (Fig. 5) and also
preferentially associates with some of the complex-forming ARSs (Fig.
6). All of these results imply that hsp90 may be involved in the
associations of other complex-forming ARSs, in addition to the pair of
EPRS and IRS. If this were the case, inhibition of hsp90 would be
predicted to either disrupt or retard the assembly of the
complex-forming ARSs.
To address this possibility, we decided to monitor whether the
incorporation of the newly synthesized ARSs to the multi-ARS complex is
affected by the activity of hsp90. In these experiments, HeLa cells
were treated for different times or with different concentrations of
GA, and the nascent polypeptides were labeled in vivo with
[35S]methionine. The cells were then harvested, and
proteins were extracted from the cells and immunoprecipitated using
anti-EPRS antibody. The ARS components (IRS, LRS, MRS, QRS, RRS, and
KRS) co-precipitated with EPRS were then separated by SDS-gel
electrophoresis and quantified by autoradiography. Cellular protein
synthesis was determined by autoradiography of the protein extracts.
The total amounts of the co-precipitated ARSs were compared by the immunoblotting of the ARS components using their respective antibodies.
First, the cells were treated with 20 µM GA and harvested
at different time intervals. The harvested cells were lysed, and the
multi-ARS complex was precipitated using anti-EPRS antibody from the
extracted proteins. Immunoblotting with the corresponding ARS
antibodies showed that the similar amounts of the ARS components were
precipitated at each time point (Fig.
7A, middle
panel). The precipitated ARS complex was then subjected to
autoradiography. The amount of EPRS precipitated with anti-EPRS
antibody was decreased to about 75% of the control by the treatment of
GA for 24 h. The incorporation of other co-precipitated ARSs was
decreased from 0 to 30% under the same conditions (Fig. 7A,
left panel and line plot).
Autoradiography of the total cellular protein showed that protein
synthesis was not affected by treatment with GA (Fig. 7A,
right panel). This suggests that inactivation of
hsp90 interferes with assembly of the nascent ARSs.
To further confirm this result, cells were then treated with different
concentrations of GA, and its effects on the incorporation of the ARS
components to the complex were monitored. Cells treated under each
concentration were harvested, and the multi-ARS complex were extracted
and precipitated with anti-EPRS antibody as described above. The
incorporation of the nascent ARS components was also determined by
autoradiography. The assembly of the nascent ARS components in the
absence of GA was determined by the immunoprecipitation of the ARS
complex with anti-EPRS antibody and used as a control (Fig.
7B, left panel, leftmost
lane). Then the effect of different concentrations of GA on
the assembly of the ARS components was determined by the same method.
The incorporation of the nascent ARSs to the complex was impaired by GA
treatment in a dose-dependent manner (Fig. 7B,
left panel and line plot).
The cellular protein synthesis was not affected by the GA treatment as
determined by the autoradiography of the whole cell extract (Fig.
7B, right panel). The stability of the
preexisting multi-ARS complex remained the same without GA treatment
during the cultivation of the cells (data not shown). These results
indicate that the incorporation of the nascent ARS components to the
multi-ARS complex was sensitive to the activity of hsp90.
Although hsp90 is one of the most abundant cellular proteins, it
is highly restrictive in target selection under normal physiological conditions. Identified targets of hsp90 include steroid hormone receptors, kinases, regulatory factors, and enzymes (13, 33). However,
the cellular concentration of hsp90 is much higher than its known
target molecules, suggesting that more hsp90 substrates remain to be
identified. In addition, the role of hsp90 in the formation of
macromolecular protein complexes is not well understood. Herein, we
suggest that hsp90 associates with a subset of mammalian ARSs to
facilitate their protein-protein interactions.
The N-terminal domain of hsp90 While hsp90 preferentially associated with the sub-ARS complex, it was
not found to be present in the multi-ARS complex, suggesting that it
may be involved in the assembly process but not the maintenance of the
multi-ARS complex (Fig. 5). This is also reminiscent of a recent report
on the role of a mitochondrial protein, Bcs1p, in the assembly of the
cytochrome bc1 complex (8). This protein also binds to a subcomplex to
facilitate the assembly pathway of the cytochrome complex. A possible
role of hsp90 in the macromolecular assembly of ARSs was further
supported by the inhibitory effect of GA or RC on the interaction
between EPRS and IRS (Fig. 4) and, more directly, on the assembly of
the nascent complex-forming ARSs in vivo (Fig. 7). Although
the cellular protein synthesis was not affected by the GA treatment,
the amount of the nascent ARSs co-precipitated with anti-EPRS was
decreased by the inactivation of hsp90. This result implies that the
stability of ARSs is sensitive to the activity of hsp90. In this
regard, it is worth noting that CFTR is destabilized by interfering
with its interaction with hsp90 (35). Thus, ARSs not incorporated to
the complex may be either degraded or aggregated. However, the
stability of the preexisting ARS complex did not seem to be severely
affected by GA treatment because the similar amounts of the multi-ARS
complex were precipitated from both treated and untreated cells with
anti-EPRS antibody (Fig. 7, A and B,
middle panel). Similarly, hsp90 is important for
the membrane association of newly synthesized Src-kinase
p56lck, but not its maintenance (36).
The interaction of hsp90 with ARSs appears to be dynamic based on the
induction level of the reporter gene leu2 in two-hybrid analysis (Fig. 6). Under physiological conditions, ATP is present at
millimolar levels; thus, most of hsp90 would be expected to be
associated with ATP in vivo (29). Further, since ATP
stimulated the dissociation of hsp90 from EPRS (Fig. 3), it would be
predicted that the cellular interactions of hsp90 with ARSs would be
dynamic. Nonetheless, the potential of ARSs for the interaction with
hsp90 appears to be well correlated with their propensity for the
complex formation (Fig. 6).
The known substrates for hsp90 do not share sequence or structural
characteristics. Furthermore, ARSs interacting with hsp90 do not show
any common sequence or structural features. Instead, the two classes of
ARS that interact and do not interact with hsp90 may differ in
conformational stability or folding characteristics. Perhaps, the
complex-forming ARSs may be unstable in isolation and need to be
associated with chaperones like hsp90 until they are associated with
the neighboring ARSs. Among the non-complex-forming ARSs, some members
including GRS, HRS, and WRS showed slightly higher affinity to
hsp90 than others. Interestingly, these ARSs also contain motifs
homologous to the EPRS repeats in their N-terminal extensions (37-39).
Further, the potential for the association of GRS with the
complex-forming IRS has been previously suggested, although it is
classified as a non-complex former (26). Thus, hsp90 may be also
involved in protein-protein interactions of some non-complex-forming ARSs.
Various cellular machineries exist as macromolecular complexes. Thus,
it is important to understand the biogenesis and dynamics of these
complexes. The involvement of chaperones in macromolecular assembly has
been reported in many cases. The formation of ribulose bisphosphate
carboxylase-oxygenase is assisted by the plant homologue of E. coli groEL (9, 10), and the assembly of bacteriophage capsids also
involves chaperones (11). Here, we suggest that hsp90 may play a role
in mediating protein-protein interactions between the complex-forming ARSs.
We thank Drs. K. Shiba, E. D. First,
R. D. Campbell, and T. Takagi for kindly providing materials and
Dr. W. Seol for critical reading and advice.
*
This work was supported in part by a grant from the National
Creative Research Initiatives of the Ministry of Science and Technology
of Korea (to S. K.) and by a grant from the Korea Science and
Engineering Foundation (H. J. K.).The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
¶
To whom correspondence should be addressed: Center for ARS
Network, Sung Kyun Kwan University, 300 Chunchundong, Jangangu, Suwon,
Kyunggido 440-746, Korea. Tel.: 82-31-290-5681; Fax: 82-31-290-5682; E-mail: shkim@yurim.skku.ac.kr.
Published, JBC Papers in Press, July 25, 2000, DOI 10.1074/jbc.M909965199
The abbreviations used are:
ARS, aminoacyl-tRNA
synthetase;
XRS, ARS for amino acid(s) X;
GA, geldanamycin;
TSA, trichostatin A;
RC, radicicol.
Heat Shock Protein 90 Mediates Protein-protein Interactions
between Human Aminoacyl-tRNA Synthetases*
,,,,,¶
National Creative Research Initiatives
Center for ARS Network, Sung Kyun Kwan University, Suwon 440-746 and
the § Department of Bioscience and Biotechnology, Sejong
University, 98 Kunjadong, Kwangjingu, Seoul 143-747, Korea
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
and 
(14, 15), and consists of
two functional domains linked by a flexible and charged hinge region.
The N-terminal domain interacts with ATP (16) or its inhibitor,
geldanamycin (GA), and is also responsible for target binding (17). The
C-terminal domain is involved in dimerization, which is essential for
both function and target interaction (18). Although the structural details of hsp90 are well studied, its working mechanism and target selection remain elusive. Here, we report that hsp90 associates with
the complex-forming ARSs and mediates their protein-protein interactions.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
(20) (kindly
provided by T. Takagi, Tohoku University, Japan) with BamHI
and SmaI and ligated to pGEX4T-1. The insert was then
cleaved with BamHI and XhoI and religated into
pLexA202. The resulting plasmid was cleaved again with
EcoRI and XhoI to release the insert, which was
then ligated to pJG4-5 (B42 fusion vector). Positive interactions were
confirmed by both cell growth on leucine-depleted yeast synthetic
medium and blue colony formation on the
5-bromo-4-chloro-3-indolyl -D-galactoside (X-gal, 5 mM)-containing medium.
fused to GST or GST alone
was expressed from pGEX2T-hsp90 or pGEX2T, respectively, in E. coli BL21 (DE3). Cells were lysed by ultrasonication, and protein
extracts were prepared. EPRS-L was synthesized by in vitro
translation in the presence of [35S]methionine using
pcDNA3-EPRS-L. The in vitro translated EPRS-L was mixed
with the Escherichia coli protein extract containing GST-hsp90 or GST in binding buffer composed of 40 mM HEPES,
pH 7.6, 20% glycerol, 1 mM DTT, 0.3 µM
phenylmethylsulfonyl fluoride, and protease inhibitor mixture
(pepstatin A, leupeptin, antipain, and chymostatin; 5 µg/ml each). GA
(30 µM) or ATP (5 mM) was added as indicated
to the binding mixture to assess their effect on the interaction
between hsp90 and EPRS. Glutathione-Sepharose was added to the binding
mixture and incubated overnight at 4 °C with rotation. The reaction
mixture was then washed three times with binding buffer containing
0.1% Triton X-100, and GST or GST-hsp90 was eluted with 15 mM reduced glutathione. The eluted proteins were separated
by SDS gel electrophoresis, and the presence of EPRS-L was determined
by autoradiography.
-galactosidase, and leu2 in the two hybrid assay was
determined as described below. For the -galactosidase assay, yeast
(EGY48 strain) expressing the two proteins tested was grown overnight
in a yeast synthetic medium (Ura
, His,
Trp, 2% glucose). After checking absorbance at 600 nm,
the cells were transferred in a yeast medium (Ura,
His, Trp, 2% galactose, 0.2%
Me2SO). Equivalent numbers of cells were lysed in Z buffer
(60 mM Na2HPO4, 40 mM
NaH2PO4, 10 mM KCl, 1 mM MgSO4, and 50 mM
-mercaptoethanol, pH 7.0) containing one drop of 0.1% SDS and two
drops of chloroform for 15 min at 30 °C, and then 200 µl of 4 mg/ml o-nitrophenyl
-D-galactopyranoside was added to determine the
-galactosidase activity. When a yellow color appeared, the reaction
was stopped with 500 µl of 1 M
Na2CO3. The samples were centrifuged briefly,
and the absorbance was measured at 420 and 550 nm. The
-galactosidase activity was calculated using the formula
units = (1000 × (A420 
1.75 × A550))/(time × volume × A600). To determine the induction of the
leu2 gene, the EGY48 strain expressing LexA-IRS-C (from
Glu966 to Phe1266) and B42-EPRS-L was
cultivated in 5 ml of yeast synthetic medium (Ura,
His, Trp, 2% glucose) at 30 °C
overnight with shaking. Cells (1.5 ml) were harvested and resuspended
in 1.5 ml of yeast synthetic medium (Ura,
His, Trp, Leu, 2% galactose,
and 0.5% raffinose) and then spun down again and resuspended in 1.5 ml
of the same broth. 0.2 ml of cells were then transferred to the same
broth containing 0.001% SDS and each of the antibiotics, trichostatin
A (TSA) (24), GA, and radicicol (RC) (25). These cells were cultivated
at 30 °C overnight with shaking, and the number of the cells was
determined by hemocytometer after the same time interval. The growth of
the EGY48 strain alone or expressing LexA-IRS-C and B42 in the presence
of these antibiotics was also determined using the same methods, except
that the cells were cultivated in yeast synthetic medium
containing leucine.
-mercaptoethanol) containing protease inhibitors (pepstatin A, leupeptin, antipain, and
chymostatin (each 5 µg/ml) and 0.1 mM
phenylmethylsulfonyl fluoride) to remove blood, and this process was
repeated five times. The liver was then homogenized (PowerGen 700), and
the lysate was centrifuged at 26,000 × g for 45 min.
After removing the tissue debris, the supernatant was recentrifuged at
100,000 × g for 1 h to obtain the postribosomal
supernatant. Polyethylene glycol 6000 (Fluka) was added to a final
concentration of 2% (w/v) to the supernatant with stirring and mixed
for 30 min. The solution was then centrifuged at 12,000 × g for 20 min, the supernatant was removed, and then PEG 6000 was added to a final concentration of 15% (w/v). This solution was
then centrifuged, and the pellet was dissolved in buffer A and filtered
through a 0.4-µm filter disc. After the filtrate was dialyzed in
buffer A, the solution was loaded onto gel filtration column (Bio-Gel
A-5m; Bio-Rad). The eluted fractions containing the multi-ARS complex
were determined by the aminoacylation activity of IRS. The fractions
were then collected and loaded onto a Blue Sepharose (Bio-Rad) column
pre-equilibrated with buffer A. After washing the column, the bound
proteins were eluted using a gradient of 0-1.3 M KCl.
Fractions showing the IRS activity were collected and dialyzed in
buffer A and loaded onto a hydroxyapatite column (Bio-Rad). After
washing, the proteins in the column were eluted using a phosphate
gradient from 100 to 400 mM. The IRS-positive fractions
were collected, concentrated, and finally loaded onto a Superdex 200 HR
(Amersham Pharmacia Biotech) column. The eluted proteins in each
fraction were monitored by absorbance at 280 nm and immunoblotting with
the mixture of anti-ARS antibodies as indicated.
-glycerophosphate, 2 mM
dithiothreitol, 1 mM phenylmethylsulfonyl fluoride, 1 mM Na3VO4 and aprotinin 5 µg/ml).
Equal amounts of the proteins extracted from each treatment condition
were then mixed with anti-EPRS antibody (5 µg) and
immunoprecipitated. ARSs co-precipitated with EPRS were resolved by
SDS-polyacrylamide gel electrophoresis and detected by immunoblotting
with a mixture of their specific antibodies (EPRS, IRS, LRS, MRS, and
QRS). The nascent ARSs in the whole cell extracts or in the
immunoprecipitates were determined by autoradiography. Autoradiography
was quantified using a phosphor image analyzer (BAS-3000; Fuji).
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
was selected to interact with the tandem repeats of EPRS via its N-terminal ATP binding domain (Fig. 1).
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Fig. 1.
Structure and interaction of human EPRS and
hsp90. Human EPRS contains 1440 amino acids. It consists of two
catalytic domains (the N-terminal glutamyl- and the C-terminal
prolyl-tRNA synthetase (ERS and PRS,
respectively)) linked by three tandem repeats of 57 amino acids (40,
41). Human hsp90 contains 724 amino acids (42), consisting of the N-
and C-terminal domains responsible for ATP or GA binding and
dimerization, respectively (16, 17). The peptide-spanning tandem repeat
domain of EPRS interacts with the N-terminal domain of hsp90.
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Fig. 2.
Co-immunoprecipitation (IP)
of EPRS and hsp90. A, the endogenous EPRS in HeLa cells
was immunoprecipitated with anti-EPRS antiserum, and co-precipitation
of hsp90 and IRS was determined using their corresponding antibodies.
The cellular expression of hsp90 was determined in whole cell lysate
(WCL). Preimmune rabbit serum was used as a control. IRS
associated with EPRS in the multi-ARS complex was also co-precipitated
with EPRS. B, co-immunoprecipitation of EPRS and hsp90 was
also determined from the HeLa cells cultivated with or without
GA.
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Fig. 3.
In vitro interaction of EPRS and
hsp90. A peptide spanning the tandem repeats of EPRS (from
Val573 to Lys889) was used for in
vitro pull-down assay. This peptide was synthesized by in
vitro translation in the presence of
[35S]methionine, while hsp90 was expressed as a GST
fusion protein. Overexpressed GST alone or GST-hsp90 was mixed with the
in vitro translation mixture of the EPRS peptide and then
pulled down using glutathione-Sepharose. Co-precipitation of the
radioactively labeled EPRS was determined by SDS-polyacrylamide gel
electrophoresis and autoradiography. The hsp90 inhibitor GA (30 µM) or ATP (5 mM) was added to the
indicated binding reaction to assess its effects on the interaction
between hsp90 and EPRS.
-galactosidase, was used
for these experiments (data not shown).
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Fig. 4.
Effect of hsp90 inhibitors on interaction
between EPRS and IRS. The yeast tester stain, EGY48, expressing
the LexA-IRS-C and B42-EPRS-L was cultivated in yeast synthetic
medium lacking leucine for 48 h with no drug
(white bar), TSA (10 µg/ml; light
gray bar), GA (5.6 µg/ml; dark
gray bar), and RC (10 µg/ml; black
bar), and the cell number was counted using a hemocytometer.
At the same time, EGY48 itself or the cells expressing LexA-IRS-C and
B42 were cultivated in yeast synthetic medium with leucine as
described above to determine whether these antibiotics had any
nonspecific effects on the cells.
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Fig. 5.
Association of hsp90 with the sub-ARS
complex. The multi-ARS complex was partially purified from bovine
liver as described under "Experimental Procedures." The sample
containing the multi-ARS complex was loaded onto a gel filtration
column, and the proteins were fractionated. The eluted proteins were
resolved using SDS gel electrophoresis, and some of the components for
the multi-ARS complex (EPRS, LRS, MRS, QRS, p43, and p38) were detected
with their corresponding antibodies (upper
panel). The leftmost lane shows the
components present in the multi-ARS complex before gel filtration
chromatography. The middle and rightmost
lanes show the components detected in the major peak
fraction eluted in void volume and the accompanying peak fraction,
respectively. The corresponding elution profile is shown in the
lower panel.
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Fig. 6.
Interactions of hsp90 with complex-forming
ARSs. A total of nine complex-forming proteins (six ARSs and two
auxiliary factors, p38 and p43) and nine non-complex-forming ARSs were
tested for interaction with hsp90 by yeast two-hybrid assay. Positive
interactions were determined by the induction of -galactosidase on a
yeast synthetic plate containing 5-bromo-4-chloro-3-indolyl
-D-galactoside (5 mM) (inset) or
in liquid medium using o-nitrophenyl
-D-galactopyranoside as a substrate (bar
graph). Similar results were obtained from three independent
experiments.
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Fig. 7.
Effect of GA on the incorporation of nascent
ARSs to the multi-ARS complex. Newly synthesized cellular proteins
were labeled with [35S]methionine. Then the
multi-ARS complex was immunoprecipitated with anti-EPRS antibody, and
the incorporation of the nascent ARSs to the multi-ARS complex was
monitored by autoradiography (leftmost panel).
The amounts of the immunoprecipitated ARSs were determined by Western
blotting with the mixture of their respective antibodies
(middle panel). The effect of GA on the cellular
protein synthesis was determined by autoradiography of the whole cell
lysate (rightmost panel). The relative
intensities of the ARS components found in the multi-ARS complex were
quantified by scanning each band in the autoradiograph and
plotted. HeLa cells were treated with GA (20 µM)
and harvested at the indicated times (A), or the cells were
cultivated for 24 h at the indicated concentration of GA
(B).
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
responsible for the binding to GA and
ATP (16, 17) associates with the EPRS peptide that also interacts with
other complex-forming ARSs (26, 27). The association of hsp90 with EPRS
was sensitive to hsp90 inhibitor, GA, and ATP (Figs. 2 and 3),
suggesting a specific interaction. In addition, the ATP-induced
dissociation of hsp90 from EPRS is consistent with a previous report
that millimolar concentrations of ATP induce the dissociation of hsp90
from actin filaments (34). Taken together, these results indicate that
the chaperone activity of hsp90 is required for its interaction with EPRS.
ACKNOWLEDGEMENTS
FOOTNOTES
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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