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Role of cysteine residues in the activity of rat glutathione transferase P (7-7): Elucidation by oligonucleotide site-directed mutagenesis
Vol. 179, No. 2, 1991 September
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
16, 1991
Role
Pages
of
Gysteine
Residues
in
the
Transferase
ELUCIDATION Katsuto
Tamai,*
Hongxie
Satoh,*
* Second
Department
Akira
Shen ,* Yasui,t
t the
Received
August
Tuberculosis
Pharmacology
of
SITE-DIRECTED
Shigeki
Tsuchida,*
Atsushi
Oikawa,t Hirosaki
Hirosaki
036,
Division,
and Cancer,
Rat
Glutathione
(7-7):
of Biochemistry, Medicine,
for
P
BY OLIGONUCLEOTIDE
Kimihiko
Institute
Activity
790-797
Tohoku
MUTAGENESIS' Ichiro
Hatayama,* Sato *,2
and Kiyomi University
School
of
Japan the Research University,
Sendai,
980, Japan
1, 1991
Sumnary: To clarify the role(s) of thiol (sulfhydryl) groups of cysteine (Cys) residues in the activity of the rat glutathione transferase P (7-7) pGP5, containing the entire coding sequence of form (GST-P), a cDNA clone, GST-P (Y. Sugioka et al., (1985) Nucleic Acids Res. 12, 6044-6057) was inserted into the expression vector pKK233-2 and the recombinant GST-P (rGST-P) expressed in E. coli JMl09. All four Cys residues in rGST-P were independently substitu-h alanine (Ala) by site-directed mutagenesis, the resultant mutants as well as the rGST-P being identical to GST-P purified from Liver preneoplastic nodules with regard to molecular weight and immunochemical staining. Since all mutants proved as enzymatically active towards I-chloro-2,4-dinitrobenzene as Liver GST-P, it was indicated that none of the four Cys residues is essential for GST-P activity. However, the mutant with Ala at the 47th position from the N-terminus (Ala47) became resistant to irreversible inactivation by 0.1 mM N-ethylmaleimide (NEM), whereas the other three mutants remained as sensitive as the nonmutant type (rGST-P). Ala47 was also resistant to inactivation by the physiological disulfides, cystamine or cystine, which cause mixed disulfide and/or intraor inter-subunit disulfide bond formation. These results suggest that the 47-Cys residue of GST-P may be located near the glutathione binding site, and modulation of this residue by thiol/disulfide exchange may play an important role in regulation of activity. 0 1991 Academic Press, Inc.
This work was supported in part by Grants-in-Aid for Cancer Research rom the Ministry of Education, Science and Culture of Japan. To whom correspondence should be addressed. Abbreviations used: GST, glutathione transferase; GST-P, rat GST 7-7; recombinant GST-P; SDS-PAGE, sodium dodecyl sulfate-polyacrylamide rGST-P, NEM, N-ethylmaleimide; MCE, 2-mercaptoethanol; CDNB, gel electrophoresis; 1-chloro-2,4-dinitrobenzene; GSH, reduced glutathione; DTT, dithiothreitol; IPTG, isopropyl-H-D-thiogalactopyranoside; EDTA, kbp._ . kilo base pairs: ethylene diaminetetraacetic acid; PMSF, pheny lmethylsulfony 1 fluoride; &, dUTPase; ""g, uracil N-glucosylase; MCS, multi-cloning site. DDO6-291X/91 Copyright All rights
$1.50
0 1991 by Academic Press. Inc. of reproduction in any form reserved.
790
Vol.
179,
No.
We have Class be
Pi;
namely
for
from
the
which
playing
has
to been
In the
other
or
cystine,
the
MATERIALS
roles
Cys
using
AND
(2).
in
residues
the
catalytic role
of
site-directed
the
class
thiol
N-ethyl-
47th
peroxide
position
be
responsible
laboratories
erythrocyte
GSTs
can
hydrogen
may
other
horse to
Pi
as
in
GST-MI1
e.g.
subunits
and
2.5.1.18)
mouse
such at
COMMUNICATIONS
, EC
modifiers;
from
had
GST
(5),
also
both
group-modifiers. have
thiol
groups
reaction.
played
GST-P
with
residue
sensitive the
irreversible
thiol
Cys
(4)
that
the
together
Reports
are
(GSTs
respective
GST
Pi,
study,
respectively
clarified
NEM
RESEARCH
metabolites
the
the
placenta
present three
of of
suggested
functional
with oxygen
alteration
Class
GST-7T
treatment
N-terminus
bovine
BIOPHYSICAL
transferases
human
active
with
belong it
Thus,
or
inactivation that
and
by
that the
AND
glutathione
GST-P
(1,2)
and
(31,
described
was
rat
(NEM)
(47-Cys)
that
inactivated
maleimide
of
reported
markedly
(H202)
BIOCHEMICAL
2, 1991
in and
by
thiol
groups
inactivation
by
reversible
thiol
of NEM
the and
47th
and
cystamine
group-modifiers,
mutagenesis.
METHODS
Materials. Plasmid pKK233-2 was purchased from Amersham. Plasmid pGP5, containing 734 bp of GST-P cDNA ligated to pUC8, was the generous gift of Dr. M. Muramatsu, University of Tokyo. E. coli JM109, CJ236 and MV1190 T4 DNA ligase, T4 kinase, and the Klenow were obtained from Bio-Rad. fragment of DNA polymerase I were from Takara Shuzo Co. (Kyoto). Cystine, cystamine and CDNB were from Wako Pure Chemical Industries (Tokyo). All other chemicals were of analytical grade. GST preparations and assay. Rat GST-P was purified from livers bearing preneoplastic hyperplastic nodules, the antibody being prepared as described previously (6). GST activity was assayed using CDNB as substrate as described by Habig et al. (7). Construction of expression vector of GST-P cDNA. The plasmid pKKS was constructed to contain an additional WI site in the multiple cloning site (MCS) of pKK233-2 as follows. The plasmid pKK233-2 was restricted with EcoRI and Sal1 to remove an internal SphI site located outside of the Y MCS, treated wiTthe Klenow fragment, and ligated with T4 DNA ligase. A 18 bp fragment containing an WI site was isolated from the plasmid pUC18 by digestion with PstI and HindIII, and inserted between PstI and Hind111 7 sites in the MCS of the pKK233-2, and the resultant plasmid was designated Two synthesized oligonucleotides (61 bases and the complepKKS (Fig. 1). mentary 53 bases) coding 20 amino acids from the N-terminus of GST-P were annealed and the double strand fragment was ligated at the NcoI and WI sites with the expression vector pKKS. This construct (pKKS-PI) was digested with HindIII, treated with the Klenow fragment of DNA polymerase I and digested with S+I. The resulting 3.8 kbp fragment was separated by electrophoresis on 0.75% agarose gel and extracted. The plasmid pGP5 containing the full length cDNA of rat GST-P (81, was cleaved at the SalI 7 site, treated with the Klenow fragment, and then cleaved at the -1 site. This 670 bp fragment containing the cDNA encoding amino acids from number 21 to the end of GST-P was inserted into. pKKS-Pl between the *I and Klenow fragment-treated HindIII sites. The resulting expression vector of GST-P was designated pKKGP5 (Fig. 1). E. coli JM109 cells transformed Expression and purification of rGST-P. with the plasmid pKKGP5 were grown overnw be confluent in 10 ml of LB medium supplemented with 50 ug/ml ampicillin at 37°C with vigorous shaking. The medium was mixed with 1 1 of fresh LB medium, and cultured
791
Vol.
BIOCHEMICAL
179, No. 2, 1991
partially
synthesized
GST-P
5’ CATG inserted of pKKS
N and
RESEARCH COMMUNICATIONS
NPSH
cDNA
CATG between
AND BIOPHYSICAL
3
S sites
S
F.&.-L Construction of the expression vector of GST-P cDNA. N, P, S, H, E, HI1 and Sal represent recognition sites of restriction enzymes -1, %I, WI, Hi&III, %I, H&II, and XI, respectively. Ptac, -tat resistance gene. The inserted GST-P cDNA is promoter; Amp , ampicillin shown to consist of two shadowed portions separately constructed.
for about 2 h. At log phase, IPTG was added at a final 1 mM concentration. After an additional 14 h culture, the cells were harvested by centrifugation, resuspended in 10 ml of the lysing buffer (20 mM Tris-HCl, pH 8.0, 1 mM 22 mM NH4C1, 0.1 mM PMSF), and disrupted DTT, 1 mM EDTA, 5% (v/v) glycerol, using a sonicator (Model 200M, Kubota, Tokyo). The cell free extract obtained by centrifugation at 105,OOOxg for 60 min at 0°C was subjected to affinity chromatography as described previously (6). A HincII fragment (Fig. Construction and expression of Ala mutant GST-P. 1) was isolated from the pKKGP5 and inserted into the phage M13mp19 to produce M13mp19-GP5. This derivative was used as a single strand DNA template for mutagenesis of the respective Cys-residues at the 14th, 47th, 1Olst and 169th positions. E. coli CJ236 (dut , 9 ) were grown overnight in 10 ml of YT medium containing3mp19-GP5 phages and 34 pg/ml chloramphenicol at 37°C with vigorous shaking. The medium was centrifuged for 10 min at 2OOOxg, and 1 ml of supernatant containing Ml3mp19-GP5 phages and 1 ml of the E. Coli CJ236 overnight culture were mixed together with 100 ml of YT mediumagain incubated overnight. The culture medium was centrifuged at 10,OOOxg for 10 min, and supernatant was used as the template DNA. One tenth pmol of the template DNA was annealed with 20 pmol of the synthetic oligonucleotides shown in Table 1 in lop1 of annealing buffer (20 mM TrisHCl, pH 7.4, 10 mM MgC12, 50 mM NaCl). After primer extension a?d liga+tion, the DNA was used to transform the competent E. coli MV 1190 (E , 3 >. The transformed cells were plated on 2% agarxning YT medium, and incubated overnight at 37°C. Ten clear plaques were picked up to prepare single stranded and replicative form DNAs of M13mp19-GP5.
792
Vol.
179,
No.
BIOCHEMICAL
2, 1991
Table
1.
Nucleotide
sequences
used
Position
of
AND
for
site
of
BIOPHYSICAL
the
RESEARCH
synthetic
directed
COMMUNICATIONS
oligonucleotides
mutagenesis
Sequence
cysteine
changed
14
TGT -.GCT
5'-CCAGTTCGAGGGCG&TGAGGCCACGCGCATG-3'
47
TGT +GCT
5'-TCGCTCAAGTCCACTgCTGTATGGGCAGCTC-3'
101
TGC + GCC
169
TGC -
5'-GTGGAGGACCTTCGAEAAATATGGTACCCTCA-3' 5'-CTGGCCCCTGCC%CTGGACAACTTCCCCCTG-3' -
*
position
of
Synthetic
GCC
changed
oligonucleotide
sequence
sequence.
To select single stranded M13mp19-GP5 inclyging the desired mutation, dot blot hybridization was carried out with 5'P-labeled synthetic oligonucleotides containing the respective mutations. DNAs that gave positive signals were sequenced to confirm the mutations (9). Replicative forms of the M13mpl9-GP5 were restricted with HincII and ligated at two HincII sites of the expression plasmid pKKS. The plasmid DNAs were used to transform E. coli JMl09, and the mutants of rGST-P (Ala14, Ala47, Ala101 and Ala1691 were expressed and purified using the same method as used for the wild type rGST-P.
RESULTS AND DISCUSSION GST-P
Expression Since
in
rat
GST-P
AGGA sequence initiation
in
for
medium
under free
protein infected (lane the
bands
than
that
sequence rGST-P sequence the
described
which
JM109
(15 units/mg) of the
subunit (8).
1).
first
of
rGST-P
This
from
GST-P acid
liver
with
60% of the
that
of GST-P
rGST-P
N-terminus. 793
ZA),
(lane protein
subunit
(lane
the an extra
2) and rGST-P migrated
to
41,
and all
of
GST-P
(Fig.
2B).
(Table
previously
(6).
the
N-terminus
deduced
from
contained
culture
of E. coli
band
to liver
from
with
500 ml of the
fraction
extra
described
the
pKKGP5 exhibited
the
units/mg
the
transformed
chromatography
rat
residues
in
with in
the antibody
was 11.3
of liver 20 amino
was identical However,
GST-P
from
On SDS-PAGE (Fig.
affinity
with
site,
Shine-Dalgarno
E. coli
protein
obvious
(lane
reacted
as the
transformed
was not
as authentic
activity
upstream
above.
by S-hexylglutathione
similarly
8 bases
of GST-P gene.
pKKS as a control
same position
binding
1 mg of rGST-P
of E. Coli 21,
a ribosomal
GST-P cDNA was used
expression
conditions
(lane
with
The specific
at
the
contain
pKKGP5 located
approximately
3) purified
these
not
plasmid
ATG of the
extract band
coli
cDNA did
efficient
pKKGP5 produced
cell
the
codon
sequence
Escherichia
the
21,
lower
The of the cDNA base
a methionine
Vol.
179, No. 2, 1991
BIOCHEMICAL
Ml
2
AND BIOPHYSICAL
3
1
4
RESEARCH COMMUNICATIONS
2
3
4
Fin. 2. SDS-PAGE and Western blotting of rGST-P expressed in E. coli. ALiquots of the cell free extract of E. coli JM109 transformed~lasmid pKKS or pKKGP5, purified rGST-P and 1-T-P were subjected to SDS-PAGE (A) according to the method of Laemmli (10) and Western blotting (B) as described by Towbin et al. (11). Lanes 1 and 2, extracts (200 pg each) of E. coli containing pKKS and pKKGP5, respectively. Lane 3, rGST-P (1.5 pg) purified from E. coli extract by S-hexylglutathione affinity chromatography; lane 4, purifiedliver GST-P (1.0 pg). Lane M, marker proteins; phosphorylase a (94 kDa), bovine serum albumin (67), ovalbumin (431, carbonic anhydrase (30), soybean trypsin inhibitor (20.1) and(Y-lactoalbumin (14.4). Proteins were stained with Coomassie Brilliant Blue. In Pig. B, immunostaining using anti-GST-P antibody was performed on the proteins separated in A.
Kinetic
Properties As
shown
specific for
either
of
and
mM, of
the
Table
2,
activities
values
0.30
in
of
GSH the
the
than and
Type
Ala
101
Ala14,
CDNB
two
three
Wild
were
and
substrates
at
1 mM.
than
those
type
(Table
2).
For
2.
Ala69
Ala47,
larger
Table
Mutants
Specific
Wild
activity
wild
type
11.3
the
-
0.11
and type
Ala
all
kinetic and
14
forms
higher
type the
GSH,
(0.10 CDNB,
wild
fixing
For
rGST-P
significantly
the
by
activities rGST-P
of had
and
determined
times
wild
Specific
and
(rGST-P).
Km
concentration Km value mM)
of
had
of of
the
Ala47 other
similar
properties
11.0
47
12.3
Ala
of
101
20.6
the
Ala
169
18.5
(units/mg) Km for
GSH (mM)*
0.11
0.10
0.30
0.11
0.11
Km for
CDNB
5.0
5.0
5.0
4.9
5.0
*
calculated
(mM)* from
Lineweaver-Burk
plot.
794
mutants
Km values.
mutants
Ala
was
Vol.
BIOCHEMICAL
179, No. 2, 1991
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Preincubation Fip. 3. Inactivation and cystamine (B). each) were incubated Ala47; n , AlalOl;
Inactivation
of
Ala101
and
shown
These
3A,
NEM
with
a similar
However,
Ala14
and
4A
nonreducing
After
treatment molecular
the
native
GST-P
48,
but be
not
in
produced
CyslOl
this
within
Ala47 in
more
and (lane
association a subunit
of extra
with DTT band
Ala169 3)
of
(lane and
of
a Mr (lane (21.5 5)
as (lane
disulfide
GST-P
the
kDa)
was
well
as 41,
(lane
with
the
in
wild
band
was
bond
cystamine
an
addition it of in
the
Ala14
type
(lane
considered
between formation),
extra to
but
detected
type.
buffer.
of
2),
the
formation
wild
restoration
also
with 3B).
by
in
kDa
inacti-
sample
detected
disulfide
795
than
the
is
inactivated (Fig.
kDa
23.5
the
GST-P
amount
along
5 min, activity.
residue
to
a small
of
for the
inactivated from
Ala14,
47-Cys
30 min,
3)
of
was
liver
removed
bond
(intra-subunit
the
inactivated
was
and
mM NEM 80%
Ala101 and
liver
Cystamine
resistant
while
was
21.5
Ala101
with
more
type
for
(Mr)
also
strongly
MCE
0.1
only
and type
about
that
wild
patterns
band
Because 2)
others,
the
i.e.
subunit addition
lane
the to
NEM
wild
with
report
1 mM cystamine
after
the
retained
was
were
weight
by
of
Ala47 than
SDS-PAGE
Mutants
still
previous
manner
with
with
(Fig.
our
Ala
preincubation
Ala47
conditions;
band
activity.
after
Ala169,
shows
under
disappeared
lost whereas
1 mM cystamine in
and activities
inactivation.
cystamine
Fig.
Type) initial
confirmed
in
vation
the
were
Fig.
results
involved
(Wild
90% of
Ala169 in
30
Time (min.)
of the rGST-P (wild type) and Ala mutants by NEM (A) Purified wild type and Ala mutants of rGST-P (0.1 unit A, Ala14; 0, with 0.1 mM NEM or 1 mM cystamine. A, Ala169; 0, wild type.
rGST-P
than
More
as
20
10
6
1) to
Cys47 causing
and
Vol.
179, No. 2, 1991
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Fie. SDS-PAGE of GST-P, the wild type and the Ala mutants under the nonreducing conditions. In Fig. A., 5 pg of protein was used for each lane. Lane 1, nontreated GST-P; lane 2, GST-P treated with 1 mM cystamine for 30 min; lane 3, GST-P reactivated with DTT. In Fig. B, the wild type and the Ala mutants were similarly treated with 1 mM cystamine for 30 min, as in Fig. 3B. 4 pg of protein was used for each lane. Lane 1, the wild lanes 2 to 5, Alal4, Ala47, Ala101 and Ala169, respectively. M, the type; same standard proteins as used in Fig. 2. Molecular weights (kDa) of extra GST-P bands are relative values estimated on the assumption of the native GST-P subunit being 23.5 EDa. Proteins were stained with Coomassie Brilliant Blue.
the
apparent
extra
band
(23.5
kDa),
reduction with
between
disulfide
bond
shown),
that
Ala14
wild
type
the
and and
extra
mutants
band than
but
of
the
reported
complete
GST-P
inactivated
Taken
together,
vicinity
weight
NEM
to
the
a low
explained
(Fig.
GSH,
by
thiol/disulfide
thought
21.5
kDa
the to
by that
the
47-Cys
The
fact than
larger
the
amounts
produced
with
inactivates
DTT
treatment
the
formation of
the
of
these
and
alkylation
an in
796
the
may
element cells
and
by
of
disulfide
addition
(3).
with the
in
the
group
of
the
low
molecular
binding
the
occurrence
(1.2)
which
facilitate
(2).
located
thiol
disturb
processes,
or
and
affinity be
exchange
important the
may of
GST-P
inactivation
column residue
carcinogenic
ratio
the
(results
cystamine
that were
at
range
formation.
mechanism(s)
metabolites
be
cystamine
formation
a basic
(H202)
thiol/disulfide
oxygen In
with
GST-P
S-hexylglutathione
that site,
of
4B).
the
its
binding
site.
of
suggesting
lost
active
evidence
achieved
in
(inter-subunit
by
the
bond
subunits
inactivated by
another subunit
disulfide
disulfide
bond
showed GST-P
with
toward
peroxide
is
NEM
is
disulfide
mixed
4)
native
produced
shift
strongly
modulation
active
with
type
by
GSH or
with pI
hydrogen
(lane the
different
from
that
of
inactivation
weight
involved
or
stress
be
speculate
disulfides
oxidative induce
the
by
the
more
be
we
of
residue
GSH
again
in
mostly
wild
with
may
residues
reactivation
thioltransferase
bond(s)
be
molecular
with
We have -r,
can
with
might
partly were
3B)
a dimer
evident
further
Ala101
that
Thus,
was
mutant
twice
associated
Ala169
(Fig.
The
about
47-Cys
be
as
(3).
kDa,
formation). to
residue,
not
Mr
37 that
the
considered
47-Cys
of
suggesting
formation
was
in
Mr
of of might
formation
Vol.
179,
of
No.
protein
which
are
control of
mixed
disulfides.
increased
in
at the
their
BIOCHEMICAL
2, 1991
roles
AND
The possibility
preneoplastic
thiol/disulfide in carcinogenesis
BIOPHYSICAL
RESEARCH
that
GST forms
and neoplastic
level,
is
and drug
of great
cells, interest
COMMUNICATIONS
in Class
might for
Pi,
be under elucidation
metabolism.
ACKNOWLEDGMENT Tokyo
The authors thank for the generous
Professor Masami Muramatsu gift of plasmid pGP5.
of
the University
of
REFERENCES 1.
2. 3. 4.
Sato, K. (1989) Adv. Cancer Res. 52, 205-255. Tamai, K., Satoh, K., Tsuchida, S., Hatayama, I., Maki, T., K. (1990) Biochem. Biophys. Res. Commun. 167, 331-338. Shen, H., Tamai, K., Satoh, K., Hatayama, I., Tsuchida, S., K. (1991) Arch. Biochem. Biophys. 286, 178-182. Schaffer, J., Gallay, O., and Ladenstein, R. (1988) J. Biol. 263,
5. 6. 7. 8. 9. 10. 11. 12.
and Sato, and Sato, Chem.
17405-17411.
Ricci, G., Del Boccio, G., Pennelli, A., Aceto, A., Whitehead, E. P., and Federici, G. (1989) J. Biol. Chem. 264, 5462-5467. Satoh, K., Kitahara, A., Soma, Y., Inaba, Y., Hatayama, I., and Sato, K. (1985) Proc. Natl. Acad. Sci. USA. 82, 3964-3968. Habig, W. H., Pabst, M. J., and Jakoby, W. B. (1974) J. Biol. Chem. 249, 7130-7139. Sugioka, Y., Kano, T., Okuda, A., Sakai, M., Kitagawa, T., and Muramatsu, M. (1985) Nucleic Acids Res. 13, 6049-6057. Sanger, F., Nicklen, S., and Coulson, A, R. (1977) Proc. Natl. Acad. Sci. USA. 74, 5463-5467. Laemmli, U. K. (1970) Nature 227, 680-685. Towbin, H., Staehelin, T., and Gordon, J. (1979) Proc. Natl. Acad. Sci. USA. 76, 4350-4354. Cerutti, P. A. (1985) Science 227, 375-381.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
16, 1991
Role
Pages
of
Gysteine
Residues
in
the
Transferase
ELUCIDATION Katsuto
Tamai,*
Hongxie
Satoh,*
* Second
Department
Akira
Shen ,* Yasui,t
t the
Received
August
Tuberculosis
Pharmacology
of
SITE-DIRECTED
Shigeki
Tsuchida,*
Atsushi
Oikawa,t Hirosaki
Hirosaki
036,
Division,
and Cancer,
Rat
Glutathione
(7-7):
of Biochemistry, Medicine,
for
P
BY OLIGONUCLEOTIDE
Kimihiko
Institute
Activity
790-797
Tohoku
MUTAGENESIS' Ichiro
Hatayama,* Sato *,2
and Kiyomi University
School
of
Japan the Research University,
Sendai,
980, Japan
1, 1991
Sumnary: To clarify the role(s) of thiol (sulfhydryl) groups of cysteine (Cys) residues in the activity of the rat glutathione transferase P (7-7) pGP5, containing the entire coding sequence of form (GST-P), a cDNA clone, GST-P (Y. Sugioka et al., (1985) Nucleic Acids Res. 12, 6044-6057) was inserted into the expression vector pKK233-2 and the recombinant GST-P (rGST-P) expressed in E. coli JMl09. All four Cys residues in rGST-P were independently substitu-h alanine (Ala) by site-directed mutagenesis, the resultant mutants as well as the rGST-P being identical to GST-P purified from Liver preneoplastic nodules with regard to molecular weight and immunochemical staining. Since all mutants proved as enzymatically active towards I-chloro-2,4-dinitrobenzene as Liver GST-P, it was indicated that none of the four Cys residues is essential for GST-P activity. However, the mutant with Ala at the 47th position from the N-terminus (Ala47) became resistant to irreversible inactivation by 0.1 mM N-ethylmaleimide (NEM), whereas the other three mutants remained as sensitive as the nonmutant type (rGST-P). Ala47 was also resistant to inactivation by the physiological disulfides, cystamine or cystine, which cause mixed disulfide and/or intraor inter-subunit disulfide bond formation. These results suggest that the 47-Cys residue of GST-P may be located near the glutathione binding site, and modulation of this residue by thiol/disulfide exchange may play an important role in regulation of activity. 0 1991 Academic Press, Inc.
This work was supported in part by Grants-in-Aid for Cancer Research rom the Ministry of Education, Science and Culture of Japan. To whom correspondence should be addressed. Abbreviations used: GST, glutathione transferase; GST-P, rat GST 7-7; recombinant GST-P; SDS-PAGE, sodium dodecyl sulfate-polyacrylamide rGST-P, NEM, N-ethylmaleimide; MCE, 2-mercaptoethanol; CDNB, gel electrophoresis; 1-chloro-2,4-dinitrobenzene; GSH, reduced glutathione; DTT, dithiothreitol; IPTG, isopropyl-H-D-thiogalactopyranoside; EDTA, kbp._ . kilo base pairs: ethylene diaminetetraacetic acid; PMSF, pheny lmethylsulfony 1 fluoride; &, dUTPase; ""g, uracil N-glucosylase; MCS, multi-cloning site. DDO6-291X/91 Copyright All rights
$1.50
0 1991 by Academic Press. Inc. of reproduction in any form reserved.
790
Vol.
179,
No.
We have Class be
Pi;
namely
for
from
the
which
playing
has
to been
In the
other
or
cystine,
the
MATERIALS
roles
Cys
using
AND
(2).
in
residues
the
catalytic role
of
site-directed
the
class
thiol
N-ethyl-
47th
peroxide
position
be
responsible
laboratories
erythrocyte
GSTs
can
hydrogen
may
other
horse to
Pi
as
in
GST-MI1
e.g.
subunits
and
2.5.1.18)
mouse
such at
COMMUNICATIONS
, EC
modifiers;
from
had
GST
(5),
also
both
group-modifiers. have
thiol
groups
reaction.
played
GST-P
with
residue
sensitive the
irreversible
thiol
Cys
(4)
that
the
together
Reports
are
(GSTs
respective
GST
Pi,
study,
respectively
clarified
NEM
RESEARCH
metabolites
the
the
placenta
present three
of of
suggested
functional
with oxygen
alteration
Class
GST-7T
treatment
N-terminus
bovine
BIOPHYSICAL
transferases
human
active
with
belong it
Thus,
or
inactivation that
and
by
that the
AND
glutathione
GST-P
(1,2)
and
(31,
described
was
rat
(NEM)
(47-Cys)
that
inactivated
maleimide
of
reported
markedly
(H202)
BIOCHEMICAL
2, 1991
in and
by
thiol
groups
inactivation
by
reversible
thiol
of NEM
the and
47th
and
cystamine
group-modifiers,
mutagenesis.
METHODS
Materials. Plasmid pKK233-2 was purchased from Amersham. Plasmid pGP5, containing 734 bp of GST-P cDNA ligated to pUC8, was the generous gift of Dr. M. Muramatsu, University of Tokyo. E. coli JM109, CJ236 and MV1190 T4 DNA ligase, T4 kinase, and the Klenow were obtained from Bio-Rad. fragment of DNA polymerase I were from Takara Shuzo Co. (Kyoto). Cystine, cystamine and CDNB were from Wako Pure Chemical Industries (Tokyo). All other chemicals were of analytical grade. GST preparations and assay. Rat GST-P was purified from livers bearing preneoplastic hyperplastic nodules, the antibody being prepared as described previously (6). GST activity was assayed using CDNB as substrate as described by Habig et al. (7). Construction of expression vector of GST-P cDNA. The plasmid pKKS was constructed to contain an additional WI site in the multiple cloning site (MCS) of pKK233-2 as follows. The plasmid pKK233-2 was restricted with EcoRI and Sal1 to remove an internal SphI site located outside of the Y MCS, treated wiTthe Klenow fragment, and ligated with T4 DNA ligase. A 18 bp fragment containing an WI site was isolated from the plasmid pUC18 by digestion with PstI and HindIII, and inserted between PstI and Hind111 7 sites in the MCS of the pKK233-2, and the resultant plasmid was designated Two synthesized oligonucleotides (61 bases and the complepKKS (Fig. 1). mentary 53 bases) coding 20 amino acids from the N-terminus of GST-P were annealed and the double strand fragment was ligated at the NcoI and WI sites with the expression vector pKKS. This construct (pKKS-PI) was digested with HindIII, treated with the Klenow fragment of DNA polymerase I and digested with S+I. The resulting 3.8 kbp fragment was separated by electrophoresis on 0.75% agarose gel and extracted. The plasmid pGP5 containing the full length cDNA of rat GST-P (81, was cleaved at the SalI 7 site, treated with the Klenow fragment, and then cleaved at the -1 site. This 670 bp fragment containing the cDNA encoding amino acids from number 21 to the end of GST-P was inserted into. pKKS-Pl between the *I and Klenow fragment-treated HindIII sites. The resulting expression vector of GST-P was designated pKKGP5 (Fig. 1). E. coli JM109 cells transformed Expression and purification of rGST-P. with the plasmid pKKGP5 were grown overnw be confluent in 10 ml of LB medium supplemented with 50 ug/ml ampicillin at 37°C with vigorous shaking. The medium was mixed with 1 1 of fresh LB medium, and cultured
791
Vol.
BIOCHEMICAL
179, No. 2, 1991
partially
synthesized
GST-P
5’ CATG inserted of pKKS
N and
RESEARCH COMMUNICATIONS
NPSH
cDNA
CATG between
AND BIOPHYSICAL
3
S sites
S
F.&.-L Construction of the expression vector of GST-P cDNA. N, P, S, H, E, HI1 and Sal represent recognition sites of restriction enzymes -1, %I, WI, Hi&III, %I, H&II, and XI, respectively. Ptac, -tat resistance gene. The inserted GST-P cDNA is promoter; Amp , ampicillin shown to consist of two shadowed portions separately constructed.
for about 2 h. At log phase, IPTG was added at a final 1 mM concentration. After an additional 14 h culture, the cells were harvested by centrifugation, resuspended in 10 ml of the lysing buffer (20 mM Tris-HCl, pH 8.0, 1 mM 22 mM NH4C1, 0.1 mM PMSF), and disrupted DTT, 1 mM EDTA, 5% (v/v) glycerol, using a sonicator (Model 200M, Kubota, Tokyo). The cell free extract obtained by centrifugation at 105,OOOxg for 60 min at 0°C was subjected to affinity chromatography as described previously (6). A HincII fragment (Fig. Construction and expression of Ala mutant GST-P. 1) was isolated from the pKKGP5 and inserted into the phage M13mp19 to produce M13mp19-GP5. This derivative was used as a single strand DNA template for mutagenesis of the respective Cys-residues at the 14th, 47th, 1Olst and 169th positions. E. coli CJ236 (dut , 9 ) were grown overnight in 10 ml of YT medium containing3mp19-GP5 phages and 34 pg/ml chloramphenicol at 37°C with vigorous shaking. The medium was centrifuged for 10 min at 2OOOxg, and 1 ml of supernatant containing Ml3mp19-GP5 phages and 1 ml of the E. Coli CJ236 overnight culture were mixed together with 100 ml of YT mediumagain incubated overnight. The culture medium was centrifuged at 10,OOOxg for 10 min, and supernatant was used as the template DNA. One tenth pmol of the template DNA was annealed with 20 pmol of the synthetic oligonucleotides shown in Table 1 in lop1 of annealing buffer (20 mM TrisHCl, pH 7.4, 10 mM MgC12, 50 mM NaCl). After primer extension a?d liga+tion, the DNA was used to transform the competent E. coli MV 1190 (E , 3 >. The transformed cells were plated on 2% agarxning YT medium, and incubated overnight at 37°C. Ten clear plaques were picked up to prepare single stranded and replicative form DNAs of M13mp19-GP5.
792
Vol.
179,
No.
BIOCHEMICAL
2, 1991
Table
1.
Nucleotide
sequences
used
Position
of
AND
for
site
of
BIOPHYSICAL
the
RESEARCH
synthetic
directed
COMMUNICATIONS
oligonucleotides
mutagenesis
Sequence
cysteine
changed
14
TGT -.GCT
5'-CCAGTTCGAGGGCG&TGAGGCCACGCGCATG-3'
47
TGT +GCT
5'-TCGCTCAAGTCCACTgCTGTATGGGCAGCTC-3'
101
TGC + GCC
169
TGC -
5'-GTGGAGGACCTTCGAEAAATATGGTACCCTCA-3' 5'-CTGGCCCCTGCC%CTGGACAACTTCCCCCTG-3' -
*
position
of
Synthetic
GCC
changed
oligonucleotide
sequence
sequence.
To select single stranded M13mp19-GP5 inclyging the desired mutation, dot blot hybridization was carried out with 5'P-labeled synthetic oligonucleotides containing the respective mutations. DNAs that gave positive signals were sequenced to confirm the mutations (9). Replicative forms of the M13mpl9-GP5 were restricted with HincII and ligated at two HincII sites of the expression plasmid pKKS. The plasmid DNAs were used to transform E. coli JMl09, and the mutants of rGST-P (Ala14, Ala47, Ala101 and Ala1691 were expressed and purified using the same method as used for the wild type rGST-P.
RESULTS AND DISCUSSION GST-P
Expression Since
in
rat
GST-P
AGGA sequence initiation
in
for
medium
under free
protein infected (lane the
bands
than
that
sequence rGST-P sequence the
described
which
JM109
(15 units/mg) of the
subunit (8).
1).
first
of
rGST-P
This
from
GST-P acid
liver
with
60% of the
that
of GST-P
rGST-P
N-terminus. 793
ZA),
(lane protein
subunit
(lane
the an extra
2) and rGST-P migrated
to
41,
and all
of
GST-P
(Fig.
2B).
(Table
previously
(6).
the
N-terminus
deduced
from
contained
culture
of E. coli
band
to liver
from
with
500 ml of the
fraction
extra
described
the
pKKGP5 exhibited
the
units/mg
the
transformed
chromatography
rat
residues
in
with in
the antibody
was 11.3
of liver 20 amino
was identical However,
GST-P
from
On SDS-PAGE (Fig.
affinity
with
site,
Shine-Dalgarno
E. coli
protein
obvious
(lane
reacted
as the
transformed
was not
as authentic
activity
upstream
above.
by S-hexylglutathione
similarly
8 bases
of GST-P gene.
pKKS as a control
same position
binding
1 mg of rGST-P
of E. Coli 21,
a ribosomal
GST-P cDNA was used
expression
conditions
(lane
with
The specific
at
the
contain
pKKGP5 located
approximately
3) purified
these
not
plasmid
ATG of the
extract band
coli
cDNA did
efficient
pKKGP5 produced
cell
the
codon
sequence
Escherichia
the
21,
lower
The of the cDNA base
a methionine
Vol.
179, No. 2, 1991
BIOCHEMICAL
Ml
2
AND BIOPHYSICAL
3
1
4
RESEARCH COMMUNICATIONS
2
3
4
Fin. 2. SDS-PAGE and Western blotting of rGST-P expressed in E. coli. ALiquots of the cell free extract of E. coli JM109 transformed~lasmid pKKS or pKKGP5, purified rGST-P and 1-T-P were subjected to SDS-PAGE (A) according to the method of Laemmli (10) and Western blotting (B) as described by Towbin et al. (11). Lanes 1 and 2, extracts (200 pg each) of E. coli containing pKKS and pKKGP5, respectively. Lane 3, rGST-P (1.5 pg) purified from E. coli extract by S-hexylglutathione affinity chromatography; lane 4, purifiedliver GST-P (1.0 pg). Lane M, marker proteins; phosphorylase a (94 kDa), bovine serum albumin (67), ovalbumin (431, carbonic anhydrase (30), soybean trypsin inhibitor (20.1) and(Y-lactoalbumin (14.4). Proteins were stained with Coomassie Brilliant Blue. In Pig. B, immunostaining using anti-GST-P antibody was performed on the proteins separated in A.
Kinetic
Properties As
shown
specific for
either
of
and
mM, of
the
Table
2,
activities
values
0.30
in
of
GSH the
the
than and
Type
Ala
101
Ala14,
CDNB
two
three
Wild
were
and
substrates
at
1 mM.
than
those
type
(Table
2).
For
2.
Ala69
Ala47,
larger
Table
Mutants
Specific
Wild
activity
wild
type
11.3
the
-
0.11
and type
Ala
all
kinetic and
14
forms
higher
type the
GSH,
(0.10 CDNB,
wild
fixing
For
rGST-P
significantly
the
by
activities rGST-P
of had
and
determined
times
wild
Specific
and
(rGST-P).
Km
concentration Km value mM)
of
had
of of
the
Ala47 other
similar
properties
11.0
47
12.3
Ala
of
101
20.6
the
Ala
169
18.5
(units/mg) Km for
GSH (mM)*
0.11
0.10
0.30
0.11
0.11
Km for
CDNB
5.0
5.0
5.0
4.9
5.0
*
calculated
(mM)* from
Lineweaver-Burk
plot.
794
mutants
Km values.
mutants
Ala
was
Vol.
BIOCHEMICAL
179, No. 2, 1991
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Preincubation Fip. 3. Inactivation and cystamine (B). each) were incubated Ala47; n , AlalOl;
Inactivation
of
Ala101
and
shown
These
3A,
NEM
with
a similar
However,
Ala14
and
4A
nonreducing
After
treatment molecular
the
native
GST-P
48,
but be
not
in
produced
CyslOl
this
within
Ala47 in
more
and (lane
association a subunit
of extra
with DTT band
Ala169 3)
of
(lane and
of
a Mr (lane (21.5 5)
as (lane
disulfide
GST-P
the
kDa)
was
well
as 41,
(lane
with
the
in
wild
band
was
bond
cystamine
an
addition it of in
the
Ala14
type
(lane
considered
between formation),
extra to
but
detected
type.
buffer.
of
2),
the
formation
wild
restoration
also
with 3B).
by
in
kDa
inacti-
sample
detected
disulfide
795
than
the
is
inactivated (Fig.
kDa
23.5
the
GST-P
amount
along
5 min, activity.
residue
to
a small
of
for the
inactivated from
Ala14,
47-Cys
30 min,
3)
of
was
liver
removed
bond
(intra-subunit
the
inactivated
was
and
mM NEM 80%
Ala101 and
liver
Cystamine
resistant
while
was
21.5
Ala101
with
more
type
for
(Mr)
also
strongly
MCE
0.1
only
and type
about
that
wild
patterns
band
Because 2)
others,
the
i.e.
subunit addition
lane
the to
NEM
wild
with
report
1 mM cystamine
after
the
retained
was
were
weight
by
of
Ala47 than
SDS-PAGE
Mutants
still
previous
manner
with
with
(Fig.
our
Ala
preincubation
Ala47
conditions;
band
activity.
after
Ala169,
shows
under
disappeared
lost whereas
1 mM cystamine in
and activities
inactivation.
cystamine
Fig.
Type) initial
confirmed
in
vation
the
were
Fig.
results
involved
(Wild
90% of
Ala169 in
30
Time (min.)
of the rGST-P (wild type) and Ala mutants by NEM (A) Purified wild type and Ala mutants of rGST-P (0.1 unit A, Ala14; 0, with 0.1 mM NEM or 1 mM cystamine. A, Ala169; 0, wild type.
rGST-P
than
More
as
20
10
6
1) to
Cys47 causing
and
Vol.
179, No. 2, 1991
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Fie. SDS-PAGE of GST-P, the wild type and the Ala mutants under the nonreducing conditions. In Fig. A., 5 pg of protein was used for each lane. Lane 1, nontreated GST-P; lane 2, GST-P treated with 1 mM cystamine for 30 min; lane 3, GST-P reactivated with DTT. In Fig. B, the wild type and the Ala mutants were similarly treated with 1 mM cystamine for 30 min, as in Fig. 3B. 4 pg of protein was used for each lane. Lane 1, the wild lanes 2 to 5, Alal4, Ala47, Ala101 and Ala169, respectively. M, the type; same standard proteins as used in Fig. 2. Molecular weights (kDa) of extra GST-P bands are relative values estimated on the assumption of the native GST-P subunit being 23.5 EDa. Proteins were stained with Coomassie Brilliant Blue.
the
apparent
extra
band
(23.5
kDa),
reduction with
between
disulfide
bond
shown),
that
Ala14
wild
type
the
and and
extra
mutants
band than
but
of
the
reported
complete
GST-P
inactivated
Taken
together,
vicinity
weight
NEM
to
the
a low
explained
(Fig.
GSH,
by
thiol/disulfide
thought
21.5
kDa
the to
by that
the
47-Cys
The
fact than
larger
the
amounts
produced
with
inactivates
DTT
treatment
the
formation of
the
of
these
and
alkylation
an in
796
the
may
element cells
and
by
of
disulfide
addition
(3).
with the
in
the
group
of
the
low
molecular
binding
the
occurrence
(1.2)
which
facilitate
(2).
located
thiol
disturb
processes,
or
and
affinity be
exchange
important the
may of
GST-P
inactivation
column residue
carcinogenic
ratio
the
(results
cystamine
that were
at
range
formation.
mechanism(s)
metabolites
be
cystamine
formation
a basic
(H202)
thiol/disulfide
oxygen In
with
GST-P
S-hexylglutathione
that site,
of
4B).
the
its
binding
site.
of
suggesting
lost
active
evidence
achieved
in
(inter-subunit
by
the
bond
subunits
inactivated by
another subunit
disulfide
disulfide
bond
showed GST-P
with
toward
peroxide
is
NEM
is
disulfide
mixed
4)
native
produced
shift
strongly
modulation
active
with
type
by
GSH or
with pI
hydrogen
(lane the
different
from
that
of
inactivation
weight
involved
or
stress
be
speculate
disulfides
oxidative induce
the
by
the
more
be
we
of
residue
GSH
again
in
mostly
wild
with
may
residues
reactivation
thioltransferase
bond(s)
be
molecular
with
We have -r,
can
with
might
partly were
3B)
a dimer
evident
further
Ala101
that
Thus,
was
mutant
twice
associated
Ala169
(Fig.
The
about
47-Cys
be
as
(3).
kDa,
formation). to
residue,
not
Mr
37 that
the
considered
47-Cys
of
suggesting
formation
was
in
Mr
of of might
formation
Vol.
179,
of
No.
protein
which
are
control of
mixed
disulfides.
increased
in
at the
their
BIOCHEMICAL
2, 1991
roles
AND
The possibility
preneoplastic
thiol/disulfide in carcinogenesis
BIOPHYSICAL
RESEARCH
that
GST forms
and neoplastic
level,
is
and drug
of great
cells, interest
COMMUNICATIONS
in Class
might for
Pi,
be under elucidation
metabolism.
ACKNOWLEDGMENT Tokyo
The authors thank for the generous
Professor Masami Muramatsu gift of plasmid pGP5.
of
the University
of
REFERENCES 1.
2. 3. 4.
Sato, K. (1989) Adv. Cancer Res. 52, 205-255. Tamai, K., Satoh, K., Tsuchida, S., Hatayama, I., Maki, T., K. (1990) Biochem. Biophys. Res. Commun. 167, 331-338. Shen, H., Tamai, K., Satoh, K., Hatayama, I., Tsuchida, S., K. (1991) Arch. Biochem. Biophys. 286, 178-182. Schaffer, J., Gallay, O., and Ladenstein, R. (1988) J. Biol. 263,
5. 6. 7. 8. 9. 10. 11. 12.
and Sato, and Sato, Chem.
17405-17411.
Ricci, G., Del Boccio, G., Pennelli, A., Aceto, A., Whitehead, E. P., and Federici, G. (1989) J. Biol. Chem. 264, 5462-5467. Satoh, K., Kitahara, A., Soma, Y., Inaba, Y., Hatayama, I., and Sato, K. (1985) Proc. Natl. Acad. Sci. USA. 82, 3964-3968. Habig, W. H., Pabst, M. J., and Jakoby, W. B. (1974) J. Biol. Chem. 249, 7130-7139. Sugioka, Y., Kano, T., Okuda, A., Sakai, M., Kitagawa, T., and Muramatsu, M. (1985) Nucleic Acids Res. 13, 6049-6057. Sanger, F., Nicklen, S., and Coulson, A, R. (1977) Proc. Natl. Acad. Sci. USA. 74, 5463-5467. Laemmli, U. K. (1970) Nature 227, 680-685. Towbin, H., Staehelin, T., and Gordon, J. (1979) Proc. Natl. Acad. Sci. USA. 76, 4350-4354. Cerutti, P. A. (1985) Science 227, 375-381.