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J. Biol. Chem., Vol. 277, Issue 50, 47980-47990, December 13, 2002
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From the
Received for publication, August 2, 2002, and in revised form, September 19, 2002
The overexpression of the human ATP-binding
cassette half-transporter, ABCG2 (placenta-specific ABC transporter,
mitoxantrone resistance-associated protein, breast cancer resistance
protein), causes multidrug resistance in tumor cells. An altered drug
resistance profile and substrate recognition were suggested for
wild-type ABCG2 and its mutant variants (R482G and R482T); the
mutations were found in drug-selected tumor cells. In order to
characterize the different human ABCG2 transporters without possible
endogenous dimerization partners, we expressed these proteins and a
catalytic center mutant (K86M) in Sf9 insect cells. Transport
activity was followed in intact cells, whereas the ATP binding and
hydrolytic properties of ABCG2 were studied in isolated cell membranes.
We found that the K86M mutant had no transport or ATP hydrolytic activity, although its ATP binding was retained. The wild-type ABCG2
and its variants, R482G and R482T, showed characteristically different
drug and dye transport activities; mitoxantrone and Hoechst 33342 were
transported by all transporters, whereas rhodamine 123 was only pumped
by the R482G and R482T mutants. In each case, ABCG2-dependent transport was blocked by the specific
inhibitor, fumitremorgin C. A relatively high basal ABCG2-ATPase,
inhibited by fumitremorgin C, was observed in all active proteins, but
specific drug stimulation could only be observed in the case of R482G
and R482T mutants. We found that ABCG2 is capable of a
vanadate-dependent adenine nucleotide trapping. Nucleotide
trapping was stimulated by the transported compounds in the R482G and
R482T variants but not in the wild-type ABCG2. These experiments
document the applicability of the Sf9 expression system for
parallel, quantitative examination of the specific transport and ATP
hydrolytic properties of different ABCG2 proteins and demonstrate
significant differences in their substrate interactions.
The multidrug-resistant phenotype of malignant cells can often
account for the failure of chemotherapy in cancer patients. In many
cases multidrug resistance is caused by the activity of ABC1 transporters, including
MDR1/P-glycoprotein (1) and MRP1 (multidrug resistance-associated
protein) (2). ABC transporters cause multidrug resistance by extruding
their drug substrates from the resistant cells and maintaining
the level of these cytotoxic agents below cell-killing concentrations.
The human ABC half-transporter, ABCG2 (placenta-specific ABC
transporter/mitoxantrone resistance-associated protein/breast cancer
resistance protein), has been identified recently (3-5) as a candidate
protein responsible for cancer multidrug resistance. The overexpression
of ABCG2 was found in several drug-selected cell lines (6-10), and in
tumorous tissues of patients (11-13). The activity of the human ABCG2
was suggested to be the major cellular defense mechanism against the
cytotoxic drug, mitoxantrone (6), but several other drugs have also
been indicated as potential substrates of this drug pump (14).
The human ABCG2 protein belongs to the White (ABCG) subfamily of ABC
transporters. The members of this subfamily are ABC half-transporters, i.e. they contain only one ABC and one transmembrane domain.
The White protein, the Drosophila homolog of human ABCG2,
forms heterodimers and transports different eye pigment precursors
(15). However, the data in the literature (5, 16-19) suggest that
ABCG2 can function as a homodimer.
It has been shown recently (20) that in drug-selected human
tumor cells ABCG2 appears in three different forms, containing Arg,
Gly, or Thr at amino acid position 482. It was suggested that these
variants possess significant differences in their cross-resistance and
drug transport patterns (20). Interestingly, in some drug-selected mouse cell lines, mutation of the equipositional amino acid in mouse
ABCG2 occurred, causing altered drug resistance profiles for the mutant
variants R482S and R482M (21).
According to the published consensus sequence in the human genome data
base (GenBankTM accession number AF103796, see Ref.
3), Arg-482 is the wild-type form of ABCG2, and the other two
variants may appear only during drug selection (20, 22). Data
concerning the drug resistance patterns of mammalian cells expressing
ABCG2 are somewhat contradictory. In one study (20) the confirmed
wild-type form of ABCG2 produced significant mitoxantrone (MX)
resistance and efflux, whereas in another report (22) the wtABCG2 was
found to be inefficient in protecting cells from MX accumulation.
The baculovirus-Sf9 heterologous expression system has been
shown to be an excellent tool for producing high level expression of
biologically active ABC proteins, and isolated membranes from virus-infected cells are suitable for the investigation of the
transport, ATPase, and nucleotide trapping activity of these ABC
transporters (23-26). Previously, we demonstrated that the ABCG2-R482G
multidrug transporter could also be expressed in insect cells, allowing
the investigation of its membrane ATPase activity (18).
In the present study, we document the applicability of the
baculovirus-Sf9 expression system for measuring the
ABCG2-dependent transport of different fluorescent
compounds in intact insect cells. Notably, we also determined the
kinetics of ABCG2-dependent Hoechst 33342 transport. In
addition to the ATPase activity, the formation of a catalytic
intermediate of the ATPase cycle is a characteristic feature of ABC
transporter proteins (27-29). This fact allowed us to detect
8-azido-ATP binding and vanadate-dependent trapping by
ABCG2, which, as documented here, required the presence of
Co2+ cations.
We generated and expressed the human wild-type ABCG2 and its variants
R482G and R482T in Sf9 cells, and we characterized their transport and ATP hydrolytic activity. As a control, we mutated a
crucial amino acid in the catalytic center of ABCG2-R482G (Lys-86 was
changed to Met) in hope of producing a non-functional transporter. Here
we show that the expression of wtABCG2 and its variants could be
achieved with a high yield. We compared the ABCG2-dependent transport of various fluorescent compounds. In parallel experiments, we
investigated the ATP hydrolytic cycle of the ABCG2 protein in isolated
membrane preparations. The full catalytic cycle was studied by
measuring vanadate-sensitive, drug-stimulated ATPase activity. The
formation of a catalytic intermediate of this reaction was examined by
following vanadate- and Co2+-dependent adenine
nucleotide trapping. The parallel investigation of transport activity,
nucleotide trapping, and ATPase activity of wtABCG2 and its amino acid
482 variants allowed the comparison of the function of these proteins.
The heterologous Sf9 expression system has the special advantage
that insect ABC proteins probably do not form heterodimers with the
human ABCG2 protein, because this latter protein is expressed at a very
high level in these cells. Therefore, this system allows a quantitative
comparison of the substrate specificity and transport activity of
homodimer-forming variants of the human ABCG2 multidrug transporter.
The parallel transport and ATP hydrolysis studies presented below may
help to understand the molecular mechanism of action of these ABCG2 proteins.
Materials--
Mitoxantrone, doxorubicin, prazosin, verapamil,
rhodamine 123, sodium orthovanadate, propidium iodide, digitonin, and
ATP were purchased from Sigma. Hoechst 33342 was purchased from
Molecular Probes. FTC was kindly provided by Lee M. Greenberger
(Wyeth-Ayerst Research). Ko 143 was a generous gift from Drs. J. Allen
and G. Koomen (Division of Experimental Therapy, The Netherlands Cancer Institute, and Laboratory of Organic Chemistry, University of Amsterdam, Amsterdam, The Netherlands). 8-Azido-[ Generation of Transfer Vector Possessing Different Human ABCG2
cDNAs--
pAcUW21-L/ABCG2 (R482G) was constructed as described
(18). Wild-type ABCG2 (Arg-482) and its variants (R482T and K86M) were created using ABCG2-R482G cDNA as a template (4) by overlap extension PCR (30). Two internal complementary primer pairs were used
with each containing the specific mutation as follows: the Arg- primer
pairs were 5'-TTATTACCAATGCGCATGTTACC-3' and
5'-GGTAACATGCGCATTGGTAATAA-3'; the R482T primer pairs were
5'-TTATTACCTATGACGATGTTACC-3' and 5'-GGTAACATCGTCATAGGTAATAA-3'; and
the K86M primer pairs were 5'-TGGAGGCATGTCTTCGTTATT-3' and
5'-TAATAACGAAGACATGCCTCCA-3', respectively. The two outer primer
pairs were 5'-CTTGGGATACTTGAATCAGC-3' and 5'-GGTCATGAGAAGTGTTGCTA-3'
for the wild-type and the amino acid 482 variants and
5'-GTATATTAATTAAAATACTATACTG-3' and 5'-GGCTCATCCAAGAACAAGAT-3' for the
K86M mutant. The PCRs were performed as described previously (31). The
PCR products containing the Arg-482 or R482T coding sequence were
digested with PstI and MscI enzymes and ligated between the corresponding sites of the pAcUW21-L/ABCG2 vector. The PCR
product coding for the K86M variant was digested with NotI
and SpeI enzymes and ligated to the NotI and
SpeI sites of the pAcUW21-L/ABCG2 (R482G) vector. The
mutations were confirmed by sequencing the
PstI-MscI or the NotI-SpeI
fragments of the constructs, respectively.
Generation of Recombinant Baculoviruses--
Recombinant
baculoviruses, carrying the different human ABCG2 cDNAs, were
generated with the BaculoGold Transfection Kit (Pharmingen) according
to the manufacturer's instructions. Sf9 (Spodoptera frugiperda) cells were infected and cultured as described (32). Individual virus clones, expressing high levels of the different human
ABCG2 variants, were obtained by end point dilution and subsequent
amplification. ABCG2 protein expression was determined by
immunoblotting and immuno-flow cytometry (see below).
Cell Culturing and Tunicamycin Treatment--
HL60 cells,
infected with the retrovirus containing the cDNA of
wtABCG2,2 were cultured in
RPMI medium, supplemented with 10% fetal calf serum, 50 units/ml
penicillin and streptomycin, and 100 nM mitoxantrone at
37 °C in 5% CO2. For inhibition of
N-glycosylation, HL60/wtABCG2 cells were grown for 72 h
in a medium containing 2.5 µg/ml tunicamycin.
Membrane Preparation and Immunodetection of ABCG2--
After 3 days of virus infection, the Sf9 cells were harvested, and their
membranes were isolated. Membrane protein concentrations were
determined by the modified Lowry method as described (32). Immunoblotting was performed on membrane or cell extract samples as
described in Ref. 32. Different ABCG2 proteins were detected by the
monoclonal BXP-21 antibody (2000-fold dilution), which was kindly
provided by Drs. George Scheffer and Rik Scheper (33). The
protein-antibody interaction was visualized by the enhanced chemiluminescence technique (ECL, Amersham Biosciences) using anti-mouse horseradish peroxidase-conjugated secondary antibody (20,000-fold dilution, Jackson ImmunoResearch). Immuno-flow cytometry was performed by labeling the Sf9 cells (also used for dye
uptake studies; see below) at 4 °C, by using the anti-ABCG2
monoclonal antibody 5D3 (eBioscience), which recognizes a
cell-surface epitope on ABCG2. The antibody was used at a dilution of
1:500, and binding was visualized by the addition of a second,
phycoerythrin-conjugated anti-mouse IgG (Immunotech), at a dilution of
1:250. Flow cytometric determination of the antibody reaction was
carried out using a FACSCalibur cytometer (BD Biosciences).
Mitoxantrone or Rhodamine 123 Uptake in Intact Sf9
Cells--
40 h after infection with the ABCG2 cDNA-containing
baculoviruses, Sf9 cells were washed once and resuspended in
HPMI medium (120 mM NaCl, 5 mM KCl, 400 µM MgCl2, 40 µM
CaCl2, 10 mM Hepes, 10 mM
NaHCO3, 10 mM glucose, and 5 mM
Na2HPO4). Aliquots of the suspension,
containing 2-5 × 105 cells, were preincubated in the
presence or absence of an inhibitor (10 µM FTC or 1 µM Ko 143) or 10 µM prazosin for 5 min at
37 °C. The reaction was started by the addition of 1-20
µM MX or 2 µM rhodamine 123. After
incubation for 30 min at 37 °C, the cells were washed once with
ice-cold HPMI medium and then resuspended in ice-cold HPMI, containing
30 µg/ml propidium iodide. The cells were stored on ice until the
flow cytometric measurements. A FACSCalibur cytometer, equipped with a
488 nm argon and 635 nm red diode laser and 530- and 670-nm bandpass
filters, was used to determine the cellular fluorescence of rhodamine
123 and MX, respectively. 15,000 cells were counted; dead cells were
excluded based on propidium iodide staining.
Hoechst 33342 Dye Accumulation Assay--
Accumulation of
Hoechst dye (Hst) was measured in a fluorescence spectrophotometer at
350 nm (excitation)/460 nm (emission), by using 5 × 105 cells in 2 ml of HPMI solution. This dye becomes
fluorescent only in a complex with DNA (34). Cells were preincubated at 37 °C in HPMI for 4 min and further incubated with 2.5-5
µM Hst for 10 min. Subsequently the inhibitor FTC (10 µM) or Ko 143 (1 µM) was added to the
cells. The initial increase of fluorescence observed was due to a rapid
dye uptake and nuclear staining in dead cells, whereas further cellular
dye uptake was reflected by an increase in fluorescence. At the end of
each experiment, for standardization, a full cellular staining was
obtained by the addition of 8 µM digitonin, which
disrupts the integrity of the cell membrane.
ATPase Activity Measurement--
Isolated membranes of
Sf9 cells expressing ABCG2 were kept at 8-Azido-[
In the nucleotide trapping experiments isolated Sf9 cell
membranes (150 µg of protein) were incubated for 2-5 min at 37 °C in reaction buffer, with or without 1 mM sodium
orthovanadate, 0.05 MBq of 2-5 µM
8-azido-[
At the end of the binding and trapping experiments, the membranes were
suspended in disaggregation buffer, run on 10% Laemmli-type gels, and
electroblotted onto polyvinylidene difluoride membranes (Bio-Rad).
Labeling was detected by quantitative autoradiography in a
PhosphorImager (Bio-Rad). The labeling experiments were repeated two
times, and the figures show the results of one representative experiment. The identity of the
32P-azido-nucleotide-labeled bands was reconfirmed by
immunostaining the same blot with anti-ABCG2 BXP-21 antibody (see above).
Expression of Wild-type ABCG2 and Its Mutant Variants in Sf9
Cells--
We have shown earlier that the human ABCG2 multidrug
transporter can be expressed in its biologically active form in
Sf9 insect cells (18) similarly to other ABC proteins (23-26).
In the present study we utilized this expression system to produce the
wild-type human ABCG2 protein and its variants, R482G and R482T, as
well as a catalytic center mutant, K86M.
Site-directed mutagenesis was performed on a human ABCG2 cDNA,
which possesses Gly at position 482 (4), to create the wild-type (Arg-482) and the R482T and K86M variants of the ABCG2
half-transporter. Fig. 1A
shows the predicted membrane topology of the ABCG2 multidrug transporter and the localization of the mutated amino acids Lys-86 and
Arg-482.
Sf9 cells were transfected with recombinant baculoviruses
carrying the respective human ABCG2 cDNAs. The level of ABCG2
expression was detected by immunoblotting using the BXP-21 monoclonal
antibody (33). Fig. 1B demonstrates that all four ABCG2
proteins were successfully expressed in Sf9 cells. The level of
their expression was almost equal and about 60 times higher than that
of the expression obtained by retroviral transduction of the wtABCG2 in
HL60 cells.2 We have shown earlier that the human ABCG2 in
Sf9 cells was expressed in an underglycosylated form. As
documented in Fig. 1B, all the ABCG2 proteins expressed in
Sf9 cells migrated at an apparently lower molecular weight
(~60 kDa) than ABCG2 expressed in HL60 cells (about 70 kDa), but with
the same apparent molecular weight as the lower (non-glycosylated) band
in the tunicamycin-treated HL60 cells. Therefore, we conclude that
wtABCG2 and its variants are expressed underglycosylated in the insect
cells. Flow cytometry immuno-detection of cell surface expression of
ABCG2, determined by the 5D3 monoclonal antibody, also showed similar
expression levels for the wild-type ABCG2 and its mutant variants (see below).
Flow Cytometry Assay of Mitoxantrone and Rhodamine 123 Extrusion in
Intact Sf9 Cells, Expressing wtABCG2 and Its Mutant
Variants--
In order to investigate the transport characteristics of
the different ABCG2 proteins expressed in insect cells, we have
developed appropriate assay conditions for detecting the extrusion of
various fluorescent compounds by flow cytometry and/or
spectrofluorimetry in intact Sf9 cells. Based on exploring a
number of variables, we have established that 40 h after infection
with the ABCG2 cDNA-containing baculoviruses, the Sf9 cells
were suitable for intact cell assays. In this case heterologous
membrane protein expression reached a uniform and near-maximum level,
whereas cell destruction by baculovirus was limited to below 30%. We
have also established that HPMI medium (see "Experimental
Procedures") adjusted to pH 7.4 (the optimal pH for growing
Sf9 cells is 6.1) could be used in these transport experiments
without significant cell destruction in a time frame of up to 2 h
(data not shown in detail).
In order to assay fluorescent drug or dye uptake, Sf9 cells
under the above conditions were incubated with the assayed compounds for 30 min at 37 °C, and then the cells were washed and resuspended in ice-cold HPMI for flow cytometric measurements. Staining of the
samples with propidium iodide was used for gating out the dead cells
(see "Experimental Procedures"). In each experiment the expression
of the different ABCG2 proteins was determined by Western blotting of
the same cell preparations, to ensure equal levels of the ABCG2s in all
experiments. In parallel flow cytometric experiments, we have also
measured the cell surface expression of ABCG2 protein in Sf9
cells by the 5D3 monoclonal antibody, detecting an extracellular
epitope of human ABCG2 (35). We found equal expression levels for the
wild-type, R482G, R482T, and K86M/R482G mutant variants (data
not shown).
For blocking ABCG2-dependent drug or dye extrusion, we used
FTC, a specific inhibitor of this protein. As shown earlier, this agent
strongly inhibits ABCG2 function in micromolar concentrations in a
variety of cellular systems (36, 37), including the function of ABCG2
expressed in Sf9 cells (18). In order to ensure full blockade of
ABCG2-dependent transport (see below), we have used 10 µM FTC or its powerful analog Ko 143 (see Ref. 38). These compounds have no measurable fluorescence in the wavelength ranges applied here and therefore could be used in these experiments.
Fig. 2A shows MX accumulation
studies in intact Sf9 cells, expressing either the wild-type
ABCG2 or one of its mutant variants or
Prazosin, a known substrate of ABCG2 (16, 37), also increased the level
of MX accumulation in insect cells expressing the active ABCG2
proteins, whereas it had no effect on the cells expressing the K86M
mutant (see Fig. 2A). This observation indicates that
prazosin is a substrate of the wtABCG2 and its amino acid 482 variants.
In order to compare the MX transport capacity of the wtABCG2 and its
mutant variants, we applied a wide range of MX concentrations in
similar experiments. Fig. 2, B and C, compiles
the cellular fluorescence levels in these transport experiments by
using 1-20 µM MX concentrations, with or without the
addition of 10 µM FTC. As documented, at increasing MX
concentrations, the wild-type (R482) ABCG2 was found to be somewhat
less effective in protecting Sf9 cells against MX accumulation
than the other two amino acid 482 variants; the accumulation of MX was
about 15 ± 4% more in wtABCG2-expressing cells than in cells
containing the R482G or R482T variants. In addition, the MX transport
capacities of the amino acid 482 variants R482G and R482T were
found to be similar in these experiments.
Next we performed similar transport studies for the fluorescent dye
rhodamine 123, which was indicated to be a transported substrate of the
ABCG2 variants R482G and R482T (20). As shown in Fig.
3, we found that insect cells expressing
the wild-type ABCG2 or the K86M mutant accumulated significantly more
rhodamine 123 than cells expressing the R482G or R482T variants. In
contrast to that found for the wild-type ABCG2, in the R482G or R482T
variants the addition of FTC greatly increased rhodamine 123 accumulation indicating an ABCG2-dependent extrusion of
this compound.
These data support the fact that MX is a substrate for wtABCG2 and its
amino acid 482 variants, although MX transport may be less efficient by
the wild-type protein than by the R482G or R482T variants. In contrast,
the wild-type ABCG2 is practically inactive for rhodamine 123 transport, whereas the R482G and R482T mutants actively extrude this
fluorescent dye.
Kinetic Measurements of Hoechst 33342 Transport by wtABCG2 and Its
Mutant Variants in Intact Sf9 Cells--
The fluorescent dye
Hoechst 33342 (Hst) has been described to be a transported substrate of
ABCG2 present in mammalian cells (39). Moreover, stem cells expressing
human ABCG2 showed a decreased Hoechst 33342 dye accumulation (35). In
order to follow the kinetics of Hst dye accumulation in intact,
ABCG2-expressing Sf9 cells, we have developed an assay system
that allows the continuous detection of dye uptake. Hst dye penetrates
cells passively and becomes fluorescent only upon its rapid and strong
binding to DNA (34). Thus the increase in fluorescence intensity
directly reflects the rate of dye accumulation. Active dye extrusion
that prevents the increase of intracellular fluorescence can be
continuously monitored in a spectrofluorometer. By using the
above-described cell preparation and incubation conditions, the Hst dye
uptake assay could be applied for assessing the transport activity of the wtABCG2 and its variants in intact Sf9 cells.
Fig. 4A shows a typical Hst
dye uptake experiment using intact Sf9 cells harvested post-40 h
of recombinant baculovirus infection, expressing either ABCG2-R482G or
its K86M mutant variant. After the addition of Hst (indicated by
arrows), a fast initial increase of fluorescence intensity
due to a rapid dye uptake and nuclear staining in dead cells can be
observed. Further dye uptake of living cells, the result of Hst influx
and its efflux by ABCG2, is reflected by a slower increase in
fluorescence. As documented, Hst dye uptake is significantly slower in
the Sf9 cells that express the ABCG2-R482G protein (Fig.
4A, line A) than in cells expressing the
K86M/R482G mutant (line B). The latter rate is similar to that in control,
In order to compare the Hst transport activity of the wild-type ABCG2
and its mutant variants, by using the above-described technique, we
determined the accumulation rate of 0.5-5 µM Hst into
ABCG2-expressing Sf9 cells, both in the presence and in the absence of 10 µM FTC. Fig. 4, B and
C, shows that the rate of Hst influx was low and was greatly
increased by the inhibitor FTC in the wild-type ABCG2 (Fig.
4B) and also in the R482G and R482T variants (Fig. 4,
B and C). The K86M mutant was found to be
inactive at all Hst dye concentrations examined (Fig. 4C). Based on these quantitative estimations, we found no significant difference between the Hst transport capacity of the wtABCG2 and its
amino acid 482 variants.
Membrane ATPase Activity of the Wild-type ABCG2 and Its Mutant
Variants--
In order to follow the catalytic rate of the wtABCG2 and
its mutant variants, we measured vanadate-sensitive ATP hydrolysis in
isolated Sf9 cell membrane preparations. The membrane fractions, containing equal amounts of the different ABCG2 proteins (see Fig.
1B), were assayed for ATPase activity, as described under "Experimental Procedures."
We have shown earlier (18) that ABCG2-R482G expressed in Sf9
cells had a high level of vanadate-sensitive membrane ATPase activity,
and this activity could be significantly increased by substrates and
decreased by the inhibitors of this protein. In the present study we
have compared the ATPase activity of the wild-type human ABCG2 and its
variants (R482G, R482T, and K86M) in the presence and absence of a
variety of potential ABCG2 substrates or inhibitors.
As shown in Fig. 5A, the
basal, vanadate-sensitive ATPase activity was significantly higher in
membranes containing any of the wtABCG2 or its amino acid 482 variants
than in those containing ABCG2-K86M/R482G or
When examining the substrate stimulation of the ABCG2 ATPase activity,
we found that this stimulation was significantly different in the three
active proteins (Fig. 5, B-D). In case of the R482G and
R482T mutants, vanadate-sensitive ATPase activity could be greatly
stimulated by several potential ABCG2 substrates (e.g. prazosin, mitoxantrone, adriamycin, rhodamine 123, benzamil, and camptothecin), corresponding to the transport activity of these proteins. However, in case of the wild-type protein, we found no
measurable stimulation of the ATPase activity by any of these compounds, including known wild-type ABCG2-substrates (e.g.
mitoxantrone and prazosin). Interestingly, Hoechst 33342, a transported
substrate of all active ABCG2 transporters (see above), did not
stimulate the ATPase activity of any of these proteins, rather, the
addition of Hst to the membranes decreased the ATPase activity in a
concentration-dependent manner (see Fig. 5,
B-D). It is worthwhile to note that Hst had no effect on
the ATPase activity of Sf9 membranes containing ABCG2-K86M or
We found that the effect of different ABCG2 substrates on the ATPase
activity of variants R482G and R482T was almost similar. There was no
significant difference either in the relative extent of their drug
stimulation or in the drug concentration causing half-maximal
activation (Kact value). Adriamycin stimulated
their ATPase activity about 40%, with Kact
values of 5 and 6.8 µM, respectively. Rhodamine 123, a
specific substrate of the amino acid 482 mutants, gave a maximum of
30% stimulation, and the Kact values were 4.5 and 4 µM, respectively, for the R482G and R482T mutants.
The maximum extent of stimulation of the R482G and R482T-ATPases by
prazosin was 100 and 70%, and the Kact values
were 7 and 3 µM. Mitoxantrone showed a maximum of 50%
stimulation of the ATPase activity of the R482G and R482T variants,
with Kact values of 1 and 0.8 µM, respectively.
FTC was found to be an effective inhibitor for the vanadate-sensitive
ABCG2-ATPase activity both for the wild-type enzyme (76% inhibition at
10 µM) and the R482G variant (74% inhibition at 10 µM); however, its inhibitory effect was smaller and
required higher FTC concentrations in the case of the R482T variant
(37% inhibition at 10 µM) (see Fig. 5). The
concentration of FTC causing half-maximal inhibition of the
ABCG2-ATPases was 0.4 µM for the wild-type enzyme, 0.5 µM for the R482G variant, and 0.7 µM for the R482T mutant.
The lack of drug stimulation for the ATPase activity of the wild-type
ABCG2 was surprising in the light of its high efficiency drug and dye
extrusion present in the intact Sf9 cells. We speculate that
this may be the result of unknown ABCG2 substrates, present in the
membrane preparations or ATPase assay media. In order to explore these
possibilities, we have examined the effects of salts and buffering
solution, antioxidants (e.g. dithiothreitol), as well as
protease inhibitors present in the membrane preparations and the ATPase
assay. We found no significant effect of any of these conditions on the
ATPase activity of the wild-type ABCG2 or the R482G variant; neither
their basal activity nor the effects of drugs were changed. Washing the
membranes with KCl (0.1-1 M) or albumin (2% bovine serum
albumin) also had no significant effect on the ABCG2-ATPase or its drug
stimulation (data not shown).
[
To characterize the ATP binding activity of the wild-type and mutant
ABCG2 proteins, we performed photoaffinity labeling in isolated
Sf9 membranes. Membranes containing the different ABCG2 variants
were incubated on ice with 20 µM
8-azido-[
As shown in Fig. 6A, we found
that there was no significant ATP binding to ABCG2 when an
Mg2+ complex of azido-ATP was used. However, the addition
of Co2+ to the media resulted in highly detectable
8-azido-ATP binding to ABCG2 (Fig. 6B), which was competed
in the presence of 8 mM unlabeled CoATP. Therefore, in
further labeling experiments we used the cobalt complex of
8-azido-[
In order to analyze the transition state formation of the ABCG2
transporters, Sf9 membranes containing the different ABCG2 variants were incubated at 37 °C for 2-5 min in the presence of 5 µM 8-azido-[
As shown in Fig. 7B, in the presence of 1 mM
vanadate and 5 µM Co-8-azido-[
It has been shown in the case of well characterized ABC multidrug
transporters, MDR1 and MRP1, that transported drugs significantly increase the rate of nucleotide trapping (26, 29). In order to explore
the effect of drugs on the nucleotide trapping in the wtABCG2 and its
amino acid 482 variants, we examined such effects in the
above-described conditions and in the presence of various concentrations of possible ABCG2 substrates.
As shown in Fig. 8, we found significant
differences in the adenine nucleotide trapping of the wild-type, R482G,
and R482T ABCG2 transporters. When we analyzed these data with a
quantitative PhosphorImager, in the absence of added drugs the
wild-type ABCG2 (Fig. 8, lane 4) showed a more pronounced
nucleotide trapping activity, 2.6 ± 0.03- and 2.05 ± 0.5-fold of the R482G and R482T variants (lanes 7 and
10), respectively. The addition of prazosin, an activator of
the ABCG2-ATPase of the R482G and R482T variants, significantly
stimulated nucleotide trapping in the same variants (see Fig. 8,
lanes 6 and 9, the stimulations were 2.0 ± 0.22- and 1.7 ± 0.04-fold, respectively). However, prazosin had
an inhibitory effect (50 ± 6% decrease in the labeling) on
the nucleotide incorporation in the wild-type ABCG2 (lane
3). Mitoxantrone, also a substrate of all three active ABCG2
transporters, had a similar effect on the nucleotide trapping of the
ABCG2 variants (not shown). The specific ABCG2 inhibitor, FTC,
eliminated nucleotide trapping by all ABCG2 variants (Fig. 8,
lanes 2, 5, and 8). Verapamil is not a substrate
of the ABCG2 multidrug transporters, and this compound had no effect on
the trapping of the active protein variants (not shown). We confirmed
by immunoblotting that the amount of ABCG2 proteins used in the
labeling experiments were approximately equal (see Fig. 8). As a
further control, the experiments were repeated three times, and similar
results were found when both 2 or 5 µM 8-azido-ATP was
used.
In this paper we describe the expression and detailed functional
analysis of the wild-type human ABCG2 multidrug transporter and its
mutant variants R482G, R482T, and K86M. This protein has been
demonstrated to provide drug resistance in tumor cells by an active
extrusion of various cytotoxic compounds (5, 16). ABCG2, which may also
have important physiological functions, for example, providing
xenobiotic resistance in the placenta and stem cells (3, 35, and 39),
is a so-called ABC half-transporter, which most probably requires
dimerization partner(s) for its transport activity (14). Three human
ABCG2 protein sequences have been published (3-5), which differed in
their amino acid position 482. According to the established sequence in
the human genome data base (GenBankTM accession
number AF103796), the wild-type ABCG2 contains arginine at this
position, whereas the other two variants R482G and R482T most probably
were generated during drug selection in tumor cell lines (20, 22).
In a previous analysis, Honjo et al. (20) described
significant differences in the substrate specificity of the three
different ABCG2 proteins found in drug-selected cell lines or
transiently expressed in mammalian cells. However, the corresponding
results in different publications were somewhat inconsistent, for
example MX resistance was almost absent in cells expressing the
confirmed wild-type ABCG2 in one study (22), whereas such a resistance and active MX extrusion were found to exist in another study (20). Relatively low expression levels, detected for ABCG2 in mammalian cells, hindered a detailed biochemical characterization, and the possible involvement of endogenous ABCG2-related proteins in these cells may significantly modify the transport function of this dimerizing protein.
The aim of the present study was to provide a quantitative
characterization both for the transport and the ATP hydrolytic activity
of the wtABCG2 and its variants R482G and R482T. For this purpose we
applied the Sf9-baculovirus expression system, which has already
been established as a suitable system for the expression of ABC
transporters (23-25), including ABCG2 (18).
As documented under "Results," we obtained a uniformly high level
expression of the wtABCG2 and its amino acid 482 variants, and as a
negative control also expressed a Walker A Lys mutant of this protein
(K86M). We introduced the K86M mutation into the R482G variant of
ABCG2, because we expected that the mutation of the key Lys will
abolish the function of ABCG2 regardless the amino acid found in
position 482. Similar mutations, even if present only in one catalytic
domain, inactivated all known ABC multidrug transporter proteins
examined so far (32, 40, 41). The K86M mutant of ABCG2/R482 was already
investigated for Hoechst 33342 transport in mammalian cells (35), and
it was found to be inactive. On the other hand the R482G variant could
be easily investigated in all four assays as described under
"Results."
In order to follow the transport activity and the molecular mechanism
of action of the wtABCG2 and its mutant variants, we developed suitable
assays. First, we showed that intact Sf9 cells expressing the
different ABCG2 transporters can be used for measuring the uptake of
the fluorescent drug MX and the fluorescent dye rhodamine
123 by flow cytometry. Second, we developed a quantitative assay for
ABCG2-dependent Hst extrusion to follow the kinetics of
Hoechst 33342 (Hst) dye uptake, a known substrate of the MDR1 and ABCG2
multidrug transporters (35, 39, 42). Finally, in order to trace the
catalytic steps related to the transport activity of ABCG2, we utilized
isolated Sf9 cell membranes, and we found the appropriate
conditions to detect the specific ATP-binding and adenine nucleotide
trapping that is characteristic of many related ABC transporters.
Comparing the transport activity of the wtABCG2 and its mutant
variants, we found that the wild-type and the two amino acid 482 variants actively exported mitoxantrone, whereas rhodamine 123 extrusion could only be observed in cells expressing the R482G and
R482T proteins. We found that wild-type ABCG2, although expressed at
similar levels in the same cell type, was somewhat less effective in MX
extrusion than the other two amino acid 482 variants. Our MX-transport
results are in accordance with data presented by Honjo et
al. (20), whereas they contradict the lack of MX transport activity found for the wild-type ABCG2 by Komatani et al.
(22). When measuring the Hst transport activity of the different ABCG2 proteins in intact cells, we found that there was no significant difference in the Hst transport capacity of the wtABCG2 and its amino
acid 482 variants. This study provides the first comparative data
regarding the Hst transport activity of different ABCG2 variants and
the MX-transport capacity of these variants expressed in the same
amount in the same cell type. Our direct transport experiments fully
support that ABCG2 forms an active homodimer.
When investigating the catalytic cycle of the human ABCG2 protein, we
compared the vanadate-sensitive ATPase activities of the wtABCG2 and
its mutant variants and the possible modulation of this activity by
transported substrates and inhibitors. We have already described a high
level, vanadate-sensitive ATPase activity, stimulated by several
transported compounds, for the human ABCG2-R482G variant in isolated
Sf9 cell membranes (18). In the present experiments a relatively
high basal ATPase activity was found in case of the wild-type ABCG2 and
the R482T variant, too. However, stimulation of the ABCG2-ATPase
activity was observed only in Sf9 membranes containing the R482G
or R482T variants and not the wild-type ABCG2.
Despite this difference, similarities were found for the wtABCG2 and
its amino acid 482 variants. The selective transport inhibitors, FTC
and Ko 143, inhibited the ATPase activity of all these proteins. Also,
Hoechst 33342, a transported ABCG2 substrate, did not stimulate ATPase
activity but produced a concentration-dependent inhibition
of the ATPase activity both of the wild-type and the ABCG2-482 mutants.
A possible explanation for the above described findings in the ATPase
activity measurements may be a partial and variable uncoupling of the
ABCG2-ATPase activity from the transport activity in these isolated
membranes. However, this would make it difficult to explain how the
substrate drugs and inhibitors reduce this ATPase activity in a
concentration-dependent manner. Alternatively, and more
likely, a significant stimulation of the ABCG2-ATPase can be caused by
(yet unknown) substrates present in these membrane preparations. In
case of the R482G and R482T variants, this endogenous stimulation
(caused by endogenous activators, producing what we observe as a high
base-line ATPase) is only partial, and further stimulation by the
transported compounds is observed. In case of the wild-type ABCG2,
endogenous stimulation reaches a maximum level; therefore, upon
addition of substrates either no effect or only the inhibition of the
ATPase activity is seen when the transported substrates compete with
the endogenous activators. A third possibility is that human ABCG2
expressed in insect cells could be lacking post-translational
modifications (e.g. glycosylation and phosphorylation)
necessary for complete function. However, the results of our transport
experiments did not indicate an altered function of the wild-type ABCG2
expressed in insect cells. Additional experiments, involving mammalian
cell expression systems, will be needed to explore these issues further.
In order to investigate further the mechanistic properties of the
wtABCG2 transporter and its variants, we have studied both specific ATP
binding and nucleotide trapping of these proteins. We used 8-azido-ATP
and found that neither ATP binding nor nucleotide trapping could be
observed in ABCG2 in the absence of divalent cations or in the presence
of Mg2+ ions. However, significant nucleotide binding and
trapping could be detected in the presence of Co-8-azido-ATP. The
requirement of Co-8-azido-ATP for labeling may be the result of a
spatial arrangement of the reactive groups in the ABCG2 protein,
allowing its covalent interaction with only Co-8-azido-ATP. A Co-ATP
complex has already been used in studying the MDR1-ATPase reaction. In that case both Mg2+ and Co2+ ions were found to
be suitable to obtain a trapped nucleotide, although an increased
stability (and decreased hydrolysis) of the Co-ATP complex was observed
(28). The use of Co-ATP complex in the present studies opened the door
for a detailed characterization of the ATP hydrolytic cycle of the
ABCG2 protein.
We have documented that the 8-azido-ATP labeling of the wtABCG2 and its
amino acid 482 variants and that of the K86M mutant was similar, which
is to say that they seem to have similar ATP binding capacities.
However, we found significant differences in the
vanadate-dependent nucleotide trapping, reflecting the transition state intermediate formation of the wtABCG2 and its variants. Clearly, the K86M mutant was unable to form the transition state intermediate, in agreement with the inactivity of this mutant in
the ATPase and transport measurements. The mutation of a similar lysine
residue in a single ABC domain of MDR1 or MRP1 fully inhibits their ATP
hydrolysis and vanadate-induced transition state formation (32, 40,
41).
We found that the nucleotide trapping characteristics of the R482G or
R482T variants were different from the wild-type ABCG2. Whereas this
transition state formation in variants R482G and R482T could be
significantly stimulated by various ABCG2 substrates (prazosin and
mitoxantrone), the transition state formation of the wild-type ABCG2
could not be stimulated but rather was inhibited by these compounds. In
all cases transition state formation was eliminated by the specific
inhibitor, FTC. These results are in close correlation with the ATPase
activity data; both the drug stimulation of the ABCG2 ATPase activity
and nucleotide trapping showed similar behavior in the ABCG2 variants.
The possible sources of these findings have already been discussed above.
It is important to note that the inhibitory effect of FTC was almost
100% in transport and trapping experiments; however, in the ATPase
assay, FTC inhibited the activities only partially. The mechanism of
action of FTC is as yet unknown, but our nucleotide trapping
experiments indicate that it decreases the formation of the transition
state intermediate. The assays described in this paper use varying
conditions (e.g. different assay media, Mg- or Co-ATP, ATP,
or 8-azido-ATP) and investigate different aspects of the activity of
ABCG2, making it difficult to compare the effect of FTC on the
different functions examined.
In summary, in this study we have documented the applicability of the
Sf9 expression system for a direct, quantitative examination of
the transport properties of wtABCG2 and its variants. Our results support the idea that ABCG2 functions as a homodimer and show that this
heterologous expression system provides an appropriate tool for
selectively studying ABCG2 mutants.
We demonstrated key differences in the substrate interactions of these
variants in intact cells, which were also reflected when studying the
steps of ATP hydrolysis. However, in several cases the substrate
stimulation of the ABCG2-ATPase could not be directly correlated with
the actual transport processes. Therefore, these results raise the
possibility that membrane-bound substrates or partial uncoupling may
significantly and differently influence the catalytic mechanism of the
amino acid 482 variants of this ABC half-transporter. The detailed
investigation of these phenomena in various expression systems may help
in explaining these discrepancies.
Altogether, the transport methods (especially the fluorimetric dye
uptake assay) described here for intact Sf9 cells expressing human ABC transporters and the ATPase assay may serve as an important basis for developing high throughput methods for the evaluation of drug
interactions with multidrug transporters.
The significant variations found in the substrate handling of the
wtABCG2 and its mutant variants and the better understanding of their
effects on the function of ABCG2 may play an important role in
modulating chemotherapy in ABCG2-expressing tumors. In addition, as we
have recently shown,2 the mutant ABCG2 variants with
altered substrate specificity may be successfully applied as
drug-specific selectable markers in human gene therapy approaches.
We are grateful to György Várady
for helping with flow cytometry and Dr. Barry Elkind for the helpful
suggestions in preparing this manuscript. The technical assistance by
Györgyi Demeter, Ilona Zombori, Judit Kis, and Gabriella
Köblös is greatly appreciated. We appreciate the kind gifts
of Ko 143 obtained from Drs. J. D. Allen and G. J. Koomen and
the anti-ABCG2 antibody obtained from Drs. George Scheffer and Rik Scheper.
*
This work was supported in part by the National Research
Foundation of Hungary Grant OTKA T 029921, T 35126, T 31952, and T
038337.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.
¶
Recipient of a Howard Hughes International Scholarship. To
whom correspondence should be addressed: National Medical Center, Institute of Haematology and Immunology, Membrane Research Group of the
Hungarian Academy of Sciences, Dioszegi u 64., H-1113 Budapest, Hungary. Tel.: 36-1-372-43-16; Fax: 36-1-372-4353; E-mail:
sarkadi@biomembrane.hu.
Published, JBC Papers in Press, October 8, 2002, DOI 10.1074/jbc.M207857200
2
O. Ujhelly, C. Özvegy, G. Várady, J. Cervenak, L. Homolya, M. Grez, G. Scheffer, D. Roos,
S. E. Bates, A. Váradi, B. Sarkadi, and K. Német,
submitted for publication.
The abbreviations used are:
ABC, ATP binding
cassette;
wt, wild-type;
Sf9, S. frugiperda;
MX, mitoxantrone;
FTC, fumitremorgin C;
Hst, Hoechst 33342 dye.
Characterization of Drug Transport, ATP Hydrolysis, and
Nucleotide Trapping by the Human ABCG2 Multidrug Transporter
MODULATION OF SUBSTRATE SPECIFICITY BY A POINT
MUTATION*
§,, and Institute of Enzymology, Biological Research
Center, Hungarian Academy of Sciences and § National Medical
Center, Institute of Haematology and Immunology, Membrane Research
Group of the Hungarian Academy of Sciences,
H-1113 Budapest, Hungary
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-32P]
ATP was purchased from ICN Biomedicals.
80 °C and were used
within 2 months following preparation. Drug-stimulated ATPase activity
was measured by colorimetric detection of inorganic phosphate
liberation, as described (18). Figures reflect the mean values of at
least four independent experiments measured in two different membrane
preparations for each type of ABCG2.
-32P]ATP Labeling--
In the
8-azido-[-32P]ATP binding experiments, isolated
Sf9 membranes (150 µg of protein) were incubated for 5 min on
ice with 20 µM 8-azido-ATP (0.1 MBq radioactivity) in
reaction buffer (50 mM Tris-HCl, 50 mM KCl, 100 µM EGTA Tris, and either 2 mM
MgCl2 or CoSO4). The membranes were
UV-irradiated and then washed twice with washing buffer (reaction
buffer containing 10 mM Mg or CoATP).
-32P]ATP, and the compounds are described in
the figure legends. Reactions were stopped by the addition of ice-cold
washing buffer. After two washing steps the membranes were
UV-irradiated on ice.
RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
A, membrane topology model of the human
ABCG2 multidrug transporter. Rectangles with
numbers indicate the predicted transmembrane helices, and
the star shows the position of the mutated amino acids,
Lys-86 and Arg-482. The possible N-glycosylation sites are
also shown. B, immunoblot detection of human wtABCG2 and its
variants expressed in Sf9 insect cells. Membranes of Sf9
(2.5 µg of total protein) or HL60 (50 µg) cells dissolved in
disaggregation buffer were subjected to electrophoresis on 7.5%
Laemmli-type gels and blotted onto polyvinylidene difluoride membranes,
followed by immunodetection with the BXP-21 antibody. Lane
1, R482T/Sf9; lane 2, wild-type
ABCG2/Sf9; lane 3, R482G/Sf9; lane
4, K86M-R482G/Sf9; lane 5, wild-type ABCG2/HL60;
lane 6, wild-type ABCG2/HL60 grown in the presence of 2.5 µg/ml tunicamycin; and lane 7,
galactosidase/Sf9.
-galactosidase. As
documented, MX uptake is relatively low in cells expressing the active
ABCG2s, whereas FTC significantly increases this accumulation. In
Sf9 cells, expressing the K86M mutant, MX uptake is
significantly higher and reaches the level of MX accumulation found in
the FTC-inhibited cells. This accumulation is similar to that found in
mock (-galactosidase)-infected Sf9 cells. These experiments
indicate that wtABCG2 and the R482G or R482T variants actively extrude
MX in the intact Sf9 cells, whereas the K86M mutant is inactive
in this respect.
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Fig. 2.
A, MX accumulation in Sf9 cells
expressing -galactosidase (-gal), wild-type ABCG2
(Arg-482), and the R482G, R482T, or K86M mutants. Sf9 cells were incubated for 30 min at 37 °C
with () or without (···) the
addition of 10 µM MX, 10 µM MX + 10 µM FTC (- - -), or 10 µM MX + 10 µM prazosin (
). After incubation the cells were washed
and suspended in an ice-cold buffer containing propidium iodide, for
the recognition of dead cells. Flow cytometry was performed as
described under "Experimental Procedures." B and
C, concentration dependence of MX accumulation in Sf9
cells, expressing wtABCG2 and its mutant variants. The experiments were
performed as described at A, by using 1-20 µM
MX. Intracellular mean fluorescence values, obtained as a function of
MX concentration during the uptake experiment, are shown. The figure
shows the average ± S.D. of three measurements.
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Fig. 3.
Rhodamine 123 accumulation in Sf9
cells expressing the wild-type (Arg-482), R482G, R482T, or K86M/R482G
variants of ABCG2. Sf9 cells were incubated for 30 min at
37 °C with 2 µM rhodamine 123 in the presence
(- - -) or absence ( ) of 10 µM FTC. After incubation
the cells were washed and suspended in an ice-cold buffer containing
propidium iodide, for the recognition of dead cells. Flow cytometry was
performed as described under "Experimental Procedures."
-galactosidase-infected Sf9 cells (not
shown). The rate of Hst dye uptake in cells expressing ABCG2-R482G
(Fig. 4A, line A) greatly increases upon the
addition of the specific inhibitor FTC (or Ko 143, not shown). However,
there is no change in the rate of Hst accumulation in cells expressing
the K86M/R482G mutant (Fig. 4A, line B) or
-galactosidase (not shown). At the end of each experiment, for
quantitation of the maximum cellular fluorescence, the cells were
permeabilized by the addition of digitonin, and this maximum uptake was
used as a correction factor in the quantitative estimations.
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Fig. 4.
Hoechst 33342 (Hst) accumulation in
Sf9 cells expressing different ABCG2 variants. Hoechst dye
uptake (0.5-5 µM) was measured in a fluorescence
spectrophotometer at 350 nm (excitation)/460 nm (emission), by using
5 × 105 cells in a HPMI solution. 10 µM
FTC was used to inhibit ABCG2-mediated Hst transport. At the end of
each experiment, for standardization, a full cellular staining was
obtained by the addition of 8 µM digitonin, disrupting
the integrity of the cell membrane. A shows the increase in
fluorescence due to the uptake of 2.5 µM Hst in
ABCG2-R482G- (line A) or ABCG2-K86M/R482G (line
B) -expressing Sf9 cells. B and C,
the rate of Hst influx ( 
fluorescence/ time) into Sf9
cells expressing the wtABCG2 or the R482T mutant (B) and
R482G or K86M/R482G (C) was determined at different Hst
concentrations with or without the ABCG2 inhibitor FTC. Data points
indicate the mean ± S.D. values of three independent
measurements.
-galactosidase (not
shown here). Despite the similar ABCG2 expression levels, this basal
ATPase activity was ~1.5-fold higher in case of the R482G variant
(71 ± 10.8 nmol of Pi/mg of membrane protein/min)
than in case of the wild-type ABCG2 or the R482T variant (45 ± 8.85 and 46 ± 9.04 nmol of Pi/mg of membrane
protein/min, respectively) and negligible in the ABCG2-K86M mutant
(5 ± 0.5 nmol of Pi/mg of membrane protein/min). This
latter vanadate-sensitive ATPase activity was similar to that observed in the -galactosidase-containing Sf9 cell membranes (4.2 ± 0.8 nmol of Pi/mg of protein/min). In wtABCG2 and in
R482G and R482T proteins FTC (or Ko 143) powerfully inhibited the
vanadate-sensitive ATPase activity.
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Fig. 5.
ATPase activity measured in membranes of
Sf9 cells expressing the wild-type, R482G, R482T, or K86M/R482G
variants of human ABCG2. ATPase activity of isolated Sf9
membranes was determined by measuring vanadate-sensitive inorganic
phosphate liberation, using 3.3 mM MgATP. Data points
represent the mean ± S.D. values of at least four measurements,
performed in two or three different membrane preparations.
A, ATPase activity in the absence of added compounds
(control), with 100 µM prazosin, or with 10 µM FTC. B-D, effects of different
concentrations of compounds on the vanadate-sensitive ATPase activity
in isolated membranes of Sf9 cells expressing different ABCG2
variants. ATPase activity determined in membranes of wtABCG2-
(B), R482G- (C), or R482T
(D)-expressing Sf9 cells. Control indicates the
ATPase activity measured in the absence of added compounds. The
background ATPase activity measured in Sf9 cells expressing
-galactosidase is indicated on the figures with dashed
lines.
galactosidase (data not shown).
-32P]8-azido-ATP Binding and Nucleotide Trapping
by wtABCG2 and Its Mutant Variants in Isolated Sf9 Cell
Membranes--
It has been reported (28) that the steps of the
catalytic cycle (ATP binding and the transition state formation during
ATP hydrolysis) of various ABC proteins can be investigated by using the radioactive ATP analog 8-azido-[-32P]ATP in a
complex with Mg2+, Co2+, or Mn2+
cations. ATP binding can be followed by labeling under non-hydrolytic conditions, whereas the formation of an inhibitor (vanadate and fluoro-aluminate)-sensitive reaction intermediate is examined under
hydrolytic, "nucleotide trapping" conditions (26-29). In order to
establish proper labeling conditions, we tested Mg-8-azido-ATP in the
membrane ATPase activity measurement, and we found that it is a good
energy donor substrate for the ABCG2 ATPase. In the presence of 3.1 mM Mg-8-azido-ATP, the vanadate-sensitive ATPase activity
of ABCG2-R482G was 77% compared with the activity measured in the
presence of a similar concentration of MgATP (data not shown).
-32P]ATP and either 2 mM
MgCl2 or 2 mM CoSO4 for 5 min.
After UV irradiation, washing, gel electrophoresis, and
electroblotting, the radioactivity in the ABCG2 protein bands
(confirmed by immunoblotting) was quantitated.
-32P]ATP. We found that 8-azido-ATP binding
was similar in the wild-type and in the R482G, R482T, and K86M mutant
variants under these conditions (Fig. 6B). ATP binding was
abolished in all variants in the presence of EGTA (chelating all
divalent cations used here, not shown).
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Fig. 6.
[ -32P]8-azido-ATP binding
of the wild-type and R482G, R482T, or K86M/R482G mutant ABCG2
proteins. Sf9 membranes containing the different ABCG2
variants or -galactosidase were incubated on ice for 5 min with 20 µM 8-azido-[-32P]ATP and 2 mM Mg2+ (A) or 2 mM
Co2+ (B). Labeling and detection were performed
as described under "Experimental Procedures." The effect of
pretreatment with 8 mM unlabeled Co-8-azido-ATP is shown on
B. The position of human ABCG2 is indicated by an
arrow. -gal, -galactosidase.
-32P]ATP, either 2 mM MgSO4 or CoSO4, and with or
without 1 mM sodium orthovanadate. Again, there was no
significant labeling of ABCG2 proteins when Mg2+ was used
in these experiments (see Fig.
7A), neither in the absence or
presence of vanadate nor in the presence of 1 mM
AlF
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Fig. 7.
[ -32P]8-azido-ATP trapping
of the R482G and K86M/R482G mutant ABCG2 proteins. Sf9
membranes containing ABCG2-R482G (see A, lane 2,
and B, lanes 1-3), ABCG2-K86M
(B, lane 5), or -galactosidase
(-gal) (see A, lane 1 and
B, lane 4) were incubated for 5 min at 37 °C
with 5 µM 8-azido-[-32P]ATP, 1 mM sodium orthovanadate (except for lane 1) and
2 mM Mg2+ (A) or 2 mM
Co2+ (B) as described under "Experimental
Procedures." Lane 2 represents when 4 mM
Na-EDTA was added to the reaction. Labeling and detection were
performed as described under "Experimental Procedures." The
position of the ABCG2 multidrug transporter is indicated by an
arrow.
-32P]ATP,
ABCG2 (R482G) showed a high level of nucleotide trapping (lane
3). The radioactive band, corresponding to the nucleotide trapping
by the ABCG2 protein, was specific for this protein (confirmed by
immunoblotting), and there was no nucleotide occlusion observed when
the reaction mixture did not contain sodium orthovanadate (Fig.
7B, lane 1) or when 4 mM Na-EDTA was present in
the reaction mixture (lane 2). The ABCG2-specific
radioactive band was absent in the membranes of
-galactosidase-expressing Sf9 cells (Fig. 7B, lane
4). As documented in Fig. 7B, the functionally inactive ABCG2-K86M/R482G did not show any nucleotide trapping activity under
these conditions (lane 5).
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Fig. 8.
Comparison of the effect of different
compounds on the
[ -32P]8-azido-ATP trapping of
the wild-type, and R482G or R482T variants of the ABCG2 protein.
Sf9 membranes (150 µg) containing wtABCG2 (lanes
2-4), ABCG2-R482G (lanes 5-7), ABCG2-R482T
(lanes 8-10), or -galactosidase (lane 1) were
incubated for 2 min at 37 °C with 2 µM
8-azido-[-32P]ATP, 1 mM sodium
orthovanadate, and 2 mM Co2+ as described under
"Experimental Procedures." Lanes 1, 4,
7, and 10 show nucleotide trapping when the reaction
mixture did not contain additional compounds. In other experiments the
reaction media contained 10 µM prazosin (lanes
3, 6, and 9) or 5 µM FTC
(lanes 2, 5, and 8). Arrows
indicate the position of the ABCG2 protein. The quantity of the
different ABCG2 variants was determined by Western blotting (see the
bottom of the figure) on the same polyvinylidene difluoride
membranes using the BXP-21 antibody. -gal,
-galactosidase.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
ACKNOWLEDGEMENTS
FOOTNOTES
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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