Originally published In Press as doi:10.1074/jbc.M008443200 on October 5, 2000
J. Biol. Chem., Vol. 275, Issue 52, 40874-40878, December 29, 2000
Intersubunit Interactions in Plasmodium falciparum
Thioredoxin Reductase*
Zita
Krnajski
§,
Tim-Wolf
Gilberger¶,
Rolf D.
Walter, and
Sylke
Müller
From the Biochemical Parasitology, Bernhard Nocht
Institute for Tropical Medicine, Bernhard-Nocht-Strasse 74, D-20359
Hamburg, Germany
Received for publication, September 14, 2000, and in revised form, October 2, 2000
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ABSTRACT |
The thioredoxin redox system is composed of the
NADPH-dependent homodimeric flavoprotein thioredoxin
reductase (TrxR) and the 12-kDa protein thioredoxin. It is responsible
for the reduction of disulfide bridges in proteins such as
ribonucleotide reductase and several transcription factors.
Furthermore, thioredoxin is involved in the detoxification of hydrogen
peroxide and protects the cell against oxidative damage. There exist
two classes of TrxRs: the high Mr and the low
Mr proteins. The well characterized Escherichia coli TrxR represents a member of the low
Mr class of proteins, whereas the mammalian,
Caenorhabditis elegans, and Plasmodium
falciparum proteins belong to the family of high
Mr proteins. The primary structure of these
proteins is very similar to that of glutathione reductase and lipoamide
dehydrogenase. However, the high Mr TrxRs
possess, in addition to their redox active N-terminal pair of
cysteines, a pair of cysteine residues or a selenenylsulfide motif at
their C terminus. These residues have been shown to be crucial for the
reduction of thioredoxin. In this study we address the question whether
the active site residues of P. falciparum TrxR are provided
by one or both subunits. Differentially tagged wild-type and
PfTrxR mutants were co-expressed in E. coli and
the recombinant protein species were purified by affinity
chromatography specific for the respective tags of the recombinant
proteins. Co-expression of PfTrxR wild-type and mutant proteins resulted in the formation of three different protein species: homodimeric PfTrxR wild-type proteins,
homodimeric mutant proteins, and heterodimers composed of one
PfTrxR wild-type subunit and one PfTrxR mutant
subunit. Co-expression of the double mutant PfTrxRC88AC535A
with PfTrxR wild-type generated an inactive heterodimer, which indicates that PfTrxR possesses intersubunit active
sites. In addition, the data presented possibly imply a coopertive
interaction between both active sites of PfTrxR.
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INTRODUCTION |
Infection with Plasmodium falciparum, the causative
agent of malaria tropica, is responsible for 2-3 million deaths per
year. The malaria parasite spends part of its developmental life cycle in human erythrocytes where it is challenged with enhanced oxidative stress. Therefore the parasite needs efficient anti-oxidants to protect
itself against damages, such as nucleic acid modifications, lipid
peroxidation, or oxidation of thiol-containing proteins, caused by
reactive oxygen species. The thioredoxin redox system, composed
of the NADPH-dependent homodimeric thioredoxin reductase (TrxR)1 and the 12-kDa
protein thioredoxin (Trx) confers reduction of protein disulfides,
ribonucleotide reductase being the most prominent example (1). Apart
from this, thioredoxin interacts with a number of transcription factors
in prokaryotic and eukaryotic cells, resulting in modified DNA binding
activities and altered gene transcription (2). Another important
function is the interaction of reduced thioredoxin with
thioredoxin-dependent peroxidases, which detoxify reactive
oxygen species and aid in the prevention of oxidative damage in the
cell (3).
There exist two classes of TrxRs, the low Mr
proteins are represented by the 35-kDa Escherichia coli
TrxR; the high Mr proteins were identified in
mammals, P. falciparum, and also the free living nematode
Caenorhabditis elegans (4-7). The two classes of proteins do not only differ in their primary structure but also in their reaction mechanisms. E. coli TrxR achieves catalysis by a
conformational change (8, 9), whereas high Mr
TrxRs transfer reducing equivalents to their substrate by an
intramolecular dithiol/disulfide interchange between the N-terminal
redox active cysteines and the C-terminal pair of cysteines (10-12).
The primary structure of PfTrxR resembles that of
glutathione reductase and lipoamide dehydrogenase with respect to the
location of the N-terminal redox active cysteine pair, and the
occurrence of the C-terminal pair of cysteines is similar to
mercuric ion reductase. In mercuric ion reductase it was shown that the
C-terminal residues are involved in the catalytic process but are not
redox active as in TrxRs (13, 14).
To achieve transfer of electrons from the N terminus to the C terminus,
the redox active residues should be located in close proximity to each
other. There are two possible conformations which allow this transfer:
either by the formation of an intermolecular interaction between
the two subunits of the dimeric protein or by an intrasubunit
interaction where each of the subunits forms its own active site (Fig.
1). In mercuric ion reductase an
intermolecular interaction between both subunits occurs (15). In
glutathione reductase and lipoamide dehydrogenase the active sites are
also formed by an interaction of both subunits; the redox active
cysteine residues are provided by one subunit, and the acid/base
catalyst is provided by the second subunit (16).
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Fig. 1.
Possible organizations of the active sites of
the dimeric P. falciparum thioredoxin reductase.
A, intrasubunit active sites; two independent active sites
are formed. The mutations of Cys88  Ala and
Cys535 Ala are shown. B, intersubunit active
site; residues of both subunits contribute to the formation of both
active sites of the dimeric protein. The mutations of Cys88
Ala and Cys535 Ala are
shown.
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To analyze the organization of the PfTrxR active sites, we
decided to co-express wild-type and mutant PfTrxR
(PfTrxRC88A, PfTrxRC535A, or
PfTrxRC88AC535A) in E. coli and to separate the recombinant proteins. Using this method we expected to generate homodimeric enzymes consisting of wild-type or mutant subunits only and
heterodimeric proteins consisting of one wild-type and one mutant
subunit. Co-expressing single or double mutant PfTrxRs with
PfTrxR wild-type and characterizing the recombinant protein species should give a clear picture of how the active sites of PfTrxR are formed and answer the question whether the
homodimeric protein possesses intersubunit or intrasubunit active sites
(Fig. 1).
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EXPERIMENTAL PROCEDURES |
Materials--
E. coli thioredoxin was a kind gift
from Professor Charles H. Williams, Jr. (Ann Arbor, MI). The expression
vector pJC40 was a gift from Dr. Joachim Clos (Bernhard Nocht
Institute, Hamburg, Germany). The expression vector pASK-IBA7 and
StrepTactin-Sepharose were from the Institut für
Bioanalytik (Göttingen, Germany). His-Bind-Resin was from
Novagen (Heidelberg, Germany). The plasmid pACYC184, restriction
enzymes, T4 DNA ligase, and T4 DNA polymerase were obtained from New
England Biolabs (Frankfurt am Main, Germany). Pfu polymerase
and E. coli BLR (DE3) were from Stratagene (Heidelberg, Germany). 5,5'-Dithiobis(2-nitrobenzoic acid) (DTNB) was purchased from
Sigma (Deisenhofen, Germany). NADPH and bovine serum albumin were from
Roche Molecular Biochemicals (Mannheim, Germany). All other reagents
and chemicals used were from Merck (Darmstadt, Germany) or Sigma.
DNA Manipulation and Nucleotide Sequence Analyses--
Routine
DNA manipulations and transformations were performed as described by
Sambrook et al. (17). The plasmids containing the
genetically modified PfTrxR constructs were sequenced using the Sanger dideoxy-chain termination reaction for double-stranded DNA
(17).
P. falciparum TrxR Mutants--
The PfTrxR mutants
PfTrxRC88A and PfTrxRC535A were generated
previously (18, 19). The double mutant PfTrxRC88AC535A was generated according to Gilberger et al. (18) using the
mutagenic oligonucleotides sense
5'-GCTAAAGGAGGAGCTGGGGGTGGAAAATGTGG-3' and antisense
5'-TCACATTTTCCACCCCCAGCTCCTCCTTTAGC-3' and
PfTrxRC88A in pJC40 as a template. The introduction of the
second mutation was verified by nucleotide sequence analysis of the
entire insert as described above.
Construction of Expression Plasmids--
To guarantee
co-expression and co-existence of two individual plasmids in one
E. coli cell, they need to have distinct origins of
replication and selectable markers. We intended to use one plasmid
containing an N-terminal Strep-tag and one plasmid
containing an N-terminal His-tag, which would result in the formation
of differentially tagged recombinant proteins. The His-tag plasmids (pSZ1, pSZ1TrxRC88A, pSZ1TrxRC535A, and pSZ1TrxRC88AC535A) were constructed as shown in Fig. 2. The
plasmid pACYC184 (carrying the p15A origin of replication and a
chloramphenicol acetyltransferase as selectable marker) was
digested with SalI, and the 5'-overhang was filled in with
T4 DNA polymerase according to standard methods (17). The expression
cassette of pJC40 was isolated using DrdI, and the
3'-overhang was blunted with T4 DNA polymerase. The
SalI-digested plasmid pACYC184 and the isolated pJC40
expression cassette were digested with BspHI and
ligated using T4 DNA ligase, resulting in the expression plasmid pSZ1.
To obtain the expression plasmids pSZ1TrxRC88A, pSZ1TrxRC535A,
pSZ1TrxRC88AC535A, respectively, the PfTrxR mutants
PfTrxRC88A, PfTrxRC535A, and
PfTrxRC88AC535A were amplified by PCR using Pfu
polymerase and plasmid DNA containing the respective mutant
PfTrxR as template with the following PCR program: 95 °C
(1 min) and 30 cycles of 95 °C (1 min), 50 °C (1 min), and
68 °C (3 min). The sense oligonucleotide
5'-GCGCCCCGGGCATGTGTAAAGATAAAAACG-3' coding for the first 6 amino acids
of PfTrxR contained a SmaI restriction site. The
antisense oligonucleotide 5'-GCGCGGGCCCTTATCCACATTTTCCACCCCC-3' encoding the last 6 amino acids of PfTrxR generated an
ApaI restriction site to facilitate directional cloning. The
expression plasmid pSZ1 and the gel-purified mutant PfTrxR
inserts were double digested with SmaI and ApaI
and ligated using T4 DNA ligase.
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Fig. 2.
Construction of expression plasmid pSZ1.
To obtain a plasmid that possesses a p15A origin of replication and
allows expression of a recombinant protein with an N-terminal His tag,
the plasmid pSZ1 was constructed. The expression cassette of pJC40 was
subcloned into pACYC184 as described under "Experimental
Procedures."
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Wild-type PfTrxR was amplified by PCR using Pfu
polymerase using the same PCR protocol as described above. The sense
oligonucleotide 5'-GCGCGCGGTCTCGGCGCTGTAAAGATAAAAACG-3' coding for the
first 6 amino acids and the antisense oligonucleotide
5'-GCGCGCGGTCTCGTATCATTATCC-ACATTTTCCACC-3' encoding the last 5 amino
acids of PfTrxR both contained BsaI restriction
sites. The purified PCR product (PfTrxRWT) and the expression vector pASK-IBA7 (ColE1 origin of replication, can be
selected for with ampicillin) were digested with BsaI and
ligated using T4 DNA ligase, resulting in
pStrepPfTrxRWT.
Co-expression and Purification of PfTrxR Homo- and
Heterodimers--
The expression vector pStrepPfTrxRWT was
transformed into competent E. coli BLR (DE3). Subsequently
the bacteria containing pStrepPfTrxRWT were made competent
and used for co-transformation with pSZ1TrxRC88A, pSZ1TrxRC535A, or
pSZ1TrxRC88AC535A (pSZ1Mut), respectively. An overnight culture
of the freshly co-transformed bacteria was diluted 1:50 in 3 liters of
fresh Luria Bertani-medium containing 50 µg
ml
1 ampicillin and 35 µg
ml1 chloramphenicol and grown at 37 °C
until the A600 reached 0.5. Expression of
wild-type protein (pStrepPfTrxRWT) was induced using 200 µg of anhydrotetracycline per liter of bacterial culture, and
the temperature was reduced to 20 °C. Three hours later the expression of pSZ1Mut was induced by addition of 500 µM
isopropyl 
-D-thiogalactopyranoside, and the bacterial
cultures were incubated overnight. The cells were harvested by
centrifugation (4000 × g, 10 min). The bacterial
pellet was resuspended in buffer W (100 mM Tris/HCl, pH
8.0, 1 mM EDTA), sonicated (Branson Sonifier 250), and the
cell lysate was centrifuged at 100,000 × g for 1 h (Centrikon-T 1065, Kontron). The supernatant was applied to a
StrepTactin column (2 ml) and washed with 10 ml of buffer W. Elution of the Strep- tag proteins was performed using 2.5 mM desthiobiotin in buffer W. Flow-through (30 ml) and
eluant (5 ml) were dialyzed separately overnight against 2 l of
binding buffer (20 mM Tris/HCl, pH 7.9, 5 mM
imidazole, 0.5 M NaCl). Subsequently flow-through and
StrepTactin eluant were applied separately to
Ni2+-chelating chromatography following the manufacturer's
recommendations. The purification resulted in three fractions: 1)
PfTrxRWT homodimer (Strep/Strep-tagged), 2)
PfTrxR mutant homodimer (His/His-tagged), and 3)
PfTrxRWT/PfTrxR mutant heterodimer
(Strep/His-tagged) (Fig. 3).
Protein concentrations were determined either by using the molar
extinction coefficient of 11340 M1 cm1
for the protein bound FAD at 460 nm (18) or by the method of Bradford
(20) using bovine serum albumin as a standard.
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Fig. 3.
Scheme of the purification procedure of
recombinantly co-expressed P. falciparum thioredoxin
reductase species. The 100,000 × g supernatant of
lysed bacteria co-expressing PfTrxRWT and PfTrxR
mutant proteins was applied to StrepTactin-Sepharose in the
first purification step. The His-tagged homodimer of mutant protein was
collected in the flow-through, the Strep-tagged
homodimer of wild-type PfTrxR and
Strep/His-tagged heterodimer of wild-type, and mutant
PfTrxR bound to the resin and were eluted with
desthiobiotin. Flow-through and eluant were dialyzed separately
and subsequently subjected to individual Ni2+-chelating
chromatographies. This procedure resulted in the separation of
three different protein species: 1) homodimeric Strep-tagged
PfTrxRWT, 2) homodimeric His-tagged PfTrxR mutant
proteins, and 3) heterodimeric Strep/His-tagged wild-type
and mutant PfTrxR.
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The purity of the three enzyme species was analyzed on a 7.5%
SDS-PAGE, and the proteins were visualized with Coomassie Brilliant Blue.
Enzyme Assays--
The specific activities of homo- (wild-type
and mutant PfTrxR) and heterodimeric proteins were
determined by the DTNB and thioredoxin reduction assays using E. coli Trx and insulin (19). The DTNB reduction assay (1 ml,
20 °C) contained 100 mM potassium phosphate buffer, pH
7.5, 0.2 mg ml1 bovine serum albumin, 2 mM EDTA, 2 µg of enzyme, 200 µM NADPH, and
3 mM DTNB. The change in absorbance was monitored at 412 nm (Uvikon 932, Kontron). The E. coli Trx reduction assay (1 ml, 37 °C) consisted of 100 mM HEPES buffer, pH 7.5, 0.2 mg ml1 bovine serum albumin, 2 mM
EDTA, 2 µg of enzyme, 200 µM NADPH, 200 µg of
insulin, and 100 µM E. coli Trx. The change in
absorbance was measured at 340 nm.
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RESULTS AND DISCUSSION |
Expression and Purification of PfTrxR Homo- and
Heterodimers--
The dimeric high Mr TrxRs
identified in mammals and P. falciparum possess one redox
active pair of cysteine residues in the N-terminal region and one
Cys-seleno-Cys or Cys-XXXX-Cys motif at their C
terminus, respectively (6, 21). It has been shown that both motifs are
essential for enzymatic activity with thioredoxin as substrate (10-12,
19). Even though it has been proposed that there exists a high degree
of structural similarity between the high Mr
TrxRs with glutathione reductase and lipoamide dehydrogenase (10, 18),
the catalytic mechanism of the TrxRs appears to be much more
complicated than that of the latter enzymes. Wang et al.
(10, 11) have shown that during catalysis reducing equivalents are
transferred from FAD to the N-terminal pair of cysteines and
subsequently reduce the C-terminal cysteine pair by an intramolecular
dithiol/disulfide exchange. To achieve such an interchange the N- and
C-terminal residues involved in this process need to be in close
proximity. There are two possible arrangements one can envisage for
such an interaction. One of them would be an intramolecular interaction
and thus the formation of two independent active sites in the
homodimeric protein; the second would be an intermolecular interaction
where amino acid residues are supplied by both subunits to form the
active sites of the enzyme (Fig. 1). To investigate how the active
sites of PfTrxR are formed, we co-expressed different
PfTrxR-species in E. coli BLR (DE3), separated
the generated proteins from each other and determined their specific
activities and Km values. Co-expression and
subsequent purification of StrepPfTrxRWT with three
constructs carrying different active site mutations resulted in the
isolation of three different protein species: Strep-tagged
wild-type homodimers, His-tagged mutant homodimers, and
Strep/His-tagged wild-type/mutant heterodimers (Figs. 3
and 4). The protein concentrations of the
three protein species in one preparation, however, was quite different.
The homodimeric proteins were expressed at much higher levels than the
heterodimeric proteins. There are several explanations for this
phenomenon. It is possible that the heterodimers formed during
co-expression are not very stable and are degraded more rapidly by the
bacterial cell than the homodimeric proteins. Another reason might be
the synthesis of monomers that do not dimerize co-translationally and
are therefore degraded rapidly by the bacterial cell. It has been shown
previously that monomeric mouse glutathione reductase is degraded
rapidly by bacterial cells (22). The generation of E. coli
glutathione reductase hybrid protein species resulted in high yields of
proteins, and there was no mention about a differential expression
pattern concerning the different protein species that were generated
(23). Similarly, the co-expression of mercuric ion reductase hybrids
apparently did not result in different yields of the hybrid proteins
(15).
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Fig. 4.
SDS-PAGE of homo- and heterodimers of
P. falciparum thioredoxin reductase. Proteins
obtained after purification on StrepTactin-Sepharose and
Ni2+-chelating chromatography were separated on a 7.5%
SDS-PAGE. Lane 1, 1 µg homodimeric Strep-tagged
wild-type PfTrxR; lane 2, 2 µg of heterodimeric
Strep/His-tagged wild-type/mutant protein; lane
3, 1 µg of homodimeric His-tagged mutant PfTrxR.
Marker, 10-kDa ladder.
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Specific Activities of Recombinant PfTrxR Homo- and
Heterodimers--
The specific activities of the co-expressions with
wild-type and three mutant PfTrxRs were determined using two
different assay systems. The results are summarized in Table
I. The specific activities of the
Strep-tagged wild-type PfTrxR are comparable with
those of preparations of nontagged recombinant PfTrxR in both assays (4.5 ± 1.5 units mg1
without tag versus 3.9 ± 0.5 units
mg1 with a Strep-tag using 100 µM E. coli thioredoxin and 6.2 ± 0.8 units mg1 versus 5.6 ± 1.6 units mg1 using DTNB).
The activities of PfTrxRWT and PfTrxRC88A with
E. coli thioredoxin are in good accordance with the expected
results regardless whether the active sites of PfTrxR are
formed by an intersubunit or intrasubunit interaction. The homodimers
are either 100% active (PfTrxRWT, 3.9 units
mg1) or show a very low activity of 0.4 unit
mg1 (PfTrxRC88A). It has been
shown previously that the mutation of Cys88 into
alanine resulted in a loss of DTNB and thioredoxin reducing activity
and thus that this residue is essential for the catalytic activity of
PfTrxR (18). The hybrid protein formed between
PfTrxRWT and PfTrxRC88A has 56% of wild-type
activity, which suggests that the protein possesses one fully active
catalytic site and one inactive catalytic site. Using DTNB as a
substrate the results are similar. The heterodimer formed between
wild-type and mutant subunit exhibits similar kinetic parameters to
those of the wild-type protein (Km PfTrxRWT/mutant
heterodimer: 384 ± 59 µM versus
Km PfTrxRWT: 429 ± 57 µM),
indicating that the C88A mutation is only acting on one of the active
sites, and no interaction is transmitted across the interface to the
second active site.
The alteration of Cys535 into alanine rendered the
protein inactive toward E. coli thioredoxin, and the DTNB
reduction by this mutant was decreased to about 60% of wild-type
activity (19). In accordance PfTrxRWT in this co-expression
experiment is fully active, and the C535A mutant homodimer is almost
completely inactive using E. coli thioredoxin as a substrate
and maintains about 60% of its DTNB reducing activity. The heterodimer
between PfTrxRWT and PfTrxRC535A subunits
maintains only 42% of residual activity rather than 50%, for the
reduction of E. coli thioredoxin. This slight discrepancy
could possibly be explained by contamination of this protein fraction
with inactive homodimers of mutant protein, which may occur during the
purification procedure. The results obtained in the DTNB reduction
assay are, however, more difficult to explain. The heterodimers between
PfTrxRWT and PfTrxRC535A show a residual activity
of 55%, which is much lower than the expected 80%, taking into
account that one fully active and one slightly impaired catalytic site
(60% residual activity) are formed in this enzyme hybrid (Table I).
Interestingly the Km value for DTNB reduction is
higher than for the wild-type protein (678 ± 1 µM
versus 429 ± 57 µM) and lower than for
the PfTrxRC535A homodimer (678 ± 1 µM
versus 800 ± 22 µM). These results
suggest that the alteration of Cys535 in one active
site possibly results in subtle changes in the reactivity of the second
active site, which may interfere with DTNB and also thioredoxin
reduction. An asymmetry in the catalytic activity of the two active
sites of PfTrxR occurring during the interchange of
electrons between the N-terminal cysteine residues and the C-terminal
cysteine residues has been previously proposed by Wang et
al. (24), and asymmetry of the active sites occurs in several
other members of this enzyme family (25-27). The data presented here
support this hypothesis, and these possible cooperative interactions
will be investigated in more detail in future studies.
The key experiment that allows us to draw final conclusions
about the formation of the PfTrxR active sites was the
co-expression of PfTrxRWT with the double mutant
PfTrxRC88AC535A. Both enzymatic assays show the results
expected when the active sites of PfTrxR are formed by an
intersubunit interaction between both subunits of the dimeric protein
(Fig. 5). The heterodimers between
PfTrxRWT and PfTrxRC88AC535A were inactive
and the homodimeric mutant proteins also did not show an appreciable
enzymatic activity with thioredoxin (Table I). Therefore it can be
concluded that the interaction of the N-terminal cysteine residues
Cys88 and Cys93 with the protein-bound FAD
occurs on one subunit, and the reducing equivalents are then
transferred to the C-terminal cysteine residues Cys535 and
Cys540 of the second subunit. The thiolate anions are most
likely stabilized by the acid/base His509 also provided by
the second subunit (18). This conformation resembles those of the
glutathione reductase, lipoamide dehydrogenase, and mercuric ion
reductase. Perham and co-workers (23, 28) have demonstrated a similar
interaction between the subunits in E. coli glutathione
reductase by separating homo- and heterodimers by engineering an
arginine-tag to one of the subunits and co-expressing the
arginine-tagged and unmodified proteins in E. coli. Neither of the hybrid proteins formed in this study had any influence on the
kinetic parameters, indicating that in glutathione reductase no
cooperative effects between the two subunits occur (29). In mercuric
ion reductase, which like PfTrxR possesses an additional pair of Cys residues at the C-terminus, intersubunit active sites are
formed (15). A cooperative interaction between both active sites has
been suggested in mercuric ion reductase (25) similar to our
observations on PfTrxR described in Wang et al.
(24) and in this study. The generation of heterodimeric
PfTrxR protein species will facilitate future studies on the
catalytic mechanism of the protein, such as potential cooperative
interactions between the active sites during catalysis (25, 26, 30). In
addition the knowledge of the architecture of the PfTrxR
catalytic centers allows the overexpression of dominant negative
mutants in P. falciparum, which will help to determine the
biological role of the protein in the parasites. Ultimately this
approach will aid to validate and assess P. falciparum
thioredoxin reductase as a target for a chemotherapeutic intervention
of malaria.
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Fig. 5.
Intersubunit organization of P. falciparum thioredoxin reductase. A,
Strep-tagged wild-type PfTrxR; B,
His-tagged PfTrxRC88AC535A; C,
Strep/His-tagged heterodimer-residues of both subunits
contribute to the formation of both active sites.
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FOOTNOTES |
*
This work was supported by Deutsche Forschungsgemeinschaft
Grant MU837/1-1.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.
§
This work was part of the doctoral study at the University of
Hamburg, Faculty of Biology (performed by Z. K.).
¶
Current address: The Walter and Eliza Hall Institute of
Medical Research, P. O. Royal Melbourne Hospital, Melbourne 3050, Australia.
To whom correspondence should be addressed: Current address:
School of Life Sciences, Wellcome Trust Biocentre, University of
Dundee, Dundee DDI 5EH, Scotland, UK. Tel.: 44-1382-345-843; Fax:
44-1382-345-764 E-mail: sylkemueller@yahoo.com.
Published, JBC Papers in Press, October 5, 2000, DOI 10.1074/jbc.M008443200
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ABBREVIATIONS |
The abbreviations used are:
TrxR, thioredoxin
reductase;
Trx, thioredoxin;
DTNB, 5,5'-dithiobis(2-nitrobenzoic acid);
PfTrxR, Plasmodium falciparum thioredoxin
reductase;
TrxR, thioredoxin reductase;
PCR, polymerase chain reaction;
PAGE, polyacrylamide gel electrophoresis;
WT, wild-type.
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