(Received for publication, February 25, 1997, and in revised form, April 30, 1997)
From the Department of Biochemistry and Molecular Biology, Wayne State University School of Medicine, Detroit, Michigan 48201
The ars operon of plasmid R773 encodes an ATP-dependent extrusion pump for arsenite and antimonite in Escherichia coli. The ArsA ATPase is the catalytic subunit of the pump protein, with two nucleotide binding consensus sequences, one in the NH2-terminal half and one in the COOH-terminal half of the protein. A 12-residue consensus sequence (DTAPTGHTIRLL) has been identified in ArsA homologs from eubacteria, archebacteria, fungi, plants, and animals. ArsA enzymes were constructed containing single tryptophan residues at either end of this conserved sequence. The emission spectrum of the fluorescence of the tryptophan on the COOH-terminal end (Trp-159) indicated a relatively hydrophilic environment for this residue. An increase in intrinsic tryptophan fluorescence and a blue shift of the maximum emission wavelength were observed upon addition of MgATP, indicating movement of Trp-159 into a relatively less polar environment. No fluorescence response was observed with MgADP, with nonhydrolyzable ATP analogs, or with MgATP by catalytically inactive enyzmes. This suggests that the location Trp-159 is shifted only during hydrolysis of ATP. In contrast, the emission spectrum of Trp-141, located on the NH2-terminal side of the consensus sequence, indicated a relatively nonpolar environment. The maximum emission wavelength red shifted upon addition of MgADP. MgATP slowly produced a response that correlated with product formation, suggesting that the environment of Trp-141 is sensitive only to MgADP binding. Thus, during ATP hydrolysis the COOH-terminal end of the conserved domain moves into a less polar environment, whereas the NH2-terminal end moves into a more hydrophilic environment as product is formed. A hypothesis is presented in which the conserved domain of ArsA and homologs is an energy transduction domain involved in transmission of the energy of ATP hydrolysis to biological functions such as transport.
Resistance to arsenical and antimonial salts in the Gram-negative bacterium Escherichia coli is conferred by the ars operon of conjugative R-factor R773 (1). This operon encodes an ATP-coupled efflux pump that actively transports the trivalent arsenicals and antimonials out of the cell; reducing the intracellular concentration of those metalloid oxyanions to subtoxic levels produces resistance (2). The pump consists of two types of polypeptides, ArsA and ArsB. ArsA is the 63-kDa catalytic subunit. ArsB is a 45-kDa integral membrane protein that is the membrane anchor for ArsA and the oxyanion-translocating sector of the pump (3). In the absence of ArsB, ArsA can be purified as a soluble ATPase (4). The NH2-terminal (A1) and COOH-terminal (A2) halves of ArsA ATPase are homologous to each other, likely the result of an ancestral gene duplication and fusion (5). Both the A1 and A2 halves contain a consensus sequence for the phosphate binding loop (P-loop) of an ATP binding site (6), and both sites are required for catalysis and resistance (7, 8). From the results of intergenic complementation and intragenic suppression, a model was proposed in which a single catalytic site was formed at the interface of an A1 and an A2 ATP binding site (9, 10).
Construction of single tryptophan-containing proteins has proven of value in the study of other E. coli transport enzymes. For example, the environments of regions of the mannitol enzyme II were investigated from the fluorescence of strategically placed tryptophan residues (11). Senior and colleagues have used tryptophan fluorescence as a direct probe of nucleotide binding in the noncatalytic sites of E. coli F1-ATPase (12, 13) and to discriminate between binding of substrate and product in the catalytic sites (14). We have shown previously that intrinsic tryptophan fluorescence can be used to investigate the interactions with its ligands (15). However, the presence of multiple tryptophan residues in ArsA decreased the signal-to-noise response to ligand binding; of the four tryptophan residues in ArsA, only Trp-159 gave a substrate-responsive signal. From that study it was not clear whether ATP binding to the A1 or A2 site or both produced enhancement of Trp-159 fluorescence.
In this study mutant arsA genes were constructed containing single tryptophan codons. By site-directed mutagenesis tyrosines were substituted for Trp-253, Trp-522, and Trp-524, and a six-histidine tag was added to the COOH terminus, producing a His-tagged ArsA containing only Trp-159 (W159H6); a His-tagged tryptophan-free ArsA was also constructed. The single tryptophan-containing W159H6 ArsA gave approximately a 4-fold increase in the signal-to-noise ratio in response to MgATP/mol of tryptophan residue compared with the wild type enzyme. The sequence D142TAPTGHTIRLL153 in A1 is highly conserved in ArsA homologs from every kingdom, implying that this common motif may have a conserved function. To examine the microenvironment of the conserved sequence, an F141W substitution was introduced into the tryptophan-free ArsA, producing a W141H6 enzyme. The fluorescence spectra indicate that Trp-141 is located in a hydrophobic region, whereas Trp-159 is surround by a relatively hydrophilic environment. Binding of MgADP moved Trp-141 into a more hydrophilic region; in contrast, the addition of MgATP shifted Trp-159 into a more hydrophobic environment.
To examine the effect of mutation in the nucleotide binding sites, substitutions in the A1 (G18R) and A2 (G337R) P-loops were introduced into single tryptophan-containing ArsAs. The results showed that neither binding of substrate nor product per se affected the fluorescence of Trp-159, suggesting that changes in Trp-159 fluorescence report a transient state during ATP hydrolysis. Since Trp-141 at one end of the conserved sequence enters a more polar environment while Trp-159 at the other end enters a less polar environment, this sequence may be an energy transduction domain that experiences significant conformational changes during hydrolysis of ATP.
Restriction enzymes and nucleic acid-modifying enzymes were the products of Life Technologies, Inc. and Promega. Mutagenic oligonucleotides were synthesized by the Macromolecular Core Facility of the Department of Biochemistry and Molecular Biology at Wayne State University School of Medicine. The ProBond Ni2+ affinity resin was obtained from Invitrogen. All other chemicals were purchased from commercial sources.
Bacterial Strains, Plasmids, Media, and Growth ConditionsThe E. coli strains and plasmids used in
this study are listed in Table I. Cells
were grown at 37 °C in LB medium (16) containing either ampicillin
(125 µg/ml) or tetracycline (12.5 µg/ml), as required. Isopropyl
-D-thiogalactopyranoside was added at the indicated
concentration to induce the expression of ArsA proteins.
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Plasmid isolation, DNA restriction endonuclease analysis, ligation, and transformation were performed as described (16). All mutations were confirmed by sequencing using a Cy5-AUTOREAD sequencing kit with an ALFexpress system (Pharmacia Biotech Inc.). Plasmid DNA for sequencing was prepared with a miniprep kit (QIAGEN).
Oligonucleotide-directed MutagenesisMutations in the
arsA gene were introduced by site-directed mutagenesis using
the Altered SitesTM in vitro Mutagenesis system
(Promega). Single-strand DNA of plasmid pW253Y (15), encoding a single
tryptophan-to-tyrosine mutation at arsA codon 253, was used
as the initial template. Plasmid pTZ3 was obtained by simultaneously
mutating tryptophan codons 522 and 524 of plasmid pW253Y to tyrosine
codons using the following oligonucleotide (respective changes
underlined):
5-GCTGTTATTGATAATGTAGCCGTAGGGGTGAATGCCTGC-3
.
To purify ArsA by Ni2+ affinity column, a six-histidine tag
(His6) was introduced to the COOH terminus of the arsA gene
of plasmid pTZ3 by inserting 18 bases encoding six histidine residues
between the last codon and the stop codon using the following
oligonucleotide (histidine codon insertions underlined):
5-TTTGCTGCCCTACGTGATGACAATAATTTAATGATGATGATGATGATGCCCAGCAAGTTGTTTGAGTTTGTCGATGCC-3
.
The resulting plasmid pTZ3H6 was used for expression and purification
of the single tryptophan-containing W159H6 ArsA by Ni2+
affinity chromatography. To construct plasmid pTZ4H6, encoding a
tryptophan-free ArsA, the 6.5-kilobase fragment from plasmid pTZ3H6 was
digested with AvaI and ligated with the 2.5-kilobase AvaI fragment from plasmid pW159Y. The ligation mixture was
transformed into E. coli strain JM109. Plasmid pW141H6,
which expresses the single tryptophan-containing W141H6 ArsA, was
constructed by mutating codon 141 of plasmid pTZ4H6 to a Trp codon
using the following oligonucleotide:
5-GGCGCGGTATCCCAAATGATATGG-3
.
The oligonucleotides used for the introduction of G18R and G337R
substitutions in the A1 or A2 consensus nucleotide binding sites in
pTZ3H6 and pW141H6 were: 5-TTACCCACGCGTCCTTTACCCG-3
(G18R) and 5
-TTCCCCACGCGACCTTTACCC-3
(G337R), where the
indicated mutations are underlined.
Cells were grown
in 100 ml of LB medium at 37 °C overnight and diluted into 1 liter
of prewarmed LB medium, with antibiotics added as required. The culture
was induced at A600 nm = 0.6-0.8 with 0.1 mM isopropyl -D-thiogalactopyranoside for
2.5 h and harvested by centrifugation. The cells (4-5 g wet
weight) were washed once with buffer A (50 mM
MOPS1-KOH, pH 7.5, 0.5 M NaCl, 20% glycerol, and 5 mM
-mercaptoethanol) and stored at
80 °C until use. The cells were
suspended in 5 ml of buffer A containing 20 mM glycine/g of
wet cells and lysed by a single passage through a French pressure cell
at 20,000 p.s.i. Diisopropyl fluorophosphate was added at 2.5 µl/g of
wet cells immediately following lysis. The lysate was centrifuged at
100,000 × g for 60 min at 4 °C, and the supernatant
solution was loaded at a flow rate of 0.5 ml/min onto a column
containing 5 ml of ProBond Ni2+ affinity resin
preequilibrated with 30 ml of buffer A containing 20 mM
glycine. The column was washed with 40 ml of buffer A followed by 40 ml
of buffer A containing 0.1 M glycine and finally with 40 ml
of buffer A containing 0.2 M glycine, all at a flow rate of
1.0 ml/min. Finally ArsA was eluted with 100 ml of 0.6 M
glycine in buffer A. ArsA-containing fractions were identified by
sodium dodecyl sulfate-polyacrylamide gel electrophoresis, pooled, and concentrated using a Millipore Ultrafree-15 centrifugal filter BIOMAX-30K (Millipore) at 2,000 × g. Purified ArsA was
quickly frozen and stored in small aliquots at
80 °C. The
concentration of purified ArsA was determined by UV absorbance at 280 nm. The extinction coefficients for W159H6 ArsA and W141H6 ArsA were
calculated to be 20,250 and 21,530 M
1
cm
1, respectively (17).
Routine ATPase assay was carried out as described (18). To correlate the rate of ATP hydrolysis with the rate of change of tryptophan fluorescence, ATPase activity was estimated from the release of phosphate by the method of Fiske and SubbaRow (19). ArsA and ATP at the indicated concentrations were incubated at room temperature for 5 min in buffer containing 50 mM MOPS-KOH, pH 7.5. One portion was used to monitor the fluorescence change, and the remainder was used to assay ATPase activity. The reaction was initiated by the addition of MgCl2 to a final concentration of 0.5 mM. At indicated times, portions of 0.2 ml were withdrawn and mixed with 0.2 ml of 20% trichloroacetic acid to terminate the reaction. Precipitated protein was removed by centrifugation, and 0.3 ml of the supernatant solution was mixed with 0.2 ml of a solution of 5% FeSO4, 1% (NH4)2MoO4, and 1 N H2SO4. After 10 min at 37 °C, the absorbance at 740 nm was measured, and phosphate concentrations were determined from the absorbance of known amounts of phosphate.
Fluorescence MeasurementsFluorescence measurements were performed on a SLM-8000C spectrofluorometer at room temperature. Samples were stirred continuously in a 1.0 × 1.0-cm quartz cuvette. The excitation wavelength was set at 295 nm for selective excitation of tryptophan fluorescence. The bandwidths for both emission and excitation monochromators were 4 nm. Spectra were corrected for background and Raman scattering by subtracting buffer spectra. Free tryptophan was used as an external standard for comparison of different spectra. To monitor the fluorescence intensity change with time or addition of quenching ligands, the emission wavelengths were set to 322 nm for W141H6, 337 nm for W159H6, and 353 nm for free tryptophan and denatured ArsAs. The concentration of ArsA was 1.25 µM, unless otherwise noted. The buffer used was 50 mM MOPS-KOH, pH 7.5. To denaturate ArsA, the protein was mixed with 6 M guanidine HCl for 3 min before measurement. To determine collisional quenching of tryptophan fluorescence, stock solutions of 8 M acrylamide and 5 M KI containing 0.1 mM Na2S2O3 were used (20). The effects of dilution and ionic strength were calibrated in parallel experiments. The quenching data were plotted according to the Stern-Volmer equation (21)
![]() |
(Eq. 1) |
The arsenite
resistance phenotype of cells of strain JM109 bearing plasmids with
mutated arsA genes was analyzed (Fig.
1). Sequential substitution of tyrosines
for Trp-253, Trp-522, and Trp-524 and addition of the six histidine
residues at the COOH terminus produced an ArsA with only Trp-159
(W159H6). Substitution of tyrosine for Trp-159 in W159H6 produced a
tryptophan-free ArsA. Subsequent substitution of tryptophan for Phe-141
resulted in the single tryptophan ArsA W141H6. Each mutated gene
conferred wild type resistance to arsenite. Introduction of a G18R
substitution in the A1 P-loop (8) or G337R in the A2 P-loop (7) in
either W159H6 or W141H6 produced an arsenite-sensitive phenotype.
Each ArsA was purified by Ni2+ affinity chromatography and ATPase assayed. Although ArsA with a COOH-terminal histidine tag had slightly less activity than the wild type enzyme, both W159H6 and W141H6 are as active as the wild type protein with a COOH-terminal histidine tag (data not shown). Combination of the G18R or G337R substitution with W159H6 or W141H6 resulted in inactive proteins. The results indicate that none of the tryptophan residues nor Phe-141 is essential for activity, allowing tryptophan fluorescence to be used as an intrinsic probe of ArsA catalysis.
Fluorescent Properties of W159H6 and W141H6 ArsA ATPasesThe polarity of microenvironment of tryptophan
residues in a protein can be assessed from their fluorescence emission
spectra (21). In a less polar environment the maximum emission
wavelength (max) of tryptophan shifts to a lower
wavelength, with an increase in the fluorescence yield (21). When
excited at 295 nm, free tryptophan in an aqueous solution has a
max at 353 nm (Fig. 2, curve 5), whereas the
max of Trp-159 and
Trp-141 were 337 nm (Fig. 2, curve 2) and 322 nm (Fig. 2,
curve 1), respectively. At the same concentration of protein
the fluorescence yield of Trp-141 was nearly twice that of Trp-159. The
max of each shifted to 353 nm upon denaturation of the
proteins with 6 M guanidine HCl (Fig. 2, curves
3 and 4). These results demonstrate that Trp-141 is in
a relatively less polar environment than Trp-159.
The environment of a specific tryptophan can also be evaluated by its
accessibility to collisional fluorescence quenchers (20). The
Stern-Volmer constants (KD) for Trp-141, Trp-159,
and free tryptophan quenching with acrylamide and I under
native and denatured conditions were determined (Table II). In native ArsA Trp-141 is in an
environment 3.3-fold less accessible to either I
or
acrylamide than Trp-159, even though both Trp-159 and Trp-141 are
almost equally accessible in denatured proteins by I
or
acrylamide. Compared with free tryptophan, Trp-141 was 37-fold and
13-fold less accessible to I
and acrylamide,
respectively, indicating that it is extremely shielded from the
solvent. In denatured ArsA, Trp-141 was 11-fold and 6-fold more
accessible by I
and acrylamide, respectively, than in the
native enzyme, whereas accessibility of Trp-159 was increased by a
factor of 3.6 and 1.5 for I
and acrylamide, respectively.
However, the KD values for the denatured proteins
were still lower than the KD values for free
tryptophan, which may indicate that the proteins are not completely
unfolded by guanidine HCl. Consistent with the results from
fluorescence emission spectra presented above, the fluorescence
quenching data also suggest that Trp-141 is located in a less polar
region than Trp-159, possibly by proximity to negatively charged amino
acid residues.
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In the presence of both 1 mM ATP and 0.5 mM MgCl2, the emission spectrum of W159H6 ArsA
exhibited a blue shift of about 5 nm, with an increase in fluorescence
intensity (Fig. 3A,
curve 1) compared with the absence of nucleotide (Fig.
3A, curve 3). Neither ATP nor MgCl2
alone produced a change in fluorescence (data not shown), indicating
that binding of the MgATP complex induced a conformational change that
moves Trp-159 into a relatively more hydrophobic region. MgADP produced
no change in the emission spectrum of W159H6 (Fig. 3A,
curve 2). In control experiments, MgATP was shown to have no
effect on the fluorescence of free tryptophan or on denatured protein
(data not shown). ArsA neither aggregates nor exhibits a change in
light scattering properties upon addition of nucleotides (22), so the
fluorescence increase cannot be due to light scattering produced by
aggregation.
In contrast, when W141H6 was incubated with MgADP, the
max exhibited a red shift of about 5 nm, with a decrease
in fluorescence intensity (Fig. 3B, curve 3)
compared with the absence of nucleotide (Fig. 3B,
curve 1). Neither MgCl2 nor ADP alone produced a
response (data not shown). Incubation of W141H6 with the
nonhydrolyzable ATP analog AMP-PNP produced no change in the emission
spectrum (Fig. 3B, curve 2). The response of
W141H6 to MgATP was more complicated. With time
max
gradually red shifted, while the fluorescence intensity decreased (Fig.
3C). After 20 min the spectra of the samples with MgATP
resembled that of W141H6 exposed to MgADP. The facts that the effect of
ATP was time-dependent and that a nonhydrolyzable ATP
analog gave no response suggest that only MgADP, the product of
hydrolysis, produces a change in the intrinsic fluorescence of Trp-141.
Since the effect of MgADP is a red shift with a decrease in
fluorescence intensity, the data suggest that binding of MgADP induces
a movement of Trp-141 into a relatively more polar environment.
Although MgATP induces an enhancement of
the fluorescence of Trp-159, in wild type ArsA the enhancement was
relatively low compared with the total tryptophan fluorescence. The
signal-to-noise ratio was increased considerably in the single
tryptophan containing W159H6 (Fig.
4A, curve 1)
compared with the wild type his-tagged enzyme (Fig. 4A,
curve 2) when the amount of each protein was adjusted to
equivalent concentrations of tryptophan residues. This enhancement
allowed a more sensitive and detailed characterization of the
MgATP-responsive signal.
Although a sustained fluorescence enhancement was observed with a
saturating concentration of MgATP (Fig. 4A), enhancement was
transient at 5 µM ArsA with 20 µM MgATP
(Fig. 4B, curve 1). If a second pulse of ATP was
added following the decrease in fluorescence, a further transient
increase was observed (Fig. 4B, curve 1). Moreover, the rate of decay of the fluorescence signal correlated with
the rate of phosphate released during ATP hydrolysis (Fig. 5A). Addition of neither MgADP
(Fig. 4C, curve 2) nor MgATPS (Fig.
4C, curve 3) nor the combination of MgADP and
phosphate (Fig. 4C, curve 4) enhanced
fluorescence. These results indicate that neither the binding of
substrate nor the binding of products to ArsA is sufficient to cause
the fluorescence change, suggesting that the increase in fluorescence
was related to ATP hydrolysis rather than MgATP binding per
se, reporting the conformation of an intermediate formed during
the catalytic cycle.
That premise was tested by examination of the fluorescence of W159H6 with a G18R substitution in the A1 P-loop or a G337R substitution in the A2 P-loop. These substitutions have been shown previously to eliminate nucleotide binding in their respective ATP binding sites (8). Although the enzymes are catalytically inactive, they still bind nucleotide at the nonsubstituted site. Neither the G18R W159H6 (Fig. 4C, curve 5) nor the G337R W159H6 (Fig. 4C, curve 6) gave a fluorescence response following addition of MgATP, consistent with an association of Trp-159 movement and catalysis.
Binding of MgADP Results in Movement of Trp-141 to a More Polar EnvironmentAddition of MgADP to W141H6 produced a red shift in
the max and a quenching of fluorescence, whereas MgATP
produced a similar effect only at later times (Fig. 3C).
From the kinetics of the fluorescence quenching it appears that the
addition of MgADP produced a rapid decrease in fluorescence intensity
(Fig. 6, curve 1), whereas
MgATP produced a slow change that took approximately 20 min to reach
completion (Fig. 6, curve 2). Fluorescence quenching did not
occur in the absence of MgCl2 and was reversed by the addition of EDTA (data not shown), indicating a requirement for Mg2+. The nonhydrolyzable ATP analogs AMP-PNP (Fig. 6,
curve 3) and FSBA (Fig. 6, curve 4) had no effect
on the fluorescence of W141H6. Moreover, FSBA inhibited the response to
ATP (Fig. 6, curve 4). These results suggest that Trp-141
responds to binding of the product of the reaction, MgADP, and not to
MgATP. The rate of quenching produced by MgATP correlated with the rate
of ADP formation (Fig. 5B). There was no effect of MgADP or
MgATP on the fluorescence of W141H6 ArsA proteins with a G18R
substitution in the A1 P-loop or a G337R substitution in the A2 P-loop
(Fig. 6, curves 5-8). These proteins would still be
expected to bind ADP at the nonsubstituted site, so occupancy of both
sites may be required to produce the conformational change reported by
Trp-141. However, the data clearly show that Trp-141 moves into a
relatively more polar environment upon binding of MgADP and is a
sensitive probe for the binding of the product of hydrolysis.
The R773 ars operon confers arsenite and antimonite resistance to E. coli cells by encoding an ATP-coupled oxyanion pump that extrudes those toxic compounds out of the cell, lowering their intracellular concentration to subtoxic levels. The catalytic subunit of the pump, ArsA, is a 63-kDa protein that hydrolyzes ATP in the presence of Mg2+. It has a basal hydrolytic activity that is allosterically activated by antimonite or arsenite, which is accompanied by formation of a homodimer (4, 22). ArsA has two consensus ATP binding motifs (6), one in each of the A1 and A2 halves (5). Both the A1 and A2 binding sites are required for resistance and catalysis (7, 8). Based on results from biochemical analysis (22), genetic complementation (9), and intragenic suppression (10), a model has been proposed in which the interface of an A1 and an A2 binding site forms a single catalytic unit (9, 10). However, it is not known whether the interface forms from the A1 and A2 domains of a single ArsA monomer or from intersubunit interactions.
Wild type ArsA has four tryptophans located at positions 159, 253, 522, and 524 (5). We have shown previously that intrinsic tryptophan
fluorescence can be used to investigate the interactions of ArsA with
its ligands and that the fluorescence of Trp-159 is responsive to the
interaction of ArsA with MgATP (15). In this study single
tryptophan-containing ArsA enzymes were used as sensitive probes of
ligand interaction. An ArsA with a single tryptophan at residue 159 exhibited a large enhancement of fluorescence upon addition of MgATP,
with a concomitant shift in max to lower wavelength.
This increase of fluorescence intensity and the blue shift of emission
spectrum of Trp-159 indicate that the interaction of ArsA with MgATP
causes a specific conformational change that moves Trp-159 into a more
hydrophobic environment. However, the addition of nonhydrolyzable MgATP
analogs or the product, MgADP, did not produce a fluorescence change,
nor did MgATP produce a change in inactive enzymes unable to bind
nucleotide at either the A1 or the A2 site. Moreover, the fluorescence
enhancement was transient and correlated with the rate of ATP
hydrolysis. Thus it is likely that the fluorescence of Trp-159 is
reporting a transient state of the enzyme formed during ATP hydrolysis. In addition, the loss of fluorescence response following inactivation of either nucleotide binding site supports our previous hypothesis that
the A1 and A2 sites must interact to form a single catalytic unit (10,
22).
A second single tryptophan-containing ArsA was constructed in which Phe-141 was altered to Trp-141. The substitution was neutral, having no effect on ATPase activity. Comparison of the emission spectra of Trp-141 and Trp-159 suggests that the former is in a more hydrophobic environment than the latter. In accordance with this idea, the fluorescence of Trp-141 was nearly unaffected by the collisional quencher KI, whereas Trp-159 was quenched readily. In contrast to Trp-159, the fluorescence of Trp-141 was quenched by MgADP. Although MgATP produced quenching, the response was slow and paralleled formation of ADP by hydrolysis, suggesting that Trp-141 responds only to the product of the reaction. Consistent with this, nonhydrolyzable ATP analogs produced no quenching, nor did MgATP affect the fluorescence of catalytically inactive enzymes.
Thus two aminoacyl residues separated by only 17 residues
(F141DTAPTGHTIRLLQLPGAW159) respond quite
differently to nucleotides. This sequence is conserved in the A2 half
of ArsA and in homologs from every kingdom, including bacteria, archea,
fungi, plants, and animals (Fig. 7).
Although most of these homologs have been identified solely as open
reading frames by nucleotide sequencing, the conservation of this
sequence suggests that it is a functional domain. Interestingly, the
human homolog has been implicated in arsenite resistance (23). In ArsA
this sequence may be involved in ATP hydrolysis, since none of the
conformational changes occurs with nonhydrolyzable ATP analogs or with
catalytically inactive ArsA enzymes. By analogy, we would propose that
this conserved domain is involved in ATP hydrolysis in homologs, which
would, therefore, be ATPases. During ATP hydrolysis the COOH-terminal end of the domain moves into a more hydrophobic environment. As product
is formed, the NH2-terminal end moves into a more
hydrophilic environment. At the NH2 terminus of this domain
is a conserved aspartate residue, corresponding to Asp-142 in the A1
half of ArsA. In preliminary experiments we have found that a D142N
substitution results in an arsenite-sensitive
phenotype,2 suggesting that
Asp-142 may be of importance for the ATPase activity, perhaps
functioning as a ligand to Mg2+ associated with the
nucleotide. We hypothesize that the conserved domain of ArsA and
homologs is an energy transduction domain that might be involved in
transmission of the energy of ATP hydrolysis to other functions such as
transport of arsenite through the ArsB subunit of the oxyanion
pump.