(Received for publication, February 26, 1996, and in revised form, October 9, 1996)
From the Laboratory of Microbial Biochemistry,
Institute for Chemical Research, Kyoto University, Uji, Kyoto 611, and the § Biotechnology Research Laboratories, Takara Shuzo
Co., Ltd., Otsu, Shiga 520-21, Japan
Asp10 of L-2-haloacid
dehalogenase from Pseudomonas sp. YL was proposed to act as
a nucleophile to attack the -carbon of L-2-haloalkanoic acids to form an ester intermediate, which is hydrolyzed by
nucleophilic attack of a water molecule on the carbonyl carbon (Liu,
J.-Q, Kurihara, T., Miyagi, M., Esaki, N., and Soda, K. (1995)
J. Biol. Chem. 270, 18309-18312). We have found that
the enzyme is paracatalytically inactivated by hydroxylamine in the
presence of the substrates monochloroacetate and
L-2-chloropropionate. Ion spray mass spectrometry demonstrated that the molecular mass of the enzyme inactivated by
hydroxylamine during the dechlorination of monochloroacetate is about
74 Da greater than that of the native enzyme. To determine the increase
of the molecular mass more precisely, we digested the inactivated
enzyme with lysyl endopeptidase and measured the molecular masses of
the peptide fragments. The molecular mass of the hexapeptide
Gly6-Lys11 was shown to increase by 73 Da.
Tandem mass spectrometric analysis of this peptide revealed that the
increase is due to a modification of Asp10. When the enzyme
was paracatalytically inactivated by hydroxylamine during the
dechlorination of L-2-chloropropionate, the molecular mass
of the hexapeptide was 87 Da higher. Hydroxylamine is proposed to
attack the carbonyl carbon of the ester intermediate and form a stable
aspartate
-hydroxamate carboxyalkyl ester residue in the inactivated
enzyme.
Paracatalytic enzyme modification is a catalysis-linked and substrate-dependent enzyme modification (1). It involves a direct chemical reaction between an enzyme-activated substrate and an extrinsic reagent. The catalytic effect of an enzyme can increase the reactivity of a substrate with extrinsic reagents that are not constituents of the normal enzyme-substrate system. The reactive intermediates formed may thus react with extrinsic reagents to branch off from the normal catalytic pathway. Consequently, the enzyme active site may be specifically and irreversibly modified.
L-2-Haloacid dehalogenase (EC 3.8.1.2) catalyzes the
hydrolytic dehalogenation of L-2-haloalkanoic acids to
produce the corresponding D-2-hydroxyalkanoic acids (2-4).
Our recent 18O incorporation experiment showed that the
reaction of L-2-haloacid dehalogenase from
Pseudomonas sp. YL (L-DEX
YL)1 proceeds through the mechanism shown
in Fig. 1 (5); Asp10 acts as a nucleophile
to attack the -carbon atom of the substrate, producing an ester
intermediate and a halide ion. Subsequently, a water molecule
hydrolyzes this intermediate forming D-2-hydroxyalkanoic acid and restoring the side chain carboxylate group of
Asp10. The reactions catalyzed by haloalkane dehalogenase
from Xanthobacter autotrophicus GJ10 (6, 7), rat liver
microsomal epoxide hydrolase (8), and 4-chlorobenzoyl-CoA dehalogenases
from Pseudomonas sp. strain CBS3 (9) and
Arthrobacter sp. 4-CB1 (10) also proceed through similar
mechanisms, which involve the formation of an enzyme-substrate ester
intermediate.
If such an ester intermediate is accessible to solvent, nucleophiles other than water could also react with this intermediate to modify it. We used hydroxylamine as a nucleophile (11) and found that L-DEX YL is paracatalytically inactivated by hydroxylamine. Tandem MS/MS spectrometric analysis revealed that the active site Asp10 was specifically labeled. Hydroxylamine is thus useful to probe the active site carboxylate group, which constitutes an enzyme-substrate ester intermediate.
Materials
Leu11, Ser176, and Arg185 were replaced by Lys by site-directed mutagenesis, and the resultant mutant enzyme, L-DEX T15, yields a small peptide fragment containing active site Asp10 of L-DEX YL by lysyl endopeptidase digestion. (5). Catalytic properties of L-DEX T15 such as the specific activity for L-2-chloropropionate and the optimum pH were indistinguishable from those of the wild type enzyme. L-DEX YL and L-DEX T15 were purified from recombinant Escherichia coli cells, which overproduce these enzymes (12, 13). Lysyl endopeptidase of Achromobacter lyticus M497-1 and TPCK-treated trypsin were bought from Wako Industry Co., Ltd. (Osaka, Japan) and Worthington Biochemical Corp. (Freehold, NJ), respectively. L-2-Chloropropionate and monochloroacetate were purchased from Sigma (St. Louis, MO) and Nacalai Tesque (Kyoto, Japan), respectively. Hydroxylamine sulfate was obtained from Wako Industry Co. All other chemicals were of analytical grade.
Enzyme and Protein Assay
L-DEX YL and L-DEX T15 were assayed with
25 mM L-2-chloropropionate as a substrate. The
chloride ions released were spectrophotometrically determined according
to the method of Iwasaki et al. (14). In this assay,
chloride ion reacts with Hg(SCN)2 to form
HgCl2, HgCl42,
and SCN
, which gives a reddish orange color
(FeSCN2+) with ferric ion in nitric acid solution. One unit
of the enzyme was defined as the amount of enzyme which catalyzes the
dehalogenation of 1 µmol of L-2-chloropropionate/min.
Protein assay was done with a Bio-Rad protein assay kit.
Inactivation of L-DEX YL and DEX T15 by Hydroxylamine
For the experiment described in Tables I and 2 and MS analysis, reactions of l-DEX YL and L-DEX T15 with hydroxylamine were carried out with 1 ml of reaction mixtures containing 1 M Tris-H2SO4 buffer (pH 9.0), 10 µM enzyme, and 1 M hydroxylamine in the presence or absence of the indicated amount of substrates or monofluoroacetate (a substrate analog).
|
Kinetic Analysis of L-DEX YL Inactivation by Hydroxylamine
To study the relationship between hydroxylamine concentration and the inactivation rate of the enzyme, the reactions were carried out in 1.5 ml of solution containing 0.1 M Tris-H2SO4 buffer (pH 9.5), 9.4 µM L-DEX YL, 100 mM sodium monochloroacetate, and 0-0.5 M hydroxylamine at 30 °C. At intervals, 50 µl of the reaction mixture was taken off, and the residual enzyme activity was measured in 450 µl of assay mixture containing 0.1 M Tris-H2SO4 (pH 9.5) and 25 mM sodium monochloroacetate. After incubation at 30 °C for 10 min, the reaction was terminated by the addition of 50 µl of 3 M H2SO4, and the amount of chloride ions was measured by the method described above.
To examine the effect of substrate concentration on the rate of L-DEX YL inactivation, the reactions were carried out in dialysis bags each of which contained 5 ml of 0.1 M Tris-H2SO4 buffer (pH 9.5), 0.57 µM L-DEX YL, 0.5 M hydroxylamine, and 0-5 mM sodium monochloroacetate. The reactions were initiated by the addition of sodium monochloroacetate, and the dialysis bags were immediately put into 200 ml of 0.1 M Tris-H2SO4 buffer (pH 9.5) containing sodium monochloroacetate whose concentration was the same as that in the dialysis bag, in order to keep the substrate concentration constant during the reaction. The reactions were carried out at 30 °C. After 0, 1, 2, 3, and 4 min, 50 µl of the mixture was taken off from the dialysis bag, and the residual enzyme activity was measured in 450 µl of assay mixture containing 0.1 M Tris-H2SO4 buffer (pH 9.5) and 25 mM sodium monochloroacetate. Since the concentration of hydroxylamine carried into this assay mixture was sufficiently low, further inactivation of L-DEX YL in this assay mixture was negligible. After incubation at 30 °C for 10 min, the reaction was terminated by the addition of 50 µl of 3 M H2SO4, and the amount of chloride ions was measured by the method described above.
Amino Acid Sequencing
The amino acid sequences of the enzymes and peptides were determined with a fully automated protein sequencer PPSQ-10 (Shimadzu, Kyoto, Japan).
Determination of Molecular Mass of L-DEX YL Treated with Hydroxylamine
Molecular masses of the enzyme and its derivatives dissolved in 50% acetonitrile containing 0.05% formic acid were determined by introducing into a PE-Sciex API III mass spectrometer equipped with an ion spray ion source (Sciex, Thornhill, Ontario, Canada) at a flow rate of 2 µl/min. The quadrupole was scanned from 800 to 1,500 atomic mass units with a step size of 0.1 atomic mass units and a 1-ms dwell time/step. Ion spray voltage was set at 5 kV, and the orifice potential was 80 V. Data analysis was done with MacSpec software supplied by Sciex, and the theoretical molecular masses were calculated with MacBioSpec.
Proteolytic Cleavage of L-DEX YL and L-DEX T15
Digestion of Wild Type L-DEX YL with TrypsinOne ml of 1 M Tris-H2SO4 buffer (pH 9.0) containing 10 µM L-DEX YL, 1 M hydroxylamine, and 100 mM sodium L-2-chloropropionate was incubated at 45 °C for 30 min. The inactivated enzyme was dialyzed against 5,000 volumes of water, denatured with 3 M urea, and then digested with 5 µg of TPCK-treated trypsin in 0.2 M Tris-H2SO4 buffer (pH 8.0) for 12 h. L-DEX YL treated with hydroxylamine in the absence of the substrate was used as a control.
Digestion of L-DEX T15 with Lysyl EndopeptidaseTen nmol of L-DEX T15 inactivated by hydroxylamine in the presence of monochloroacetate under the same conditions as those for the wild type L-DEX YL was denatured with 8 M urea and subsequently digested with 80-100 pmol of lysyl endopeptidase at 37 °C for 12 h. L-DEX T15 treated with hydroxylamine in the absence of the substrate was used as a control.
LC/MS Analysis of the Proteolytic Digest
The proteolysate of the L-DEX YL inactivated in the presence of L-2-chloropropionate was loaded onto a packed capillary perfusion column (Poros II R/H, 320 µm × 10 cm, LC Packings, San Francisco, CA) connected to the mass spectrometer and then eluted with a linear gradient of 0-80% acetonitrile in 0.05% trifluoroacetic acid over 40 min at a flow rate of 10 µl/min. The total ion current chromatogram was recorded in the single quadrupole mode with a PE-Sciex API III mass spectrometer equipped with an ion spray ion source. The quadrupole was scanned from 300 to 2,000 atomic mass units with a step size of 0.25 atomic mass units and a 0.5-ms dwell time/step. Ion spray voltage was set at 5 kV, and the orifice potential was 80 V. The molecular mass of each peptide was calculated with MacSpec software, and the theoretical average molecular masses of the peptides were calculated with MacBioSpec software supplied by Sciex.
Mass Spectrometric Analysis of the Peptide Containing Asp10
For the analysis of the peptide containing Asp10, the proteolysates of L-DEX T15 incubated with hydroxylamine in the presence or absence of monochloroacetate were applied to a C18 column (Puresil 5-µm C18 120 Å, 4.6 × 150 mm; Millipore, Tokyo, Japan) and eluted with 0.05% trifluoroacetic acid for 5 min followed by a linear gradient of 0-80% acetonitrile in 0.05% trifluoroacetic acid over 60 min at a flow rate of 1.0 ml/min. The elution was monitored at 215 nm with a UV detector, and the fractions were collected and injected into a PE-Sciex API III mass spectrometer in the single quadrupole mode under the same conditions as described above.
Tandem MS/MS Analysis of the Peptide Containing Asp10
The MS/MS daughter ion spectra were obtained in the triple-quadrupole daughter scan mode by selectively introducing the peptides containing Asp10 (m/z 723.8, 708.7, or 650.5) from Q1 into the collision cell (Q2) and observing the daughter ions in Q3. Q1 was locked on m/z 723.8, 708.7, or 650.5. Q3 was scanned from 50 to just above the molecular mass of the peptide. A step size was 0.1, and the dwell time was 1 ms/step. Ion spray voltage was set at 5 kV, and the orifice potential was 100 V. Collision energy was 30 eV. The resolutions of Q1 and Q3 were approximately 500 and 1,500, respectively. The collision gas was argon, and the gas thickness was 2.9 × 1014 molecules/cm2.
We
found that treatment of L-DEX YL with hydroxylamine in the
presence of monochloroacetate or L-2-chloropropionate led
to an inactivation of the enzyme, whereas the treatment in the absence of the substrate or in the presence of monofluoroacetate, a substrate analog, caused no significant alteration in the enzyme activity (Table
I). Extensive dialysis of the inactivated enzyme did not result in its reactivation, suggesting a covalent modification of the
enzyme. The enzyme was inactivated as the chloride ions were released
(data not shown), and the inactivation followed pseudo-first-order
kinetics (Fig. 2A). Fig. 2B shows
that the rate of inactivation is proportional to the concentration of
hydroxylamine. The initial rates of the inactivation were plotted
against substrate concentrations, and the data were computer fitted to
the Michaelis-Menten equation as shown in Fig. 3. The
concentration of monochloroacetate causing a half-maximum rate of
inactivation was thus calculated to be about 1.7 mM, which
is close to the Km value for monochloroacetate in
the dehalogenation reaction (1.1 mM) (4). These kinetic
data show that this inactivation is due to a reaction of hydroxylamine
with an enzyme-substrate complex.
Molecular Mass and NH2-terminal Amino Acid Sequence of the Inactivated L-DEX YL
We determined by ion spray mass spectrometry molecular masses of L-DEX YL treated with hydroxylamine in the presence or absence of the substrate (Table II). The molecular mass of the native L-DEX YL was 25,863 Da, which indicates that the COOH terminus of this enzyme preparation lacks the last three amino acid residues (25,862.4 Da) (12). The molecular mass of the enzyme treated with hydroxylamine in the absence of the substrate was 25,863 Da, which is closely similar to the above value. In contrast, the molecular masses of the enzymes incubated with hydroxylamine in the presence of each of two kinds of the substrates, L-2-chloropropionate and monochloroacetate, were 25,952 and 25,937 Da, respectively, which are higher by 89 and 74 Da than that of the native protein. These indicate that L-DEX YL was modified by a molecule (or molecules) derived from the substrate (or plus hydroxylamine) to give molecular masses increased by 89 and 74 Da, respectively.
|
To examine if the active site Asp10 was modified at the step of inactivation by hydroxylamine, we carried out amino acid sequencing of the enzyme. The NH2-terminal amino acid sequencing showed that Asp10 of the enzyme was modified only in the presence of the substrate (Table II).
Molecular Masses of the Proteolytic Peptides Derived from L-DEX YL Modified by Hydroxylamine in the Presence of L-2-ChloropropionateThe enzyme modified with
hydroxylamine in the presence of L-2-chloropropionate was
digested with TPCK-treated trypsin, and the molecular masses of the
resulting peptide fragments were measured by LC/MS. When the
spectrometer was in the single quadrupole mode, the total ion current
chromatogram displayed several peaks (Fig. 4A). The molecular masses of the peptides for
peaks 1 (Fig. 4C) and 3 (Fig. 4B) were 15 and 87 Da higher, respectively, than that for the peptide in peak 2 (Fig.
4D). The value of molecular mass of the peak 2 peptide was
compatible with that of a peptide corresponding to residues 6-24
derived from the unmodified enzyme. The peptides for peaks 1 and 3 are
probably those corresponding to the same region but containing an amino
acid residue modified in the hydroxylamine reaction.
Molecular Masses of the Proteolytic Peptides Derived from L-DEX T15 Modified by Hydroxylamine in the Presence of Monochloroacetate
We have prepared a mutant enzyme, L-DEX T15, which has been shown to be very convenient for analysis of modification of the active site Asp10 because it is possible to obtain several peptides with appropriate sizes which cover the entire enzyme from the NH2 terminus to the COOH terminus after cleavage with lysyl endopeptidase (5). L-DEX T15 incubated with hydroxylamine in the presence or absence of monochloroacetate was digested with lysyl endopeptidase, and the resulting peptide fragments were separated by high performance LC. Amino acid sequencing of the isolated peptides showed that a modified amino acid occurs at the position corresponding to the active site Asp10 in the hexapeptide G-I-A-F-D-K; Asp10 was modified only in the presence of the substrate (data not shown).
The modified hexapeptide G-I-A-F-X-K (where X is
an unknown residue) was subsequently introduced into the ion spray mass
spectrometer for detailed analysis. Two major peaks, derived from
peptides with molecular masses of 708 and 723 Da, were found (Fig.
5). These values are 58 and 73 Da higher, respectively,
than that of the native hexapeptide (650 Da).
These peptide fragments were analyzed in more detail by tandem MS/MS
spectrometry. The parent ions of m/z 650.5, 708.7, and 723.8, corresponding to the native peptide and the two
modified peptides, were selected in the first quadrupole and subjected to collision-induced fragmentation in a collision cell in the second
quadrupole. The mass spectra of the daughter ions produced are shown in
Fig. 6. The peaks at m/z 553.6, 482.2, and 335.2 generated from the parent ion of
m/z 723.8 correspond to the y series
fragment ions of the peptides A-F-X-K, F-X
-K,
and X
-K, respectively (where X
is an
unidentified residue). They are about 73 Da higher than those of peaks
at m/z 480.2, 409.3, and 262.0 derived from the
native peptide corresponding to A-F-D-K, F-D-K, and D-K, respectively.
The peaks at m/z 538.5, 467.4, and 320.1 from the
parent ion of m/z 708.7 correspond to the
peptides A-F-X"-K, F-X"-K, and X"-K,
respectively (where X" is an unidentified residue). They are
about 58 Da higher than those of the corresponding peaks from the
native peptide. However, molecular masses of the remaining portions (K)
derived from these three peptides were essentially identical with each
other (147.3, 147.3, and 147.1). These show that the active site
Asp10 was specifically modified by molecules derived from
the substrate and hydroxylamine.
L-DEX YL is inactivated by hydroxylamine only in the presence of the substrate, whereas a substrate analog that is not subject to dehalogenation does not induce inactivation. The concentration of the substrate causing a half-maximum rate of inactivation is close to its Km value in the normal dehalogenation reaction, suggesting that the binding of the substrate to the active site of the enzyme is required for the inactivation by hydroxylamine. Moreover, mass spectrometric analysis of the inactivated enzyme showed that the active site Asp10 of the enzyme is modified with substrate- and hydroxylamine-derived moieties. These results indicate that hydroxylamine inactivates L-DEX YL paracatalytically; the intermediate derived from an enzyme-substrate complex is attacked by an extrinsic reagent.
The molecular mass of L-DEX YL inactivated by hydroxylamine
in the presence of monochloroacetate was shown to be about 74 Da higher
than that of the native L-DEX YL. The mass spectrometric analysis of the Asp10-containing peptides derived from the
inactivated L-DEX YL showed that there are two different
species whose molecular masses are 58 and 73 Da higher than that of the
unmodified peptide. Since we could not detect the modified
L-DEX YL whose molecular mass is about 58 Da higher than
that of the native L-DEX YL, the peptide species with 58-Da
higher mass number probably was formed by degradation of the other
peptide species showing 73-Da higher mass number in the course of
preparation of the peptide fragments. The increment of the molecular
mass of 73 Da, which is more reliable than that of 74 Da observed for
the whole modified protein, is postulated to be due to modification of
Asp10 leading to the formation of aspartate -hydroxamate
carboxymethyl ester as shown in Fig. 7. The species with
58 Da higher molecular mass would result from hydrolysis of
hydroxyimido moiety of the above modified aspartate generating
carboxymethylated Asp10.
With L-2-chloropropionate as substrate, the treatment of
L-DEX YL with hydroxylamine caused an 87-Da increment in
the molecular mass, and a species whose molecular mass is 15 Da higher
than that of the native protein was also produced during the
preparation of the peptide fragments. These increments in molecular
mass can also be explained based on the mechanism shown in Fig. 7. The increment of 87 Da may be due to the conversion of Asp10 to
the -hydroxyimido carboxyethyl ester. The 15 Da higher molecular mass species could be formed by hydrolysis, generating an aspartate
-hydroxamate residue.
Under the normal enzymatic reaction conditions, Asp10 of
the enzyme acts as a nucleophile to attack the -carbon of the
substrate leading to the formation of an ester intermediate, which is
to be hydrolyzed by nucleophilic attack of a water molecule (5). When
hydroxylamine is present, it attacks the carbonyl carbon of the
Asp10 ester intermediate as shown in Fig. 7. The
nonenzymatic reaction is thought to proceed through pathway 2 in Fig. 7
in preference to pathway 1, resulting in the formation of an aspartate
-hydroxamate residue. However, the mass spectrometric analysis of
the modified residue showed that pathway 1 is preferred to pathway 2 in
the case of L-DEX YL modification. The residues
facilitating the elimination of the hydroxyl group and suppressing the
elimination of the carboxyalkoxyl group are probably present in the
active site of the enzyme.
An alternative inactivation mechanism shown in Fig. 8
can also account for the 73- and 87-Da increments in the molecular mass of the enzyme inactivated in the presence of monochloroacetate and
L-2-chloropropionate, respectively. Since MS has only
identified the atoms incorporated into the inactivated enzyme and not
their chemical arrangement, further studies are necessary to determine the exact structure of the modified Asp10 residue.
Hydroxylamine has a much higher nucleophilicity than water and has been
used successfully as an acyl group acceptor to trap acylenzyme
intermediates of several enzymes, such as chymotrypsin (15),
D-alanine carboxypeptidase (16), aliphatic amidase (17), lipoprotein lipase (18), and -ketoacyl-acyl carrier protein synthetase (19). In the presence of hydroxylamine, these ester intermediates are cleaved by hydroxylamine. Since the acyl moieties of
the intermediates in these enzyme reactions are derived from the
substrates, the reaction with hydroxylamine leads to the formation of
hydroxamate analogs of the normal products. The formation of such
hydroxamate analogs is considered evidence for the formation of an
ester intermediate in the enzyme reaction. Unlike these enzymes, the
active site Asp10 of L-DEX YL was specifically
modified by hydroxylamine. This strongly indicates that an ester
intermediate, whose acyl moiety is derived from Asp10, is
produced during the reaction, which strongly supports the mechanism shown in Fig. 1.
The reactions catalyzed by haloalkane dehalogenase from X. autotrophicus GJ10 (6, 7), rat liver cytosolic epoxide hydrolase (8), and 4-chlorobenzoyl-CoA dehalogenases from Pseudomonas sp. strain CBS3 (9) and Arthrobacter sp. 4-CB1 (10) are proposed to proceed through the same mechanism that involves enzyme-substrate ester intermediates whose acyl moieties are derived from a carboxylate group of the enzyme. The observation that the enzyme from Arthrobacter sp. 4-CB1 is inactivated by hydroxylamine (10) suggests that hydroxylamine might be used to trap ester intermediates produced in these catalytic reactions and to label the active site residues of these enzymes.