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Previous Article | Next Article 
Applied and Environmental Microbiology, December 2001, p. 5735-5739, Vol. 67, No. 12
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.12.5735-5739.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Engineering Cytochrome P450 BM-3 for Oxidation
of Polycyclic Aromatic Hydrocarbons
Qing-Shan
Li,1
Jun
Ogawa,1
Rolf D.
Schmid,2 and
Sakayu
Shimizu1,*
Division of Applied Life Sciences, Graduate
School of Agriculture, Kyoto University, Kitashirakawa-oiwakecho,
Sakyo-ku, Kyoto 606-8502, Japan,1 and Institut
für Technische Biochemie, Universität Stuttgart,
D-70459 Stuttgart, Germany2
Received 25 June 2001/Accepted 24 September 2001
 |
ABSTRACT |
Cytochrome P450 BM-3, a self-sufficient P450 enzyme from
Bacillus megaterium that catalyzes the subterminal
hydroxylation of long-chain fatty acids, has been engineered into a
catalyst for the oxidation of polycyclic aromatic hydrocarbons. The
activities of a triplet mutant (A74G/F87V/L188Q) towards naphthalene,
fluorene, acenaphthene, acenaphthylene, and 9-methylanthracene were
160, 53, 109, 287, and 22/min, respectively. Compared with the
activities of the wild type towards these polycyclic aromatic
hydrocarbons, those of the mutant were improved by up to 4 orders of
magnitude. The coupling efficiencies of the mutant towards naphthalene,
fluorene, acenaphthene, acenaphthylene, and 9-methylanthracene were 11, 26, 5.4, 15, and 3.2%, respectively, which were also improved several
to hundreds fold. The high activities of the mutant towards polycyclic
aromatic hydrocarbons indicate the potential of engineering P450 BM-3
for the biodegradation of these compounds in the environment.
| |
INTRODUCTION |
Polycyclic aromatic hydrocarbons
(PAHs) are ubiquitously present in the environment and have harmful
effects on humans (3, 7). Recently, the potentials of P450
enzymes to transform PAHs have been evaluated to develop novel
strategies in environmental bioremediation (6, 8, 21).
Hydroxylation of PAHs by P450 enables the biodegradation of PAHs.
Hydroxylated PAHs are more water-soluble and are the substrates for
oxidases, such as peroxidase and laccase, that decompose phenolic
compounds. The oxidation of PAHs by mammalian P450 enzymes has been
extensively investigated (21, 22), but because of the low
stability and activity of these P450s they are less promising from the
perspective of the biodegradation of PAHs in the environment. Bacterial
P450s are relatively stable and highly active and can often be prepared in large amounts using recombinant expression systems. Protein engineering of bacterial P450s with activities toward PAHs could be an
alternative method for this purpose (15, 16, 18).
P450cam has been engineered for the degradation of PAHs with the
highest turnover, 3.0 and 4.5/min, for phenanthrene and fluoranthene, respectively (6). Cytochrome P450 BM-3 from Bacillus
megaterium is another one of the best-studied bacterial P450s
whose crystal structure is available (1, 4, 9, 10, 17,
20). P450 BM-3 can be largely prepared by recombinant expression
in Escherichia coli (11-13) and is a stable,
highly active, and self-sufficient P450 consisting of a catalytic heme
domain and a diflavin reductase domain in a single polypeptide of 119 kDa (17, 20). These properties are closer to application
requirements than those of other P450s. However, this P450 has a
well-defined substrate specificity and catalyzes the hydroxylation of
long-chain fatty acids and the epoxidation of the double bonds of
long-chain unsaturated fatty acids (1, 4, 10, 17, 20).
Protein engineering of P450 BM-3 to obtain activities towards
substrates other than long-chain fatty acids, such as short-chain fatty
acids or indole, was reported recently (11, 19). Just before we submitted this manuscript, Carmichael and Wong
(2) reported the oxidation of pyrene, phenanthrene, and
fluoranthene by mutants of P450 BM-3. However, we obtained another
mutant showing higher activities for the oxidation of other PAHs
such as naphthalene, fluorene, acenaphthene, acenaphthylene, and
9-methylanthracene. The triplet mutant (A74G/F87V/L188Q) obtained by us
does not share any mutation with the mutants reported by Carmichael and
Wong except that one of the mutated positions (Phe87) is shared with some of their mutants (2). A74 and L188 in our mutation
essentially constitute the entrance of the substrate access channel and
have hydrophobic interactions with substrates (9), while
R47 and Y51 in the mutation of Carmichael and Wong act as anchors for the carboxylate group of the substrate (2). Here, we
report our results.
| |
MATERIALS AND METHODS |
Chemicals.
1,2-Dihydroxyacenaphthene was prepared by
reduction of acenaphthenequinone with sodium hydrosulfite. Other
chemicals were of analytical grade and are commercially available.
Randomization of specific codons of P450 BM-3.
Three sites
(Phe87, Leu188, and Ala74) were randomized by site-directed mutagenesis
using a Stratagene QuikChange kit (La Jolla, Calif.) as described
previously (11, 13). The following PCR primers were
employed for the respective sites: for Phe87, 5'-GCAGGAGACGGGTTGNNNACAAGCTGGACG-3' and
5'-CGTCCAGCTTGTNNNCAACCCGTCTCCTGC-3'; for Leu188,
5'-GAAGCAATGAACAAGNNNCAGCGAGCAAATCCAG-3' and
5'-CTGGATTTGCTCGCTGNNNCTTGTTCATTGCTTC-3'; and for Ala74,
5'-GCTTTGATAAAAACTTAAGTCAANNNCTTAAATTTGTACG-3' and
5'-CGTACAAATTTAAGNNNTTGACTTAAGTTTTTATCAAAGC-3'.
Expression and purification of WT and mutant P450 BM-3.
The
wild-type (WT) and mutant P450 BM-3 genes were expressed under the
control of the strong, temperature-inducible
PRPL-promoter of pCYTEXP1
in E. coli strain UM2, a catalase-deficient strain (14), as described previously (12). Cell
disruption, purification, and determination of the concentration of the
purified enzyme were carried out as described elsewhere
(13).
Isolation of mutants.
Some mutants of P450 BM-3 produced
pigments in the culture broth after induction of the expression of
their genes in E. coli UM2. Structural analysis of the major
pigment indicated that it might have a polycyclic aromatic structure.
Thus, we used the pigments as indicators to screen mutants with higher
activities towards PAHs. From the mutant created by randomized
mutagenesis of the codon of the respective site, 100 colonies were
isolated to ensure that most of the 19 possible kinds of amino acids
were tested. Under these conditions, the probability of obtaining each amino acid is greater than 95%, except for tryptophan and methionine, for which the probability is 79% (12). The selected
colonies were cultured in tubes containing 1 ml of Luria-Bertani medium at 30°C for 3 h, and then the temperature was shifted to 42°C for 10 h to induce the expression of P450 BM-3 mutant genes and to
allow the production of pigments. After cells had been separated by
centrifugation, the absorbance of the supernatants containing pigments
was measured at 545 nm. The mutant that produced the largest amount of
pigments among all the mutants at the same site was used as a template
for the next site-specific randomized mutagenesis. All mutations
described in this report have been confirmed by DNA sequencing.
Enzyme activity assay.
To measure the NADPH consumption
rate, 60 µl of a 2.5 µM P450 sample was mixed with 480 µl of 0.1 M Tris-HCl buffer (pH 7.4) containing 6 µl of substrate dimethyl
sulfoxide (DMSO) stock solution. The concentrations of the substrate
stock solutions were 200, 20, 30, 50, and 15 mM for naphthalene,
fluorene, acenaphthene, acenaphthylene, and 9-methylanthracene,
respectively. After 2 min of standing, 60 µl of 3.5 mM NADPH was
added to start the reaction. NADPH consumption was monitored at 340 nm
with a Shimadzu MultiSpec-1500 spectrophotometer (Kyoto, Japan) at
25°C for 20 s (or 150 s for WT, because of its low
activity). The NADPH concentration was calculated using
M = 6,200 M
1
cm1 (23).
To measure the coupling efficiency (the ratio [percentage] of NADPH
used for substrate oxidation to the total amount of NADPH consumed by
P450), 100 µl of a 45 µM P450 sample was mixed with 4,800 µl of
0.1 M Tris-HCl buffer (pH 7.4) containing 50 µl of substrate stock
solution and 80 U of catalase (9,200 U/mg; Wako Pure Chemical
Industries). After 2 min of standing, 100 µl of 20.0 mM NADPH was
added, followed by standing for 2 h at 25°C to allow all the
NADPH to be consumed. Before extraction, an internal standard of
1-naphthalenol, at a final concentration of 15 µM, was added to a
reaction mixture containing a substrate other than naphthalene. For the
reaction with naphthalene, 1-fluorenol was used as the internal
standard at a final concentration of 15 µM. Reaction mixtures were
extracted with 3 ml of chloroform twice and then the extracts were
evaporated to around 100 µl for gas-liquid chromatography (GC)
analysis. The coupling efficiencies of PAHs were calculated from the
amounts of products determined by GC, GC-mass spectrometry (MS), or
high-performance liquid chromatography (HPLC). The hydroxylation
activity was calculated by multiplying the NADPH consumption rate by
the coupling efficiency.
GC and GC-MS analysis.
GC analysis was performed with a
Shimadzu GC-17A gas chromatograph equipped with a flame ionization
detector and a split injection system and fitted with a capillary
column (DB-17, 30 m by 0.554 mm internal diameter; J & W
Scientific, Folsom, Calif.). The column temperature was initially
100°C, and then it was raised to 280°C at the rate of 5°C/min and
maintained at that temperature for 20 min. The injector and detector
were operated at 280°C. Helium was used as the carrier gas at 30 kPa/cm2. GC-MS analysis was performed on a GC-MS
QP5050 (Shimadzu) with a GC-17A gas chromatograph equipped with a
capillary column (HR-1; 25 m by 0.25 mm internal diameter; Shinwa
Kako, Kyoto, Japan) at 150°C. Helium was used as the carrier gas at
225 kPa/cm2. MS was performed in the electron
impact mode at 70 eV with a source temperature of 250°C. Split
injection was employed with the injection port at 250°C.
HPLC analysis.
HPLC analysis was performed to determine the
amounts of 1-naphthol and 2-naphthol. The naphthalene reaction samples
were extracted twice with chloroform, 6 ml in total, evaporated to
dryness, and then dissolved in 5% DMSO for HPLC analysis. HPLC
analysis was carried out on a C18 reverse-phase
column (Cosmosil 5C AR-II; 4.6 mm internal diameter by 250 mm; Nacalai
Tesque, Kyoto, Japan) and eluted at 1.0 ml/min with a methanol-water
gradient containing 1% acetic acid. The methanol gradient was as
follows: 0 to 4 min, 0% (vol/vol); 4 to 10 min, 0 to 28%; 10 to 50 min, 28 to 80%; 50 to 60 min, 80%. The absorbance of the
eluent was monitored at 275 nm.
Determination of binding spectra.
The substrate-induced
spectral shifts of P450 BM-3 enzymes were recorded with a Shimadzu
MultiSpec-1500 spectrophotometer at 30°C. Naphthalene, fluorene,
acenaphthene, and acenaphthylene dissolved in DMSO at concentrations of
300, 3, 15, and 15 mM, respectively, were freshly prepared for
analysis. For each substrate, the substrate solution was added in small
amounts to the enzyme solution containing 3.8 µM P450 in 0.1 M
Tris-HCl (pH 7.4) in a cuvette, and the same amount of DMSO was added
to the reference cuvette containing the enzyme solution. For each
substrate for any enzyme, triplicate binding assays with 18 substrate
concentrations were performed. The change in absorbance (A)
was determined by subtracting A425
(trough) from the A390 (peak). The
maximum heme spin-state shift of WT binding to palmitic acid was taken
as a 100% heme spin-state shift. Data analysis and calculations were carried out according to methods described elsewhere (23).
| |
RESULTS |
Isolation of P450 BM-3 mutants for PAH oxidations.
Mutants of
P450 BM-3 for PAH oxidations were obtained by increasing the
productivity of pigments with polycyclic aromatic structure in the
culture broth through three steps of site-specific randomized
mutagenesis. Phe87 was selected as the first site for mutation because
several mutants which have a substitution at this site with Val, Ala,
or Gly were initially found to produce the pigments. Leu188 and Ala74
were selected as the second and third sites for mutation according to
the results of previous work on the hydroxylation of indole and
shorter-chain fatty acids (11, 12). After the first
mutation, 14 colonies produced pigments after induction and the 1 producing the highest amount of pigments was selected for DNA
sequencing, which revealed the substitution of Phe87 by Val (F87V). The
F87V mutant was used as the template DNA for the second round of
site-specific randomized mutagenesis at Leu188. Seventy-two colonies
produced pigments during the cultivation and the one exhibiting the
highest activity was found to contain a new substitution of Leu188 by
Gln besides Phe87Val (F87V/L188Q). The
A545 due to the pigment production of
the culture of this double mutant was 2.3 times higher than that of
F87V. This double mutant DNA was used as the template for the third
round of site-specific randomized mutagenesis at Ala74. Seventy-seven
colonies produced pigments and the one producing the highest amount of
pigments was found to be a triple mutant containing a new substitution of Ala74 by Gly besides the Phe87Val and Leu188Gln mutations
(A74G/F87V/L188Q). The A545 of the
culture of this triplet mutant was 1.2 times higher than that of
F87V/L188Q.
PAH oxidation activity.
The WT showed quite low NADPH
consumption rates and coupling efficiencies for all of the PAHs (Tables
1 and 2). The first substitution of Phe87Val improved the NADPH consumption rates from
several- to nearly 50-fold (Table 1) and the coupling efficiencies towards these PAHs several- to 200-fold (Table 2). In total, the first
substitution improved the enzyme activities towards these PAHs by 2 to
3 orders of magnitude (Table 3). The
second substitution of Leu188Gln also significantly improved the enzyme activities towards all the three-ring PAHs by several- to more than
30-fold. The third substitution of Ala74Gly again greatly enhanced the
enzyme activities towards all the PAHs, mainly by increasing the NADPH
consumption rates. At last, the activities of the triplet mutant
towards all these PAHs were 2 to 4 orders of magnitude higher than
those of the WT.
Analysis of products from PAHs.
The products derived from PAHs
by the WT and all mutants of P450 BM-3 are summarized in Fig.
1. The WT and all mutants catalyzed the
oxidation of naphthalene to a mixture of 96% 1-naphthol (retention time [RT], 36.2 min) and 4% 2-naphthol (RT, 34.8 min), as confirmed by coelution with authentic samples on HPLC. In our experiments, to
correctly evaluate the reaction selectivity, the further oxidation of
1-naphthol or 2-naphthol was limited to a negligible level by using
NADPH at a low concentration (0.4 mM).
The oxidation of fluorene and 9-methylanthracene by all enzymes
produced only one product for each substrate, 9-fluorenol (RT, 33.5 min) and 9-anthracenemethanol (RT, 48.4 min), respectively, as
confirmed by coelution with authentic samples on GC and by the results
of GC-MS. There was no evidence of other products or further oxidation
of the products to other compounds.
The oxidation of acenaphthene by all mutants produced one product (RT,
30.4 min) which was identified as 1-acenaphthenol by coelution with an
authentic sample on GC and by the results of GC-MS. When a high
concentration of NADPH (4 mM) was used, a further oxidized compound was
detected which was identified as 1,2-dihydroxyacenaphthene (RT, 34.7 min) by coelution with a chemically synthesized sample on GC and by the
results of GC-MS.
The oxidation of acenaphthylene by all mutants produced one peak on GC
(RT, 30.6 min), but the peak was separated into a major peak (RT, 1.7 min) and a minor one (RT, 1.6 min) on GC-MS. The major one was
1-acenaphthylenol and the minor one was 1,2-acenaphthylene oxide, as
suggested by the results of GC-MS analysis. GC-MS data, EI-MZ
m/z (M+-x intensity [percentage]),
for the major product (1-acenaphthylenol) were as follows:
168(M+, 85), 140(M+
28,
100), 139(M+29, 90),
113(M+55, 12), 89(M+79,
13), 84(M+84, 16),
70(M+98, 69), 63(M+105,
29), 50(M+118, 6). Values for the minor product
(1,2-acenaphthylene oxide) were 168(M+, 78),
152(M+16, 46),
140(M+28, 83),
139(M+29, 90),
113(M+55, 11), 89(M+79,
11), 84(M+84, 22),
69(M+99, 56),
63(M+105, 33),
50(M+118, 10). The peak area of the minor
product was 3.1% of that of the total products. When a high
concentration of NADPH (2 mM) was used, two further oxidized
products were detected which were identified as
1,2-dihydroxyacenaphthene (RT, 34.7 min) and acenaphthenequinone (RT,
36.7 min) by coelution with a chemically synthesized sample and the
authentic compound, respectively, on GC and by the results of GC-MS.
Analysis of substrate binding.
Only the mutations described
here did not cause a heme spin-state shift, i.e., the hemes in these
mutant enzymes without substrate binding are all in a low spin-state.
Substrate binding to P450 usually triggers a heme spin-state shift from
low to high, and it can be monitored as the changes of P450 absorbance
spectra. The heme spin-state shift and dissociation constant assay
results are given in Table 4. The binding
of 9-methylanthracene was not examined because of its strong absorbance
in the spectral range of analysis. The first substitution of Phe87Val
significantly improved the heme spin-state shift for all four PAHs but
had nearly no effect on the dissociation constant for all four
substrates. The further two substitutions had no significant effect on
either the heme spin-state shift or the dissociation constant for all four substrates.
| |
DISCUSSION |
Phe87 plays a critical role in the control of PAH binding to P450
BM-3. The aromatic ring of Phe87 extends into the heme pocket and is
positioned above the porphyrin plane (9), which may prevent PAH binding close to the active site. Replacement of Phe87 with
Val does not significantly affect the affinity of P450 BM-3 for these
PAHs, but it largely increases the PAH-induced heme spin-state shift
(Table 4) and coupling efficiencies of NADPH utilization (Table 2).
These results suggest that the PAHs bind close to the heme with better
positioning in the active site with respect to the activated oxygen
intermediate that is generated during the catalytic cycle.
The PAH oxidation rates of the triplet mutant were 3 to 4 orders of
magnitude faster than those of the WT. Compared with the activities of
most mammalian P450s with turnover numbers of around 1.0/min
(5), the activities of the triplet mutant towards these substrates are quite high. Coupling efficiency is an important factor
for determining the substrate oxidation rate. The highest couplings
obtained on engineering of P450cam towards phenanthrene and
fluoranthene were only 1.3 and 3.1%, respectively (6). The coupling efficiencies of the triplet mutant towards these three-ring PAHs were improved 1 to 2 orders of magnitude from that of
the WT, and the values themselves are also significantly high (Table
2).
The activities of P450 BM-3 towards pyrene, phenanthrene, and
fluoranthene were also increased by the combination of the three mutations (R47L/Y51F/A264G) (2). However, there is no
common mutation between this mutant and our triplet mutant
(F87V/L188G/A74G). Therefore, it should be possible, perhaps with the
help of X-ray structure analysis data, to further increase the activity
towards PAHs by combining additional mutation(s). Such work and further study on application of the P450 BM-3 mutant for the biodegradation of
PAHs by whole cells coexpressing an NADPH regeneration enzyme are in progress.
| |
ACKNOWLEDGMENTS |
We thank T. Sakaki, Division of Food Science and Biotechnology,
Graduate School of Agriculture, Kyoto University, for useful discussions.
Q.-S. Li is a postdoctoral fellow supported by the Japan Society for
Promotion of Science (JSPS). This work was supported in part by a
grant-in-aid of JSPS for foreign researchers (no. P99115 to Q.S.L.) and
by a grant from the Research for the Future Program (JSPS-RFTF 97I00302
to S.S.).
| |
FOOTNOTES |
*
Corresponding author: Division of Applied Life
Sciences, Graduate School of Agriculture, Kyoto University,
Kitashirakawa-oiwakecho, Sakyo-ku, Kyoto 606-8502, Japan. Phone:
81-75-753-6115. Fax: 81-75-753-6128. E-mail:
sim{at}kais.kyoto-u.ac.jp.
| |
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Applied and Environmental Microbiology, December 2001, p. 5735-5739, Vol. 67, No. 12
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.12.5735-5739.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Trefzer, A., Jungmann, V., Molnar, I., Botejue, A., Buckel, D., Frey, G., Hill, D. S., Jorg, M., Ligon, J. M., Mason, D., Moore, D., Pachlatko, J. P., Richardson, T. H., Spangenberg, P., Wall, M. A., Zirkle, R., Stege, J. T.
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Abstract
Introduction
