Department of Botany and Plant Pathology, Oregon State University, Corvallis, OR 97331, USA1
Author for correspondence: Daniel J. Arp. Tel: +1 541 737 1294. Fax: +1 541 737 5310. e-mail: arpd{at}bcc.orst.edu
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ABSTRACT |
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Keywords: butane metabolism, alkane oxidation, diiron monooxygenase
Abbreviations: BMOB, butane monooxygenase regulatory protein; BMOD, bmoD gene product; BMOH, butane monooxygenase hydroxylase; BMOR, butane monooxygenase reductase; MMOB, methane monooxygenase regulatory protein; MMOD, mmoD (orfY) gene product; MMOH, methane monooxygenase hydroxylase; MMOR, methane monooxygenase reductase; pMMO, particulate methane monooxygenase; sBMO, soluble butane monooxygenase; sMMO, soluble methane monooxygenase
a The GenBank accession number for the bmoXYBZDC sequence is AY093933.
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INTRODUCTION |
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Non-specific bacterial oxygenases used for bacterial growth with aliphatic or aromatic compounds employ an array of prosthetic groups including flavin, haem, copper, binuclear iron centres and mononuclear iron centres (Arp et al., 2001 ). Propane-oxidizing bacteria which utilize terminal and subterminal oxidation pathways have been identified (Ashraf et al., 1994
; Stephens & Dalton, 1986
), but the propane monooxygenases have not been further characterized. Bacteria capable of metabolizing liquid alkanes do so by a terminal oxidation pathway and utilize three-component systems containing an integral membrane alkane hydroxylase, rubredoxin and rubredoxin reductase. Examples include the alkane hydroxylases from Pseudomonas oleovorans (McKenna & Coon, 1970
) and Acinetobacter ADP1 (Ratajczak et al., 1998
), xylene monooxygenase (Suzuki et al., 1991
) and membrane desaturases, which belong to a distinct category within the diiron monooxygenase family (Shanklin et al., 1994
). Methane-oxidizing bacteria possess a particulate methane monooxygenase (pMMO), which may contain copper at the active site (Zahn & DiSpirito, 1996
). Under conditions of copper starvation, some methanotrophs can use a soluble diiron methane monooxygenase (sMMO) with different protein composition and iron coordination than alkane hydroxylases (Stanley et al., 1983
). The sMMO enzymes are three-component systems consisting of a soluble hydroxylase, an NADH-oxidoreductase and a small regulatory protein (Colby & Dalton, 1978
; Fox et al., 1989
). The soluble methane monooxygenase hydroxylase from methanotrophic bacteria is a prototypical non-haem carboxylate-bridged diiron monooxygenase that has been characterized extensively (Lipscomb, 1994
; Wallar & Lipscomb, 1996
). The presence of a µ-hydroxo-bridged iron centre was determined by X-ray crystallography and spectroscopy (Dewitt et al., 1991
; Elango et al., 1997
; Rosenzweig et al., 1993
). The substrate range of sMMO includes C1C7 alkanes, alkenes and some aromatic compounds (Green & Dalton, 1989
). Soluble toluene monooxygenases have also been described, including four-component diiron monooxygenases (Pikus et al., 1996
), three-component diiron monooxygenases (Newman & Wackett, 1995
) and three-component mononuclear iron dioxygenases (Subramanian et al., 1979
, 1981
, 1985
).
The diversity among bacterial enzymes that degrade aliphatic and aromatic compounds is also found among those that initiate butane metabolism (Hamamura et al., 1999 ). Nocardioides sp. strain CF8 utilizes a copper-containing enzyme reminiscent of pMMO and ammonia monooxygenase, while P. butanovora utilizes an uncharacterized monooxygenase that does not require copper (Hamamura et al., 1999
). Biochemical and genetic information about enzymes that catalyse the oxidation of short-chain, gaseous alkanes is largely absent. Recently, a gene encoding a 54 kDa polypeptide was shown to be involved in butane oxidation in Pseudomonas sp. IMT37. The sequence was not similar either to alkane hydroxylases (liquid alkanes) or to methane monooxygenase, and furthermore did not have significant similarity to any entries in the protein sequence databases (Padda et al., 2001
). This work describes the butane monooxygenase genes from P. butanovora and confirms that the cluster is involved in butane metabolism and is similar to mmo gene clusters.
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METHODS |
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Cell culture and preparation of cell extracts.
Pseudomonas butanovora was cultured at 30 °C in sealed serum bottles as previously described (Hamamura et al., 1997 ) except that yeast extract and CO2 were omitted. The carbon source supplied for growth was either 7% (v/v) butane added as an overpressure, 10 mM sodium lactate or 10 mM sodium citrate. Cells were typically harvested between 0·5 and 0·7 OD600. P. butanovora was also cultured in a sealed 17 litre fermenter sparged with 7% butane (v/v) and periodic replenishments of O2 to 20% (v/v). An average of 2 g of cells (wet weight) per litre of culture was obtained. Cells were harvested by centrifugation (10 min at 5000 g; 10 °C), washed by resuspension with 30 mM potassium phosphate (pH 7·2), pelleted and stored as a paste at -70 °C. Frozen cells were thawed in 3 vols lysis buffer per mg cell paste. The lysis buffer consisted of buffer A [25 mM MOPS (pH 7·2), 5% (v/v) glycerol, 1 mM DTT], plus 200 µM Fe(NH4)2(SO4)2, 2 mM cysteine, 0·1 mg deoxyribonuclease I ml-1 (Sigma) and 0·2 mg lysozyme ml-1. After three freezethaw cycles, the lysate was subjected to sonication with a microtip (Ultrasonics) for four cycles of 30 s pulses. The cell extract was clarified by ultracentrifugation (105000 g for 1 h).
Assay conditions.
Whole-cell assays were performed in 10 ml sealed serum vials using ethylene, an alternative substrate for butane monooxygenase (Sayavedra-Soto et al., 2001 ). Cells (0·5 mg protein) were incubated at 30 °C in 1 ml buffer [30 mM potassium phosphate (pH 7·2), 2 mM sodium butyrate] and with 20% (v/v) ethylene in the head-space. Formation of ethylene oxide was detected by gas chromatography as described by Hamamura et al. (1999)
. In vitro assays contained 25 mM MOPS (pH 7·2), 2 mM NADH, 20% (v/v) ethylene, and 0·12·0 mg cell extract or column fractions. Acetylene, a mechanism-based inactivator of butane monooxygenase (Hamamura et al., 1999
), was used to inactivate the substrate-binding component of butane monooxygenase. Cell suspensions were incubated as above, but with acetylene [1% (v/v)] replacing ethylene. After incubation for 30 min at 30 °C with shaking, the cells were washed, lysed, and the resulting cell extract was clarified by ultracentrifugation as above. This acetylene-inactivated extract (6·5 mg protein) was used as a source of acetylene-insensitive soluble butane monooxygenase (sBMO) components in the activity assays where indicated.
Separation of the butane monooxygenase components.
The soluble portion of the cell extract was applied to a 1·6 x 18 cm Q-Sepharose FF column equilibrated with buffer A (see above). The column was washed with 70 ml buffer A and developed with a 350 ml linear gradient from 0 to 550 mM NaCl in buffer A. The first component, proposed to be the regulatory protein, eluted between 250 and 300 mM NaCl. Individual fractions that were able to reconstitute butane monooxygenase activity by complementing the hydroxylase and reductase components were pooled. The second component, proposed to be the hydroxylase component, eluted between 320 and 360 mM NaCl and the third component, proposed to be the reductase component, eluted between 400 and 450 mM NaCl. Likewise, the individual fractions which complemented the other two protein components to reconstitute butane monooxygenase activity were pooled and concentrated by ultrafiltration (Millipore; YM100 for the hydroxylase component, YM10 for the reductase component).
Protein characterizations.
SDS-PAGE (10% total gel, 2·6% cross-linker running gel) was performed following the Laemmli procedure (Laemmli, 1970 ) and the proteins were stained with Coomassie blue. The apparent molecular masses of polypeptides were determined by comparison with Rf values of standard proteins. The partially purified components associated with butane monooxygenase activity were resolved by SDS-PAGE and electroblotted onto PVDF membranes (Immobilon-P; Millipore). The N-terminal amino acid sequences of the polypeptides were determined by Edman degradation at the Institute of Molecular Biology Biotechnology Laboratory, University of Oregon. Protein concentrations were determined by the biuret assay (Gornall et al., 1949
). Whole cells were first solubilized with 3 M NaOH for 30 min at 65 °C. Bovine serum albumin was used as the standard.
Plasmids, bacterial strains and nucleic acid manipulations.
Table 1 summarizes the plasmids and strains used in this study. DNA manipulations were performed using standard protocols (Sambrook et al., 1989
). Degenerate primers for PCR DNA amplification were designed from the N-terminal amino acid sequences of the butane monooxygenase polypeptides with the consensus-degenerate hybrid oligonucleotide primer strategy (CODEHOP; Rose et al., 1998
). The forward primer sequence was 5'-ATCTTCACCCGCGGCATGGTNGAYCCNGA-3' and the reverse primer sequence was 5'-GGCGACGATCTTGTACTGYTGCATNARCAT-3'. DNA was amplified by PCR using Taq DNA polymerase (Fermentas) following the directions of the manufacturer. The amplified DNA product was cloned into pGEM-T Easy (Promega) using Escherichia coli strain JM109 as host and used to screen the genomic library. The genomic library of P. butanovora was constructed in
-Gem11 (Promega) with E. coli strain LE392 as host (Sambrook et al., 1989
). To sequence the portions of the bmo genes not represented by the library clone, genomic DNA was digested with either EcoRI or BamHI, religated, and used as a template for inverse PCR (Sambrook et al., 1989
). These inverse PCR amplification products were cloned, sequenced, and used to design primers for high-fidelity amplification with Pfu DNA polymerase (Stratagene). Pfu PCR products were amplified from P. butanovora genomic DNA and sequenced directly to minimize errors due to DNA polymerase misincorporation. Discrepancies were resolved by sequencing multiple PCR products. Oligonucleotide primers were synthesized by Invitrogen. DNA sequencing was performed at the Center for Gene Research and Biotechnology Central Services Laboratory, Oregon State University. Sequence data were analysed using software from the GCG Wisconsin Package Version 10.0 (Acelerys). Sequence comparisons were made using the National Center for Biotechnology Information web site and BLAST (Basic Local Alignment Search Tool) (Altschul et al., 1997
). Accession numbers of the sequences are listed in Table 2
.
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Generation of mutant strains.
To generate a plasmid containing the complete sequence of bmoX for genetic manipulation, a Pfu (Stratagene) DNA polymerase PCR product was amplified from genomic DNA using the following primers: 5'-TGCTGATCTAGAACGAGATCGC-3' and 5'-TCCAGGTCTAGATCAGATCAGAAAG-3'. To simplify cloning into pBluescript II SK(-), an XbaI restriction site was engineered into the PCR primers. The underlined nucleotides are altered from the actual bmo sequence. A 3410 bp XbaI restriction digest fragment of the product was cloned into the XbaI site of pBluescript II SK(-), resulting in the formation of plasmid pPbu281. To remove a BamHI site in the vector, pPbu2 was constructed. For the inactivation of bmoX, the 4730 bp lacZ::kanr cassette from pKOK6 (Kokotek & Lotz, 1989 ) was inserted into the BamHI site of pPbu2 to obtain plasmid pPbu41 with the cassette in the orientation shown in Fig. 4. The site of insertion was at position 259 of the reported bmo sequence, which is located 60 nucleotides downstream of the ATG start codon of bmoX (see Fig. 4). The constructs were confirmed by DNA sequencing. The kanamycin-resistance constructs were introduced into P. butanovora by electroporation as described by Vangnai et al. (2002)
. Briefly, early stationary-phase P. butanovora cells (120 µl) in water were mixed with 1 µl plasmid DNA (0·5 µg) in a chilled electroporation cuvette (Invitrogen). Electroporation conditions were as follows: 1300 V, 71 µF and 200
. After pulsing, the cells were first recovered in basal medium with citrate for 3 h at 30 °C and then challenged with 50 µg kanamycin sulfate ml-1. After two days in liquid culture, the cells were selected on citrate-kanamycin plates.
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RESULTS |
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Acetylene, a mechanism-based inactivator of butane monooxygenase, was used to target the component that contains the active site of substrate oxidation (Hamamura et al., 1999 ). Acetylene-inactivated extracts (see Methods) retained 15% of the activity measured in untreated extracts. Only one of the protein components was able to restore ethylene oxidation activity to acetylene-inactivated extracts. Presumably, all necessary protein components except the active-site-containing component were not significantly affected by acetylene. The acetylene-sensitive component was enriched in three polypeptides with molecular masses of 54, 43 and 25 kDa, which are referred to as the
, ß and
subunits, respectively (Fig. 1
). By analogy with the hydroxylase components from multicomponent monooxygenases, this protein is referred to as the butane monooxygenase hydroxylase component (BMOH). The specific activity of BMOH for ethylene oxidation, as determined by restoration of activity to acetylene-inactivated extract, was 42 nmol (min mg hydroxylase protein)-1. A second component exhibited a high rate of NADH:potassium ferricyanide oxidoreductase activity. This protein, referred to as the reductase (BMOR), was enriched in a 45 kDa polypeptide. A third component (BMOB) was required for ethylene oxide activity in combination with the hydroxylase and the reductase, but did not exhibit any redox properties, nor was it able to restore activity to acetylene-inactivated extracts. This component was heat labile, but it was not noticeably enriched in any particular peptides. Further purification and characterization is required to confirm our supposition that this component contains the small-molecular-mass regulatory protein found in sMMOs (Fox et al., 1989
; Green & Dalton, 1985
), alkene monooxygenases (Miura & Dalton, 1995
; Small & Ensign, 1997
), and several aromatic monooxygenases (Newman & Wackett, 1995
; Powlowski & Shingler, 1990
).
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Sequence analysis of the genes encoding sBMO
A 3010 bp PCR product was amplified from genomic DNA using degenerate oligonucleotide primers designed from the N-terminal sequences of the BMOH ß subunit and the BMOR polypeptide (see Methods). The nucleotide sequence of this PCR product revealed a high degree of similarity to sMMOs (Cardy et al., 1991 ; Stainthorpe et al., 1990
). The product was cloned and the insert was used to screen the P. butanovora genomic library (probe 1, Fig. 2
). A 2993 bp portion of the bmo genes was sequenced from a genomic library clone,
Pbu17 (Table 1
), while the remaining upstream and downstream portions not present in the library clone were sequenced directly from high-fidelity PCR products amplified from genomic DNA. The sequence data of the assembled 6343 bp contig covers each strand with a minimum of threefold redundancy. The bmo structural genes (5797 bp) are ordered as shown in Fig. 2
. The deduced amino acid sequences of the bmoY, Z and C genes (MSTNIFTRGMVDPE, MSKQVWYNTPV and MLMQQYKIVARFEDG, respectively) agreed with the N-terminal sequences obtained from the partially purified BMOH-ß, BMOH-
and BMOR peptides. Furthermore, the theoretical molecular masses (mentioned below) are comparable to the relative molecular masses determined by SDS-PAGE. ShineDalgarno-like ribosome-binding sites were found upstream of the bmo start sites by the following distances: 5 bases upstream of bmoX (GGAGG), 9 bases upstream of bmoY (GGAG), 9 bases upstream of bmoZ (GGAGG), 7 bases upstream of bmoD (GAGG) and 11 bases upstream of bmoC (GGAG). No clear ribosome-binding sequence was recognized upstream of bmoB.
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The soluble BMOH component contains three subunits (, ß and
) encoded by bmoX, bmoY and bmoZ, with theoretical molecular masses of 60·8, 45·0, 19·4 kDa, respectively. By analogy with other hydroxylase components, BMOH is likely to have an
2ß2
2 quaternary structure. The highest identity between sBMO and sMMO was found in the
subunits of BMOH and methane monooxygenase hydroxylase (MMOH) (6364%). The
subunit contains the diiron active site of sMMO, where reduction of the metal centre, binding and subsequent cleavage of molecular oxygen, and substrate binding and hydroxylation all take place (Merkx et al., 2001
; Coufal et al., 2000
; Whittington & Lippard, 2001
). By analogy with sMMO, the sBMO residues probably involved in coordinating the two irons are E111, E141, H144, E206, E240 and H243 (Fig. 3a
). The residues involved in the H-bonding network of MMOH are conserved in BMOH (Coufal et al., 2000
; Whittington & Lippard, 2001
). The universally conserved residues possibly involved in an analogous H-bonding network in sBMO are D140, R143, S235, D239, R242, Y64 and K71. Of the 457 amino acids that are identical or conserved among MMOH
-subunit sequences (Fig. 3a
), 391 are conserved in BMOH-
. The remaining 66 BMOH amino acids that are not conserved at positions of high conservation among the six MMOHs are potentially of the most interest in terms of structurefunction relationships. A 19-residue substrate-binding hydrophobic pocket adjacent to the diiron centre was identified from the crystal structure of MMOH from Methylosinus trichosporium (Elango et al., 1997
). Fourteen of the BMOH residues that align with the hydrophobic pocket residues are identical. Of the remaining residues, the three differences that seem most likely to influence the nature of the pocket are T148, V181 and L279, which align with C151, M184 and F282 of MMOH (Fig. 3a
).
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The reductase component (BMOR) has a theoretical molecular mass of 39·8 kDa and is encoded by bmoC. The sequence analysis and comparison (data not shown) reveals a [2Fe2S] binding domain (ferredoxin domain) similar to those found in plants and bacteria (Lelong et al., 1995 ). The cysteine ligands to ferredoxin ironsulfur centres are conserved in BMOR and located at residues 43, 48, 51 and 84 (42, 47, 50 and 82 in the methane monooxygenase reductase MMOR from Methylococcus capsulatus). A second domain (flavin domain) contains motifs for NADH-binding and flavin-binding sites (data not shown). The first solution structure of the ferredoxin domain of MMOR was recently solved from Methylococcus capsulatus (Bath) (Muller et al., 2002
). The universally conserved G45 in MMOR that forms a hydrogen bond with S65 from the backbone glycine carbonyl is occupied by A46 in BMOR. Although the similarity between sBMO and sMMO is less for the reductases than the other components, several structural features of MMOR ferredoxin may be conserved in BMOR. For example, the sequences of a helixprolinehelix motif apparently unique to MMOR ferredoxins are identical or similar in BMOR: QVL (6971) corresponds to QAL (6769) of MMOR helix
2, P73 of BMOR is also conserved, and DEEED (7478) corresponds to EEEEE (7276) involved in
3 of MMOR. The MMOR
2 helix was suggested to be essential for binding MMOH (Muller et al., 2002
).
The 9·6 kDa bmoD gene product is similar in size and derived amino acid sequence to mmoD (orfY) (11·9 kDa). Merkx & Lippard (2002) have recently suggested that this conserved, yet previously uncharacterized, ORF in sMMO may be involved in assembly of the sMMO hydroxylase diiron centres. BMOD shares 1314% identity with the MMOD proteins. Only 19% of MMOD residues are universally conserved. A gene found in the phenol hydroxylase cluster encodes a protein, DmpK, similar in size to MMOD. Studies with the overexpressed protein revealed that DmpK may help assemble the hydroxylase component of phenol hydroxylase by inserting iron into the apoprotein (Powlowski et al., 1997
). DmpK-like proteins are found in other aromatic soluble diiron monooxygenases, including the tbmA gene product, which is 23% identical to DmpK (Johnson & Olsen, 1995
). However, there is very little sequence similarity between these aromatic assembly proteins and BMOD or MMOD. In fact, only one residue is universally conserved among all of the proteins. If BMOD functions similarly to MMOD, then this conserved cysteine, C55, may also be involved in the interaction of the protein with the hydroxylase component during assembly of the metal centre (Merkx & Lippard, 2002
).
Inactivation of the bmoX gene
We examined whether the bmo gene cluster was essential for growth on butane by mutagenesis of bmoX, which encodes the hydroxylase subunit gene with the diiron active site. Insertional inactivation of bmoX was accomplished using a lacZ::kanr cassette. The P. butanovora mutant (Pbu41) was unable to utilize butane as a growth substrate, whereas growth with lactate, citrate or 1-butanol was normal compared to wild-type growth. A low rate of ethylene oxidation [0·062 nmol (min mg protein)-1] was exhibited by the mutant strain independent of prior exposure to butane. Incubations of the mutant strain for as long as 18 h with butane, to allow for induction of bmo gene expression, did not increase the rate of ethylene oxidation. This rate of ethylene oxidation in the mutant was not present in boiled cells and was approximately 0·4% of the ethylene oxidation rate present in butane-grown wild-type cells [15 nmol (min mg protein)-1]. Butane did not induce the expression of the two 1-butanol dehydrogenases in the bmoX::lacZ::kanr mutant, whereas incubation with 1-butanol induced 1-butanol dehydrogenase activity to wild-type levels in the mutant strain, as expected. The position of the cassette insertion in bmoX was confirmed by Southern blot analysis (Fig. 4
).
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DISCUSSION |
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The soluble multicomponent diiron monooxygenases require small-molecular-mass regulatory proteins which do not have any redox properties and do not have any organic or inorganic cofactors (Wallar & Lipscomb, 1996 ). Such a component does not participate in reactions catalysed by toluene dioxygenase (Subramanian et al., 1985
), xylene monooxygenase (Suzuki et al., 1991
) or alkane hydroxylase reactions (Kok et al., 1989
). The regulatory protein binds to the hydroxylase and controls the efficiency of the hydroxylase in sMMO systems in several ways, the most dramatic of which increases the rate of an intermediate reaction with O2 by 1000-fold (Liu et al., 1995
). The high sequence identity (53%) of BMOB with the MMOB from Methylosinus trichosporium OB3b and Methylococcus capsulatus (Bath) emphasizes the similarities between the two systems. The possibility that BMOB could substitute for MMOB in the interaction with the hydroxylase protein from sMMO is intriguing (Stirling & Dalton, 1979
). The effector protein of toluene-4-monooxygenase from P. mendocina (T4moD) could be replaced in the reconstituted system by the T3MO effector protein from P. pickettii, although with less affinity. But the effector proteins from Pseudomonas sp. JS150 or B. cepacia G4 T2MOs could not replace T4moD (Hemmi et al., 2001
). Those experiments examining the structures and functional groups of the regulatory proteins emphasized the high degree of specificity of the regulatory proteins for their respective hydroxylases.
We have not ruled out the possibility that an additional component may be involved in butane monooxygenase. Toluene-4-monooxygenase (Pikus et al., 1996 ) and Xanthobacter Py2 alkene monooxygenase (Small & Ensign, 1997
) are composed of four components, a result of separate ferredoxin and reductase redox components. The sequence of the sBMO oxidoreductase protein (BMOR) contains distinct binding site motifs for a [2Fe2S] ferredoxin domain as well as pyridine-nucleotide- and flavin-binding motifs for a flavin domain. These features are typically found in oxidoreductases from three-component systems that do not require a separate ferredoxin. No ORF with similarity to ferredoxins was found either upstream or downstream of the bmo gene cluster. Together, these features of BMOR further distinguish BMO from membrane alkane hydroxylases, which utilize soluble rubredoxin and soluble NADHrubredoxin reductase electron-transfer components. The likely role of the reductase in sBMO is to transfer electrons from NADH via FAD and the [2Fe2S] ferredoxin to the diiron centre of the hydroxylase, analogous to the sMMO mechanism. Binding studies have revealed different types of interactions for the reductase and the regulatory protein with the hydroxylase component (Muller et al., 2002
; Walters et al., 1999
), providing further evidence of different binding sites on the sMMO hydroxylase for the two components (Gassner & Lippard, 1999
).
P. butanovora is not capable of growth with sugars, methane or alkenes (Hamamura et al., 1999 ; Takahashi et al., 1980
). Furthermore, P. butanovora does not appear to oxidize methane to methanol (Arp, 1999
). Although sMMO catalyses the co-oxidation of butane, the products are predominantly 2-butanol, with smaller amounts of 1-butanol formed, whereas with P. butanovora sBMO, 1-butanol is the only detected product of butane oxidation (Arp, 1999
). Given this difference, comparisons between methane monooxygenases and butane monooxygenase may provide insights into the source of substrate specificity of these homologous enzymes. sMMO is unique among the soluble monooxygenases in the ability to oxidize methane, and the reasons why are not clear. The explanation for the methane discrepancy may be found at the substrate-binding pocket, which for sMMO could provide the additional binding energy needed to oxidize methane, or help orient the substrate for reaction with oxygen, or, in conjunction with the regulatory protein, ensure that solvent is completely excluded from the active site. The surprisingly high homology of sBMO to sMMO may provide a framework for designing site-directed mutagenesis experiments to reveal the basis for this difference in catalytic activity between methane monooxygenases and the other soluble alkane monooxygenases.
The obligate requirement of the bmo gene cluster for butane metabolism was confirmed by mutagenesis of bmo genes. Given that 1-butanol induced wild-type levels of 1-butanol dehydrogenase activity in the sBMO mutant, it appears that the further metabolism of butane oxidation products is not disrupted. Growth with lactate, citrate or 1-butanol also was normal compared to wild-type growth. The residual level of ethylene oxidation detected in the mutant is similar to what was previously observed in catabolite-repression studies, where lactate- or lactate- and butane-grown wild-type cells possessed 0·3% of the activity found in butane-grown wild-type cells (Sayavedra-Soto et al., 2001 ). As suggested before, this activity may be due to a separate butane-sensing mechanism or to an additional alkane-oxidizing enzyme with limited specific activity for ethylene oxidation. This activity was not sufficient for bacterial growth with butane, arguing against a catabolic role.
No other transcription initiation promoters were as clearly suggested from the sequence of the bmo genes as the putative 54 promoter upstream of bmoX. Sequences with some similarity to both
54 and
70 promoter elements were present in the region upstream of bmoY, but no such similarities were identified in the bmoD or bmoC regions. With respect to the levels of MMOH present in extracts, MMOD and MMOR are expressed at molar ratios of 1·8% in Methylococcus capsulatus and 10% in Methylosinus trichosporium, respectively (Fox et al., 1989
; Merkx & Lippard, 2002
). This is consistent with correspondingly lower levels of mRNA for mmoD and mmoC present in extracts of wild-type Methylococcus capsulatus expressing sMMO (Nielsen et al., 1996
). The mmo genes in Methylococcus capsulatus (Bath) seem to be co-transcribed from a single
70 promoter element upstream of mmoX (Nielsen et al., 1996
). However, in Methylosinus trichosporium OB3b, Methylocystis sp. M and Methylomonas sp. KSWIII putative
54 promoters upstream of mmoX as well as an additional putative
70 promoter in the mmoYmmoX intergenic region of Methylosinus trichosporium may be involved in the transcription of mmo genes (McDonald et al., 1997
; Murrell et al., 2000
; Nielsen et al., 1997
). Given that transcription start sites have been mapped to 11, 12 and 13 nucleotides, as well as other distances, downstream of the -12 promoter element (Barrios et al., 1999
), the transcription start site of the bmo genes cannot be predicted from the promoter sequence. If the
54-like promoter element upstream of the bmoX gene is involved in recruiting
54 to form
54RNA polymerase holoenzyme, then the involvement of a
54-dependent enhancer binding protein in the initiation of transcription is expected. A comprehensive study of the transcription of the bmo genes involving mapping of the transcription start site, mutation of putative promoter sequences and transcriptional regulators will be required to understand the regulation of this multicomponent enzyme system.
The cloning and sequencing of the bmo genes will assist with mutagenesis for future studies of the complex regulation of the pathway of butane metabolism in P. butanovora as well as studies of the mechanism of butane oxidation. The purification and biochemical characterization of the three sBMO components is anticipated to augment the molecular characterization.
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ACKNOWLEDGEMENTS |
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Received 16 April 2002;
revised 25 June 2002;
accepted 2 August 2002.