Applied and Environmental Microbiology, October 1998, p. 3549-3555, Vol. 64, No. 10
Scripps Institution of Oceanography,
University of California in San Diego, La Jolla, California
92093-0202
Received 23 April 1998/Accepted 12 July 1998
Pseudomonas putida MnB1 is an isolate from an Mn
oxide-encrusted pipeline that can oxidize Mn(II) to Mn oxides. We used
transposon mutagenesis to construct mutants of strain MnB1 that are
unable to oxidize manganese, and we characterized some of these
mutants. The mutants were divided into three groups: mutants defective in the biogenesis of c-type cytochromes, mutants defective
in genes that encode key enzymes of the tricarboxylic acid cycle, and
mutants defective in the biosynthesis of tryptophan. The mutants in the
first two groups were cytochrome c oxidase negative and did
not contain c-type cytochromes. Mn(II) oxidation capability could be recovered in a c-type cytochrome
biogenesis-defective mutant by complementation of the mutation.
Bacterial Mn(II) oxidation has a
major impact on the biogeochemical cycling of Mn and the many trace
metals that adsorb to the surfaces of Mn oxides (46, 48).
Bacterial Mn(II) oxidation is of practical concern in the fields of
agriculture, bioremediation, and drinking water treatment. Mn
deficiency in plants is often the result of bacterial and fungal Mn(II)
oxidation in the soil (35); biological Mn(II) oxidation can
be used for the removal of toxic contaminants from mine drainage
(36) and is also an alternative to chemical oxidation
in the clean-up of excess Mn from drinking water (37).
Despite the fact that bacterial Mn oxidation has attracted much
attention from microbiologists for almost a century (28), little is known about the reason for this phenomenon or the mechanisms that are involved. It has frequently been proposed that the oxidation of soluble Mn(II) to insoluble Mn(IV) oxyhydroxides may result in
energy gains for the bacteria for either autotrophic or mixotrophic growth, and the findings of several researchers suggest that such energy gains occur (2, 10, 15, 30). An article reviewing new
insights that have been gained through molecular studies of enzymatic Mn(II) oxidation has recently been published (47).
Traditionally, much of the interest in bacterial Mn(II) oxidation
focused on the so-called iron- and manganese-depositing bacteria, such
as Leptothrix discophora, from which an Mn-oxidizing protein
has been isolated (1, 7). With the isolation of more
Mn-oxidizing bacteria over the years, it became clear that rather than
being limited to a few specialized strains, Mn oxidation is widespread
and is a common trait in ubiquitous seawater and freshwater
pseudomonads (13, 23, 38). Pseudomonas
manganoxidans MnB1 (= ATCC 23483) was isolated from an Mn crust
that accumulated in drinking water pipes in Trier, Germany
(44), and was recently reclassified as a Pseudomonas
putida strain (12), a fact that was confirmed by us on
the basis of the sequence of the 16S rRNA gene. Upon reaching the
stationary phase, this organism oxidizes Mn(II) in liquid and
solid media to Mn(IV) oxyhydroxides, which are precipitated on the cell
surface. Within 2 days of growth on an Mn(II)-containing agar
medium, the colonies, which are originally cream colored, become brown
due to the accumulation of the precipitates. MnB1 produces a soluble
protein late in the logarithmic growth phase, which catalytically
oxidizes Mn(II) in cell extracts. This activity is destroyed by heat or
by treatment with a protease (12, 29).
Since P. putida is a ubiquitous freshwater and soil
bacterium, it provides an excellent model system for the study of
Mn(II) oxidation. In this study we used transposon mutagenesis to
obtain mutants of strain MnB1 that lost the ability to oxidize
Mn(II). The mutated genes were partially sequenced and
cloned, and the partial sequences were used to identify the genes
based on similarities to genes in the GenBank database. A similar
approach was used to study a related Pseudomonas strain,
strain GB-1, and the results are reported in the accompanying paper
(13).
Bacterial strains, media, and growth conditions.
The strains
and plasmids used in this study are shown in Table
1. The mutants used are shown in Table
2.
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
c-Type Cytochromes and Manganese
Oxidation in Pseudomonas putida MnB1
ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
TABLE 1.
Bacterial strains and plasmids used in this work
TABLE 2.
Mutants
Mutagenesis.
Transposon mutants were generated by
conjugation of strain MnB1 with E. coli S17-1 
pir
carrying the suicide plasmid pUTKm, which contains a
mini-Tn5 synthetic transposon that confers kanamycin resistance (25) (Fig. 1).
Conjugations were performed overnight at 30°C on cellulose filters
(Micron Sep filters; Micron Separation Inc., Westboro, Mass.) placed on
LB agar plates. After conjugation the cells were resuspended in LB
medium, diluted, and plated onto TSA or TSI selective media. The
resulting exconjugants were then replica plated onto LEP medium plates
by using transfer membranes (Magna nylon membranes; Micron Separation
Inc.), and colonies that did not turn brown after several days were
isolated. These colonies were transferred back to selective medium to
confirm their resistance and then were considered nonoxidizing mutants.
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DNA extraction. DNA was purified with DNA purification columns (Qiagen-tip 100/G; Qiagen Inc., Chatsworth, Calif.).
Southern blotting. Mutants were analyzed by Southern blotting to confirm that a single transposon insertion was present and to identify a restriction fragment containing the end of the transposon of a suitable size for cloning. DNA from mutants were digested with restriction enzymes NotI or SstII, which cut close to the I end of the transposon (Fig. 1). When both enzymes failed to produce a fragment smaller than 10 kb, the DNA was cut with both NotI and SalI. The digested DNA was electrophoresed in a 0.8% TBE agarose gel, and the gel was dried for 3 h in a gel drier (model 483; Bio-Rad Laboratories, Hercules, Calif.). The dried gel was then probed with a labeled oligonucleotide complementary to the I end of the transposon (I-end) by standard procedures.
DNA library. A strain MnB1 DNA library was cloned into cosmid SuperCos I (Stratagene, La Jolla, Calif.) by using the manufacturer's instructions. The library contained 50,000 CFU, and the mean insert size was greater than 30 kb.
Cloning of disrupted genes. Most of the mutated genes were cloned into a plasmid vector. Chromosomal DNAs from the mutants were digested with an enzyme combination that yielded a positive fragment in Southern analyses of suitable size for cloning. The digested DNA were electrophoresed in 0.8% TBE agarose, and areas corresponding to the positive bands were cut out, purified with Geneclean (Bio 101, La Jolla, Calif.), cloned into the vector pBluescript (Stratagene), and transformed into E. coli XL1-blue. The resulting colonies were screened by colony hybridization with the same oligonucleotide probe used for the Southern blots (I-end); positive colonies were isolated, their plasmids were extracted, and the identities of the plasmids were confirmed by restriction analysis followed by DNA hybridization with the I-end oligonucleotide.
Inverse PCR. Some of the mutated genes were not cloned but were amplified by using inverse PCR (39). Chromosomal DNAs were digested with restriction enzyme XhoI or AvaI, which cut once within the body of the transposon. The digested DNA were diluted to a concentration of 2 µg/ml and were self-ligated for 16 h at 15°C to allow circularization of the DNA fragments. The circular molecules were then amplified by a step-down PCR (24) by using back-to-back primers (primers S2 and S3) located near the ends of the transposon. When amplification was weak or nonspecific, a second PCR was conducted by using nested primers (S4 and I-end or S4 and O-end).
Sequencing. All sequencing was done with an ABI automated sequencer (model 373A) by using a PRISM Ready Reaction DyeDeoxy terminator cycle sequencing kit (Perkin-Elmer). Cloned genes were sequenced by using plasmid DNA and primers T3 and T7. PCR-amplified genes were sequenced directly by using the purified inverse PCR products and primers S2, I-end, and O-end. The 16S rRNA sequence was obtained by PCR amplification using standard methods and primers (33).
Sequence analysis. DNA sequences were identified by using the BLAST (basic local alignment search tool) server of the National Center for Biotechnology Information accessed over the Internet (4). Sequence contigs were assembled with the program ASSEMBLY LIGN (Kodak, Rochester, N.Y.). The 16S rRNA sequence was aligned with other sequences using the Ribosomal Database Project WWW server (34).
Complementation. A 4-kb SstII fragment (adjacent to the I end of the transposon and containing part of ccmF and several genes upstream from it, including ccmC and ccmE [Fig. 2]) cloned from the ccmF mutant UT303 was used as a probe to isolate several library clones. A positive 2.2-kb NotI fragment was isolated from one of these clones (p303cos1) and was cloned into the broad-host-range plasmid pBBR1-MCS5. Since this vector does not have a NotI site, the fragment was first cloned into pBluescript and then cleaved again as a BamHI-SstI fragment and cloned into the broad-host-range vector. The resulting plasmid (pCO1) was mobilized into ccmE mutant UT403 by triparental conjugation. Conjugation was performed as described above but at a higher temperature (33°C) by using E. coli XL1-blue containing derivatives of broad-host-range plasmid pBBR1-MCS5 (32) as the donor and E. coli HB101 containing plasmid pRK2013 as the helper (19). Recipient colonies were selected on TSA plates containing kanamycin, gentamicin, nalidixic acid, nitrofurantoin, and triphenyltetrazolium chloride and were transferred to Mn(II)-containing LEP medium to screen for Mn(II) oxidation.
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Enzyme activity and cytochrome c assays. Cytochrome c oxidase activity was determined qualitatively by a tetramethyl-p-phenylenediamine dihydrochloride (TMPD)-based assay (45). Since Mn oxides react with TMPD, yielding false-positive results, cultures were grown on LB agar plates to avoid the presence of any Mn oxides. Isocitrate dehydrogenase activity was determined qualitatively by spectrophotometric assays (43).
Cytochrome c was assayed spectrophotometrically. Cells were grown in 350 ml of LB medium containing kanamycin (100 µg/ml) to the late log phase. The cells were harvested by centrifugation, resuspended in 5 ml of phosphate buffer (pH 7.4) containing 7.5% glycerol, and lysed with a French pressure cell at 15,000 lb/in2. The lysates were centrifuged twice at 100,000 × g for 30 min. The supernatant fraction (cell extract) was analyzed with a split-beam scanning spectrophotometer (lambda 3; Hewlett-Packard) with phosphate buffer in the reference cuvette. Reduced spectra were obtained by adding sodium dithionite to a final concentration of 1 mM to the sample and reference cuvettes, and oxidized spectra were obtained by adding potassium ferricyanide to a final concentration of 250 µM to both cuvettes.Nucleotide sequence accession numbers. The nucleotide sequences obtained in this study have been deposited in the GenBank database. The accession number for the 16S rRNA gene is U70977. The accession numbers for other genes are shown in Table 2.
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RESULTS |
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Abstract
Introduction
Materials & Methods
Results
Discussion
References
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16S rRNA sequence. To verify that strain MnB1 is indeed a strain of P. putida, we amplified by PCR and sequenced 1,487 bp of the 16S rRNA gene of this strain. The sequence obtained was manually aligned with similar sequences in the GenBank database and was 98.6% identical to the sequence of P. putida PB4 (accession no. D37925). This confirmed that strain MnB1 is indeed a P. putida strain.
Isolation of mutants.
The frequency of plasmid transfer during
conjugation could not be measured with the delivery system used. The
frequency of cells in which a transposition event occurred
was calculated by determining the ratio of recipient cells that
acquired kanamycin resistance during conjugation to the total number of
recipient cells; this ratio was found to be about 2.5 × 10
6. Since the presence of antibiotics in a
medium strongly inhibits Mn oxidation, we first
selected for conjugants on a selective medium and then replica
plated the cells onto Mn-containing, antibiotic-free medium to screen
for a loss of Mn oxidation. The frequency of stable
non-Mn-oxidizing mutants was about 1 in 5,000 kanamycin-resistant colonies.
Sequence analysis. DNA sequences flanking the transposon insertion points in the mutants were determined and were submitted to GenBank (Table 2), and the detailed results of BLAST searches have been published elsewhere (9). Sequence analysis of mutated genes revealed that some of the mutants had insertions in the same operons or in genes whose products have similar functions in the organism, and thus the mutants could be divided into the following three groups: group i, cytochrome c biogenesis mutants (insertions in ccmF, ccmA and ccmE); group ii, tricarboxylic acid (TCA) cycle mutants (insertions in sdhA, sdhB, sdhC, aceA, and icd); and group iii, tryptophan biosynthesis mutants (trpE).
Most of these mutants could be identified from the sequence directly flanking the transposon insertion point; the only exception was mutant UT5802, in which the sequence flanking the insertion point did not match any of the sequences in the GenBank database. We amplified the DNA flanking the insertion point of mutant UT5802 by inverse PCR and used the PCR product as a probe to isolate an intact version of the region from the genomic library. A positive 4-kb PstI fragment was isolated from a library cosmid (p5802cos1) and cloned into pBluescript (resulting in p5802Pst). Sequences obtained from both ends of this fragment revealed the presence of two putative isocitrate dehydrogenase-encoding genes (icd) located back to back and flanking the insertion spot. The insertion was located upstream of both genes, which are transcribed in opposite directions away from the insertion point. The two genes are different and are similar to icd genes from E. coli and from Azotobacter vinelandii. To see if the insertion had an effect on the expression of the proteins, we assayed the mutant for isocitrate dehydrogenase activity. While the wild type and all other mutants were isocitrate dehydrogenase positive, mutant UT5802 was clearly isocitrate dehydrogenase negative (results not shown), confirming that the insertion indeed inactivated both icd genes. Table 2 shows the phenotypes and mutated genes of the different mutants, and Table 3 summarizes information about the putative roles of the mutated genes in the organism.
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Cytochrome c oxidase activity and cytochrome c presence. Since the group i mutants had transposon insertions in the cytochrome c biogenesis operon, we tested all of the mutants for cytochrome c oxidase activity. All of the group i and group ii mutants had lost this activity, while the group iii mutants retained it (Table 2). Spectrophotometric analysis of cytochrome c showed that a lack of c-type cytochromes correlated with a lack of oxidase activity (Fig. 3).
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Complementation of a ccmE mutant. To verify that the insertions in the ccm operon are indeed responsible for the Mn(II) oxidation deficiency in these mutants, we complemented one of the ccm mutants (mutant UT403) with a DNA fragment containing the same region isolated from the chromosome. A plasmid (pCO1) containing this region was mobilized into ccmE mutant UT403 by triparental conjugation, and recipient colonies that contained the plasmid were selected on TSA plates containing gentamicin. All of the resulting colonies were kanamycin resistant, and all were cytochrome c oxidase positive and oxidized Mn(II) when they were transferred to antibiotic-free LEP medium plates.
Chemical complementation of mutants. Cross-streaking experiments, in which one strain was streaked close to a streak of another strain, revealed that wild-type cells secreted a substance into the medium that diffused into the agar and restored Mn(II) oxidation in most group ii mutants (namely, the sdh and aceA mutants). The wild type could not restore oxidation in the ccm mutants, but ccm mutants and even E. coli could induce oxidation in the sdh and aceA mutants. In an attempt to identify the diffusive compound, disks soaked with different intermediates of the TCA cycle were placed on a plate covered with a lawn of an sdh mutant (mutant UT501). The compounds that were tested were succinate, fumarate, 2-oxoglutarate, oxaloacetate, acetyl coenzyme A, and malate. Only one of these compounds, malate, induced Mn(II) oxidation in cells growing around the disk, but the induction was slow and weak.
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DISCUSSION |
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Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Characterization of mutants. The four group i mutants (mutants UT302, UT303, UT402, and UT403) had insertions in different genes (ccmF, ccmF, ccmA, and ccmE, respectively) of an operon that has been found to be crucial for the assembly of mature c-type cytochromes in several other bacterial species (Fig. 2), including Bradyrhizobium japonicum, Rhodobacter capsulatus, E. coli, and Pseudomonas fluorescens (for a recent review, see reference 49). The best matches (70 to 85% identity) are with sequences of similar genes of two strains of the related organism P. fluorescens (strains 17400 and 09906). All group i mutants grew very well on LEP medium and formed large colonies similar to those of the wild type. They were all cytochrome c oxidase negative (Table 2) and had no detectable c-type cytochromes (Fig. 3). The restoration of Mn oxidation in a ccmE mutant by complementation with a chromosomally derived copy of the ccmE gene confirmed the role of the ccm operon in Mn oxidation. The same conclusion is also reported for the Mn-oxidizing bacterium P. putida GB-1 in the accompanying paper (13).
One might wonder why we did not find mutations in genes encoding a specific cytochrome(s). A possible reason is that elimination of a single cytochrome does not result in a markedly different phenotype of the mutant, because other cytochromes in the cell assume the role of the missing cytochrome (17, 50). Thus, the only way to obtain a cytochrome c-deficient phenotype is to eliminate all of the cytochromes together by knocking out cytochrome biosynthesis. However, other explanations are possible, as discussed below. The eight mutants in group ii had insertions in genes encoding different enzymes of the TCA cycle; four of them (mutants UT405, UT501, UT4201, and UT3501) had insertions in genes encoding different subunits of the succinate dehydrogenase (sdh) complex (Fig. 2). Despite the fact that no similar genes have been sequenced from a Pseudomonas species before, the match with the E. coli sequences provided reliable identification (Table 2). Three other mutants (mutants UT1124, UT1405, and UT3308) had insertions in the aceA gene, which encodes the lipoate acetyltransferase subunit of the pyruvate dehydrogenase complex. The closest match in the database was to a similar sequence from Pseudomonas aeruginosa. In the last mutant in this group (mutant UT5802) two different isocitrate dehydrogenase genes were inactivated by a single insertion of a transposon. While it is outside the scope of this investigation, it should be noted that icd genes have not been identified in a Pseudomonas species before, and the arrangement of two genes similar to the genes from E. coli and A. vinelandii, back to back, deserves closer attention in the future. All group ii mutants grew more slowly than the wild type, formed smaller colonies, and, unlike the wild type and group i mutants, could not grow on succinate. Their longevities were also decreased, and colonies left on plates for 1 month died, unlike the wild-type colonies, which remained viable for much longer periods of time. Interestingly, all of these mutants were cytochrome c oxidase negative and had no detectable c-type cytochromes (Fig. 3). This fact led to the hypothesis that the Mn oxidation deficiency in these mutants may be a secondary phenomenon caused by the lack of c-type cytochromes, which results from the unusual biosynthetic pathways which must exist in such mutants either because of a lack of precursor molecules or because of a negative effect on the regulation of cytochrome c synthesis. One possible explanation is a lack of heme. All cytochromes contain heme, and the first committed step in heme biosynthesis is the synthesis of
-levulinate (18). In Pseudomonas strains -levulinate is synthesized from glutamate (6), which
in turn is synthesized largely from 2-oxoglutarate, an
intermediate of the TCA cycle. It is possible that the bypass of
essential enzymes, such as pyruvate dehydrogenase, isocitrate
dehydrogenase, and succinate dehydrogenase, depletes the concentration
of available 2-oxoglutarate to such a degree that heme biosynthesis
stops or is greatly diminished. Under these conditions the bacteria
are not able to synthesize active c-type cytochromes. To
test this hypothesis, disks soaked with hemin (a source of heme),
-levulinate (a precursor of heme synthesis), and glutamate (a
precursor of -levulinate) were placed next to streaks of the group
ii mutants. However, these compounds failed to restore oxidation in any
of the mutants. This negative result might rule out this explanation, but it is also possible that the generally impaired energy metabolism in these mutants had a negative effect on the regulation of heme biosynthesis, or perhaps these compounds could not be transported into
the cells.
An intriguing finding was the fact that when P. putida MnB1
cells (either wild type, group i mutants, group iii mutants) and even
E. coli cells were streaked near group ii mutants, they
secreted a substance into the medium that restored Mn(II)
oxidation in group ii mutants. While we could not discover
the nature of this substance, it is clear that there was not a
direct chemical reaction between the secreted substance and Mn(II) in
the medium, since E. coli, which does not oxidize Mn(II),
still restored oxidation in the mutants. Rather, the substance must
affect the mutants in a way that partially restores their ability to
oxidize Mn(II).
The two group iii mutants had insertions in the trpE gene,
which encodes the subunit of anthranilate synthetase, an
enzyme that is involved in the biosynthesis of tryptophan. A
similar gene has been sequenced from P. putida before,
and there was more than 90% identity with that sequence. These
two mutants grew like the wild type on LEP and LB media and formed
large colonies. Their Mn(II) oxidation capabilities were severely
deficient, but after a long time on LEP medium plates (>1 month), they
showed some oxidation. When grown on plates supplemented with
tryptophan, they oxidized Mn(II) after 3 days. Unlike most of the other
mutants, these mutants were oxidase positive. While it is difficult to interpret this unexpected result, it is possible to speculate. It
has been shown that mutants of Methylobacterium extorquens and Paracoccus denitrificans deficient in c-type
cytochrome biogenesis cannot assemble tryptophan-tryptophylquinone, a
unique cofactor of the enzyme methylamine dehydrogenase
(41). If a similar cofactor was essential for Mn(II)
oxidation, one would expect that a defect in cytochrome c
biosynthesis would stop Mn(II) oxidation completely, while a defect in
tryptophan synthesis would greatly slow the process down.
The cytochrome c biogenesis operon has been shown to be
involved directly or indirectly in many different functions of
bacterial cells. To mention a few, mutants of P. fluorescens
17400 lost the ability to produce the siderophore pyoverdine
(20), mutants of P. fluorescens 09906 lost copper
resistance and general competitiveness (51), and mutants of
Azorhizobium caulinodans lost the ability to
hydroxylate nicotinate (31). There are several ways in which the products of the cytochrome c biogenesis operon can
be involved in Mn(II) oxidation; one frequently cited way is that
c-type cytochromes are essential components in an electron
transfer chain that channels electrons from a Mn(II)-oxidizing factor
to the electron acceptor, most likely oxygen (5, 14, 21,
27). However, a c-type cytochrome may be a part of the
Mn(II)-oxidizing factor itself, as in the case of the hydroxylamine
oxidoreductase complex in the genus Nitrosomonas, which
catalyzes the oxidation of hydroxylamine to nitrite. This complex
contains approximately 24 c-type cytochromes of many types
(16). As discussed above for the trpE
mutants, a third option is that either the products of the cytochrome
c maturation genes or c-type cytochromes
themselves are involved in the biosynthesis of other molecules, such as
tryptophan-tryptophylquinone, which may be involved in Mn(II)
oxidation. For more discussion of the potential role of the
ccm operon in Mn oxidation, see the accompanying paper
(13).
So far, while our research has identified several genes that play a
role in Mn oxidation, it has not revealed a gene encoding an
Mn(II)-oxidizing factor. We cannot rule out the possibility that such a
component exists and could be found by isolating and characterizing
more mutants. We tested 16 more non-Mn(II)-oxidizing mutants that have
not been characterized yet (and are not described here) and found that
2 of them were TMPD positive and therefore may have a mutation in such
a gene. Furthermore, the presence of two Mn(II)-oxidizing factors was
recently demonstrated in a closely related strain, P. putida GB-1, by Mn staining of sodium dodecyl
sulfate-polyacrylamide gels containing electrophoresed supernatant
fractions of cell extracts (40). Mn(II)-oxidizing activity
was detected by the formation of Mn oxide on the protein bands
after incubation of the gel in an MnCl2 solution. A
non-Mn(II)-oxidizing mutant of strain GB-1 (13) was
found to have a mutation in a novel gene that includes two motifs
encoding copper binding sites, indicating a relationship to the
multicopper oxidase family. Considering that two Mn(II)-oxidizing
bacteria (L. discophora and Bacillus sp. strain
SG-1) were found to have Mn(II) oxidation-related proteins that belong
to this group (47), it is quite possible that the novel gene
encodes an Mn oxidase in P. putida GB-1 and that a very
similar gene will be found in strain MnB1.
Clearly, the process of Mn(II) oxidation in P. putida is
complex, and considerable effort will be required before we fully understand it. In future work in our lab we will continue
to isolate and characterize transposon mutants while we pursue
isolation and identification of the Mn(II)-oxidizing components of
strain MnB1.
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ACKNOWLEDGMENTS |
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We thank K. N. Timmis for providing plasmid pUTKm, M. E. Kovach for providing plasmid pBBR1-MCS5, L. Park for her great help, M. Silverman for advice, and D. Bartlett for reviewing the manuscript. We also thank J. P. M. de Vrind, G. J. Brouwers, P. L. A. M. Corstjens, J. den Dulk, and E. W. de Vrind-de Jong for sharing their findings with us prior to publication.
Portions of this research were supported by grants MCB94-07776 and OCE94-168944 from the National Science Foundation. R.C. was supported in part by a fellowship from the University of California Toxic Substances Research and Teaching Program.
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FOOTNOTES |
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* Corresponding author. E-mail: btebo{at}ucsd.edu.
Present address: Department of Biology, University of California in
San Diego, La Jolla, CA 92093-0634.
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Abstract
Introduction
Materials & Methods
Results
Discussion
References
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