Biochemical investigations of the muconate and chloromuconate
cycloisomerases from the chlorophenol-utilizing strain
Rhodococcus opacus (erythropolis) 1CP had
previously indicated that the chlorocatechol catabolic pathway of this
strain may have developed independently from the corresponding pathways
of proteobacteria. To test this hypothesis, we cloned the
chlorocatechol catabolic gene cluster of strain 1CP by using PCR with
primers derived from sequences of N termini and peptides of purified
chlorocatechol 1,2-dioxygenase and chloromuconate cycloisomerase.
Sequencing of the clones revealed that they comprise different parts of
the same gene cluster in which five open reading frames have been
identified. The clcB gene for chloromuconate cycloisomerase
is transcribed divergently from a gene which codes for a LysR-type
regulatory protein, the presumed ClcR. Downstream of clcR
but separated from it by 222 bp, we detected the clcA and
clcD genes, which could unambiguously be assigned to
chlorocatechol 1,2-dioxygenase and dienelactone hydrolase. A gene
coding for a maleylacetate reductase could not be detected. Instead,
the product encoded by the fifth open reading frame turned out to be
homologous to transposition-related proteins of IS1031 and
Tn4811. Sequence comparisons of ClcA and ClcB to other
1,2-dioxygenases and cycloisomerases, respectively, clearly showed that
the chlorocatechol catabolic enzymes of R. opacus 1CP
represent different branches in the dendrograms than their proteobacterial counterparts. Thus, while the sequences diverged, the
functional adaptation to efficient chlorocatechol metabolization occurred independently in proteobacteria and gram-positive bacteria, that is, by functionally convergent evolution.
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INTRODUCTION |
Although various chloroaromatic
compounds are known to be degraded slowly or incompletely under certain
conditions (23), numerous bacteria are able to utilize some
representatives of this class of chemicals as sole sources of carbon
and energy (26, 54). In many of the cases where growth
occurs, the chloroaromatic substrates are initially converted to
chlorocatechols. These can be cleaved in ortho position,
i.e., between the hydroxyl groups, to chlorosubstituted
cis,cis-muconates. Cycloisomerization of the
latter and concomitant chloride elimination will yield dienelactones (4-carboxymethylenebut-2-en-4-olides) which may still carry the remaining chlorine substituents (Fig. 1).
Subsequent hydrolysis of the lactone and reduction of the resulting
maleylacetate, in most cases, generate 3-oxoadipate, an intermediate
also of the catechol and the protocatechuate branch of the ubiquitous
3-oxoadipate pathway (Fig. 1).
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FIG. 1.
Degradative pathways for catechol, 4-chlorocatechol, and
3,5-dichlorocatechol. Designations as gene products, as previously
assigned for gram-negative or gram-positive bacteria, are given in
parentheses. Enzymes with a specific function in chlorocatechol
catabolism are set off by heavy arrows.
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As initially shown especially for the 3-chlorobenzoate-utilizing
Pseudomonas sp. strain B13 and for the
2,4-dichlorophenoxyacetate-degrading strain Ralstonia
eutropha (Alcaligenes eutrophus) JMP134(pJP4), different sets of enzymes are induced for catechol catabolism on the
one hand and for chlorocatechol catabolism on
the other (13, 39, 53, 59, 60). Thus, chlorocatechol
1,2-dioxygenase (EC 1.13.11.-), chloromuconate cycloisomerase (EC
5.5.1.7), and dienelactone hydrolase (EC 3.1.1.45) catalyze reactions analogous to those of catechol 1,2-dioxygenase (EC 1.13.11.1), muconate
cycloisomerase (EC 5.5.1.1), and 3-oxoadipate enol-lactone hydrolase (EC 3.1.1.24). They differ from the latter, however, in
having higher relative turnover numbers and/or lower
Km values for chlorosubstituted substrates
or the metabolites generated from them by chloride elimination. The
fourth enzyme characteristic for chlorocatechol catabolism,
maleylacetate reductase (EC 1.3.1.32), has no equivalent among catechol
catabolic enzymes and compensates for the different oxidation states of
the metabolites of the two pathways.
Genetic studies, which have so far focused on gram-negative bacteria,
have shown that the enzymes of chlorocatechol pathways are often
encoded by catabolic plasmids such as pJP4 of R. eutropha JMP134 (11), pAC27 of the 3-chlorobenzoate-utilizing
Pseudomonas putida AC866 (6), pP51 of the
1,2,4-trichlorobenzene-mineralizing Pseudomonas sp.
strain P51 (68), and pEST4011 isolated from the
2,4-dichlorophenoxyacetate-degrading P. putida EST4021
(42). Several years ago, sequencing of chlorocatechol gene
clusters from the former three plasmids (20, 52, 69) showed
the chlorocatechol 1,2-dioxygenases and chloromuconate cycloisomerases
to be homologous to catechol 1,2-dioxygenases and muconate
cycloisomerases, respectively. More interestingly, the
chlorocatechol 1,2-dioxygenases of these plasmids were derived
from a common ancestor not shared by the catechol 1,2-dioxygenases, as
the chloromuconate cycloisomerases diverged from an ancestral
enzyme not in the line of descent of known muconate cycloisomerases
(58). The dienelactone hydrolases are evolutionarily so
remote from the 3-oxoadipate enol-lactone hydrolases that their common
evolutionary background could be identified only by their
three-dimensional structure or sequence signatures related to it
(29, 50, 58). These observations, as well as conserved
structures of the gene clusters, suggested that the proteobacterial
chlorocatechol pathways, as represented by those on pAC27, pJP4, and
pP51, diverged from the same ancestral pathway (58). The
catabolic genes from many other strains were shown by hybridization to
be related to those of the plasmids mentioned above (4, 21, 36,
42, 65). In other cases, no hybridization was found under the
conditions used (4, 21, 34, 36).
The gram-positive bacterium Rhodococcus opacus
(erythropolis) 1CP has previously been isolated with
2,4-dichlorophenol as the carbon source (25). Purification
and characterization of its chlorocatechol 1,2-dioxygenase,
chloromuconate cycloisomerase, and dienelactone hydrolase revealed
unusual properties (43, 44, 63). Especially interesting was
the observation that with respect to the conversion of
2-chloro-cis,cis-muconate and the chloromuconolactones derived from it, the muconate, and the
chloromuconate cycloisomerase of R. opacus 1CP were more
similar to each other than to proteobacterial muconate or
chloromuconate cycloisomerases characterized thus far (63).
If these phenotypic similarities of the Rhodococcus enzymes
resulted from a closer evolutionary relationship, then this would mean
that the adaptation to chlorosubstituted substrates occurred
independently among the proteobacteria and the gram-positive bacteria.
Thus, on the basis of a sequence divergence, a functional
convergence (12) would have to be assumed. Proof of
this hypothesis would require sequence information from both the
enzymes involved in catechol catabolism and those involved in
chlorocatechol catabolism of Rhodococcus. We recently
reported on the characterization of the catechol gene cluster
(17), and in the accompanying report (18) we
present sequences of enzymes for protocatechuate degradation, some of
which also contribute to the catechol branch of the 3-oxoadipate
pathway. In this communication, we show that the chlorocatechol
enzymes of R. opacus 1CP do indeed represent
different branches than the previously characterized enzymes
encoded on plasmids pAC27, pJP4, and pP51.
(Some of the results reported here have recently been presented in a
preliminary communication [16].)
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MATERIALS AND METHODS |
Strains, plasmids, and cultivation conditions.
R.
opacus 1CP was isolated with 2,4-dichlorophenol as the carbon
source (25, 66). To obtain biomass for the enzyme
purifications, the strain was cultivated in a mineral medium with
4-chlorophenol as described previously (63).
Escherichia coli DH5
(5), obtained from Gibco
BRL, was grown aerobically at 37°C with constant shaking in LB
(Luria-Bertani) medium (56) supplied with ampicillin (100 µg/ml), if appropriate. The plasmids used in this study are described
in Table 1.
Enzyme assays and estimation of protein concentration.
The
activity of chloromuconate cycloisomerase was measured
spectrophotometrically at 260 nm as described by Schlömann et al.
(59), using 0.1 mM
2-chloro-cis,cis-muconate as the substrate (extinction coefficient, 17,100 M
1 · cm1 [13]). The latter was available from
a previous preparation (72). Dienelactone hydrolase was
assayed at 280 nm, using a modification of the procedure of Schmidt and
Knackmuss (60) in the presence of 50 mM Tris-HCl (pH 7.5)
and 0.05 mM cis-dienelactone (cis-4-carboxymethylenebut-2-en-4-olide) (extinction
coefficient, 17,000 M1 · cm1
[59]; obtained from S. R. Kaschabek and W. Reineke, Wuppertal, Germany).
Protein purifications.
Chlorocatechol 1,2-dioxygenase was
purified basically as described previously (43).
For the purification of chloromuconate cycloisomerase, a cell extract
was prepared in 50 mM BisTris-HCl
(bis-[2-hydroxyethyl]-imino-tris[hydroxymethyl]methane-HCl; pH 6.5)
plus 1 mM dithiothreitol (DTT) by grinding the cells with glass beads
and clarifying the crude extract as described previously (17). The extract (volume, 250 ml; protein, 800 mg; total
activity, 14.6 U; specific activity, 0.018 U/mg) was subjected to a
purification scheme which differed from that of Solyanikova et al.
(63) especially in the first step and in the additional
reversed-phase chromatography. From a Pharmacia Q Sepharose High
Performance HR 16/10 column (bed volume, 20 ml), used with 50 mM
BisTris-HCl (pH 6.5), 1 mM DTT, and a linear NaCl gradient (0 to 0.5 M
NaCl over 300 ml), the most active fractions eluted at ca. 0.35 M NaCl.
(NH4)2SO4 was added to 1.6 M (final
concentration), and the preparation was chromatographed on a Pharmacia
Phenyl Superose HR 10/10 column. Elution with a linear gradient of
(NH4)2SO4 (1.6 to 0 M over 104 ml)
in 50 mM Tris-HCl (pH 7.5), 2 mM MnSO4 yielded
cycloisomerase-containing fractions at about 0.35 to 0.4 M
(NH4)2SO4. The preparation was subjected to gel filtration on a Pharmacia Superdex 200 prep-grade HiLoad 16/60 column (bed length, 60 cm), using 50 mM Tris-HCl (pH
7.5)-2 mM MnSO4-0.2 M NaCl for elution. The resulting
preparation (volume, 9 ml; protein, 12.3 mg; total activity, 8.25 U)
had a specific activity of 0.67 U/mg, equivalent to a 37-fold
purification. The purified enzyme was prepared for tryptic digestion by
reversed-phase chromatography. A ca. 0.2-mg aliquot of the purified
enzyme was loaded onto a Pharmacia ProRPC HR 5/10 column with
0.1% (vol/vol) trifluoroacetic acid in H2O and eluted with
a linear gradient (over 18 ml) to 0.1% (vol/vol) trifluoroacetic acid
in acetonitrile. The absorption peak at ca. 65% (vol/vol) acetonitrile
was collected and concentrated in a vacuum centrifuge.
For purification of dienelactone hydrolase, an extract (volume, 65 ml;
protein, 124 mg; total activity, 51.9 U; specific activity, 0.42 U/mg)
was prepared in 50 mM Tris-HCl (pH 7.2) with 0.1 mM DTT. Compared to a
previous purification (44), more advanced chromatographic
media were used. Chromatography with Q Sepharose High Performance
HR16/10 and a gradient from 0 to 0.75 M NaCl over 400 ml was followed
by Phenyl Sepharose Fast Flow HR16/10 chromatography using a gradient
from 2 to 0 M (NH4)2SO4 over 280 ml. The final Superdex 75 HR10/30 (bed length, 30 cm) step yielded a
preparation (volume, 1.5 ml; protein, 0.28 mg; total activity, 8.3 U)
with a specific activity of 29.7 U/mg, equivalent to a 71-fold
purification.
The purity of enzyme preparations was investigated by discontinuous
sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis as
described previously (17). The gels were stained with a
Pharmacia silver-staining kit.
Protein cleavage, isolation of peptides, and sequencing of
peptides and N termini.
Trypsin digestion of chlorocatechol
dioxygenase, chloromuconate cycloisomerase, and dienelactone hydrolase
as well as subsequent separation of tryptic peptides by reversed-phase
high-pressure liquid chromatography were performed by the procedure of
Stone et al. (64), with details as described by Eulberg et
al. (17). The amounts of chlorocatechol dioxygenase,
chloromuconate cycloisomerase, and dienelactone hydrolase after
precipitation, washing, and drying were 66, 90, and 30 µg,
respectively.
Purification and general in vitro manipulations of DNA.
Genomic DNA of R. opacus 1CP was obtained as described
previously (17). Plasmid DNA from E. coli DH5
was isolated with Pharmacia Flexiprep kits. For other general methods,
see the accompanying report (18).
Amplification of segments of the chlorocatechol 1,2-dioxygenase
gene and of the chloromuconate cycloisomerase gene.
Oligonucleotides were custom synthesized according to the sequences of
an N terminus and of several internal peptides (Table 2). To reduce the degeneracy of the
oligonucleotides, a codon usage table for the previously sequenced
genes catA, catB, and catC of strain
1CP (17) was used. The 50-µl PCR mixtures contained 50 pmol of each primer, ca. 0.25 µg of genomic template DNA, 0.1 mM each
deoxynucleotide triphosphate, Goldstar DNA polymerase buffer [75 mM
Tris-HCl (pH 9), 20 mM (NH4)2SO4,
0.01% (wt/vol) Tween 20], 1.5 mM MgCl2, and 0.5 U of
Goldstar DNA polymerase (Eurogentech). A denaturing agent (dimethyl
sulfoxide or formamide) (71) was added to the reaction
mixtures to enhance the specificity of hybridization (2 to 8%
[vol/vol] dimethyl sulfoxide or formamide for amplification of a
fragment of the dioxygenase gene; 3 and 6% [vol/vol] dimethyl
sulfoxide for the amplification of a cycloisomerase gene fragment). The
thermocycling parameters for amplification of the chlorocatechol
1,2-dioxygenase gene fragment were as follows: 30 cycles of denaturing
(95°C, 30 s), annealing (48°C, 2 min), and polymerization
(72°C, 45 s), with an additional 2.5 min of denaturing before
addition of the polymerase during the first cycle (10) and
an additional 4.25 min of polymerization during the last cycle. For
amplification of the chloromuconate cycloisomerase fragment, a
thermocycling program without a separate polymerization step was used
as appropriate for the small size of the product expected: 30 cycles of
denaturing (95°C, 30 s) and annealing (48°C, 1 min), with an
additional 2.5 min of denaturing before addition of the
polymerase during the first cycle and 20 s of polymerization at 72°C after the last cycle.
Cloning strategy and hybridization procedures.
PCR products
were ligated into a T-tailed vector (45). The plasmids
containing the ca. 220-bp product obtained with the chlorocatechol 1,2-dioxygenase-derived primers and the ca. 60-bp product obtained with the chloromuconate cycloisomerase-derived primers
were designated pRERD1 and pRERC1, respectively. The insert of
pRERD1 was digoxigenin labeled by using a DIG DNA Labeling and
Detection Kit Nonradioactive (Boehringer), while the insert of pRERC1
was labeled, after denaturation (100°C, 10 min) and immediate
chilling on ice, by tailing with digoxigenin-dUTP using a DIG
Oligonucleotide Tailing Kit (Boehringer). On Southern blots of genomic
DNA of strain 1CP digested with PstI or EcoRI, we
could identify a ca. 2.9-kb PstI fragment by hybridization
with the labeled insert of pRERD1 and a ca. 3.7-kb EcoRI
fragment by hybridization with the labeled insert of pRERC1 (procedure
as described in the Boehringer manual). Identical digests were loaded
onto second gels, and slices that corresponded in size to the positions
of the respective hybridization signals were excised. The DNA was eluted from the gel slices and ligated into the dephosphorylated PstI or EcoRI site of pBluescript II KS (+). The
resulting gene banks were transformed into cells of E. coli
DH5. The clones which carried the DNA of interest were then
identified with the corresponding probe (performed by a procedure
analogous to that described in reference 17). The
plasmid hybridizing to the labeled insert of pRERD1 was designated
pRER5; the one which hybridized with pRERC1 was designated pRER7. An
adjacent clone, pRER6, which completed the open reading frame for
dienelactone hydrolase on pRER5, was obtained by digoxigenin labeling a
ca. 300-bp NotI-PstI fragment of the open reading
frame and by using that to identify a ca. 10-kb HindIII
fragment. A 2,409-bp SacII subclone of pRER6 which overlaps
with pRER5 was also identified by hybridization with the labeled ca.
300-bp NotI-PstI fragment and was designated pRER61.
DNA sequence analysis.
The nucleotide sequences of the
overlapping inserts of pRER5, pRER7, and a part of pRER6 were
determined partly by sequencing nested deletions or subclones and
partly by sequencing with custom-synthesized primers. For the
sequencing reactions, an Applied Biosystems Prizm kit was used, with
subsequent electrophoresis and analysis in an Applied Biosystems A373
sequencer. Computer-based sequence analyses were done with the PC/GENE
program package (Intelligenetics Inc., Mountain View, Calif.). Database
searches were performed by the programs BLASTX (3, 24) and
FASTA (51). Multiple sequence alignments were performed by
the PC/GENE version of CLUSTAL (31), with open and unit gap
costs set to 10. Dendrograms based on the Fitch-Margoliash
algorithm were obtained by using the programs PROTDIST, FITCH, and
DRAWTREE, and bootstrap data were obtained by additionally using the
programs SEQBOOT and CONSENSE, all from the PHYLIP program package
(19).
Nucleotide sequence accession number.
The 7,240-bp sequence
of the overlapping inserts of pRER7, pRER5, and pRER61 shown in Fig. 3
will appear in the EMBL, GenBank, and DDBJ nucleotide sequence
databases under accession no. AF003948.
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RESULTS |
Cloning of the clc gene cluster from R. opacus 1CP.
As a basis for the cloning of the clc
gene cluster, the chlorocatechol 1,2-dioxygenase, the chloromuconate
cycloisomerase, and the dienelactone hydrolase from strain 1CP, which
previously had been purified and characterized biochemically (43,
44, 63), were purified again from 4-chlorophenol-grown R. opacus 1CP cells. Aliquots of the purified proteins were subjected
to trypsin digestion, and selected isolated peptides were sequenced (Table 2). Some of these peptide sequences, as well as the
previously sequenced N terminus of the chloromuconate
cycloisomerase (63), served for the design of
degenerate primers for PCR experiments (Table 2). PCR products
were obtained independently for the chlorocatechol 1,2-dioxygenase gene
(a ca. 220-bp fragment) and for the chloromuconate cycloisomerase gene
(a ca. 60-bp fragment). The plasmids that resulted from the ligation of
the PCR products into pBluescript II KS (+), designated pRERD1 and
pRERC1, respectively, were checked by sequencing to contain the
fragment of interest. The inserts of pRERD1 and pRERC1 were labeled
with digoxigenin and were used to identify a ca. 2.9-kb PstI
clone and a ca. 3.7-kb EcoRI clone (designated pRER5 and
pRER7, respectively). By DNA sequence analysis, it was shown that the
inserts of the two plasmids overlap, which means that the
chlorocatechol 1,2-dioxygenase gene and the chloromuconate cycloisomerase gene are part of the same cluster of chlorocatechol catabolic genes. A major clone with an insert overlapping that of
pRER5, pRER6, and its subclone, pRER61, were constructed to allow the
complete sequencing of this gene cluster.
Sequence analysis of pRER5, pRER7, and pRER61.
The sequenced
7,240 bp of the overlapping inserts of pRER5, pRER7, and pRER61
comprised five complete open reading frames (Fig.
2 and
3). The first open
reading frame (position 1,700 to 579) is transcribed in the opposite
direction of the other open reading frames. It was identified as
clcB, the gene of the chloromuconate cycloisomerase, by
showing that the sequence of its predicted gene product contains all
determined peptide sequences as well as the reported N-terminal
sequence (63) in which one position turned out to be wrong
(Table 2; Fig. 3). In addition, the predicted subunit molecular mass of
the protein encoded by this open reading frame (39,532 Da) fits well
with the 40 to 42 kDa determined by SDS-polyacrylamide gel
electrophoresis of purified chloromuconate cycloisomerase
(63). The product of the clcB gene shows high sequence similarities to known bacterial muconate and chloromuconate cycloisomerases: 41.8% identical positions with R. opacus
CatB (in the alignment of Fig. 4), 36.2 to 38.3% with muconate
cycloisomerases of 
-proteobacteria, and 36.5 to 40.3% identical
positions with chloromuconate cycloisomerases of proteobacterial
plasmids (excluding TfdDII, for which no biochemical data
have been reported [33.9%]). The residues which are involved in
manganese coordination, as well as those which are directly involved in
the enzyme mechanism (22, 30, 33), are conserved throughout
the known muconate and chloromuconate cycloisomerases, including ClcB
from Rhodococcus (but excepting TfdDII) (Fig.
4).
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FIG. 2.
Restriction map of the inserts of pRER5, pRER7, and
pRER61 carrying 7,240 bp of R. opacus 1CP DNA in the
multiple cloning site of pBluescript II KS (+). The lengths and
orientations of open reading frames are indicated by large arrows. Two
small arrows indicate the locations of the imperfect inverted repeats.
Between the presumed clcR and clcA was found a
hairpin structure that possibly represents a transcription
terminator.
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FIG. 3.
Sequence of the 7,240 bp of R. opacus 1CP DNA
cloned in pRER5, pRER7, and pRER61. The predicted amino acid sequences
of the open reading frames are shown below the DNA sequence. Amino acid
sequences obtained by direct sequencing of proteins or tryptic peptides
are underlined. For clcB, which is divergently transcribed
from all other open reading frames, the complementary (in this case,
coding) strand is also given. A segment between clcR and
clcA, which forms a hairpin structure and possibly
represents a transcription terminator, is indicated by two arrows of
opposite orientation. An imperfect inverted repeat is represented by
underlined and italicized bases between clcB and
clcR as well as downstream of ORF5.
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FIG. 4.
Sequence alignment of muconate cycloisomerases (CatB),
chloromuconate cycloisomerases (TfdD, ClcB, and TcbD), and a
cycloisomerase of unknown biochemistry (TfdDII) as
calculated by the CLUSTAL program. Numbering above the sequences refers
to positions in the alignment, not in single sequences. Amino acids in
positions in which at least eight of the nine aligned sequences are
identical are highlighted. Amino acids that are identical in all
muconate but different in all chloromuconate cycloisomerases (or vice
versa) are shaded. (TfdDII was not included because of the
lack of biochemical data for this hypothetical protein.) Aspartate and
glutamate residues involved in manganese coordination (arrows pointing
upward), as well as lysine and glutamate residues directly involved in
the enzyme mechanism (arrows pointing downward), are indicated
(22, 30, 33). Accession numbers and references for the
published sequences: TfdDII, U16782 (67); ClcB
of pAC27, M16964 (20); TcbD, M57629 (69); TfdD,
M35097 (52); CatB R. opacus 1CP, X99622
(17); CatB A. (Acinetobacter)
calcoaceticus, M76991 (62); CatB P. putida PRS2000, U12557 (35) with two corrections in
positions 158 and 263 of the alignment (57); CatB P. putida RB1, M19460 (1). The N-terminal amino acid of
TfdD has been determined to be methionine, although the associated
codon is GTG (27).
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Divergently transcribed from clcB, a second open reading
frame, coding for a protein with a molecular mass of 33,261 Da, was found to extend from positions 2509 to 3420. It is similar to transcriptional activators of the LysR type, especially to those regulating chlorocatechol catabolic gene clusters on proteobacterial plasmids (36.8 to 39.0% identical positions in the alignment of Fig.
5) and to -proteobacterial regulators
of catechol catabolism (29.8 and 26.7% identical positions,
respectively, with CatR and CatM). Thus, this open reading frame was
considered to represent the clcR gene, coding for a
regulatory protein.
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FIG. 5.
Sequence alignment of the presumed ClcR of R. opacus to known LysR-type regulatory proteins that govern operons
for catechol catabolism (CatM and CatR) or chlorocatechol catabolism
(ClcR, TfdR, TcbR, and TfdT). Numbers above the sequences refer to
positions in the alignment, not in single sequences. Amino acids in
positions in which at least seven of the eight sequences are identical
are highlighted. Accession numbers and references for the published
sequences: TfdR of pJP4, M98445 (46); ClcR of pAC27, L06464
(8); TcbR, M57629 (70); TfdT, U16782
(40); CatM, M76991 (55); CatR, U12557
(35). The amino acid sequence of TfdR from pEST4011 was
obtained by translating the DNA sequence after generating a frameshift
by insertion of one nucleotide behind position 726 of the submitted
sequence (U32188 [38]).
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The product predicted from the third open reading frame, positions 3643 to 4416, contains all of tryptic peptides that were sequenced of
chlorocatechol 1,2-dioxygenase (Table 2; Fig. 3). The gene was thus
designated clcA, although the deduced N-terminal amino acid
sequence differed in 10 of 26 positions from the previously published,
obviously incorrect N-terminal sequence of the purified protein
(43). ClcA shows high sequence similarities to bacterial catechol and chlorocatechol 1,2-dioxygenases: 38.9 to 40.5% identical positions with Rhodococcus or Arthrobacter CatA
(in the alignment of Fig. 6), 29.2 to
33.3% with catechol 1,2-dioxygenases of -proteobacteria, and 34.1 to 39.5% identical positions with chlorocatechol dioxygenases of
proteobacterial plasmids. The amino acids that have been reported to be
involved in iron binding (28, 41) are also conserved in the
sequence predicted for chlorocatechol 1,2-dioxygenase of strain 1CP.
The calculated molecular mass of ClcA is 28,952 Da, which is consistent
with calculated molecular masses of other chlorocatechol dioxygenases
(27.6 to 29.0 kDa). The rhodococcal ClcA thus does not seem to be
significantly shorter than its counterparts from gram-negative strains
as suggested by Maltseva et al. (43), who reported to have
determined a molecular mass of 26.5 kDa for the purified enzyme by
SDS-polyacrylamide gel electrophoresis.
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FIG. 6.
Sequence alignment of catechol 1,2-dioxygenases (CatA
and PheB) and chlorocatechol 1,2-dioxygenases (ClcA, TcbC, TfdC, and
TfdCII) as calculated by the CLUSTAL program. The numbering
above the sequences refers to positions in the alignment, not in single
sequences. Amino acids in which at least 12 of the 13 sequences are
identical are highlighted. Amino acids that are identical in all
catechol but different in all chlorocatechol 1,2-dioxygenases (or vice
versa) are shaded. Histidine and tyrosine residues that were previously
reported to be involved in iron binding (28, 41) are
indicated by arrows. Accession numbers and references for the published
sequences: TfdCII, U16782 (67); TfdC of
pEST4011, U32188 (38); ClcA of pAC27, M16964
(20); TcbC, M57629 (69); TfdC of pJP4, M35097
(52); CatA R. opacus 1CP, X99622 (17);
CatA R. erythropolis AN-13, D83237 (47); CatA
Arthrobacter sp. mA3, M94318 (14); CatA A. calcoaceticus ADP1, M76991 (49); CatA for phenol
degradation by A. calcoaceticus NCIB8250, Z36909
(15); CatA P. putida PRS2000, U12557
(35); PheB Pseudomonas sp. EST1001, M57500
(37). Two sequences of catechol 1,2-dioxygenases from
Pseudomonas strains (48) which are very similar
to the sequence of CatA from P. putida PRS2000 have been
omitted for clarity.
|
|
The fourth open reading frame, between positions 4429 and 5187, represents clcD, the gene of the dienelactone hydrolase. All tryptic peptides obtained from the purified enzyme occur within the
predicted sequence (Table 2; Fig. 3). The calculated molecular mass of
the clcD gene product (27,304 Da) is somewhat lower than the
one (30 kDa) determined for the purified protein (44). With the dienelactone hydrolases TfdE of pJP4, TcbE of pP51, and ClcD of
pAC27, ClcD from Rhodococcus shares between 17.9 and 22.2% identical positions in the alignment of Fig.
7. This is considerably less than the
respective scores obtained for comparisons of chlorocatechol 1,2-dioxygenases or chloromuconate cycloisomerases from the same sources. The protein predicted from clcD was found to be
most similar to the dienelactone hydrolases TfdE of pEST4011 and
TfdEII of module 2 on pJP4, with which it shares 30.0 and
31.1% identical positions, respectively. Thus, while the rhodococcal
dienelactone hydrolase in the dendrogram of Fig.
8 resides on the same branch as two
proteobacterial enzymes, TfdE of pEST4011 and TfdEII of module 2 on pJP4, the sequence similarity to them is still
significantly less than the similarity between the rhodococcal
chloromuconate cycloisomerase or chlorocatechol 1,2-dioxygenase and
their proteobacterial counterparts. The catalytic triad residues
identified for ClcD of pAC27 (50) are also contained in ClcD
from Rhodococcus (Fig. 7).
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FIG. 7.
Sequence alignment of dienelactone hydrolases as
calculated by the CLUSTAL program. Numbers above the sequences refer to
positions in the alignment, not in individual sequences. Amino acids in
those positions in which at least five of the six sequences are
identical are highlighted. Presumed catalytic triad residues
(50) are indicated by arrows. Accession numbers and
references for the published sequences: TfdEII, U16782
(67); TfdE of pEST4011, U32188 (38); ClcD of
pAC27, M16964 (20); TcbE, M57629 (69); TfdE of
pJP4, M35097 (52).
|
|
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FIG. 8.
Dendrograms illustrating sequence similarities between
proteins involved in catechol and chlorocatechol catabolism. (A)
Catechol and chlorocatechol 1,2-dioxygenases; (B) muconate and
chloromuconate cycloisomerases; (C) dienelactone hydrolases; (D)
LysR-type regulatory proteins. The dendrograms were calculated by the
PHYLIP program package (19) based on CLUSTAL alignments of
the sequences in Fig. 4 to 7 and the respective outgroup sequences. For
the sequences used in Fig. 4 to 7, the resulting alignments were very
similar but, close to some gaps, not quite identical to those shown.
Numbers on the branches indicate the frequency (percentage) with which
the corresponding cluster occurred during bootstrap analyses. They show
that the affiliation of a certain protein to one of the major groups
could be deduced with great confidence. The exact branching pattern of
these major groups, in contrast, as well as the branching within the
groups is not certain, as indicated by low bootstrap numbers. The
dendrograms for cycloisomerases and dienelactone hydrolases were
calculated from the complete alignments (with the exception that the
amino acids in positions 3 to 38 of "ORF2" of
Methylobacterium extorquens were omitted). For the
dioxygenases, only positions 140 to 258 of the alignment in Fig. 6, and
for the regulators, only positions 1 to 217 of the alignment in Fig. 5,
were considered. All dendrograms are drawn to the same scale with
respect to evolutionary distance (in centimeters per unit branch
length). Gray branches represent enzymes which are specific for
chlorocatechol catabolism; the position of the transition from black to
gray was chosen arbitrarily. Functions and accessions numbers of the
proteins used as outgroups: PcaG and PcaH, and  subunits of
protocatechuate 3,4-dioxygenases, of A. calcoaceticus
(A. cal.) (M33798), Burkholderia cepacia
(M30791), P. putida (L14836) and R. opacus
(AF003947) TftH, hydroxyquinol 1,2-dioxygenase, of B. cepacia (U19883); HadC, hydroxyquinol 1,2-dioxygenase, of
Ralstonia pickettii (D86544); GalD, galactonate dehydratase,
of E. coli (L10328 and U19577); SpaA, protein possibly
involved in the metabolism of signalling lactones, of
Streptomyces coelicolor (X94190); MdlA, mandelate racemase,
of P. putida (J05293); AaaR, N-acyl amino acid
racemase, of Amycolatopsis sp. (D30738); IlvR, regulator of
isoleucine and valine synthesis, of Caulobacter crescentus
(L24392); CynR, regulator for cyanate detoxification, of E. coli (M93053); AlsR, acetoin synthesis regulator, of
Bacillus subtilis (L04470); XapR, xanthosine catabolic
regulator, of E. coli (X73828); Usf protein, hypothetical
protein, of Aquifex pyrophilus (U17575); "ORF2,"
hypothetical protein, of M. extorquens (U72662); "ClcD,"
hypothetical protein homologous to dienelactone hydrolases, of
Synechocystis sp. PCC6803 (D90904); "DLH," hypothetical
protein homologous to dienelactone hydrolases, of
Azospirillum brasiliense (X67216).
|
|
A fifth open reading frame (ORF5; bases 5628 to 6356) was
detected 441 bp downstream of clcD. Its predicted gene
product shows significant sequence similarity to putative
transposition-related proteins, especially to those of
Tn4811 from Streptomyces lividans 66 (7) (42.2% identical positions) and of IS1031C
from Acetobacter xylinum (9) (38.0% identical
positions). Comparison of the sequences of the inverted repeats of
IS1031C to the sequence in Fig. 3 indicated that the left
inverted repeat is most similar (10 out of 21 bases identical) to the
segment directly following the stop codon of ORF5 (positions 6357 to
6377). This corresponds to the arrangement in IS1031C. The
right inverted repeat is most similar (8 out of 21 bases identical) to
a segment of the intergenic region between clcB and
clcR (positions 2002 to 2022). Comparison of the R. opacus 1CP sequences of the two regions to each other revealed
that they form an imperfect inverted repeat as indicated in Fig. 3.
A hairpin structure could be detected between catR and
catA, suggesting that the presumed clcR gene
might be transcribed independently from the clcAD genes
(Fig. 3).
| |
DISCUSSION |
The chlorocatechol degradative pathways which are represented by
the clcR,ABDE gene cluster of plasmid pAC27
(8, 20), by the tfdT,CDEF cluster
(module 1) of pJP4 (40, 52), and by the
tcbR,CDEF cluster of pP51 (69, 70)
diverged from a common ancestral pathway already adapted for
chlorocatechol catabolism (58). This conclusion could be
drawn basically from two sorts of evidence. (i) The proteins encoded by
the genes mentioned above are more similar to each other than to their
counterparts in catechol degradation or to enzymes of other pathways.
Correspondingly, they belong to the same branches in all four
dendrograms depicted in Fig. 8. (ii) The three gene clusters referred
to above show a marked similarity (Fig.
9). All three consist of a LysR-type regulatory gene divergently transcribed from an operon
comprising, in that order, genes for a chlorocatechol 1,2-dioxygenase,
a chloromuconate cycloisomerase, a dienelactone hydrolase,
and a maleylacetate reductase, with an additional ORF between the
cycloisomerase and the hydrolase genes of pAC27 and pP51. Since such a
similar genetic structure is unlikely to have evolved two or more times
independently, it should have occurred prior to the divergence of the
lines giving rise to the gene clusters now present on pAC27, pJP4, and
pP51.
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|
FIG. 9.
Structures of gene clusters for catechol and
chlorocatechol catabolism. Homologous genes are shaded in the same way.
Functions of the proteins encoded by the genes are evident from Fig. 1.
For tfdR of pEST4011, see the legend to Fig. 5. The
information for this figure was compiled from references given in a
previous review (58) as well as from references 17,
35, 38, 40, 55, and 67.
|
|
In concordance with our hypothesis derived from biochemical evidence
(63), the sequences of all four rhodococcal proteins involved in chlorocatechol degradation differed considerably from those
of their protobacterial counterparts, but still proved to be homologous
to the respective proteins of catechol and other chlorocatechol
pathways (Fig. 4 to 8). In fact, in the dendrograms which illustrate
the relatedness of the respective gene products, the
Rhodococcus proteins represent branches separate from those of the corresponding proteins from proteobacteria (Fig. 8). In accordance with the sequence differences, the structure of the chlorocatechol gene cluster of strain 1CP also differs from those of
pAC27, pP51, and module 1 of pJP4 (Fig. 9). The cycloisomerase gene
clcB is transcribed divergently from
clcR,AD, and a maleylacetate reductase gene could
not be detected in this gene cluster and was cloned on a separate
fragment (61). Thus, the organization of the genes does not
provide any indication that the Rhodococcus pathway may have
evolved from the same origin as the chlorocatechol pathways of the
plasmids pAC27, pP51, and pJP4 (module 1).
The deep branching of the enzymes and regulatory proteins of
chlorocatechol pathways in Fig. 8 challenges the general opinion that
catechol catabolism evolved first and then gave rise to chlorocatechol catabolism. However, the two different known branches of catechol degradative pathways, from gram-positive bacteria on the one hand and
from -proteobacteria on the other, have one feature in common: catC directly follows catB (Fig. 9). This feature
is also conserved in R. eutropha, a -proteobacterium
(32). Since the catC product, muconolactone
isomerase, is an enzyme characteristic of catechol catabolism (Fig. 1),
this conserved structure suggests that the catechol pathway has indeed
evolved first. This conclusion is consistent with aromatic compounds,
which give rise to catechol during their degradation, being more common
in nature than chloroaromatic compounds that are degraded via
chlorocatechols. Thus, according to present knowledge, chlorocatechol
degradation did in fact evolve from catechol degradation. And
obviously, it did so independently in gram-positive bacteria and
proteobacteria, that is, by functionally convergent evolution.
The sequences of proteobacterial dienelactone hydrolases are known to
be so dissimilar to those of their counterparts in catechol pathways,
the 3-oxoadipate enol-lactone hydrolases, that recruitment of a
dienelactone hydrolase from a preexisting pathway other than for
catechol or protocatechuate turnover had to be postulated (58). Given that the Rhodococcus chlorocatechol
pathway evolved independently from that of pAC27, pP51, and pJP4
(module 1), it was considered possible that Rhodococcus
found a completely different solution for lactone hydrolysis. It was
therefore interesting to find that ClcD of strain 1CP is, in fact,
related to other dienelactone hydrolases and not, for example, to
3-oxoadipate enol-lactone hydrolases. However, in contrast to the
chlorocatechol 1,2-dioxygenase and chloromuconate cycloisomerase of
R. opacus 1CP, its dienelactone hydrolase resides on the
same branch of the dendrogram as two putative isofunctional enzymes of
proteobacterial origin (Fig. 8C). These putative dienelactone
hydrolases are encoded by plasmid pEST4011 and by a second
chlorocatechol module on pJP4, respectively (38,
67 [U16782]). The respective catabolic genes have
only very recently been characterized, and no biochemical evidence has
yet been reported for the function of either of the putative
dienelactone hydrolases. But even if one accepts that these gene
products are dienelactone-hydrolyzing enzymes, their relatively close
evolutionary relationship to the dienelactone hydrolase of R. opacus 1CP does not call into question the conclusion that the
chlorocatechol pathway of this strain evolved independently from that
of proteobacterial plasmids. Considering that the absolute evolutionary
distance between Rhodococcus ClcD and TfdE of pEST4011 or
TfdEII of pJP4 is even greater than that between the major groups of dioxygenases and cycloisomerases, a plausible interpretation of the similarity pattern of the dienelactone hydrolases would be that
similar enzymes and their genes were independently recruited into the
gene clusters of pEST4011 and module 2 of pJP4 on the one hand and
R. opacus 1CP on the other.
It is interesting that while the putative dienelactone hydrolases of
pEST4011 and module 2 of pJP4 are relatively similar to the
Rhodococcus enzyme, the respective chlorocatechol
1,2-dioxygenases are more closely related to the other proteobacterial
dioxygenases (Fig. 8A). The latter is also true for the LysR-type
regulator TfdR of pJP4 (46, 74) and for a presumed analogous
regulator which may be deduced from the reported sequence of pEST4011
when allowing for one frameshift (Fig. 8D). As argued above, the
ancestral chlorocatechol gene cluster from which those of pAC27, pP51,
and module 1 of pJP4 diverged must be assumed to have included all necessary genes, among them those coding for chloromuconate
cycloisomerase and dienelactone hydrolase. Since the dioxygenases
of pEST4011 and of module 2 of pJP4 diverged from that same origin
(Fig. 8A), they should, at some time, have been associated with
cycloisomerases and hydrolases closely related to those of pAC27, pP51,
and module 1 of pJP4. By some sort of gene shuffling, the hydrolase
genes have apparently been replaced by those more closely related to the corresponding Rhodococcus gene. A cycloisomerase gene
has so far not been found in the gene cluster of pEST4011. The presumed chloromuconate cycloisomerase of module 2 of pJP4, TfdDII,
might even represent a new branch of cycloisomerizing enzymes (Fig. 8B). This, however, must be considered speculation because of the
absence of biochemical data on TfdDII.
Not only with respect to the evolution of whole pathways but also for
the constituting groups of enzymes, the sequence information from
R. opacus 1CP bears potentially significant new information. Comparison of the dioxygenase sequences revealed that even though they
represent different evolutionary groups, the chlorocatechol 1,2-dioxygenases of R. opacus and of proteobacterial
plasmids are considerably shorter at the N termini than are catechol
1,2-dioxygenases. It would be interesting to see whether this feature
influences the catalytic properties. Especially informative should be
those positions in the dioxygenases and cycloisomerases in which the chlorocatechol enzymes of Rhodococcus and proteobacteria
carry the same amino acids but different ones than the respective
catechol enzymes (Fig. 4 and 6). These positions either may have been
conserved or may have been gained independently because of their
importance for the turnover of chlorinated substrates. Based on
structural data of muconate and chloromuconate cycloisomerases
(30, 33), we have previously identified some of the amino
acids relevant for substrate specificity by using site-directed
mutagenesis (73). The occurrence of functionally convergent
evolution should allow us to obtain new insight into the adaptations
which are necessary at the molecular level to yield an enzyme with
altered catalytic properties.
We are indebted to H.-J. Knackmuss for valuable discussions and
for making it possible for us to do this work. We thank H. Weber and R. Getzlaff for protein and peptide sequencing, R. Schmid for the
opportunity to use an automated DNA sequencer, and S. Bürger as
well as S. Lakner for performing the DNA sequencing. We are grateful to
W. Reineke and S. R. Kaschabek for a gift of cis-dienelactone.
The work was funded by a fellowship of the
Landesgraduiertenförderung to D.E. and by grants from the
Deutsche Forschungsgemeinschaft.
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Abstract
Introduction
