Positive Selection for Mutations Affecting Bioconversion of Aromatic Compounds in Agrobacterium tumefaciens: Analysis of Spontaneous Mutations in the Protocatechuate 3,4-Dioxygenase Gene

doi:10.1128/JB.182.21.6145-6153.2000

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Journal of Bacteriology, November 2000, p. 6145-6153, Vol. 182, No. 21
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Positive Selection for Mutations Affecting Bioconversion of Aromatic Compounds in Agrobacterium tumefaciens: Analysis of Spontaneous Mutations in the Protocatechuate 3,4-Dioxygenase Gene

Donna Parke^*

Department of Molecular, Cellular and Developmental Biology, Yale University, New Haven, Connecticut 06520-8103

Received 17 February 2000/Accepted 16 August 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

A positive selection method for mutations affecting bioconversion of aromatic compounds was applied to a mutant strain ofAgrobacterium tumefaciens A348. The nucleotide sequence of theA348 pcaHGB genes, which encode protocatechuate 3,4-dioxygenase(PcaHG) and $beta$ -carboxy-cis,cis-muconate cycloisomerase (PcaB) forthe first two steps in catabolism of the diphenolic protocatechuate,was determined. An omega element was introduced into the pcaBgene of A348, creating strain ADO2077. In the presence of phenoliccompounds that can serve as carbon sources, growth of ADO2077is inhibited due to accumulation of the tricarboxylate intermediate.The toxic effect, previously described for Acinetobacter sp.,affords a powerful selection for suppressor mutations in genesrequired for upstream catabolic steps. By monitoring loss of themarker in pcaB, it was possible to determine that the formationof deletions was minimal compared to results obtained with Acinetobactersp. Thus, the tricarboxylic acid trick in and of itself does notappear to select for large deletion mutations. The power of theselection was demonstrated by targeting the pcaHG genes of A.tumefaciens for spontaneous mutation. Sixteen strains carryingputative second-site mutations in pcaH or -G were subjected tosequence analysis. All single-site events, their mutations revealedno particular bias toward multibase deletions or unusual patterns:five ( $-$ 1) frameshifts, one (+1) frameshift, one tandem duplicationof 88 bp, one deletion of 92 bp, one nonsense mutation, and sevenmissense mutations. PcaHG is considered to be the prototypicalferric intradiol dioxygenase. The missense mutations served tocorroborate the significance of active site amino acid residuesdeduced from crystal structures of PcaHG from Pseudomonas putidaand Acinetobacter sp. as well as of residues in other parts oftheenzyme.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The $beta$ -ketoadipate pathway consists of two convergent branches that convert aromatic compounds into tricarboxylic acid (TCA)cycle intermediates. The protocatechuate (3,4-dihydroxybenzoate)branch of the pathway, widespread among soil bacteria, servesas a common catabolic destination for quinate, shikimate, andnumerous aromatic substrates, including its diphenolic namesake(Fig. 1). Because of its ubiquity in soil microbes, biochemicalcharacterization, and role as a common track in the biotransformationof diverse aromatic compounds, the $beta$ -ketoadipate pathway has beena fruitful subject of investigation in several species of bacteria(18, 30).

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FIG. 1. Steps for the conversion of 4-hydroxybenzoate, quinate, and protocatechuate to intermediates of the TCA cycle, shown above the organization of A. tumefaciens A348 genes required for initial steps in the catabolic pathway. Spotlights link enzymes with their encoding genes; pcaQ encodes an activator of pcaDCHGB expression. Arrows denote units and directions of transcription. Enzymes: PobA, 4-hydroxybenzoate hydroxylase; PcaHG, protocatechuate 3,4-dioxygenase; PcaB, $beta$ -carboxy-cis,cis-muconate cycloisomerase; PcaC, $gamma$ -carboxymuconolactone decarboxylase; PcaD, $beta$ -ketoadipate enol-lactone hydrolase; PcaIJ, $beta$ -ketoadipate succinyl coenzyme A (CoA) transferase; PcaF, $beta$ -ketoadipyl-CoA thiolase.

A positive selection method has been described for a derivative of Acinetobacter sp. strain ADP1 that contains the pcaBDK1deletion (16, 17). Lacking two enzymes required for growthat the expense of protocatechuate, the strain cannot grow at theexpense of the compound or of substrates that feed into it. Buildupof inhibitory levels of the intermediate $beta$ -carboxy-cis,cis-muconatewas deduced to lead to the additional failure of the strain togrow on nonselective media in the presence of added aromatic substrates.The ability to screen for secondary mutant strains that can reducetoxic levels of the tricarboxylic acid has proved to be a powerfulexperimental tool (7, 12). Genetic analysis of secondarymutant strains derived from the $Delta$ pcaBDK1 strain, ADP500, revealedthat many of them contained large deletions in the pca regionof the chromosome (12).

Characterization of the pca genetic region of the tumorigenic plant pathogen Agrobacterium tumefaciens A348 (30) has providedan opportunity to investigate the role of aromatic compound degradationin the process of wound colonization. Plant wound sites are likelyto be particularly rich in aromatic compounds, which can be toxic.It is not known whether the ability to degrade particular aromaticcompounds contributes to successful colonization of the plantwound by A. tumefaciens nor to what extent the aromatic constituentsof the wound environment exert a toxic effect. Obtaining a mutantthat is particularly sensitive to the presence of aromatic growthsubstrates would facilitate efforts to understand this aspectof colonization and could be used to generate second-site mutantsthat would complement such a study. Therefore, this investigationwas undertaken to determine whether the positive selection methodused with Acinetobacter could be applied successfully to A. tumefaciens.

The outcome of the pcaB-tricarboxylic acid positive selection method is likely to depend on a number of variables which includegene organization and regulation. In Acinetobacter sp. strainADP1, the enzyme that produces the potentially toxic tricarboxylicacid is encoded by the last two genes of the pcaIJFBDKCHG transcript(8); its substrate, protocatechuate, is a coinducer of thetranscript. In A. tumefaciens A348, the product of this enzymaticreaction, carboxymuconate, is the coinducer of the pcaDCHGB transcript(Fig. 1B) (30). Because pcaB lies downstream of pcaHG, a selectableelement could be inserted into it without terminating transcriptionof pcaHG.

The initial target of spontaneous mutation in A. tumefaciens was protocatechuate 3,4-dioxygenase (PcaHG). This enzyme catalyzesan intradiol cleavage of the aromatic ring by oxygen. High-resolutioncrystal structures of the dioxygenases from Pseudomonas putida(27) and Acinetobacter sp. (45) have been determined. AlthoughPcaHG quarternary structures from diverse microbes vary, the unitpromoters have been found to be the same: a heterodimer comprisedof an $alpha$ and a $beta$ chain, encoded by pcaG and pcaH, respectively,and a nonheme ferric ion. With the active site located at the $alpha$ / $beta$ interface, critical active site residues are contributed byboth subunits, but only the $beta$ subunit contains iron ligands (26).

The ability of an Agrobacterium radiobacter strain to oxidize 4-sulfocatechol was shown to be mediated by a novel PcaHG (14).The holoenzyme complex of the sulfocatechol dioxygenase was muchsmaller than that of most characterized PcaHGs (23). Informationgleaned from the sequence and mutational analysis of the A. tumefaciensA348 protein should be relevant to the ongoing study of the relateddioxygenases of A. radiobacter.

The primary goal of this investigation was to discover whether the pcaB mutant trick which works so well in Acinetobacterwould be effective in a different genetic background. An additionalgoal was to assess the types of spontaneous mutations generatedby exposure to toxic levels of carboxymuconate. To this end, thespontaneous pcaH or pcaG mutations generated under the toxic selectionconditions were catalogued without bias with respect to particularlydesirable types, such as missense mutations. As an outcome ofthe work, a number of novel PcaHG mutants were isolated. Althoughprevious work established the order pcaH-pcaG-pcaB in A. tumefaciensA348, only a small segment of the former two genes was sequenced(34). This communication presents a sequence analysis of thethree genes in theirentirety.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Molecular techniques and growth media. Standard methods of molecular biology were used (3, 41). Conjugations were carried out as previously described (32).A. tumefaciens cultures were grown in Luria-Bertani medium (43)or minimal medium (35) at 30°C. Minimal medium was supplementedwith carbon source(s) at the following concentrations: succinateor arabinose at 10 mM, quinate at 5 mM, or 4-hydroxybenzoate at1.5 mM. Luria-Bertani medium, used for growth of Escherichia coliat 37°C, was supplemented with one or more of the antibioticsampicillin, spectinomycin, streptomycin, and tetracycline at concentrationsof 80, 40, 20, and 12.5 µg ml¹, respectively. Minimal medium prepared for A. tumefaciens includedampicillin, spectinomycin, and tetracycline at concentrationsof 100, 125, and 1.25 µg ml¹, respectively, asnecessary.

Construction and characterization of a pcaB mutant strain. Table 1 lists strains and plasmids integral to the project. Sequence analysis identified a unique AgeI site 0.43 kb fromthe 5' end of the pcaB gene in pARO523 (Fig. 2). An $Omega$ transcriptiontermination element with compatible ends was ligated into thesite, forming pARO579 (Fig. 2). The pcaB:: $Omega$ mutation was introducedinto A. tumefaciens A348 through conjugation with E. coli S17-1(pARO579).The mating mix was plated onto agar-solidified minimal mediumcontaining succinate plus spectinomycin. Spc^r colonies were screened for absence of the vector Ap^r marker, and a pcaB:: $Omega$ candidate was purified. The pcaB:: $Omega$ isolate,strain ADO2077, failed to grow at the expense of aromatic compounds,and it was maintained on medium free of aromatic or hydroaromaticcompounds. Location of the $Omega$ element was verified by PCR usingprimers flanking the site of insertion, described below, followedby gel electrophoresis. As expected, introduction of plasmid pARO4carrying a heterologous pcaB restored the ability of ADO2077 togrow at the expense of quinate. Furthermore, introduction of eitherpARO561 or pARO580 (Fig. 2) restored ADO2077 to a quinate⁺ phenotype.

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TABLE 1. Bacterial strains and plasmids used

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FIG. 2. Subclones used in construction of A. tumefaciens strain ADO2077 and analysis of mutant strains. ADO2077 accumulates carboxymuconate in the presence of protocatechuate or certain of its metabolic precursors. Beneath a map of chromosomal pca genes are subclones used to sequence, to create the pcaB:: $Omega$ mutation, and to analyze ADO2077 as well as secondary mutant strains derived from it. The small arrows, not drawn to scale, shown under pcaC and pcaB represent the locations of primers ATPCAH2 (on the left) and DP523HF2 (on the right) used in PCR amplification of mutant pcaHG sequences. The distance from the 3' end of pcaB to the PstI site is 1.7 kb, and this DNA encodes a set of genes with homology to ABC-type transporter genes (Parke, unpublished).

Growth tests with ADO2077 and A348 were conducted in liquid minimal medium containing succinate to determine the sensitivityof ADO2077 to 4-hydroxybenzoate. Each replicate set of experimentsoriginated from a single colony inoculated into liquid minimalmedium containing succinate. A diluted, overnight culture of thosecells was used as a source of approximately 10⁴ cells, which were inoculated into 5 ml of liquid minimal mediumcontaining succinate alone or succinate plus different concentrationsof 4-hydroxybenzoate. The low inoculum was used to minimize thecontribution of suppressor mutants to the population of ADO2077cells. Growth of cultures exposed to succinate alone was closelymonitored. When those cells reached stationary phase, which tookthe same length of time for A348 and ADO2077 cells, growth yieldswere determined for all conditions in each replicate set of tubes.Due to low growth yields under some conditions and the presenceof a compound(s) that absorbed at 600 nm, it was necessary toobtain viable counts for the ADO2077 cells. Viable counts werealso made for one replicate of the wild-type cells, but sincethe correlation between optical density at 600 nm and viable countwas consistent for them, growth yields could be determined byoptical density and converted into viable counts for other replicatesof thesecells.

Second-site suppressor mutation frequency was measured by spreading an overnight culture grown at the expense of succinateonto selective medium. The same cells were diluted, and theirviable count was determined on a nonselective medium. Suppressormutation frequency was the fraction of the total viable countthat appeared as CFU on the selective medium at 30°C. Colonieswere counted after 5 days on succinate plus 1.5 mM 4-hydroxybenzoateand after 3 days on arabinose plus the aromaticcompound.

Isolation of pcaH or pcaG secondary mutant strains. ADO2077 was plated onto minimal medium containing succinate plus 1.5 mM 4-hydroxybenzoate. Protocatechuate itself was notused in the initial selection because of its instability (7).Colonies that appeared to be resistant to 4-hydroxybenzoate werepurified. Further screening for pcaH or -G mutants involved testingeach isolate for accumulation of protocatechuate upon exposureto 4-hydroxybenzoate. For this test, minimal medium containing4-hydroxybenzoate and succinate was supplemented with p-toluidine,a chromophore specific for diphenolics (31). In addition, isolateswere rechecked on the medium used for the initial selection aswell as screened on medium supplemented with protocatechuate ratherthan 4-hydroxybenzoate. Presumptive pcaH or -G secondary mutantstrains, isolated at 30°C, were assessed for heat sensitivityby screening at 21°C. Strains that had preserved the Spc^r $Omega$ marker and had accumulated protocatechuate were mated withE. coli S17-1(pARO523) and plated onto selective medium with quinateas the sole carbon source. An independent analysis was carriedout by introducing pARO561. Strains for which pARO523 and pARO561(Fig. 2) restored the ability to grow at the expense of quinateand 4-hydroxybenzoate were presumed to be pcaH or -G mutants.The pcaHG region in each mutant was recovered from the chromosomeby PCR amplification as described below, and both genes weresequenced.

Correction of the pcaB:: $Omega$ mutation in strains carrying secondary mutations in pcaH or -G. To discern the effect of a pcaH or -G mutation on the phenotype of Agrobacterium in the absence of the pcaB mutation, it wasdesirable to correct the latter mutation. In Acinetobacter strainADP500, it is possible to select for replacement of $Delta$ pcaBDK1 withwild-type genes because the strain also contains a mutation incatD. The latter gene encodes an enzyme that is isofunctionalwith PcaD and that catalyzes a reaction in the dissimilation ofbenzoate; expression of pcaD is sufficient to allow catD mutantcells to grow at the expense of benzoate (12, 21). Given thatA. tumefaciens has a different gene organization, correction ofthe pcaB mutation required a differentapproach.

Replacement of pcaB:: $Omega$ with the wild-type gene was carried out on eight strains with missense, deletion, or insertion mutationsin pcaH or -G. Introduction of pARO2 provided a heterologous PcaHGto compensate for the PcaH or -G mutation. A. tumefaciens strainscarrying pARO2 were mated with E. coli S17-1(pARO580). Agrobacteriumcells that had acquired the pcaB marker of pARO580 (Fig. 2) andretained pARO2 were able to grow at the expense of quinate. Followingcolony purification on solidified minimal medium containing quinateplus tetracycline, colonies were screened for the absence of thepARO580 Ap^r marker and the pcaB $Omega$ marker. Ap^s Spc^s Tc^r quinate⁺ colonies were cultured in nonselective liquid medium to curethem of pARO2. Following subculture, Tc^s strains were presumed to retain the pcaH or -G mutation, withthe wild-type pcaB restored. Strains carrying only the pcaH or-G mutation exhibited varying, reduced growth onquinate.

PCRs. Template DNA was prepared according to directions supplied with InstaGene Matrix (Bio-Rad). PCR conditions for the primerpair ATPCAH2 and DP523HF2 were 97°C for 3 min, 30 cycles of denaturingat 94°C for 1 min, annealing at 59°C for 30 s, and elongationat 72°C for 1 min. Conditions for the primer set ATPCAB and DP523HF1were similar except for annealing at 65°C for 30 s and elongationat 72°C for 2 min 30 s. The Keck Biotechnology Resource Lab atYale University synthesized PCR primers. Primers ATPCAH2 (5'-CCGCCAACCACGCTTTCAAG-3'),located near the 3' end of pcaC, and DP523HF2 (5'-CGCATCTGCCGCACGAGTT-3'),located in pcaB, were used to amplify pcaH or-G mutant strains,and their locations are shown in Fig. 2. Primers ATPCAB (5'-CG C A G G C G C A G G T G G G A A C A G-3') and DP523HF1 (5'-CGCGATATCCTGCCCGAACTT-3')served to amplify the region encompassing the pcaB:: $Omega$ mutation.When generating template from a mutant strain for sequence analysis,usually several independent PCRs were performed, the reactionproducts were pooled, and a QIAquick PCR purification step (QiagenInc.) preceded DNAsequencing.

DNA sequencing. Analysis of A. tumefaciens pcaB makes reference to sequence data for Sinorhizobium meliloti generated by S. R. Long and colleaguesat the Department of Biological Sciences, Howard Hughes MedicalInstitute, and the Stanford DNA Sequencing and Technology Center(http://cmgm.stanford.edu/~mbarnett/1xgenome.htm). ABI PRISM terminatorcycle sequencing with AmpliTaq DNA polymerase, conducted at theYale Keck Biotechnology Resource Lab, was employed to sequenceboth strands of the pcaHGB region by primer walking with pARO523or pARO561 as atemplate.

Nucleotide sequence accession number. The DNA sequence for the pcaQDCHGB genes from A. tumefaciens A348 has been deposited in the GenBank database under accessionno. U32867.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Evidence that the pca gene cluster is chromosomal in A. tumefaciens A348. Although it was previously established that the pca genetic region of A348 was not located on its Ti plasmid (36), it remainedpossible that a cryptic plasmid, pAtC58, carried these sequences.Strain UIA5, which has a C58 chromosomal background similar tothat of A348 except for antibiotic resistance markers, is curedof pTi and pAtC58. However, it displayed the growth propertiesof A348 on minimal medium with quinate as the sole carbon source.Establishment of a chromosomal location of the pca genes in thisstrain is interesting in light of evidence that the genes forquinate and protocatechuate are located on the pSymb megaplasmidin the related bacterium S. meliloti (4). It remains to bedetermined whether the pca genetic region is on the circular orthe linear chromosome of A348 (13).

Sensitivity of the pcaB:: $Omega$ strain ADO2077 to 4-hydroxybenzoate. Figure 3 shows the growth yields of ADO2077 compared to its parental strain in the presence of increasing concentrations of4-hydroxybenzoate. Growth inhibition by 4-hydroxybenzoate wasimperceptible at 1 µM, was notable at 10 µM, and appeared to becomplete at 1 mM. On minimal medium plates containing succinate,4-hydroxybenozate caused total inhibition of cell growth at 1mM as well, and this was the minimum concentration required toscreen for suppressor mutants. Only extremely slow growth of singlecolonies was observed on solid media containing succinate plus10⁴ M aromatic compound. For comparison, the phenotype of Acinetobactersp. strain ADP853 (W. M. Coco and L. N. Ornston, Abstr. 97th Gen.Meet. Am. Soc. Microbiol., abstr. K-81, p. 355, 1997), a pcaBstrain, was examined. This strain was used rather than ADP500because its mutation is restricted to pcaB. A culture of ADP853was streaked on the same succinate plates containing differentconcentrations of 4-hydroxybenzoate. Formation of single coloniesof ADP853 was totally inhibited by 10 µM 4-hydroxybenzoate. Itshould be noted that cells recover from growth inhibition oncethe aromatic compound is removed. The viable cell concentrationin cultures exposed to 1 mM 4-hydroxybenzoate for the durationof the experiments shown in Fig. 3 remained stable (Fig. 3); however,the mechanism of carboxymuconate inhibition remains unknown.

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FIG. 3. Growth yields of pcaB mutant strain ADO2077 in the presence of different concentrations of 4-hydroxybenzoate (4-HB) relative to those of the parental strain A348. As detailed in Materials and Methods, the growth yields for each replicate set of conditions were determined when the cells grown in the presence of succinate alone reached full growth yield, and this occurred at about the same time for both A348 and ADO2077. Values for ADO2077 exposed to 10⁵, 10⁴, and 10³ M 4-hydroxybenzoate, difficult to gauge in the figure, are 2.4 × 10⁷, 3.2 × 10⁶, and 3.5 × 10³ CFU ml¹, respectively. The data presented are the means from three independent growth tests. The error bars represent standard error of the mean for each set of conditions.

Curiously, supplementation of minimal medium containing succinate or arabinose with the precursor substrate quinate (Fig.1) was not growth inhibitory to ADO2077. The rationale for thisresult may lie in feedback regulation of quinate dissimilation.The ADO2077 pcaB mutation was very stable: revertants did notarise out of a population of 3 × 10¹⁰ cells plated ontoquinate.

Characterization of pcaB:: $Omega$ strains which are resistant to 4-hydroxybenzoate. Resistant colonies appeared on plates of minimal medium containing succinate plus 1.5 mM 4-hydroxybenzoate at a frequencyof 5 × 10⁶ at 30°C. The colonies appeared significantly faster when arabinosewas substituted for succinate, but ultimately the frequency wasthe same. A similar frequency of resistant colonies was notedfor ADP853 on the same succinate plus 4-hydroxybenzoate medium,a reflection of the large number of potential targets for suppressormutations. The number of genes or genetic regions that could beresponsible for resistance to 4-hydroxybenzoate is limited, however(Fig. 1): the pob structural gene or its upstream regulatory gene,the pcaQ regulatory gene or the intergenic region upstream ofit, or the pcaH or pcaG structural gene. Strains later shown tobe pcaH or -G mutants excreted protocatechuate in the presenceof precursor substrate, they generally grew slower on a mediumcontaining 4-hydroxybenzoate than pob mutants, and they grew morerapidly than the latter strains on minimal medium supplementedwith protocatechuate. Mutations in pcaQ or the region betweenpcaQ and pcaD would accumulate protocatechuate as well, but thefollowing test distinguished pcaH or -G mutations from these.The final step was correction of the quinate phenotype by pARO523 and pARO561 (Fig. 2). The plasmids shouldnot restore the wild-type phenotype to a regulatory mutant. Useof pARO561 rules out the possibility that DNA beyond the HincIIsite contributed to the wild-typephenotype.

Strains resistant to 4-hydroxybenzoate were also screened for retention of the $Omega$ element which lies 0.46 kb downstream ofpcaG in ADO2077. Out of 120 purified isolates, only 2 had deletionsthat covered the region of the Spc^r insertion. Furthermore, every presumptive pcaH or -G mutant forwhich PCR amplification was carried out possessed the primer sequencesupstream and downstream of pcaHG (Fig. 2).

Sequence analysis of pcaB. The ATG start codon of the A. tumefaciens A348 pcaB gene is located 12 bp downstream of pcaG and 7 bp downstream of a putativeShine-Dalgarno sequence. The gene is 1,062 bp long, with a G+Ccontent of 63.6%. The HincII site shown in Fig. 2 is 73 bp beyondthe 3' end of pcaB. One half of an 8-bp stem palindrome precedesthe HincII site by 5 bp. A set of genes with homology to ATP-bindingcassette transporter genes lies downstream of pcaB; the firstopen reading frame of the set is 0.37 kb beyond the stop codonof pcaB (D. Parke, unpublisheddata).

The A348 PcaB sequence was subjected to BLAST analysis (2), and the top five scoring sequences were analyzed further bythe Clustal alignment method. Of the five, the A348 PcaB mostclosely resembled a PcaB-like sequence from P. putida (GenBankaccession no. 5091486) (39). Alignment by the Clustal methodrevealed 37% amino acid sequence identity of that strain againstthe A348 primary sequence. Since the functional enzymes from otherspecies are distant from that of A348 as well, the enzyme clearlytolerates extensivedivergence.

Homologs examined by the Clustal method included two P. putida strains (GenBank accession no. 2851427 and 5091486), Acinetobacterstrain ADP1 (GenBank accession no. 6093650), Bradyrhizobium japonicum(GenBank accession no. 6093651), and Rhodococcus opacus (GenBankaccession no. 2935026) (9, 21, 24, 46). Compared to theother five PcaBs, that of A348 is truncated at the C terminus.Relative to the Acinetobacter sp. strain ADP1 pcaB gene, it istruncated by 297 bp. One of the P. putida genes (GenBank accessionno. 2851427) is also divergent at the 3' end, being 135 bp shorterthan that of ADP1. The C-terminal 150 amino acid sequence of aputative PcaB was deduced from the preliminary database on S.meliloti. Alignment of the available C-terminal half of this proteinwith that of A348 revealed a sequence identity of 65%. The S.meliloti open reading frame ends two amino acids short of theA. tumefaciens sequence. The S. meliloti pcaB homolog was locatedon an 881-bp contig, and the end of the gene was about 200 bpfrom the end of the fragment. It should be noted that the presumed5' end of the pcaB gene was found on another contig just downstreamof pcaG in S. meliloti, as inA348.

Alignment of the additional C-terminal PcaB sequences of the other, divergent species reveals a number of conserved residues.Such conservation suggests that the C-terminal portion of thoseproteins is important and that compensatory mutations may havebeen required for functionality of the truncated A348cycloisomerase.

Sequence analysis of pcaHG. The sequence of A348 pcaHG, with a G+C content of 60.1%, and its deduced amino acid sequence are presented in Fig. 4. Thetranslational start of pcaH overlaps the last four bases of pcaC,and 5-bp upstream of it lies a putative Shine-Dalgarno motif inthe sequence GGAGGAG. The subunits share a common evolutionaryorigin (15, 26): Clustal alignment of the A. tumefaciens PcaHand PcaG revealed that 32% of the aligned residues of the $beta$ subunitare identical to those of the $alpha$ subunit.

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FIG. 4. Nucleotide and translated amino acid sequences of pcaH and pcaG from A. tumefaciens A348. The initiation codon of pcaG is boxed for clarity. Locations of mutations are shown above the wild-type sequence. Mutations include a deletion of G (pcaH2, pcaH3, pcaG4, and pcaG6), insertion of G (pcaG2), deletion of T (pcaH4), and the G-to-T transversion of pcaG8. Locations of missense mutations (pcaH5, pcaH6, pcaH7, pcaH9, pcaG3, pcaG5, and pcaG7) are underlined; the new base is shown above an arrow. Additional mutations are the 88-bp tandem duplication (2x) pcaH8, shown as a highlighted sequence, and the 92-bp deletion of pcaH10, denoted by over- and underlining. Asterisks mark the putative Shine-Dalgarno sequence for pcaG translation.

Alignment of the A. tumefaciens $alpha$ or $beta$ subunits with their respective homologs from seven other bacterial strains representingfour genera was made using Clustal analysis; the seven strainsare listed in the legend to Fig. 5. By this method, the A. tumefaciens $beta$ chain showed 59% identity with that of P. putida (GenBank accessionno. 1172050) and 58% with that of Acinetobacter (GenBank accessionno. 6174894). The $alpha$ subunits (GenBank accession no. 1172049 and6174893) were slightly more divergent, with values of 46 and 57.8%,respectively. By this measure, the A348 subunits resembled thoseof the other two species as much as or more than the latter tworesembled each other.

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FIG. 5. Conserved residues of A. tumefaciens A348 PcaG and PcaH sequences and amino acid substitutions caused by missense mutations. Oval balloons above the PcaG and PcaH sequences contain residues substituted in the mutant strains, next to the gene designations underlying the changes. Table 2 and Fig. 4 provide additional information on each mutation. The Clustal method of sequence alignment was applied to PcaG and PcaH chains from strain A348 and the following species and strains (with GenBank accession numbers in parentheses): Acinetobacter sp. strain ADP1 (6174893 and 6174894), Burkholderia cepacia (129711 and 129714), Pseudomonas marginata (4096596 and 4096595), P. putida NCIMB 9869 (4808515 and 4808514), P. putida ATCC 23975 (1172049 and 1172050), Pseudomonas sp. strain HR199 (4886556 and 4886555), and R. opacus (2935025 and 2935024) (6, 9, 7, 11, 15, 29, 48). Gaps introduced in the A348 PcaG sequence by Clustal alignments are not shown; however, none of the gaps are unique to A348. Shaded boxed residues are identical in all strains; unshaded boxed residues represent amino acids that are not necessarily identical in all strains but belong to the following related groups: residues with nitrogenous side chains (H, K, N, Q, R), acidic (D, E), small nonpolar (I, L, V), polar (S, T), or aromatic (F, W, Y). Amino acids boxed below the Agrobacterium sequences are identical in the aligned proteins of all other bacteria compared. Also shown below the A348 line are four residues implicated in binding Fe³⁺. To facilitate comparison with structurally characterized proteins, the numbering beneath the amino acid residues corresponds to published positions in P. putida and Acinetobacter sp. subunits (7, 27). Thus, the residues in PcaG are numbered $-$ 2 to 200 and those of PcaH are numbered 298 to 542, which necessarily differs from the numbering used in Fig. 4 and Table 2.

Spectrum of mutations in pcaH and pcaG. Unique spontaneous mutations were distributed along the nucleotide sequence of pcaH and pcaG (Fig. 4; Table 2). Two mutationswere exceptional, altering multiple base pairs: pcaH8, an 88-bptandem duplication; and pcaH10, a 92-bp deletion. Both mutationsresulted in frameshifts (Fig. 4; Table 2). Of the remaining 14mutations, 6 caused frameshifts; 5 were 1-bp deletions, and 1was a 1-bp duplication. The eight point mutations included one,pcaG8, that introduced a nonsense codon near the end of pcaG;the rest were missense mutations. In keeping with the relativenumbers of transition and transversion mutations in other systems(42), there were five of the former and three of thelatter.

There is evidence that spontaneous mutations are influenced by DNA context (1, 5, 12, 22, 25, 40). Interpretingthe role of short sequence motifs, minor and extended direct repetitions,palindromes, and quasi-palindromes in predisposing particularnucleotides to mutate will be facilitated by analysis of manymutations, occurring in different genetic contexts. Although thecollection of A. tumefaciens pcaH or -G strains is small, themutations were examined for examples of nucleotide sequence patternsthat might have contributed to their occurrence. For many mutations,alternative rationales could be proposed, and these were not strikinglypersuasive. It seems likely that many of the mutations representrare events in the panoply of screenable mutations. Of uncertainsignificance four of the five single-base-pair deletions lostthe third nucleotide in the short palindrome (or 2-bp repeat)5'-GCGC-3' (pcaH2, pcaH3, pcaG4, and pcaG6 [Fig. 4]). The pcaG4mutation also perfects an inverted repetition, 5'-GTGCGCGGCAC-3'with the deletion underlined. The fifth single-base-pair deletion,pcaH4, occurred at the 3' nucleotide in a 3-bp repeat, possiblydue to 5' to 3' slipped strand mispairing of the coding strand.Four of the missense mutations, considered the most common typesof transition mutations, may have arisen by base modification.Exposure of the pcaH5 nucleotide in the loop of a predicted palindrome(5'-GCGGC-4 nt-GCCGC-3') may have made it selectively vulnerabletomutation.

The wild-type sequence corresponding to the 88-bp duplication of pcaH8 has short, inverted repeats which span each gap juncture(5'-ACGGCGT-3' upstream and 5'-TTC GAA-3' or 5'-TCGAAGGCGA-3'downstream) as well as short palindromes at each end (5'-TGG CCA-3'upstream and 5'-GATCCGCTGATC-3' downstream). In addition, neareach endpoint is the direct repetition 5'-GGCG-3'. There is strongevidence that spontaneous deletions are promoted by short directidentities (1, 5). The 92-bp deletion of pcaH10 has a shortrepetition flanking each end (5'-C-A--G-CTGAT--C-C-3', where thedashes represent nonidentical bases) as well as very short invertedrepeats flanking the gap (5'-CAG-3' upstream and 5'-CTG-3' downstream[Fig. 4]). The fact that the pcaH8 duplication and pcaH10 deletionoverlap further suggests the mechanism of slipped mispairing:short, noncontiguous sequence repetitions in this region (forexample, five repeats of 5'-TGATC-3' or 5'-CGATC-3) may have contributedto stepwise misalignments or to intragap distance-shortening secondarystructures.

Analysis of missense mutations in PcaH and PcaG. As noted above, the degree of divergence of the A. tumefaciens protomer from that of the Pseudomonas and Acinetobacter homologsis similar to that of the latter two from each other. Thus, itis not unreasonable to apply information gleaned from crystalstructures of the Pseudomonas and Acinetobacter enzymes (27,45) to analysis of Agrobacterium PcaH or -G mutations. Conversely,certain spontaneous PcaH or -G mutations isolated in Agrobacteriummay corroborate inferences drawn from crystal structures and guidesite-directed mutagenesis of the structurally characterizedenzymes.

To provide a framework for analysis of the amino acid substitutions caused by the mutations, Clustal alignment of the $alpha$ and $beta$ chains, respectively, of six other bacterial species with thoseof A348 was made, and data from the alignments were used to createFig. 5. Numbering of residues below the A348 polypeptide sequencesin this particular figure is sequential from the $alpha$ to the $beta$ subunits,and it follows the numbering used for previous structural analysesin order to facilitate reference to them (7, 27). Consequently,the numbering referred to in the next paragraph does not followthe A. tumefaciens sequence nomenclature of Fig. 4 and Table 2.A few amino acids of the A. tumefaciens A348 subunits are differentfrom those conserved in the other sequences (for details see thelegend to Fig. 5). Reflecting the divergence statistics alreadymentioned, the $beta$ subunits required a negligible number of gaps(and none in the A. tumefaciens subunit) to achieve alignment;apparently less divergence was tolerated in the iron-binding subunit.

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TABLE 2. Strains with sequenced spontaneous mutations in pcaH and -G

In the A. tumefaciens protomer, residues critical to structure and function, such as the iron ligands Tyr408, Tyr447, His460,and His462 (27, 45), are conserved. Amino acids that interactdirectly with the substrate (Thr12, Pro15, Tyr16, Tyr324, Tyr447,Trp449, Arg457, and Ile491) are also strictly conserved as isGln477, which forms a critical hydrogen bond to Arg457 (28)(Fig. 5). An indentation in the substrate binding cavity has beenproposed to be the position from which oxygen interacts with theC-3/C-4 carbon of substrate (27, 28, 45). Residues Ala13(Gly13 in Acinetobacter), Gly14, Pro15, Tyr16, Val17, Trp400,Tyr408, His462, and iron form the minicavity. All of these residuesare conserved in the A. tumefaciensprotomer.

All but two of the amino acids altered in the A. tumefaciens mutants are different from those mutated in the PcaH and -G analysesof Acinetobacter (7, 12). The most striking validation ofthe efficacy of the pcaB positive selection technique and thescreening procedure used with A. tumefaciens is the location ofmutations pcaH6 and pcaH9 in the translated protein. In the pcaH6mutant ADO2091, Tyr447, an iron ligand that also rotates to interactwith protocatechuate, is converted to Ser447 (Fig. 5). Directedmutants at Tyr447 of the P. putida $beta$ chain were constructed tocorroborate its role in catalysis (10, 28). The pcaH9 mutant,ADO2093, has an R457H change (Fig. 5). It has been proposed thatArg457 stabilizes development of a negative charge on C-4 of protocatechuate,making it susceptible to nucleophilic attack by oxygen (28).An R457C mutation in Acinetobacter was isolated previously (12).Several residues, among them Gly14, are proposed to orient theactive site residue Pro15 so that it can interact with the aromaticring of the substrate (7, 27). Knockout mutation G14S inADO2098 (pcaG3) (Fig. 5) may compromise the active-site conformation.It may undermine the function of the putative oxygen-binding minicavitymentioned above aswell.

Although heat-sensitive mutants of PcaHG may be characterized by large changes in the denaturation temperature along withminor structural changes, some mutants active only at lower temperaturemay have an alteration in the active site rather than in theirstability (7). In ADO2092 (pcaH7), a P448L mutation led toa heat-sensitive phenotype. Pro448 helps to define the activesite pocket (45), and it contributes to the interface betweentwo protomers in the P. putida crystal structure (27). A secondheat-sensitive mutant, ADO2099 (pcaG5), has an A123T mutation.In Acinetobacter, a mutation of A123V (12) was also heat sensitiveand was interpreted to create structurally destabilizing van derWaals clashes (7).

Pointing to the value of augmenting comparative sequence alignments with spontaneous mutation analysis is the fact that twoof the A348 mutations occur at sites not strictly conserved indivergent PcaHGs. The site of the W129R mutation of ADO2100 (pcaG7)is occupied by Ser in the P. putida $alpha$ chain. Ser129 appears toform a main chain hydrogen bond with the conserved Glu69, whichforms one half of a specific charge pair at the $alpha$ / $beta$ interface(27). The other mutation in a nonconserved residue is V426Din ADO2090 (pcaH5), which has uncharged residues in the analogousposition in most of the other species' subunits. The mutationmay disrupt hydrophobic interactions: in the P. putida enzyme,Val426 is proposed to form part of the $alpha$ / $beta$ interface (27). TheV426D change leads to a subtler decrease in enzyme activity, asjudged by protocatechuate accumulation by ADO2090 exposed to 4-hydroxybenzoateor quinate compared to strainADO2091.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

An endogenous catabolic trickle through the protocatechuate pathway may arise from hydroaromatic intermediates in the biosynthesisof aromatic compounds. The greater tolerance of ADO2077 than ofan Acinetobacter pcaB mutant strain toward aromatic and hydroaromaticcompounds confers the advantage of decreasing the likelihood ofsecondary mutations arising during maintainance of the strainand of the concomitant isolation of sibling suppressor mutants.Given the selection conditions used, it is likely that the typesof mutations isolated in A. tumefaciens include some that aresubtler than those in Acinetobacter, since a slight reductionin activity of the dioxygenase is likely to protectADO2077.

The most striking difference between the types of secondary mutations arising in Acinetobacter and A. tumefaciens is the numberand extent of deletions. In one Acinetobacter study, 25% of the $Delta$ pcaBDK1 suppressor mutants were large deletions which extendedequally upstream and/or downstream of pcaB and pcaHG (12). InA. tumefaciens, fewer than 2% of 120 suppressor mutants had undergonea deletion sizable enough (at least 0.46 kb) to delete the $Omega$ marker.That value admittedly underestimates the total number of deletionmutants because it measures only pca deletions that extend inthe 3' direction. It does indicate, however, that the catabolitetoxicity at the root of the selection does not a priori causea disproportionate number of deletions. To circumvent screeningthe preponderance of nonmissense mutations that would add littleto understanding the function of PcaHG, a second study of spontaneouspcaHG mutants in Acinetobacter focused on heat-sensitive mutants,which comprised 5% of the population of 4-hydroxybenzoate-resistantpcaBDK1 mutants (7). In a screen of a similar collection ofA. tumefaciens mutants, it was necessary to use a temperaturedifferential of 9°C rather than the 15°C used with Acinetobacter.In spite of this, 3 to 4% of 70 A. tumefaciens mutants screenedwere heat-sensitive PcaHG mutants, indicating that the same strategyfor narrowing the spectrum of pcaHG mutants analyzed should workwith the narrower temperaturerange.

The isolation of unambiguous A. tumefaciens PcaHG mutants that have a clear relationship to structure and function validatesthe selection method and screening process employed. Its successdemonstrates that the positive selection method may have widerapplications that go beyond its use in derivatives of Acinetobactersp. strain ADP1. Although the competence of ADP1 for natural transformationelevates it to the status of a model experimental organism, certainquestions require mutants in particular microbes. Not only doesa pcaB mutant afford the potential to generate mutants for structure-functionanalysis of enzymes and regulatory proteins, it also providesan environmental sleuth and a preliminary assessor of preferredcarbon sources, along with the underlying regulatoryimplications.

	ACKNOWLEDGMENTS

I am grateful to W. M. Coco for providing Acinetobacter sp. strain ADP853, to S. K. Farrand for offering A. tumefaciens UIA5,and to L. N. Ornston for encouragement. Additional thanks aredue to L. N. Ornston and D. M. Young for critical reading of themanuscript. Preliminary sequence data for Sinorhizobium melilotiwere generated by S. R. Long and colleagues at the Departmentof Biological Sciences, Howard Hughes Medical Institute, and theStanford DNA Sequencing and Technology Center (http://cmgm.stanford.edu/~mbarnett/1xgenome.htm).Concurrent with the preparation of this communication, M. Contzenand A. Stolz prepared a manuscript on sequence analysis of relateddioxygenases of Agrobacterium radiobacter. Appreciation is extendedto them for open communication during thisprocess.

This investigation was supported by Department of Energy grantDOE88ER13947.

	FOOTNOTES

^* Mailing address: Department of Molecular, Cellular and Developmental Biology, Yale University, P. O. Box 208103, New Haven,CT 06520-8103. Phone: (203) 432-3505. Fax: (203) 432-6161. E-mail:donna.parke{at}yale.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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	ALL ASM JOURNALS

1.	Albertini, A. M., M. Hofer, M. P. Calos, and J. H. Miller. 1982. On the formation of spontaneous deletions: the importance of short sequence homologies in the generation of large deletions. Cell 29:319-328[CrossRef][Medline].
2.	Altschul, S. F., T. L. Madden, A. A. Schafer, J. Zhang, Z. Zhang, W. Miller, and D. J. Lipman. 1997. Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Res. 25:3389-3402[Abstract/Free Full Text].
3.	Ausubel, F. M., R. Brent, R. E. Kingston, D. D. Moore, J. G. Seidman, J. A. Smith, and K. Struhl (ed.). 1991. Current protocols in molecular biology. Wiley Interscience, New York, N.Y.
4.	Charles, T. C., and T. M. Finan. 1991. Analysis of a 1600-kilobase Rhizobium meliloti megaplasmid using defined deletions generated in vivo. Genetics 127:5-20[Abstract].
5.	Chedin, F., E. Dervyn, R. Dervyn, S. D. Ehrlich, and P. Noirot. 1994. Frequency of deletion formation decreases exponentially with distance between short direct repeats. Mol. Microbiol. 12:561-570[Medline].
6.	Cronin, C. N., J.-H. Kim, J. Fuller, X.-P. Zhang, and W. S. McIntire. 1999. Organization and sequences of p-hydroxybenzaldehyde dehydrogenase and other plasmid-encoded genes for early enzymes of the p-cresol degradative pathway in Pseudomonas putida NCIMB 9866 and 9869. DNA Seq. 10:7-17[Medline].
7.	D'Argenio, D. A., M. W. Vetting, D. H. Ohlendorf, and L. N. Ornston. 1999. Substitution, insertion, deletion, suppression, and altered substrate specificity in functional protocatechuate 3,4-dioxygenases. J. Bacteriol. 181:6478-6487[Abstract/Free Full Text].
8.	Doten, R. C., K.-L. Ngai, D. J. Mitchell, and L. N. Ornston. 1987. Cloning and genetic organization of the pca gene cluster from Acinetobacter calcoaceticus. J. Bacteriol. 169:3168-3174[Abstract/Free Full Text].
9.	Eulberg, D., S. Lakner, L. A. Golovleva, and M. Schlomann. 1998. Characterization of a protocatechuate catabolic gene cluster from Rhodococcus opacus 1CP: evidence for a merged enzyme with 4-carboxymuconolactone-decarboxylating and 3-oxoadipate enol-lactone-hydrolyzing activity. J. Bacteriol. 180:1072-1081[Abstract/Free Full Text].
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