The davDT Operon of Pseudomonas putida, Involved in Lysine Catabolism, Is Induced in Response to the Pathway Intermediate {delta}-Aminovaleric Acid

Pseudomonas putida KT2440 is a soil microorganism that attachesto seeds and efficiently colonizes the plant's rhizosphere.Lysine is one of the major compounds in root exudates, and P.putida KT2440 uses this amino acid as a source of carbon, nitrogen,and energy. Lysine is channeled to ${delta}$ -aminovaleric acid and thenfurther degraded to glutaric acid via the action of the davDTgene products. We show that the davDT genes form an operon transcribedfrom a single ${sigma}$ ⁷⁰-dependent promoter. The relatively high levelof basal expression from the davD promoter increased about fourfoldin response to the addition of exogenous lysine to the culturemedium. However, the true inducer of this operon seems to be ${delta}$ -aminovaleric acid because in a mutant unable to metabolizelysine to ${delta}$ -aminovaleric acid, this compound, but not lysine,acted as an effector. Effective induction of the P. putida P_davDpromoter by exogenously added lysine requires efficient uptakeof this amino acid, which seems to proceed by at least two uptakesystems for basic amino acids that belong to the superfamilyof ABC transporters. Mutants in these ABC uptake systems retainedbasal expression from the davD promoter but exhibited lowerinduction levels in response to exogenous lysine than the wild-typestrain.

INTRODUCTION

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Introduction

Fluorescent pseudomonads are good colonizers of the rhizosphereof most crop plants, and it has been established that root exudatesplay a central role in plant-Pseudomonas sp. interactions (8,11, 24, 36). The main organic compounds of root exudates aresugars, various organic acids, flavonoids, and a number of aminoacids (3, 7). Although sugars account for most of the organicmatter in exudates (18), they do not seem to play a major rolein plant-bacterium interactions, as deduced from the findingthat they do not contribute to tomato root colonization by awell-studied Pseudomonas biocontrol strain (25). Bacterial genesinvolved in the metabolism of amino acids are differentiallyexpressed in the rhizosphere, or in response to root exudates,and mutants deficient in amino acid utilization are less competitivein rhizosphere colonization than the wild-type strain (4, 5,12, 44-46). A similar observation was made with mutants of aRhizobium sp. unable to use proline as the sole carbon and nitrogensource (19).

By means of a transposon carrying a promoterless lux operonto generate transcriptional fusions by insertional mutagenesis,Espinosa-Urgel and Ramos (12) identified the Pseudomonas putidadavT gene, whose expression increased in bacteria colonizingthe rhizosphere. The davT gene encodes the enzyme ${delta}$ -aminovalerateaminotransferase, which participates in a key step in lysinecatabolism. Expression of the davT::lux fusion was enhancedin response to the addition of lysine in the culture medium.This is consistent with the relatively high concentration oflysine (0.42 mM) estimated to be present in corn root exudates(3, 7, 12, 29, 31). The davT mutant was unable to use lysineor ${delta}$ -aminovalerate as a carbon source, in consonance with thelatter chemical being a point of convergence in the degradationof lysine through two different branches (Fig. 1). Althoughthe davT mutant of P. putida showed a chemoattractive responseto root exudates, it was less competitive in root colonizationassays than its parental strain (11). Root exudates containsmall amounts of different compounds. The ability of rhizobacteriato use different carbon and energy sources simultaneously couldbe important for the establishment in the rhizosphere.

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FIG. 1. L-Lysine catabolism by P. putida. L-Lysine has been proposed to enter into the periplasmic space through the OprD porin (43). Subsequently, it is transported to the cytoplasm (the present study) and is metabolized through two branches that converge at ${delta}$ -aminovaleric acid (12, 35). Further metabolism of ${delta}$ -aminovaleric acid yields glutaric acid that is channeled to Krebs cycle intermediates. The thick arrows indicate the main catabolic pathway (Revelles, unpublished). The enzymatic steps are indicated as follows: 1, L-lysine decarboxylase; 2, cadaverine aminotransferase; 3, 1-piperideine dehydrogenase; 4, L-lysine monooxygenase; 5, 5-aminovaleramide amidase; 6, 5-aminovalerate aminotransferase; 7, glutarate semialdehyde dehydrogenase.

In the present study we characterized in detail the davT chromosomalregion, and we show that this gene forms an operon with davD,the gene encoding glutaric semialdehyde dehydrogenase. We haveidentified the promoter of the davDT operon and found that itsmaximal expression requires efficient transport of lysine intothe cell and transformation of this amino acid into ${delta}$ -aminovalericacid, which appears to be the true effector for the expressionof the davDT operon.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains, plasmids, and culture conditions. P. putida KT2440, a derivative of the P. putida soil isolatemt-2, was used (13, 32). P. putida rei2 is a KT2440 derivativethat carries the 'luxCDABE genes fused in frame to the davTgene (12). Escherichia coli strain DH5 ${alpha}$ was used for cloningexperiments, and E. coli CC118 ${lambda}$ pir was used as a host for pUTplasmids (9). These strains were grown at 37°C in Luria-Bertanimedium (40). P. putida strains were grown at 30°C eitherin Luria-Bertani medium or in minimal medium, which was basalM9 medium (40) supplemented with Fe-citrate, MgSO₄, and tracemetals, as described previously (1), and with benzoate (15 mM),glucose (0.4% [wt/vol]), or sodium citrate (10 mM) as a carbonsource. When indicated lysine (10 mM), ${delta}$ -aminovaleric acid (5mM) or glutaric acid (10 mM) were added to the culture medium.When appropriate, antibiotics were added at the following concentrations:chloramphenicol, 30 µg/ml; gentamicin (Gm), 30 µg/ml;kanamycin (Km), 50 µg/ml; and tetracycline, 15 µg/ml.

DNA techniques. Preparation of plasmid and chromosomal DNA, digestion with restrictionenzymes, ligation, electrophoresis, and Southern blotting weredone by using standard methods (40). P. putida cells were electroporatedas described previously (23). Hybridizations were done by usingthe DIG DNA labeling and detection kit (Roche Laboratories,Mannheim, Germany) according to the manufacturer's instructions.Plasmid sequencing was done with universal or reverse pUC19/M13oligonucleotides as primers. Sequencing was done on an ABI Prism310 automated sequencer. Sequences were analyzed with Omiga2.0 software (Oxford Molecular) and ORF FINDER (available atthe National Center for Biotechnology Information [NCBI]) andcompared to data from the P. putida KT2440 genome, obtainedfrom NCBI, and with the GenBank database by using basic localalignment search tool (BLAST; www.ncbi.nlm.nih.gov) programs(2).

Preparation of RNA, primer extension analysis, and RT-PCR. P. putida strains KT2440 and rei2 were grown overnight in M9minimal medium with benzoate. Cells were then diluted 100-foldin fresh medium, and different aliquots were incubated in duplicatein the absence or in the presence of 5 mM lysine and 5 mM ${delta}$ -aminovalericacid until the culture reached a turbidity of ca. 1.0 at 660nm. Cells (30 ml for primer extension and 1.5 ml for reversetranscription-PCR [RT-PCR]) were harvested by centrifugation(5,000 x g for 10 min) and processed for RNA isolation accordingto the method of Marqués et al. (27). Extracts were treatedwith RNase-free DNase I (50 U) in the presence of 3 U of anRNase inhibitor cocktail (Roche Laboratories). For primer extensionanalysis, we used as a specific primer an oligonucleotide complementaryto the davD mRNA (5'-GGTCACCTTGATGGTCTGGCC-3'). The primer waslabeled at its 5' end with [ ${gamma}$ -³²P]ATP by using T4 polynucleotidekinase as described previously (27). About 10⁵ cpm of the labeledprimer was hybridized to 20 µg of total RNA, and extensionwas carried out by using avian myeloblastosis virus reversetranscriptase as described previously (27). Electrophoresisof cDNA products was done in a urea-polyacrylamide sequencinggel to separate the reaction products.

RT-PCR was done with 1 µg of RNA in a final volume of20 µl by using the Titan OneTube RT-PCR system accordingto the manufacturer's instructions (Roche Laboratories). Theannealing temperature used for RT-PCR was 60°C, and thecycling conditions were as follows: 94°C for 30 s, 60°Cfor 30 s, and 68°C for 1 min. Positive and negative controlswere included in all assays. The primers used to test contiguityin the mRNA of the davD and davT genes are available upon request.

Construction of a P. putida orf4 mutant strain. A mutant strain bearing an inactivated chromosomal orf4 wasconstructed as follows: plasmid pCHESI ${Omega}$ Km is a pUC18 derivativecontaining the origin of transfer oriT of RP4 and the ${Omega}$ -Km interposonof plasmid pHP45 ${Omega}$ Km cloned as a HindIII fragment (23). To generatethe orf4 mutation, a 593-bp fragment of P. putida orf4 was amplifiedby PCR with primers provided with EcoRI and BamHI sites andsubsequently cloned between the EcoRI and BamHI sites of pCHESI ${Omega}$ Kmin the same transcriptional direction as the P_lac promoter.The resulting plasmid, pCHESI-ORF4, was mobilized from E. coliCC118 ${lambda}$ pir into P. putida KT2440 by triparental mating with theE. coli HB101(pRK600) helper strain (15). P. putida transconjugantsbearing a cointegrate of the plasmid in the host chromosomewere selected on M9 minimal medium with benzoic acid (10 mM)as the sole carbon source and Km. A few Km-resistant cloneswere chosen to confirm that pCHESI-ORF4 integrated into anddisrupted the orf4 gene. All clones analyzed contained an inactivatedorf4 gene, and a single random clone was chosen and called P.putida ORF4:: ${Omega}$ Km.

Mini-Tn5 mutagenesis of rei2 mutant and selection of mutants with decreased light emission. P. putida rei2 (lux⁺, Km^r) was mated with E. coli CC118 ${lambda}$ pir(pUT-Gm)(S. Molin, unpublished data) and the helper strain E. coli HB101(pRK600)as described above. Transconjugants of P. putida rei2 were selectedon M9 minimal medium with citrate as the C source and with Kmand Gm. Approximately 5,000 independent transconjugants wereselected, and light emission was examined in the presence of5 mM lysine added to M9 minimal medium plates with citrate asa C source. We used a charge-coupled device camera to monitorlight emission (38) and selected six mutants that did not emitlight or emitted significantly lower levels of light than theparental strain. To exclude those that may have resulted frominsertion of mini-Tn5 in the lux genes, total DNA of the mutantswas hybridized against the entire lux operon labeled with digoxigenin.Four clones were discarded because of inactivation of the luxgenes, and the other two were retained for further characterization(see below).

ß-Galactosidase assays. The low-copy-number promoter probe pMP220 (42) is a useful vectorfor gene expression analysis because it carries a promoterless'lacZ gene with the appropriate Shine-Dalgarno sequence upstreamfrom the first ATG. We amplified the intergenic regions betweendavD and davT and between orf3 and davD and cloned them in frontof 'lacZ in pMP220 to yield pOR1 and pOR2, respectively. Theintergenic region between orf3 and davD, and between davD anddavT (Fig. 2) was amplified by PCR with primers incorporatingrestriction sites, an EcoRI site in the primer designed to meetthe 5' end, and a KpnI site in the primer designed to meet the3' end. Upon amplification, DNA was digested with EcoRI andKpnI and ligated to EcoRI-KpnI-digested pMP220 to create theappropriate fusion to 'lacZ to yield pOR1 and pOR2. These plasmidswere sequenced to make sure that no mutations were introducedin the amplified fragments. The plasmids were electroporatedinto P. putida KT2440, and the corresponding transformants weregrown overnight on M9 minimal medium with 15 mM benzoate andtetracycline. Then cultures were diluted 100-fold in the samemedium. After 1.5 h of incubation at 30°C with shaking,the cultures were supplemented or not with inducer compounds,and 4 h later ß-galactosidase activity was assayedin permeabilized whole cells according to the method of Miller(28).

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FIG. 2. Structure of an 8-kb fragment of the chromosome of P. putida KT2440 bearing the davD and davT genes. The davDT genes were sequenced as described in Materials and Methods, and our results agreed with the P. putida genome sequence available at the NCBI (33). Sequence analysis was carried out as described in Materials and Methods. The size of the product of each ORF is given below the corresponding gene in kilodaltons.

¹⁴C-labeled lysine uptake assays. P. putida KT2440 and its mutant derivatives were grown on M9minimal medium with benzoate until they reached mid-logarithmicphase (0.7 to 0.8 turbidity units at 660 nm). Cells were harvestedby centrifugation (3,500 x g for 15 min), washed with M9 mediumand benzoate, and incubated with 0.5 µM lysine (7.8 µCiof ¹⁴C per assay) for different periods of time. The cells werethen filtered and washed with 2 volumes of medium, and the filterwas transferred to a scintillation vial. Nonspecific lysine-bindingassays were done as described above except that the cells werepreincubated for 30 min at 4°C and, after the addition of[¹⁴C]lysine, were kept at 4°C.

RESULTS

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Results

The davD-davT genes form an operon that is expressed from theP_davD promoter. Espinosa-Urgel and Ramos (12) reported thatthe davD and davT genes were closely linked in the chromosomeof P. putida KT2440 and oriented in the same transcriptionaldirection (Fig. 2), but it was not determined whether the genesformed an operon. Previous work indicated that davT encodes ${delta}$ -aminovalerate aminotransferase, and the sequence similarityled us to postulate that the preceding gene, davD, encodes thenext enzyme in the lysine catabolic route, glutaric acid semialdehydedehydrogenase (12). No further analysis of the chromosomal regionwas done in the original study by Espinosa-Urgel and Ramos (12).We have now identified three open reading frames (ORFs) upstreamof davD (orf1, orf2, and orf3) whose translated products correspondto PP0209, PP0210, and PP0211, respectively (33), and one gene(orf4 PP0215) downstream from davT (Fig. 2). All of the genesare predicted to be transcribed in the same direction. Furtherdownstream from orf4 there is another ORF that is transcribeddivergently with respect to orf4 (Fig. 2).

orf1 is 852 bp long and its translated gene product exhibitsa high degree of similarity ( $~$ 75%) to a number of ATP-bindingcomponents of ABC transporter systems, such as the nitrate ABCtransporter system of Methanococcus janaschii and Synechocystissp., as well as the sulfonate transporter system of Methanosarcinaacetivorans (6, 14, 20). The stop codon of orf1 overlaps withthe start codon of orf2, which is 966 bp long and whose translatedprotein exhibits in some stretches a low degree of similarityto ficobiliproteins. However, the function of this protein isunknown. The putative orf3 presumably encodes a hypotheticalprotein of unknown function. At 487 bp downstream from the stopcodon of orf3 we identified the putative first ATG of davD gene.The intergenic space between davD and the downstream davT geneis 293 bp, whereas the distance between the stop codon of davTand the start codon of orf4 is only 138 bp. The translated productof orf4 exhibits similarity to DNA-binding regulators belongingto the two-component response regulator family.

We decided to test whether all six genes with the same orientationcould be transcribed as a single mRNA. To test the potentialoperon structure of these genes, we grew P. putida KT2440 cellsin M9 minimal medium with benzoate as the carbon source andwith 5 mM lysine and isolated mRNA from cells in the late-loggrowth phase. Then we carried out RT-PCRs with primers basedon the 3' end of each of the ORFs and the 5' end of the nextORFs. We found cDNA products of the expected sizes with theprimers corresponding to orf1 and orf2 and davD and davT (notshown) but not with primers corresponding to orf3 and davD ordavT and orf4. It should be mentioned that we have not beenable to detect mRNA corresponding to orf3 under any growth conditiontested in the present study. We therefore considered that thesix ORFs could be organized in three transcriptional units,with davD and davT forming a unit that seems to be transcribedindependently from orf4 and orf1/orf2.

The similarity of orf4 to genes encoding response regulatorsled us to test whether the orf4 gene product is involved inthe regulation of the davDT operon. To this end, we generateda mutant in orf4 as described in Materials and Methods. Themutant grew as fast as the wild type with lysine as the solecarbon and energy source, and the gene product was thereforeconsidered not to be involved in the regulation of lysine metabolism.

davD promoter region. Plasmids pOR1 (intergenic davD-davT region'::'lacZ) and pOR2(P_davD'::'lacZ) were electroporated in P. putida KT2440, andcells were grown as described in Materials and Methods in theabsence or in the presence of 5 mM lysine. We found no ß-galactosidaseactivity with pOR1 regardless of the growth conditions. In contrast,with pOR2 we detected basal expression in the absence of lysine,which increased when cells were grown in its presence (Fig.3). This suggested that a functional promoter could only belocated in front of the davD gene. These findings, along withthe RT-PCR results, suggest that transcription of davDT genesis driven exclusively from a promoter upstream of davD.

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FIG. 3. Identification of the minimal region of the davD promoter that allowed regulated expression. Intergenic regions of different length between davD and orf3 were amplified by PCR with the same primer to meet the 3' end (provided with a Kpn site) and different primers at the 5' end (provided with an EcoRI site). The PCR products, once digested with these restriction enzymes, yielded fragments of 416, 280, 137, 81, and 26 bp upstream from the +1 transcription start point. P. putida KT2440 cells bearing the indicated fusion were grown on M9 minimal medium with benzoate alone or with 5 mM lysine or 5 mM ${delta}$ -aminovaleric acid. The ß-galactosidase activity was determined as described in Materials and Methods, and values are the averages of three independent assays done in duplicate.

To identify the transcription initiation point of the davDToperon and define the minimum region required for inductionto take place, we carried out the following assays. First, weprepared mRNA from KT2440 grown with 5 mM lysine and used aprimer located 50 bp within the davD gene for primer extension.Our results revealed a major transcription initiation point(Fig. 4) located 66 bp upstream with respect to the A of thefirst ATG in davD. Analysis of the sequence upstream revealeda –10 region (5'-TAGCAT-3') very similar to 5'-TATCAT-3',which is best recognized by the P. putida sigma-70 factor (10).The promoter also exhibited a relatively well-conserved –35region (5'-TTGTCC-3') with 17 bases between the two boxes.

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FIG. 4. Transcription initiation point of the davD promoter and key sequence features in the proximal 5' region. (A) Transcription initiation mapping of the davD gene. Lane 1, RNA isolated from cells grown on M9 minimal medium with 5 mM lysine. The other lanes correspond to a sequencing ladder. The DNA sequence corresponding to the davD promoter region is shown on the left. The transcription start point is in boldface and is marked +1. The proposed –10 box is in boldface. (B) Organization of the davD promoter region. The –10 and –35 regions are indicated in boldface and by gray boxes. A T-rich region is shown in an open box. Convergent arrows indicate a potential inverted repeat.

To determine the region upstream from the +1 position in davDnecessary for the regulated expression of the operon, we amplifieddifferent portions of the region by PCR using in all cases thesame primer at the 3' end and different primers at the 5' end,so that we generated PCR-amplified fragments of different sizes(Fig. 3). These fragments were cloned in pMP220 and ß-galactosidaseactivity was measured. We found high ß-galactosidaselevels (>1,500 Miller units) when the primer allowed amplificationof at least 81 bp upstream from the +1 point.

Sequence analysis of the region between positions –81and +1 revealed, in addition to the –10/–35 boxesdescribed above, a T-rich region between –48 and –62that could function as a UP element or a curvature element,and an imperfect inverted repeat that extended from –76to –58 and that could be the target for a regulator responsiblefor the induction of this promoter (Fig. 4).

Efficient lysine transport is required for full expression of the davDT operon. Mutant rei2 carries an in-frame fusion of davT to the 'luxABCDEgenes, and the cells show increased light emission upon exposureto lysine. We mutagenized the rei2 mutant with a mini-Tn5-Gmtransposon as described in Materials and Methods and searchedfor mutants with reduced luminescence. These mutants were expectedto result from the limited uptake of lysine or from inactivationof a putative regulator. Two mutants called rei2-6 and rei2-7emitted a basal level of light and only a small increase inlight emission was found in response to lysine (Table 1). Southernblotting assays revealed a single insertion of the mini-Tn5-Gmin each of the mutants, and we sequenced the insertion site.In rei2-6 and rei2-7 mutants, the mini-transposon had interruptedORFs of 753 and 885 bp, respectively (corresponding to PP0283and PP4486). BLAST analyses against different data banks werecarried out with the translated sequence of each ORF. We foundthat in the rei2-6 and rei2-7 mutants the inactivated geneswere related to amino acid uptake systems belonging to the ABCsuperfamily (17, 30, 39, 41). The gene inactivated in mutantrei2-6 (PP0283) exhibited high similarity to the ATP-bindingcomponent of the arginine/ornithine transport system of Pseudomonasaeruginosa (94% similarity), the ATP-binding protein of thehistidine ABC transporter of P. syringae pv. tomato strain DC3000(92% similarity) and E. coli (79% similarity), and the ATP-bindingcomponent of the ornithine transport of Salmonella entericaserovar Typhimurium LT2 (79% identity). The insertion in mutantrei2-7 had inactivated a periplasmic binding protein (PP4486)of a transport system for basic amino acids (16, 34). This periplasmicbinding protein is a member of the LAO (lysine/arginine/ornithine)group (21). We hypothesized that the lower induction from P_davDin these mutants probably resulted from their limited lysineuptake. To test this hypothesis, we carried out assays with[¹⁴C]lysine in cells grown on minimal medium with benzoate asa C source and NH₄⁺ as an N source. We found that uptake of[¹⁴C]lysine in the rei2, rei2-6, and rei2-7 mutants was linearin time for about 3 min. [¹⁴C]lysine was incorporated by rei2cells at a rate of 2.5 nmol/mg of protein per min, whereas inthe mutants the rate of [¹⁴C]lysine incorporation was ca. 30%of that determined for the rei2 strain.

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TABLE 1. Relative level of light emission by rei2 and its mutant derivatives^a

${delta}$ -Aminovaleric acid enhances expression of the davDT operon. To identify the signal molecule(s) that induces expression fromthe davD promoter, we cultured P. putida KT2440 bearing pOR2on M9 minimal medium with 5 mM lysine (the first substrate inthe pathway), 5 mM ${delta}$ -aminovaleric acid (the product in whichthe two potential lysine degradation pathways converge [Fig.1]), 2.5 mM cadaverine (a potential intermediate in one of thelysine branches that can yield ${delta}$ -aminovaleric acid), and 5 mMglutaric acid (the product resulting from ${delta}$ -aminovaleric acidmetabolism). Our results revealed that, whereas glutaric acidwas not an inducer (Table 2), the other three compounds inducedexpression from the P_davD promoter. Whether lysine and cadaverineare true inducers or whether ${delta}$ -aminovaleric acid resulting fromthe metabolism of lysine and cadaverine is the true inducercould not be discerned from these results.

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TABLE 2. Induction of the davD promoter in the wild-type P. putida KT2440 and its isogenic mutant KT2440 mut-1 and RpoN^a

To further elucidate the nature of the inducer we repeated theabove assays in P. putida KT2440 mut-1, a mutant unable to convert ${delta}$ -aminovaleramide into ${delta}$ -aminovaleric acid (O. Revelles, unpublisheddata). In this mutant, ${delta}$ -aminovaleric acid induced expressionfrom P_davD at a level similar to that found in the wild type( $~$ 3-fold over the basal level), whereas induction by lysine wasnull, and induction with cadaverine was low (<2-fold). Thissuggests that ${delta}$ -aminovaleric acid resulting from the metabolismof lysine or cadaverine may be the true inducer of the davDToperon (Table 2).

Köhler et al. (22) reported that an rpoN mutant that lacked ${sigma}$ ⁵⁴ was unable to grow on lysine. Although the davDT operon promoterpresented ${sigma}$ ⁷⁰-dependent characteristics, its expression couldbe influenced by ${sigma}$ ⁵⁴ if the operon were part of a regulatorycascade with a master regulator involving ${sigma}$ ⁵⁴, as is the casein 3-methylbenzoate metabolism by the TOL plasmid of P. putidawhen cells are grown on m-xylene (37). To test this hypothesis,we transformed pOR2 in P. putida strain TK19, an rpoN mutant,and determined the ß-galactosidase activity in thepresence or in the absence of lysine cadaverine and ${delta}$ -aminovalericacid. We found an induction ratio of about 2.5, a level similarto the one obtained in the wild type. Therefore, ${sigma}$ ⁵⁴ is not directlyor indirectly involved in expression of the davD gene, and theinability of the RpoN mutant to grow on lysine should thereforebe ascribed to the need to express other catabolic segmentsof the lysine catabolic pathway.

DISCUSSION

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Discussion

Espinosa-Urgel and Ramos (12) showed before that mutagenesisof P. putida KT2440 with a mini-Tn5-lux transposon was usefulfor identifying genes whose expression increased in cells thatcolonize plant roots or are exposed to plant root exudates.The inability of the rei2 mutant to use lysine identified agene, called davT, involved in the use of this amino acid asa C source.

DNA sequencing and the series of RT-PCR assays carried out inthe present study have now shown that davT forms an operon withthe davD gene. Our in vivo assays revealed light emission bycells of the rei2 strain growing in the absence of lysine, whichincreased $~$ 3-fold in response to the exogenous addition of thisamino acid.

It has been proposed that in P. putida, the initial metabolismof lysine occurs through two branches that converge at ${delta}$ -aminovalericacid (Fig. 1). P. putida mut-1 is blocked at ${delta}$ -aminovaleramideaminotransferase—a key step in one of the loops (Fig.1)—and grows slowly on lysine (Revelles, unpublished).This suggests that the ${delta}$ -aminovaleramide branch is the majorlysine assimilation pathway in this strain. In agreement withthis hypothesis is the finding that in the mut-1 strain, lysinedid not induce the expression of the davDT operon promoter,and cadaverine only induced low levels of expression of thedavDT genes. In contrast, ${delta}$ -aminovaleric acid behaved as thestrongest effector. We are therefore tempted to propose that ${delta}$ -aminovaleric acid is the true inducer of the davDT operon.

The transcription start point of the davD promoter was identified,and deletion analysis of the promoter region revealed the needfor at least 80 bp upstream from this point for expression fromthe davD promoter. Sequence analysis of the promoter regionrevealed good –10 and –35 boxes for ${sigma}$ ⁷⁰ promoters.Because expression from P_davD can be induced by exogenous lysine,we hypothesized the participation of an as-yet-unidentifiedregulator, which might possibly bind to an inverted repeat inthe –58/–76 region. Although this motif is relativelyfar from the RNA polymerase binding site, the presence of aputative UP element in the –50/–60 region mightfacilitate contacts between RNA polymerase and the putativeregulator. This type of organization is seen in some E. coliCRP regulated promoters (7, 26) and, to our knowledge, thisis the first such case proposed for a pseudomonad.

Downstream of davT we identified orf4, whose translated productshowed homology to regulators belonging to the two-componentfamily. An orf4:: ${Omega}$ Km mutant exhibited a pattern of davDT expressionsimilar to that of the wild type, which ruled out this regulatoras responsible for the regulated expression of this operon.An alternative approach to search for a potential regulatorwas designed. We reasoned that the intensity of light emittedby the mutants in the putative regulator of the davDT operonwould be diminished. After Tn5 mutagenesis of the rei2 strainwe searched for such mutants among 5,000 transconjugants; onlytwo of them exhibited low induction levels. Analysis of theknockout genes suggested that the mutants might exhibit defectsin lysine uptake. The results with mutants rei2-6 and rei2-7showed that efficient induction of the davDT operon by exogenouslysine requires effective uptake systems.

Lysine in P. putida KT2440 seems to be taken up through at leasttwo ABC transporters that appear to consist of four proteins.Figure 5 shows the genomic organization of the two systems.In mutant rei2-6 the gene that encodes the ATP-binding proteinwas followed by the gene that encodes the solute-binding proteinand two integral membrane permeases. In mutant rei2-7 the genesencoding the two permeases lay between the genes that encodethe solute-binding protein and the ATP-binding protein. Inactivationof either of the two uptake systems resulted in a significantdecrease in the rate of lysine uptake and resulted in reducedinduction from the davD promoter.

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FIG. 5. Genetic organization of the two ABC transporter systems for L-lysine uptake in P. putida KT2440. (Top) Organization of the L-lysine transport system inactivated in mutant rei2-6; (bottom) organization of the L-lysine transport system inactivated in rei2-7. Genome organization is shown according to the findings of Nelson et al. (33). The number of amino acids of each translated product is given below the gene. BP stands for periplasmic binding protein, and ABC stands for ATP-binding protein. The function of the products encoded by adjacent ORFs in both loci is unknown.

Köhler et al. (22) reported that an RpoN mutant of P. putidadid not grow with lysine. In the RpoN mutant strain both lysineand ${delta}$ -aminovaleric acid induced expression from P_davD, and thereforethe inability to grow could not be ascribed to the preventionof expression of the branches that converge in ${delta}$ -aminovalericacid or of the davDT operon itself. Instead, the RpoN mutantseems to be unable to metabolize glutaric acid (Revelles, unpublished).It follows that lysine catabolism in P. putida involves theassemblage of several pathway stretches that are independentlyregulated: (i) the two loops that convert lysine into ${delta}$ -aminovalericacid, (ii) the davD operon for metabolism of ${delta}$ -aminovaleric acidto glutaric acid, and (iii) a segment that converts glutaricacid into Krebs cycle intermediates. This modular organizationendows the strain with high metabolic versatility to respondto different carbon or nitrogen sources supplied exogenouslyor generated internally during cell metabolism.

ACKNOWLEDGMENTS

This study was supported by EU project QLRT-02884 and nationalgrant BIO2003-00515 from the CICYT.

We thank K. Shashok and C. Lorente for checking the Englishin the manuscript.

FOOTNOTES

* Corresponding author. Mailing address: Estación Experimental del Zaidín, CSIC, Calle Profesor Albareda number 1, E-18008 Granada, Spain. Phone: 34-958-181608. Fax: 34-958-135740. E-mail: jlramos{at}eez.csic.es.

REFERENCES

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