Natural Transformation in Mesophilic and Thermophilic Bacteria: Identification and Characterization of Novel, Closely Related Competence Genes in Acinetobacter sp. Strain BD413 and Thermus thermophilus HB27

doi:10.1128/AEM.67.7.3140-3148.2001

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Applied and Environmental Microbiology, July 2001, p. 3140-3148, Vol. 67, No. 7
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.7.3140-3148.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Natural Transformation in Mesophilic and Thermophilic Bacteria: Identification and Characterization of Novel, Closely Related Competence Genes in Acinetobacter sp. Strain BD413 and Thermus thermophilus HB27

Alexandra Friedrich,¹ Thomas Hartsch,² and Beate Averhoff¹^,^*

Department of Genetics and Microbiology, Ludwig Maximilians University, 80638 Munich,¹ and Göttingen Genomics Laboratory, Institute of Microbiology and Genetics, Georg August University, D-37077 Göttingen,² Germany

Received 8 February 2001/Accepted 24 April 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The mesophile Acinetobacter sp. strain BD413 and the extreme thermophile Thermus thermophilus HB27 display high frequenciesof natural transformation. In this study we identified and characterizeda novel competence gene in Acinetobacter sp. strain BD413, comA,whose product displays significant similarities to the competenceproteins ComA and ComEC in Neisseria and Bacillus species. Transcriptionof comA correlated with growth phase-dependent transcriptionalregulation of the recently identified pilin-like factors of thetransformation machinery. This finding strongly suggests thatcomA is part of a competence regulon. Examination of the genomesequence of T. thermophilus HB27 led to detection of a comA/comEC-likeopen reading frame (ORF) which is flanked by an ORF whose productshows significant similarities to the Bacillus subtilis competenceprotein ComEA. To examine whether these two ORFs, designated comECand comEA, are implicated in natural transformation of T. thermophilusHB27, both were disrupted by using a thermostable kanamycin resistancemarker. Natural transformation in comEC mutants was reduced 1,000-fold,whereas in comEA mutants the natural transformation phenotypewas completely eliminated. These results strongly suggest thatboth genes, comEC and comEA, are required for natural transformationin T. thermophilus HB27. Several transmembrane $alpha$ -helices are predictedbased on the amino acid sequences of ComA in Acinetobacter sp.strain BD413 and ComEC in T. thermophilus HB27, which suggeststhat ComA and ComEC are located in the inner membrane and functionin DNA transport through the cytoplasmicmembrane.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Increasingly, data obtained in studies of molecular microbial ecology and genome analyses indicate that horizontal gene flowbetween different species and genera plays a major role in acquisitionof novel metabolic capabilities, of the different mechanisms ofgene transfer, natural transformation is perhaps the most versatileand provides an important mechanism for increasing the geneticvariability of microorganisms. The ability to take up free DNAvia natural transformation is widely distributed among representativesof different phylogenetic and trophic groups inhabiting distinctnatural ecosystems (35). To gain insight into the structureof the DNA uptake machinery and the mechanism of natural transformationof gram-negative soil bacteria, we used Acinetobacter sp. strainBD413 as a mesophilic model organism. This strain is known forits high competence for natural transformation (25). Acinetobactersp. strain BD413 has been shown to induce maximal competence immediatelyafter the transition from the lag phase to the exponential growthphase. During prolonged exponential growth competence is graduallylost (43, 48). Prerequisites for induction of competence fornatural transformation in Acinetobacter sp. strain BD413 havebeen investigated thoroughly and are well understood (44). SinceAcinetobacter sp. strain BD413 does not discriminate between heterologousand homologous DNA, this strain has been broadly used as a modelstrain to elucidate the significance of intra- and interspeciesgene transfer in natural soil habitats (15, 29, 35, 38,39).

Although many thermophilic bacteria are known to exhibit high levels of competence for natural transformation, informationon natural transformation systems of extremely thermophilic microorganismsis very scarce, in contrast to the abundant data on the transformationmechanisms of and the potential for DNA transfer between mesophilicbacteria (31). One extreme thermophile, Thermus thermophilusHB27, an aerobic, rod-shaped, gram-negative bacterium that growsat temperatures between 50 and 82°C, is known to exhibit highfrequencies of natural transformation (22, 31). Transformationfrequencies ranging from 10² to 10¹ were found when proliferating cells incubated at pH 6 to 9 and70°C were exposed to chromosomal DNA (31). As observed in Acinetobactersp. strain BD413, the highest transformation frequencies wereobtained in the presence of divalent cations (Ca²⁺ or Mg²⁺).

We recently identified five genes, comC, comP, comB, comE, and comF, that are required for DNA uptake in Acinetobacter sp.strain BD413 (1, 21, 34, 47, 48). Primary sequencecomparisons, mutant studies, and biochemical analyses have suggestedthat ComP is part of a DNA binding and/or transport structurethat is anchored in the cytoplasmic membrane and spans the periplasm(48). In contrast to our increasing knowledge concerning thestructure and function of transformation mechanisms in mesophilicbacteria (8), nothing is known about the components of transformationsystems of inhabitants of extreme environments, such as extremelythermophilic bacteria. The differences in physiology and environmentalconditions between the genera Acinetobacter and Thermus led usto ask whether the transformation mechanisms of these phylogeneticallydistantly related bacteria are completely different or includeconservedcomponents.

In this study we identified a novel competence gene essential for natural transformation in Acinetobacter sp. strain BD413.The deduced protein encoded by this competence gene shows significantsimilarities to the competence proteins ComA of Neisseria gonorrhoeae,ComEC of Bacillus subtilis, Rec-2 of Haemophilus influenzae, andCelB of Streptococcus pneumoniae (2, 4, 10, 17). Dueto the similarities, the novel competence gene in Acinetobactersp. strain BD413 was designated comA. Examination of the genomicDNA sequence of T. thermophilus HB27 resulted in identificationof a comA/comEC-like open reading frame (ORF) in Thermus, whichis flanked by an ORF encoding a putative protein with significantsimilarities to the competence proteins ComEA of B. subtilis andCelA of S. pneumoniae. We obtained clear evidence that the comEA-comECcompetence locus is essential for natural transformation in T.thermophilus HB27. Primary sequence comparisons and secondarystructure predictions suggested that ComEC of Thermus and ComAof Acinetobacter are transmembrane proteins which may be involvedin DNA transport through the cytoplasmic membrane. Our data stronglysuggested that ComA- and ComEC-like proteins are ubiquitous, essentialcomponents of bacterial transformation mechanisms independentof the phylogenetic relationships and natural environments ofthe transformablebacteria.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Strains, plasmids, and DNA manipulation. Acinetobacter wild-type and mutant strains were grown in Luria-Bertani (LB) medium (50) or mineral medium (41). Growthconditions described previously were used (47). A p-hydroxybenzoatehydroxylase (pobA) mutant strain of BD413, designated Acinetobactersp. strain ADP239 (19), was used in all studies. Escherichiacoli DH5 $alpha$ was used as a host strain for cloning of genomic DNA(18). E. coli S17-1( $lambda$ pir) was used as a donor strain for conjugativetransposition of mini-Tn10pLOF/Km (Ap^r, Tn10 delivery plasmid with Km^r) (20). The E. coli strains were cultured at 37°C in LB medium.T. thermophilus HB27 wild-type and mutant strains were grown ina 1:1 mixture of TM broth (31) and LB medium at 60 to 70°C.When appropriate, antibiotics were added at the following concentrations:kanamycin 20 to 40 µg/ml; ampicillin, 100 µg/ml; tetracycline,15 µg/ml; and streptomycin, 100 to 500 µg/ml. The molecular andgenetic procedures used were standard techniques (50, 51).Transformation, conjugation, and complementation studies of Acinetobactermutants and Southern hybridization experiments were performedas described previously (47). For triparental matings helperplasmid pRK2013 (13) was used. T. thermophilus HB27 was transformedby using a modified protocol described by Koyama et al. (31).

Transformation studies. Transformation studies with Acinetobacter strains were performed as described previously (47). For transformation studieswith T. thermophilus HB27 spontaneous streptomycin-resistant mutantswere selected by plating 10⁸ cells on TM medium plates containing streptomycin (500 µg/ml).The genomic DNA of the spontaneous streptomycin-resistant mutantswere used as donor DNA for transformation studies as describedpreviously (31).

Transposon mutagenesis in Acinetobacter. To identify competence loci in Acinetobacter sp. strain BD413, a genomic library of this strain was subjected to transposonmutagenesis by using a genetically engineered derivative of Tn10,mini-Tn10pLOF/Km, as described previously (20, 21). The BD413library, which contained 6,000 clones harboring 2.5- to 6-kb XbaIDNA fragments, was generated in E. coli DH5 $alpha$ by using the mobilizablebroad-host-range vector pRK415. Matings between the donor strainand pooled recipients were performed by using the filter matingtechnique as described recently (47). Transconjugants were selectedon LB medium plates containing kanamycin and tetracycline andsubjected to plasmid preparation. Plasmids were purified and digestedwith XbaI, and the XbaI fragments spanning the kanamycin resistancegene plus flanking BD413 DNA were transformed into Acinetobactersp. strain ADP239. Selection of Acinetobacter sp. strain ADP239transformants on LB medium plates containing kanamycin resultedin detection of 1,000 transformants that had acquired the kanamycinmarker gene via homologous recombination of the marker-flankingDNA with ADP239 genomic DNA. Analysis of the transformants ledto identification of one noncompetent mutant, T701. The proficiencyof homologous recombination of this mutant was tested as describedpreviously (16). The gene disrupted by mini-Tn10pLOF/Km wasidentified as comA. The mutant locus of T701 was recovered ona 10.5-kb XbaI fragment (pAF701-1) and an overlapping 3.9-kb EcoRI-EcoRVfragment (pAF701-1.2), which were cloned by using the vectorspGEM-7Zf(+) and pBluescriptII KS, respectively (Fig. 1A).

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FIG. 1. Physical maps of plasmids used in this study for Acinetobacter (A) and Thermus (B) gene disruption and complementation studies. pBKS, pBluescriptII KS; pBSK, pBluescriptII SK; pGEM, pGEM-7Zf(+). The arrows indicate directions of transcription. B, BamHI; BX, BstXI; CI, ClaI; EI, EcoRI; EV, EcoRV; HII, HincII; HIII, HindIII; KI, KpnI; XI, XbaI; Xh, XhoI; PI, PstI.

Generation of the wild-type comA gene. To clearly confirm the essential role of comA in natural transformation, complementation studies with the wild-type comA genewere performed. Isolation or generation of the comA wild-typegene was a prerequisite for these studies. Mutant T701 could notbe used to generate the comA wild-type allele. Therefore, a secondmutant had to be generated. To generate the second comA mutant,a 1.9-kb BamHI-EcoRV DNA fragment that was located downstreamof the mini-Tn10 insertion in pAF701-1.2 and included 5'-terminaltruncated comA was subcloned from pAF701-1.2. The comA allelein the resulting plasmid, pAF701-1.3 (Table 1), was disruptedby a kanamycin marker (nptII), which gave rise to plasmid pAF701-1.4(Fig. 1A). This construct containing part of comA, disrupted bythe nptII marker digested with BamHI plus EcoRV, and the 3.2-kbBamHI-EcoRV fragment carrying the disrupted comA gene was introducedinto Acinetobacter sp. strain ADP239 by natural transformation.Transformants were selected on LB medium containing kanamycin.Several of the kanamycin-resistant transformants were analyzedto determine their transformation phenotypes and, as expected,were found to be noncompetent. One such mutant, designated T702,was used for further studies. Correct allelic replacement of chromosomalwild-type comA in mutant T702 by the disrupted ORF was verifiedby Southern hybridization.

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TABLE 1. Strains and plasmids used in this study

The T702 mutant locus was recovered as a 12.5-kb HincII fragment (pAF702-2) (Table 1); this fragment contained the entirechromosomal copy of comA. To generate the comA wild-type gene,a 5.3-kb HincII-BamHI DNA fragment was subcloned from pAF702-2into pBluescriptII SK, resulting in plasmid pAF702-2.1 (Table1). The nptII marker was eliminated by digestion with PstI andsubsequent religation, resulting in plasmid pAF702-2.2 (Table1). The sequence of the analogous comA region in plasmid pAF702-2.2(spanning the PstI site) was found to be identical to the correspondingregion in the 5'- and 3'-terminally truncated comA gene in pAF701-1.2(Fig. 1A). This result confirmed that deletion of the nptII markergene from pAF702-2.1 resulted in generation of the comA wild-typeallele.

Complementation studies. To perform complementation studies, the insert of pAF702-2.2 was cloned into pRK415 (20). This was done by cloning the 4-kbinsert of pAF702-2.2 as a KpnI-BamHI fragment into linearizedpRK415, which resulted in pRK702-2.2 (Fig. 1A). This fragmentcontained the 3' end of orf1, orf2, comA, and the 3' end of orf4.For further complementation studies a second plasmid containingonly the complete comA gene was constructed. To delete the comA-flankingorf1 and orf2 regions, plasmid pAF702-2.2 was digested with HincIIplus ClaI, incubated in the presence of deoxynucleoside triphosphates(dNTPs) and the Klenow enzyme, and ligated. The 3.3-kb insertin the resulting plasmid, pAF702-2.3 (Table 1), included the3' end of orf2, comA, and the 3' end of orf4. The insert of pAF702-2.3was cloned as a 3.3-kb KpnI-BamHI DNA fragment into pRK415, whichresulted in pRK702-2.3 (Fig. 1A). Recombinant plasmids pRK702-2.2and pRK702-2.3 were conjugatively transferred into comA mutantsT701 and T702, respectively. Transconjugants were selected forgrowth on LB medium plates containing tetracycline and analyzedfor the presence of recombinant plasmids and transformationphenotype.

Disruption of comA flanking ORFs. To determine whether orf4 has a potential function in natural transformation, orf4 was disrupted by the kanamycin resistancegene, nptII. A 3.4-kb PstI-HindIII fragment of plasmid pAF702-2spanning the 3' end of comA, orf4, orf5, and orf6 was first subclonedinto pBluescriptII KS (pAF702-4.4)(Table 1) and then was clonedas a 3.4-kb PstI-KpnI fragment into pRK415, which resulted inplasmid pRK702-4.2 (Table 1). The nptII marker was cloned intothe unique BamHI site of orf4, which resulted in plasmid pRK702-4.3.Plasmid pRK702-4.3 was digested with EcoRV, and the resulting3.3-kb EcoRV fragment carrying the disrupted orf4 DNA plus flankingDNA was introduced into Acinetobacter sp. strain ADP239 by naturaltransformation in order to disrupt chromosomal orf4 by homologousrecombination. Transformants were selected for growth on LB mediumplates containing kanamycin. Correct allelic replacement of chromosomalwild-type orf4 was verified by Southern hybridization. Severalattempts were made to disrupt or to delete orf1 and orf2. Forthese experiments different subclones of pAF701-1 carrying orf1and orf2 were generated and used to insert the nptII marker intoorf1 and orf2, respectively. The resulting disrupted orf1 andorf2 DNA plus flanking wild-type DNA were transformed into Acinetobactersp. strain ADP239, but despite several attempts with differentconstructs no replacement of wild-type orf1 and orf2 by the disruptedORFs wasobserved.

Gene disruption in T. thermophilus HB27. comEC and comEA of T. thermophilus HB27 were disrupted by a kanamycin resistance gene (kat) encoding a thermostable kanamycinnucleotidyltransferase (32, 36), which was derived from theshuttle vector pMK18. pMK18 confers kanamycin resistance in E.coli (37°C) and in Thermus (70°C) (6). Two plasmids from anHB27 gene bank were used for these disruption experiments. Thegene bank was generated by cloning physically sheared, blunt-endedchromosomal DNA from T. thermophilus HB27 in HincII-digested vectorpTZ19r. Based on the sequence information, two of the gene bankplasmids, designated pNC52 and pFE87, were determined to carryhomologs of the B. subtilis comEC and comEA competence genes.These two plasmids were used for disruption of the HB27 comEC-and comEA-like genes via insertion of a thermostable kanamycinresistance marker gene (kat).

To insert the kanamycin resistance gene (kat) into the comEC-like ORF, plasmid pNC52 (Table 1) was digested with BstXI andincubated in the presence of dNTPs and the Klenow enzyme. pMK18was digested with HindIII plus BamHI, which yielded a 1.2-kb fragmentcontaining the kat gene. After incubation with the Klenow enzyme,the kat gene was ligated to BstXI-linearized pNC52, and the ligationmixture was transformed into E. coli DH5 $alpha$ . Transformants wereselected on LB medium containing 100 µg of ampicillin per ml and20 µg of kanamycin per ml. The resulting plasmid, pNC52-k (Fig.1B), was digested with XhoI, and the resulting 3.2-kb fragmentcontaining the disrupted comEC-like gene plus flanking DNA wasintroduced into T. thermophilus HB27 by natural transformation.Transformants were selected on TM medium containing 40 µg of kanamycinperml.

To disrupt the comEA-like gene, the insert of pFE87 was cloned as an HindIII-XbaI fragment into pBluescriptII KS in orderto delete restriction sites from the multiple cloning site. Theresulting plasmid, pFE87-HX (Table 1), was digested with BamHIand incubated in the presence of dNTPs and the Klenow enzyme.The blunt-ended kat gene was ligated to blunt-ended, linearizedplasmid pFE87-HX, and the ligation mixture was transformed intoE. coli DH5 $alpha$ . Transformants were selected on LB medium containing20 µg of kanamycin per ml and 100 µg of ampicillin per ml. Theresulting recombinant plasmid, designated pFE87-k (Fig. 1B), wasdigested with PstI plus XbaI, and the 3.3-kb fragment containingthe disrupted ORF plus flanking wild-type DNA was introduced intoT. thermophilus HB27 via natural transformation. Transformantswere selected on TM medium containing 40 µg of kanamycin per ml.Correct allelic replacement of chromosomal wild-type comEA- andcomEC-like genes by the disrupted ORFs was verified by Southernhybridization.

Construction of comA::lacZ transcriptional fusions and assay for $beta$ -galactosidase activities. To generate comA::lacZ transcriptional fusions, vector pKOK 6.1 (30) containing a promoter-free lacZ gene was digested withPstI. The 4.7-kb PstI fragment, carrying the promoter-free lacZgene, was inserted into the PstI site in pAF702-2.3, which resultedin pAF702-3.2 (Table 1). Correct orientation of the insert withrespect to the lacZ gene was confirmed by restriction analysis.The insert of pAF702-3.2 was subcloned as a 8-kb KpnI-BamHI fragmentin the opposite orientation with respect to the lac promoter intothe broad-host-range vector pRK415, resulting in plasmid pRK702-3.2(Table 1). pRK702-3.2 was transferred into Acinetobacter sp.strain ADP239 via triparental mating. As a control Acinetobactersp. strain ADP239 carrying the lacZ gene of pKOK6.1 cloned inthe opposite direction with respect to the lac promoter in vectorpRK415 was used. The $beta$ -galactosidase activities were determinedas described by Miller (37) and were expressed in Miller units,which are proportional to the increase in absorbance of free o-nitrophenolper minute and celldensity.

Nucleotide sequence accession number. The sequence data have been deposited in the GenBank database under accession no. AF320001 and AF319938.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Isolation and characterization of a noncompetent Acinetobacter mutant. Transposon mutagenesis of an Acinetobacter sp. strain BD413 genomic library resulted in 200 tetracycline- and kanamycin-resistantE. coli DH5 $alpha$ clones. Retransfer of the mutant loci into Acinetobactersp. strain ADP239 led to 1,000 kanamycin-resistant transformantswhich were analyzed to determine their transformation phenotypes.These studies led to detection of one completely noncompetentmutant, designated T701 (Fig. 2A).

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FIG. 2. (A) Chromosomal region of Acinetobacter sp. strain BD413 containing orf1, orf2, orf3 (comA), orf4, orf5, and orf6 and physical map of the mutant loci. (B) Chromosomal region of T. thermophilus HB27 containing ppase, comEA, comEC, and parB. The arrows indicate directions of transcription. nptII, insertion site of the Km^r gene; Tn10, insertion site of mini-Tn10; kat, insertion site of the kat gene; EI, EcoRI; EV, EcoRV; HII, HincII; HIII, HindIII.

During previous transformation studies of mutants of Acinetobacter sp. strain ADP239, a deletion the pca operon, which encodesthe key enzymes used for further breakdown of the p-hydroxybenzoatehydroxylase (PobA) reaction product (protocatechuate), was observed.A spontaneous large deletion in the pca operon would interferewith the screening system used for transformation-deficient mutants,which is based on the failure of transformation-deficient ADP239mutants to grow on p-hydroxybenzoate in the presence of wild-typeDNA since they cannot acquire the wild-type pobA allele. To excludethe possibility that there was a deletion in the pca operon, whichcould have resulted from integration of two noncontiguous DNAfragments into the ADP239 genome, mutant T701 was analyzed todetermine its ability to use protocatechuate as a sole carbonand energy source. These studies revealed that mutant T701 wasable to grow on protocatechuate, and so the possibility that therewas a deletion in the pca operon was eliminated. Furthermore,mutant T701 showed a high proficiency for DNA repair during growthin the presence of the DNA-alkylating agent methyl methanesulfonate,which eliminated the possibility that the transformation defectwas a result of an impaired RecA function. Complementation studieswith recombinant plasmids carrying comP, comB, comC, comE, and/orcomF revealed that the noncompetent phenotype of mutant T701 wasnot due to a defect in these recently identified competence genes.This was confirmed by hybridization studies (data notshown).

Cloning and nucleotide sequence analysis of the novel Acinetobacter competence locus. The mutant locus of T701 was recovered on a 10.5-kb XbaI fragment (pAF701-1) and an overlapping 3.9-kb EcoRI-EcoRV fragment(pAF701-1.2) (Fig. 1A). Sequence analysis of the mini-Tn10-flankinggenomic DNA of the mutant loci recovered led to identificationof a 3'-end-truncated ORF, 'orf3, that was disrupted by transposoninsertion. This finding suggests that orf3 plays an essentialrole in natural transformation of Acinetobacter sp. strain BD413.To allow cloning of the complete orf3 wild-type allele, an additionalAcinetobacter orf3 mutant, designated T702, was generated by insertinga kanamycin marker gene (nptII) into the PstI site of orf3. Analysisof the transformation phenotype of the resulting mutant, T702(Fig. 2A), revealed a completely noncompetent phenotype. The mutantlocus of T702 was recovered on a 12.5-kb HincII fragment (pAF702-2)(Fig. 1A). To characterize the mutant loci of mutant T701 andT702, the inserts of plasmids pAF701-1 and pAF702-2 were subclonedinto a series of overlapping clones, and a sequence analysis wasperformed. These studies led to identification of six ORFs, designatedorf1, orf2, orf3, orf4, orf5, and orf6 (Fig. 2A).

Characterization of orf1, orf2, orf3, orf4, orf5, and orf6. Each ORF starts with an ATG start codon and is preceded by a well-conserved and well-placed ribosome binding site (53).Two potential ATG start codons were found for orf3. Due to thewell-placed conserved ribosome binding site, the second ATG isthought to represent the start codon. A conserved site for a presumptive $sigma$ ⁷⁰-dependent promoter was detected 68 bp upstream of this startcodon. Additional conserved sites for presumptive $sigma$ ⁷⁰ -dependent promoters were found 25 bp upstream of orf1 and 31bp upstream of orf5. A sequence with dyad symmetry that couldform a stem-loop structure and that may act as a rho-independentterminator (46) was found 18 bp downstream of the stop codonof orf2 and 13 bp downstream of the stop codon of orf6. The ORFsare tightly clustered, and the stop codon of orf1 overlaps thestart codon of orf2. This suggests that orf1 and orf2 may formanoperon.

Similarities of the deduced proteins with proteins in databases. The predicted proteins encoded by orf1, orf2, orf3, orf4, orf5, and orf6 comprise 411, 228, 792, 337, 338, and 268 amino acids,respectively, and have deduced molecular masses of 45, 25, 91,39, 37, and 31 kDa, respectively. Orf1 and Orf2 are similar tocomponents of ABC transporters. The protein product of orf1 is22% identical to membrane protein HI1548 of H. influenzae RdKW20(14) and 20% identical to DevC of Anabaena sp. strain PCC 7120,the integral membrane component of the DevBCA exporter (12).Hydropathy plots indicated that Orf1 is strongly hydrophobic andhas at least four transmembrane helices. Orf2 is similar to ATPbinding proteins of ABC transporters, exhibiting 41, 41, and 35%identity with UgpC (52) and GlnQ (40) of E. coli and DevAof Anabaena (12), respectively. ATP binding proteins of ABCtransporters are characterized by an ATP binding motif (Walkersites A and B) which is essential for ATP binding and is highlyconserved in Orf2 (11). The deduced protein encoded by orf3is similar to proteins required for genetic transformation ofdifferent gram-negative and gram-positive bacteria; for example,Orf3 is 40% similar to gonococcal ComA (10), B. subtilis ComEC(18) and H. influenzae Rec-2 (5) and 37% similar to CelBof S. pneumoniae (45). Based on the significant similaritiesand the suggested function of Orf3 in natural transformation,Orf3 was designated ComA. Acinetobacter ComA also exhibits structuralsimilarties with its homologs, including several hydrophobic domainsin the central part of the protein. At least six hydrophobic potentiallymembrane-spanning domains were found in Acinetobacter ComA betweenresidues 250 and 530, and two additional hydrophobic domains arepresent close to the Nterminus.

The deduced protein encoded by orf4 is similar to HtrB proteins, exhibiting 35 and 33% similarity to HtrB of H. influenzae(33) and HtrB of E. coli (26), respectively. HtrB proteinsare membrane-associated proteins that are involved in lipid Abiosynthesis and are required for rapid growth of E. coli at temperaturesabove 33°C (3, 27).

The protein product encoded by orf5 is similar to proteases. The deduced protein is 36 and 41% similar to proteinase IV ofE. coli (23) and PspA of Campylobacter jejuni (7), respectively.Proteinase IV of E. coli is a nonessential protease which digestscleaved signal peptides (23), and PspA of C. jejuni is thoughtto be involved in induction and/or processing of pilus subunits(7). Database searches with the deduced protein encoded byorf6 revealed no significant similarities to knownproteins.

comA complementation studies and disruption of comA-flanking ORFs. pRK415 derivatives pRK702-2.2 and pRK702-2.3 (Fig. 1A), both carrying the comA wild-type gene, were mobilized into noncompetentmutants T701 and T702, respectively, and were found to fully restoretransformation competence. These results provide clear evidencethat comA is essential for natural transformation in Acinetobactersp. strain BD413. Complementation of the noncompetent mutantswas independent of the orientation of the insert with respectto the lac promoter, indicating that expression of comA is undercontrol of its nativepromoter.

To address the question whether orf1, orf2, and orf4 are also implicated in natural transformation, the ORFs were subjectedto mutagenesis individually, and the resulting mutants were analyzedto determine their natural transformation phenotypes. Despitemany different attempts, mutagenesis of orf1 and orf2 was notpossible. This suggests that orf1 and orf2 have functions thatare essential for cell viability. The nptII marker gene was successfullyinserted into orf4 (Fig. 2A). The resulting mutant, T703, exhibitednormal growth rates and was not affected in terms of naturaltransformation.

Growth phase-dependent transcription of comA in Acinetobacter sp. strain ADP239. In order to gain insight into regulation of comA expression and to address the question of potential coregulation of comAwith the recently identified pilin-like genes required for genetictransformation of Acinetobacter, we constructed transcriptionalfusions of comA and a promoter-free lacZ gene and monitored $beta$ -galactosidaseactivities during growth. Upon transfer of the cells into freshmedium, comA transcription decreased rapidly, but then it recoveredsteadily during growth, reaching a maximum in the late stationaryphase (Fig. 3). The course of growth phase-dependent regulationis correlated with growth phase-dependent transcriptional regulationof the pilin-like competence genes comB, comE, comF, and comP(21, 48).

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FIG. 3. Growth phase-dependent transcription of comA in Acinetobacter sp. strain ADP239. comA transcription was monitored by using comA::lacZ reporter fusions located on low-copy-number plasmid pRK415. $beta$ -Galactosidase activity was monitored as described by Miller (37). Optical densities at 600 nm (OD 600) (

), $beta$ -galactosidase activities ( $black-lozenge$ ), and transformation frequencies (

) during growth were determined at the times indicated.

Identification of comEC and comEA competence genes in T. thermophilus HB27. Searches in the genome database for T. thermophilus HB27 with Acinetobacter sp. strain BD413 ComA led to identification ofan ORF whose product shows significant similarities to the Acinetobactersp. strain BD413 and N. gonorrhoeae ComA competence proteins andthe B. subtilis ComEC competence protein. Analysis of the regionupstream of this conserved ORF led to detection of an ORF encodinga putative protein with similarities to the B. subtilis proteinComEA, which is essential for genetic transformation of B. subtilis(17, 24). Based on the significant similarities and the organizationof these two ORFs, which were analogous to the B. subtilis comEA-comECcluster, they were designated comEA and comEC. The TGA stop codonof comEA in T. thermophilus HB27 overlaps the ATG start codonof comEC, indicating that putative cotranscription of the twoORFs occurs. Downstream of comEC an ORF nearly identical to theputative parB gene (accession no. AJ277593) of T. thermophilusHB8 was identified. The orientation of this ORF is opposite theorientation of comEA and comEC (Fig. 2B).

To examine the potential function of comEA and comEC in the transformation mechanism of the highly competent extreme thermophileT. thermophilus HB27, both ORFs were subjected to gene disruptionby using the thermostable kanamycin gene kat. The resulting kanamycin-resistantT. thermophilus HB27 mutants, designated TtAF1 and TtAF2 (Table1 and Fig. 2B), were analyzed to determine their transformationphenotypes by using the genomic DNA of a spontaneous streptomycin-resistantT. thermophilus HB27 mutant. In the comEA mutant natural transformationwas completely absent, whereas in the comEC mutant natural transformationwas significantly impaired (the natural transformation frequencieswere 1,000-fold lower). Since the orientation of the downstreamputative parB gene is opposite the orientation of comEA and comEC,the transformation defects of the comEA and comEC mutants cannotbe due to a polar effect on the parB gene. The gene organizationresults together with the results of the mutant studies provideclear evidence that the Thermus comEA-comEC locus is involvedin natural transformation. Since comEC is located downstream ofcomEA, the possibility that marker insertion in comEC has a polareffect on the preceding comEA gene can be excluded. The organizationof comEA and comEC, together with the results of the mutant studiesleads to the conclusion that comEC is important for natural transformation.Although the possibility that marker insertion in comEA has apolar effect on comEC cannot be excluded, the phenotypic differencesof the comEA and comEC mutants indicate that analogous to B. subtiliscomEA and comEC, both genes, comEA and comEC, are essential forT. thermophilustransformation.

Characterization of the comEC and comEA competence genes in T. thermophilus HB27. The protein encoded by comEC consists of 677 amino acids and has a calculated mass of 72 kDa. Thermus ComEC is 40, 40, 40,37, and 37% similar to ComA of Acinetobacter sp. strain BD413,ComEC of B. subtilis, Rec-2 of H. influenzae, ComA of N. gonorrhoeae,and CelB of S. pneumoniae, respectively. Like ComA of Acinetobactersp. strain BD413, ComEC of T. thermophilus HB27 is predicted tobe an inner membrane protein with six potentially membrane-spanningdomains in the centralpart.

The ComEA protein of T. thermophilus HB27 consists of 298 amino acids, has a calculated mass of 30 kDa, and is similar toComEA of B. subtilis and CelA of S. pneumoniae, which comprise205 and 216 amino acids, respectively (17, 45). In a C-terminal60-amino-acid overlap ComEA of T. thermophilus is 60% similarto the C-terminal domain of Bacillus ComEA and Streptococcus CelA(Fig. 4). This domain includes a helix-hairpin-helix motif whichis responsible for DNA binding, as demonstrated in B. subtilis(49).

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FIG. 4. Alignment of ComEA proteins. Identical residues are indicated by gray boxes. B.s., B. subtilis; S.p., S. pneumoniae; T.t., T. thermophilus HB27.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Here we describe identification of novel competence genes in the mesophilic soil bacterium Acinetobacter sp. strain BD413and the extremely thermophilic bacterium T. thermophilus HB27.The T. thermophilus HB27 competence genes are the first competencegenes identified in an extremely thermophilic bacterium so far.Based on sequence similarities, the novel competence genes inAcinetobacter and Thermus were designated comA and comEC, respectively.Both comA of Acinetobacter sp. strain BD413 and comEC of T. thermophilusHB27 were found to be essential for natural transformation. Sequenceanalysis of the comA locus of Acinetobacter sp. strain BD413 revealedsix tandemly arranged (ORFs), designated orf1, orf2, comA, orf4,orf5, and orf6. The comEC gene of T. thermophilus HB27 is precededby an ORF that encodes a protein with significant similaritiesto the B. subtilis competence protein ComEA (17, 24). ThisORF, designated comEA, was also found to be essential for naturaltransformation in Thermus. A comEA-like competence gene was notdetected close to the comA gene in Acinetobacter sp. strainBD413.

Despite the fact that comA of Acinetobacter sp. strain BD413 is not closely associated with the recently identified Acinetobactercompetence genes comP, comB, comE, and comF, growth phase-dependenttranscriptional regulation this comA gene is similar to regulationof the pilin-like competence genes comP, comB, comE, and comF.

Although T. thermophilus, B. subtilis, and S. pneumoniae are not closely related bacteria, the genes of the conserved comEClocus of T. thermophilus and B. subtilis and the homologous celBlocus of S. pneumoniae are organized analogously. In B. subtilis,T. thermophilus, and S. pneumoniae the competence gene comEC orcelB is closely associated with a second competence gene thatwas first described in B. subtilis as comEA. However, in contrastto B. subtilis, a homolog of an additional gene, comEB, whichis present in the Bacillus competence-specific operon, is notpresent T. thermophilus and S. pneumoniae (2, 17, 45).

Clues to the function of ComA in Acinetobacter sp. strain BD413 and the function of ComEC in T. thermophilus HB27 can be derivedfrom the significant similarities of these proteins to ComA ofN. gonorrhoeae, ComEC of B. subtilis, and Rec-2 of H. influenzae(8). comA mutants of N. gonorrhoeae have been shown to takeup DNA in a DNase-resistant state (9). This finding, togetherwith the prediction that there are several transmembrane $alpha$ -helices,led to the proposal that the gonococcal ComA protein may be anintegral membrane protein involved in DNA transfer across thecytoplasmic membrane (9, 10). The comEC product in B. subtiliswas also predicted to be a polytopic integral membrane proteinwith 8 to 10 transmembrane segments and was found to be essentialfor DNA uptake but not for DNA binding (17, 24). An analogousfunction has been suggested for Rec-2 of H. influenzae (4).Based on secondary structure predictions for ComA of Acinetobactersp. strain BD413 and ComEC of T. thermophilus HB27, six centraland two N-terminal hydrophobic regions are present in ComA andComEC, respectively. Furthermore, ComA of Acinetobacter sp. strainBD413 and ComEC of T. thermophilus both have a large, hydrophilic,positively charged domain near the N terminus, as well as a largehydrophilic, positively charged C-terminal domain which may belocalized in the cytoplasm, based on the rule that positive chargesof inner membrane proteins are oriented towards the cytoplasm(5). The N terminus of ComA of Acinetobacter sp. strain BD413has structural features characteristic of signal peptides (56)including (i) a positively charged N terminus (Arg-4), (ii) ahydrophobic core (Ile-15 to Ile-23), and (iii) a small neutralC-terminal residue. Positions $-$ 1 and $-$ 3 are known to be particularlyimportant for specifying the cleavage site, which could be betweenAla-25 (position $-$ 1) and Ile-26 (position 0) according to theproposal of von Heinje (55). In contrast to ComA of Acinetobactersp. strain BD413, the N terminus of ComEC of T. thermophilus doesnot exhibit structural features characteristic of signal peptides.Based on the structural characteristics and topology data, wepropose that ComA and ComEC of Acinetobacter and Thermus, repectively,are channel-forming polytopic membrane proteins implicated intransport of DNA through the cytoplasmicmembrane.

The broad distribution of ComA- and ComEC-like factors among very different bacteria independent of their phylogenetic relationshipsand their natural environments indicates that these proteins mayplay a central role in the transformation mechanisms of very differentbacteria and that these components are highlyconserved.

It has to be noted that except for the comEA gene of the comEC locus in T. thermophilus, no comEA-like genes have been foundclose to conserved comA/comEC-like genes in gram-negative bacteria,but interestingly, multiple copies of comEA-like genes have beenidentified in the genome of N. gonorrhoeae, and at least one ofthem is involved in natural transformation (I. Chen and E. C.Gotschlich, Abstr. 99th Gen. Meet. Am. Soc. Microbiol., abstr.D/B-10, p. 211, 1999). Analogously, the possibility that thereare genes in Acinetobacter sp. strain BD413 that exhibit similaritiesto the B. subtilis competence gene comEA also cannot be excluded,and this question remains an interesting topic for thefuture.

	ACKNOWLEDGMENTS

This work was supported by grant Av 9/4-4 from the Deutsche Forschungsgemeinschaft. A. Friedrich was supported by the Fondder ChemischenIndustrie.

	FOOTNOTES

^* Corresponding author. Present address: Institut für Genetik und Mikrobiologie, LMU, Maria-Ward-Str. la, 80638 Munich, Germany.Phone: 49-89-21806186. Fax: 49-89-21806160. E-mail: B.Averhoff{at}lrz.uni-muenchen.de.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Busch, S., C. Rosenplänter, and B. Averhoff. 1999. Identification and characterization of ComE and ComF, two novel pilin-like competence factors involved in natural transformation of Acinetobacter sp. strain BD413. Appl. Environ. Microbiol. 65:4568-4574[Abstract/Free Full Text].
2.	Campbell, E. A., S. Y. Choi, and H. R. Masure. 1998. A competence regulon in streptococcus pneumoniae revealed by genomic analysis. Mol. Microbiol. 27:929-939[CrossRef][Medline].
3.	Clementz, T., J. J. Bednarski, and C. R. Raetz. 1996. Function of the htrB high temperature requirement gene of Escherichia coli in the acylation of lipid A: HtrB catalyzed incorporation of laurate. J. Biol. Chem. 271:12095-12102[Abstract/Free Full Text].
4.	Clifton, S. W., D. McCarthy, and B. A. Roe. 1994. Sequence of the rec-2 locus of Haemophilus influenzae: homologies to comE-ORF3 of Bacillus subtilis and msbA of Escherichia coli. Gene 146:95-100[CrossRef][Medline].
5.	Dalbey, R. E. 1990. Positively charged residues are important determinants of membrane protein topology. Trends Biochem. Sci. 15:253-257[CrossRef][Medline].
6.	de Grado, M., P. Castan, and J. Berenguer. 1999. A high-transformation-efficiency cloning vector for Thermus thermophilus. Plasmid 42:241-245[CrossRef][Medline].
7.	Doig, P., R. Yao, D. H. Burr, P. Guerry, and T. J. Trust. 1996. An environmentally regulated pilus-like appendage involved in Campylobacter pathogenesis. Mol. Microbiol. 20:885-894[CrossRef][Medline].
8.	Dubnau, D. 1999. DNA uptake in bacteria. Annu. Rev. Microbiol. 53:217-244[CrossRef][Medline].
9.	Facius, D., M. Fussenegger, and T. F. Meyer. 1996. Sequential action of factors involved in natural competence for transformation of Neisseria gonorrhoeae. FEMS Microbiol. Lett. 137:159-164[CrossRef][Medline].
10.	Facius, D., and T. F. Meyer. 1993. A novel determinant (comA) essential for natural transformation competence in Neisseria gonorrhoeae and the effect of comA defect on pilin variation. Mol. Microbiol. 10:699-712[CrossRef][Medline].
11.	Fath, M. J., and R. Kolter. 1993. ABC transporters: bacterial exporters. Microbiol. Rev. 57:995-1017[Abstract/Free Full Text].
12.	Fiedler, G., M. Arnold, S. Hannus, and I. Maldener. 1998. The DevBCA exporter is essential for envelope formation in heterocysts of the cyanobacterium Anabaena sp. strain PCC 7120. Mol. Microbiol. 27:1193-1202[CrossRef][Medline].
13.	Figurski, D. H., and D. R. Helinski. 1979. Replication of an origin-containing derivate of plasmid RK2 dependent on a plasmid function provided in trans. Proc. Natl. Acad. Sci. USA 76:1648-1652[Abstract/Free Full Text].
14.	Fleischmann, R. D., M. D. Adams, O. White, R. A. Clayton, E. F. Kirkness, A. R. Kerlavage, C. J. Bult, J. F. Tomb, B. A. Dougherty, J. M. Merrick, et al. 1995. Whole-genome random sequencing and assembly of Haemophilus influenzae Rd. Science 269:495-512.
15.	Gebhard, F., and K. Smalla. 1998. Transformation of Acinetobacter sp. strain BD413 by transgenic sugar beet DNA. Appl. Environ. Microbiol. 64:1550-1554[Abstract/Free Full Text].
16.	Gregg-Jolly, L. A., and L. N. Ornston. 1994. Properties of Acinetobacter calcoaceticus recA and its contribution to intracellular gene conversion. Mol. Microbiol. 12:985-992[Medline].
17.	Hahn, J., G. Inamine, Y. Kozlov, and D. Dubnau. 1993. Characterization of comE, a late competence operon of Bacillus subtilis required for the binding and uptake for transforming DNA. Mol. Microbiol. 10:99-111[Medline].
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