Evolution of a Pathway for Chlorobenzene Metabolism Leads to Natural Attenuation in Contaminated Groundwater

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Applied and Environmental Microbiology, November 1998, p. 4185-4193, Vol. 64, No. 11
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Evolution of a Pathway for Chlorobenzene Metabolism Leads to Natural Attenuation in Contaminated Groundwater

Jan Roelof van der Meer,¹ Christoph Werlen,¹ Shirley F. Nishino,² and Jim C. Spain²^,^*

Swiss Federal Institute for Environmental Science and Technology (EAWAG), CH 8600 Dübendorf, Switzerland,¹ and Air Force Research Laboratory/MLQR, Tyndall Air Force Base, Florida 32403-5323²

Received 1 May 1998/Accepted 18 August 1998

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

Complete metabolism of chlorinated benzenes is not a feature that is generally found in aerobic bacteria but is thought tobe due to a novel recombination of two separate gene clusters.Such a recombination could be responsible for adaptation of anatural microbial community in response to contamination withsynthetic chemicals. This hypothesis was tested in a chlorobenzene(CB)-contaminated aquifer. CB-degrading bacteria from a contaminatedsite were characterized for a number of years by examining a combinationof growth characteristics and DNA-DNA hybridization, PCR, andDNA sequence data. The genetic information obtained for the CBpathway of the predominant microorganism, Ralstonia sp. strainJS705, revealed a unique combination of (partially duplicated)genes for chlorocatechol degradation and genes for a benzene-toluenetype of aromatic ring dioxygenase. The organism was detected inCB-polluted groundwater by hybridizing colonies cultivated onlow-strength heterotrophic media with probes for the CB pathway.Southern hybridizations performed to determine the organizationof the CB pathway genes and the 16S ribosomal DNA indicated thatCB-degrading organisms isolated from different wells at the sitewere identical to JS705. Physiological characterization by theBiolog test system revealed some differences. The genes for thearomatic ring dioxygenase and dihydrodiol dehydrogenase of JS705were detected in toluene and benzene degraders from the same site.Our results suggest that recent horizontal gene transfer and geneticrecombination of existing genes between indigenous microorganismswere the mechanisms for evolution of the catabolic pathway. Evolutionof the CB pathway seems to have created the capacity for naturalattenuation of CB at the contaminatedsite.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

The ability of bacteria to adapt in order to exploit novel chemicals as growth substrates has been the subject of intensivestudy for almost 50 years. Early studies revealed that the enhanceddegradation of pesticides applied to agricultural soils (2).Subsequent work revealed that similar phenomena allow bacteriato degrade synthetic contaminants in a variety of ecosystems (5,6, 16, 23, 36, 38, 39, 46). Some synthetic contaminants,notably chlorinated aromatic compounds like chlorobenzenes (CBs),chlorobiphenyls, and chlorinated herbicides, can be recalcitrantto biodegradation (1, 29), perhaps because they were introducedinto the environment only recently. Chloroaromatic compounds arenot readily degraded by most microorganisms; however, bacteriathat are able to use these compounds as sole sources of carbonand energy have been isolated, mostly from contaminated ecosystems(4, 28, 35, 44).

Three possible mechanisms have been put forward to explain the apparent adaptation of microbial communities. Appropriate strainsmight (i) have been present in the community in numbers belowthe detection limit, (ii) have been introduced into the communityby dispersal from a distant area, or (iii) have arisen by geneticchanges within the indigenous community (35, 44).

Most bacteria that are able to use chlorinated aromatic compounds as sole sources of carbon and energy were isolated fromenrichment cultures prepared with inocula from polluted environments(5, 6, 10, 13, 32, 34, 37, 42, 46, 51).Although the strains and the genes for some of the degradativepathways were characterized in detail, whether the strains wererepresentative of the bacteria in the environments from whichthey were enriched or were artifacts of the enrichment procedurewas not known (35, 44). Studies of CB- and 2,4-dichlorophenoxyaceticacid (2,4-D)-degrading bacteria isolated from contaminated ecosystemssuggested that genetic changes were the major cause of the adaptationof the organisms (14, 19, 33, 48, 49). The most obviouschanges involved the presence of insertion elements or transposonsnear or within the genes that encode the metabolic pathways forbreakdown of the chloroaromatic compounds. It was postulated thatthe activity of the mobile elements caused new DNA rearrangementsand horizontal transfer of genetic material (19, 43, 50).These observations suggested that "novel" pathways were simplybuilt by adding existing genetic material from different microorganismsto the genome of a single organism. For example, the genes forCB degradation in Pseudomonas sp. strain P51 are organized intwo distinct regions (47), one of which is a transposable elementcontaining five genes necessary for the conversion of CB to chlorocatechol(48). These five genes are very similar to genes in bacteriathat degrade toluene (49). The other region contains the genesfor metabolism of chlorocatechols, which are very similar to genesin bacteria that degrade 3-chlorobenzoate (3-CBA) or 2,4-D (7,25, 45). The combination of these two regions in strain P51,however, is unique and is not found in bacteria that degrade toluene,3-CBA, or 2,4-D. Similar observations have been made for otherbacteria, including the 2,4-D-degrading organism Ralstonia eutrophaJMP134(pJP4) (14, 19). The formation of a pathway for CB degradationin a single microorganism after starting with two different specieshas also been documented in laboratory experiments (17, 24).

To date, little direct information is available on where and when genetic adaptation has taken place in natural environments.Recent field data suggested that horizontal transfer of naphthalene-degradativegenes occurred among members of a soil bacterial community (12).In the present work we investigated the origin of CB-degradingbacteria in contaminated groundwater at Kelly Air Force Base (KAFB)in Texas. CB-degrading bacteria can be isolated only from theCB-contaminated area at KAFB, not from the region outside thisarea. The contaminated site at KAFB, therefore, provided an opportunityto study the mechanisms responsible for adaptation of the microbialcommunity to degrade CB. The purpose of the study was to determinewhich of the following hypotheses best explains the adaptationof the microbial community to degrade CB. If the CB-degradingbacteria had been present in the indigenous communities in lownumbers prior to contamination, they should have been detectablewith sensitive molecular techniques (colony hybridization, whichcan detect 1 in 10⁴ cells [30], or PCR, which can detect 10² cells per ml [41]) or with selective enrichment and platingtechniques. If the CB pathway arose only once and reached KAFBby recent dispersal from elsewhere, all of the CB-degrading bacteriafrom a variety of sites should contain related genetic materialand should be less closely related to indigenous bacteria. Ifthe ability to degrade CB arose once at KAFB, identical genesfor the pathway should be distributed throughout the site. Thegenes should be different from the genes in CB-degrading bacteriaelsewhere and should be related to genes in indigenous bacteria.Finally, if the ability to degrade CB arose repeatedly throughoutthe contaminated site, a variety of gene combinations should bepresent, and they should be related to genes in indigenousbacteria.

To test the hypotheses described above, a variety of microbial isolation procedures and genetic techniques were employed.DNA probes and primers derived from the CB pathway genes of apredominant CB-degrading organism obtained from polluted groundwaterat KAFB were used to screen bacteria isolated from different wellsat KAFB under selective and nonselective conditions. The experimentswere conducted with groundwater obtained within and outside thecontaminated area at intervals over severalyears.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Site description. Groundwater samples were collected from monitoring wells located in a CB plume emanating from a former waste solvent storagearea at KAFB near San Antonio, Tex. (Fig. 1). The storage facility,known as site S1, was used from 1960 until 1973 (26). The contaminatedaquifer consists of silty sand and clay 7.6 to 10.4 m below thesurface. During 1993 and 1994 a program was begun to halt theflow of contaminants from the source area by pumping water froma series of wells just downstream of the source area. The wellsthat were sampled were selected based on the 1990 plume map (Fig.1) and included a transect along the length of the CB plume, aswell as uncontaminated wells outside the plume. Possibly due inpart to a 2-year drought in Texas during 1995 and 1996, waterwas present only sporadically in one of the wells (well S1-1)located close to the source.

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FIG. 1. Schematic overview of the CB plume and sampling wells at KAFB site S1. The interpolated isoconcentrations (in micrograms per liter) were derived from measurements obtained at observation wells in 1990 (light lines) and 1996 (dark lines). The direction of the groundwater flow is indicated by the arrow.

Sample collection and isolation of bacteria with specific degradative abilities. The sampling strategy used for the last 6 years is shown in Table 1; 2 to 3 well volumes was removed from each sampling well,and samples (1 liter) were collected aseptically. The numbersof heterotrophic CFU were estimated by spreading serial dilutionsonto one-quarter-strength tryptic soy agar plates and incubatingthe plates for 3 days at 30°C. Specific capacities to degradearomatic substances were determined by spreading appropriate dilutionsof groundwater on one-quarter-strength minimal medium (MSB) (40)solidified with 1.8% (wt/vol) agar. Aromatic substrates were providedindividually; CB, toluene, and benzene were each provided as avapor (10). 3-CBA and 2,4-D were dissolved in the media at aconcentration of 2.5 mM. Plates were incubated for 5 days at 30°Cand examined for the presence of colonies. When no visible coloniesappeared, the plates were incubated for an additional 20 daysand reexamined twice weekly. Large colonies that grew on eachsubstrate were retested along with appropriate controls to confirmthat the substrate was degraded (10). When the plating methodwas used, the detection limit for CB-degrading bacteria in groundwaterwas 20 CFU/ml.

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TABLE 1. Sampling dates and summary of studies performed at KAFB

Groundwater samples from wells outside the CB plume were used as inocula for enrichment cultures to which CB was suppliedin the vapor phase (50 ml of groundwater was mixed with 50 mlof MSB). The cultures were incubated at 30°C with shaking (250rpm). After 2 months of incubation, the cultures were sampledto determine whether CB-degrading bacteria were present, as describedabove. All confirmed CB-degrading isolates and 300 benzene- andtoluene-degrading isolates were grouped on the basis of theirGram reactions and cell and colony morphology and were characterizedby using Biolog GN or GP (Biolog, Hayward, Calif.) microplatesas appropriate. Strains were also compared after PCR amplificationof parts of their 16S ribosomal DNA (rDNA) with primers V1.1 andV3.2, restriction enzyme digestion of the amplification productswith HaeIII and Sau3AI, and separation of the restriction fragmentsby agarose gelelectrophoresis.

Bacteria and plasmids. Escherichia coli DH5 $alpha$ , the host bacterium used for all cloning experiments and plasmid isolations, was cultivated on Luria-Bertanimedium (31) supplemented with ampicillin (50 µg/ml) when appropriate.Ralstonia sp. strain JS705 was isolated from well S1-1 by growingit on CB. It was cultivated on MSB medium supplemented with CBvapor in closed flasks at 30°C. Other bacterial strains isolatedduring this study are listed in Table 2.

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TABLE 2. Properties of isolates

The plasmids used for heterologous hybridization with strain JS705 were pTCB111 (containing a tcbAaAb gene fragment) (49),pDTG351 (containing todC1C2BADE) (52), and pDC1001 (containinga 1.8-kb EcoRI-HindIII fragment of pDC100 with clcA) (7). VectorspUC18 (31), pT7Blue T (Novagen, Madison, Wis.), and pGEM-T Easy(Promega Corp., Madison, Wis.) were used to clone JS705 DNA fragments.We constructed pCBA24, which contains a 4.8-kb PstI fragment inpUC18, pCBA21, which contains a 4.5-kb PstI fragment, and pCBA31,which contains a 3.5-kb BamHI fragment in pUC18 (see below). pCBA32contains a randomly derived 3.8-kb BamHI fragment of the genomicDNA of JS705. Plasmid pCBA117 contains a 1,504-bp region of the16S rDNA of strain JS705 that was amplified by PCR with two eubacterialprimers, primers 6F and 1510R (Table 3). The fragment was clonedin plasmid pT7Blue T, and the sequences of both strands were determined.

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TABLE 3. Primers used

Colony and Southern hybridizations. The water from wells S1-1 and S1-2 used for colony hybridization was serially diluted with filter-sterilized groundwater fromthe site. Samples (100 µl) were spread onto PTYG agar containing(per liter) 0.5 g of peptone, 0.5 g of tryptone, 0.25 g of yeastextract, 0.5 g of glucose, 700 mg of MgCl₂, and 100 mg of CaCl₂.Plates were incubated at 20°C for 4 weeks. Plates containing 10³ to 10⁴ colonies were used for colony blotting and hybridization. Colonyblotting was performed on Qiabrane nylon membranes (Qiagen, Basel,Switzerland) by using previously described procedures (31).Spots that reacted positively in the DNA-DNA hybridization experimentswere matched with the colonies on the original agar plates andwere restreaked onto PTYG agar to obtain purecultures.

DNA-DNA hybridizations were performed with different gene probes at 62°C under stringent conditions by using previously describedprocedures (31). The probes used were the 4.5-kb PstI fragmentof plasmid pCBA21 and the 3.5-kb BamHI fragment of plasmid pCBA31(Fig. 2).

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FIG. 2. Genetic and physical organization of the CB pathway genes of strain JS705. (A) The upper line shows the relative positions of the aromatic ring dioxygenase gene cluster (mcb) and the genes for chlorocatechol degradation (clc) and their orientations (as determined by DNA sequencing). Below this are the approximate locations of the primer sets used (Table 3). Restriction site abbreviations: P, PstI; E, EcoRI; S, SalI; B, BamHI; X, XhoI; H, HindIII. At the bottom the cloned fragments of the region and the plasmid designations are indicated. (B) Initial enzymatic steps in the degradation of CB and toluene. The initial dioxygenation and rearomatization steps in toluene degradation are carried out by enzymes which can also mediate CB conversion.

Isolating DNA from groundwater and PCR amplification. Samples of groundwater from wells S1-1, S1-2, and S1-180 (0.5 liter) were centrifuged for 10 min at 10,000 × g in sterile250 ml centrifuge tubes. Sterilized double-distilled H₂O was processedas a control. DNA was isolated from the cell pellet essentiallyas described by Hallier-Soulier et al. (11).

PCR was used to detect DNA identical to the CB pathway genes of strain JS705. The following three sets of primers were developedand synthesized: (i) primers for specific detection of a regionin the clcA gene, (ii) primers for detection of the gene for thelarge subunit of the CB dioxygenase of strain JS705 (mcbAa), and(iii) primers for detection of the region between the clcA andmcbF genes of strain JS705 (Fig. 2 and Table 3). The compositionof the PCR mixture was the composition specified by the manufacturer(Life Technologies, Gaithersburg, Md.). Amplification productseither were analyzed on an agarose gel, blotted, and hybridizedfor verification or were cloned andsequenced.

DNA techniques. Analysis of DNA fragments on agarose gels, cloning of DNA fragments, plasmid isolation, restriction digestion, purificationof DNA fragments, and radioactive labeling were all performedby using previously described procedures (31) or the specificationsof the supplier. DNA sequencing was performed with double-strandedDNA templates by cycle sequencing by using fluorescently labeledprimers (IRD800; MWG, Ebersberg, Germany) and the protocol ofa Thermo Sequenase kit (Amersham Life Sciences, Little Chalfont,United Kingdom). Sequence reaction products were separated withan automated DNA sequence analyzer (model 400L; LiCOR, Lincoln,Nebr.).

Nucleotide sequence accession numbers. The nucleotide sequence of JS705 rDNA has been deposited in the GenBank database under accession no. AF027407. The nucleotidesequences of the clcR and clcA genes and of the mcbFAaAbAcAd geneshave been deposited in the GenBank database under accession no.AJ006307.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Detection and isolation of DNA encoding the CB degradation pathway of strain JS705. Strain JS705 was isolated from CB-contaminated groundwater at KAFB in 1992 (Table 1). Biolog GN microplate analysis resultedin identification of the strain as a member of the genus Comamonas.However, a 16S rDNA sequence analysis indicated that the highestidentity (97.4% in a 1,497-bp overlap region) was with R. eutropha(GenBank accession no. M32021). The 16S rDNA sequence of strainJS705 also clustered nearest to R. eutropha 16S rDNA sequence,as determined by the Ribosomal Database Project program SuggestTree(20), when a subsequence alignment was examined. Therefore,we named strain JS705 Ralstonia sp. strainJS705.

Total genomic DNA of JS705 was analyzed by Southern hybridization to determine whether genetic material similar to the genesfor the CB degradation pathway of Pseudomonas sp. strain P51 (45,49), for the toluene degradation pathway of Pseudomonas putidaF1 (52), and for the chlorocatechol degradation pathway of P.putida(pAC27) (7) was present. Very strong hybridization signalswere obtained with DNA probes containing the clcRABD genes (Fig.3) and DNA probes containing the tcbAaAb genes or the todC1C2ABgenes (data not shown). Three restriction fragments were clonedfrom strain JS705 into pUC18. One 4.5-kb PstI fragment (pCBA21)contained a clcRABD gene cluster that exhibited 99% DNA sequenceidentity to the gene cluster of P. putida(pAC27) (7) (Fig.2). A 4.8-kb PstI fragment (pCBA24) contained a partial duplicationof the clcRABD gene cluster. The duplicated genes, clcR and clcA,were upstream of a gene similar to todF (21), which was tentativelydesignated mcbF. The third cloned fragment, a 3.5-kb BamHI fragment(pCBA31), contained the genes for an aromatic ring dioxygenase(tentatively designated mcbAaAbAcAd) similar to the dioxygenasesencoded by the tcbAaAbAcAd (49) and todC1C2BA genes (52).The identities of all of the genes were confirmed by DNA sequencing(GenBank accession no. AJ006307). We hybridized these threecloned fragments with total DNA of strain JS705 that was digestedwith different combinations of restriction enzymes, and we constructeda physical map of the region where the CB pathway genes are located(Fig. 2). Our results revealed a unique and distinctive arrangementof genes for CB degradation in strain JS705. Although not allof the genetic and biochemical details were analyzed, we presumed,based on the strong sequence similarities between the CB genesof JS705 and the CB genes of other strains, that the CB pathwayof strain JS705 is encoded by the single region analyzed here(Fig. 2).

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FIG. 3. Southern hybridization of Ralstonia sp. strain JS705 total DNA with the 1.8-kb EcoRI-HindIII fragment of plasmid pDC1001 which carries clcA (7). Multiple bands indicate the duplicated nature of the clc gene fragments in strain JS705. Lanes X, B, P, S, E, and H, DNA digested with XhoI, BamHI, PstI, SalI, EcoRI, and HindIII, respectively.

Direct screening of colonies grown from groundwater samples by DNA-DNA hybridization. To determine the abundance of strain JS705 genetic material in groundwater, in 1994 we screened (using the colony hybridizationtechnique) 10⁴ colonies from well S1-1 (grown on PTYG agar) and 10⁵ colonies from well S1-2. Using the CB pathway probes (the insertsof plasmids pCBA21 and pCBA31), we detected 5 to 10 signals oneach membrane blotted from plates containing 10³ colonies from contaminated well S1-1. A total of 10 membranes,each containing 10⁴ colonies from uncontaminated well S1-2, were examined, and onlyone signal was found for each probe. All positive spots on wellS1-1-derived membranes reacted with both of the CB pathway probes.The two positive spots from well S1-2 samples did not cross-react.

To verify that the hybridizing colonies contained genetic material related to the genetic material of strain JS705, we isolatedDNA from nine positive colonies grown on the original agar platesfrom well S1-1 samples that had been used for hybridization. In6 of the 9 colonies we detected a proper-size DNA fragment whenPCR were performed with the clc primers (data not shown). Nonspecificamplification products were obtained with DNA from the other threecultures. Total DNA isolated from the six positive cultures, digestedwith XhoI, BamHI, or HindIII, and hybridized with probes for theclc genes from JS705(pCBA21) and for the mcb genes (pCBA31) producedpatterns similar to the JS705 pattern (data not shown). The 16SrDNA that were amplified with primers V1.1 and V3.2 (Table 3)and digested with Sau3AI and HaeIII produced the same restrictionpatterns as JS705 16S rDNA produced, which indicates that theorganisms were taxonomically very similar (Fig. 4). Neither ofthe two positively reacting spots from the well S1-2 groundwatersamples could be recovered because of the high colony densitieson the original plates.

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FIG. 4. Restriction digests of a PCR product amplified with the 16S rDNA primers from colonies that were positive in colony hybridization experiments. The positions of size markers (in kilobases) are indicated on the left. Lanes a, Sau3AI digests; lanes b, HaeIII digests; lanes c, undigested products. Lanes 1 through 5 and 7 contained six independently derived colonies; lane 6 contained the 1-kb marker; lanes 8 contained no DNA; and lanes 9 and 10 contained JS705.

Screening of DNA purified from the groundwater samples by PCR. Because no CB-degrading bacteria were detected in wells outside the CB-contaminated area in 1992 and 1993, we used PCR todetermine whether genetic material similar or identical to thegenetic material encoding the CB pathway in strain JS705 couldbe detected in uncontaminated groundwater. Purified DNA obtainedfrom groundwater from wells S1-1 and S1-2 in 1994 and 1996 andfrom well S1-180 in 1996 were used as targets in the PCR (Table1). Proper-size amplification products were detected in the DNAfrom wells S1-1 and S1-180 with mcbA primers. The identities ofthe products were confirmed by hybridization with the insert ofpCBA31 and by DNA sequencing (data not shown). No amplificationproduct for mcbA was obtained with DNA from well S1-2 in 1994.When the clcA gene primers were used, amplification products weredetected in DNA from groundwater from wells S1-1, S1-2, and S1-180.The identities of these products were confirmed by hybridizationwith the clcA probe. When the primer set for the combination clcA-mcbFwas used, we detected amplifiable targets in samples from wellS1-1 in 1994 and from well S1-180 in 1996. Using DNA isolatedfrom well S1-2 in 1996 resulted in amplification products withall three primer sets used for the CB pathway genes of strainJS705 (data notshown).

Screening of CB degraders isolated from different wells on KAFB. The results of the 1994 screening study of DNA isolated from groundwater with probes derived from JS705 led us to examineadditional wells at site S1 in 1996 and 1998 (Table 1). Sampleswere also inoculated onto plates containing toluene, benzene,3-CBA, or 2,4-D to determine whether the parental genes for theCB pathway of JS705 could be recovered in other bacteria fromsiteS1.

The total numbers of bacteria recovered from the various wells varied by 2 orders of magnitude (Table 4). CB-degrading bacteriawere isolated without enrichment from wells S1-10, S1-11, andS1-2 in 1996. Growth of the CB-degrading strains was immediateand rapid, indicating that the bacteria were active in the groundwater(22, 23). The uncontaminated wells (wells S1-18, S1-179, andS1-180) yielded no bacteria that were able to grow on CB eitherby direct isolation or in enrichment cultures in 1996. Well S1-2was negative when it was sampled in 1993 and 1994, but in 1996it yielded a small number of CB-degrading isolates. However, wellS1-2 is only slightly upgradient of the plume source, and it ispossible that contaminated water reached the well in 1996. Incontrast to samples obtained in 1993 and 1994, in December 1996well S1-1 yielded no CB-degrading bacteria. However, this wellwas dry in September 1996. Samples were obtained from wells S1-1,S1-2, and S1-180 in 1998, and CB-degrading bacteria were foundonly in well S1-1. These results were consistent with observationsmade in 1993 and 1994 but conflicted with results obtained inDecember 1996.

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TABLE 4. Numbers of culturable bacteria in groundwater in September and December 1996

The 55 CB-degrading isolates obtained in 1996 accounted for about 10% of the total CFU grown on tryptic soy agar. Two CB-degradingisolates also degraded benzene, and one degraded benzene and toluene.A total of 220 benzene-degrading isolates and 110 toluene-degradingisolates were recovered from the three wells sampled in September1996. None of the isolates selected on benzene or toluene coulddegradeCB.

CB degraders isolated from well S1-1 in 1993 and before and from wells S1-10 and S1-11 in 1996 were characterized by PCR andSouthern hybridization to determine whether they were similarto strain JS705. All of these organisms hybridized to the clcprobe (insert from pCBA21), to the mcb probe (insert from pCBA31),and to a 16S rDNA probe (insert from pCBA117) with the same patternas JS705 (Fig. 5). CB degraders isolated from other CB-contaminatedsites (one example of which is shown in Fig. 5, lane 9) produceddistinctly different patterns. DNA amplified by PCR from the 55CB-degrading strains isolated from site S1 with the three primersets used for the CB pathway genes from JS705 and with primersV1.1 and V3.2 and digested with the appropriate restriction enzymesproduced the same restriction patterns as JS705 (data not shown).These results indicate that the genes for the CB pathway werethe same in all of the CB-degrading isolates from site S1. Thedifferent CB-degrading strains could not be distinguished by geneticscreening, although differences were detected in Biolog test results(Table 2).

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FIG. 5. Southern hybridization of total DNA of selected CB degraders isolated from wells at KAFB with the pCBA21 insert for the clc genes (A) and with 16S rDNA derived from JS705 (B). DNA were digested with BamHI. Lane 1, strain JS702; lane 2, strain JS707 (a non-CB degrader); lane 3, strain JS711; lane 4, strain JS755; lane 5, strain JS756; lane 6, strain JS757; lane 7, strain JS758; lane 8, strain JS759; lane 9, strain JS727; lane 10, strain JS705. Most strains were isolated from KAFB; the only exception was strain JS727, which was isolated from Robins Air Force Base in Georgia in 1993.

Detection of genes identical to the mcb genes of strain JS705 in toluene- and benzene-degrading bacteria. Twelve representative toluene- and/or benzene-degrading bacteria isolated from site S1 were analyzed to determine the presenceof gene fragments similar to the CB pathway genes of strain JS705.Four isolates from well S1-11 and one isolate from S1-180 yieldeda product after PCR amplification with the mcb primer set. Noamplification products were obtained with the clc or mcbF-clcAprimer set. DNA sequencing of the mcb products revealed that threeof the five strains (JS743, JS745, and JS751) had a 617-bp sequencethat was identical to the sequence of the JS705 fragment (datanotshown).

Hybridization of the PstI fragment of pCBA24 with PstI-digested total DNA resulted in one positively reacting band in strainsJS743, JS745, and JS751 and two different bands in JS705 (Fig.6A). When BamHI-digested DNA was used, only one correspondingBamHI fragment (1.3 kb) was found (data not shown). The 1.3-kbBamHI fragment encompassed the mcbF gene in JS705 (Fig. 2 and6), and the results suggested that mcbF was present in the threetoluene- and benzene-degrading organisms examined. The other twostrains (JS744 and JS749) hybridized weakly with the PstI insertof pCBA24, suggesting that there was sequence similarity withparts of the probe (probably the mcbF part) but no identity (sincethe restriction patterns were different). No evidence of the clcRAgenes (Fig. 6A) or of the clcBD genes (i.e., the pCBA21 insert(data not shown) was found in the benzene- and toluene-degradingbacteria. Hybridization of the pCBA31 insert with BamHI-digestedDNA samples yielded a single band having the same size in JS705,JS743, JS745, and JS751 (data not shown). When the same probeand PstI-digested samples were used, two of three bands were thesame in JS705, JS743, JS745, and JS751 (Fig. 6B). The 1.4-kb PstIfragment that hybridized in JS705 DNA was replaced by a 4.5-kbband in JS743, JS745, and JS751. Hybridizations of the same blotswith a probe for the 16S rDNA of strain JS705 revealed clear differences(Fig. 6C). Strains JS743, JS745, and JS751 produced identicalband patterns, whereas the other two toluene and benzene degraders(JS744 and JS749) and JS705 were clearly different. These resultsindicated that the genes for the initial steps in CB degradationin JS705 were identical to the genes in the indigenous tolueneand benzene degraders (JS743, JS745, and JS751).

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FIG. 6. Southern hybridization of total DNA of selected toluene and benzene degraders from wells S1-11 and S1-180 and of JS705 with probes for the clc-mcbF genes (insert of pCBA24) (A), for the mcbAB genes (pCBA31) (B), and for 16S rDNA (C). All DNAs were digested with PstI. Lane 1, strain JS743; lane 2, strain JS751; lane 3, strain JS745; lane 4, strain JS744; lane 5, strain JS749; lane 6, strain JS705. The positions of size markers (1-kb ladder) are indicated on the left. An interpretation of the hybridization results is shown at the bottom.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

Natural attenuation can be an important process by which pollutants disappear from the environment without high treatmentcosts. This process is suitable for natural chemicals, such aspetroleum hydrocarbons, which are readily metabolizable by ubiquitousmicroorganisms in most ecosystems (3, 18). CBs, however,are among the synthetic chemicals which are not usually metabolizedby natural communities (10, 27, 44, 46). Our observationsat KAFB site S1 demonstrated that spontaneous natural attenuationof CBs has occurred since 1990 and that the size of the contaminantplume has decreased. Since active CB-degrading bacteria were detectedalmost exclusively in groundwater from wells with the highestCB concentrations, our results provide evidence that the populationof CB degraders was maintained by mineralization of CB. When theCB was depleted, the population of CB degraders fell to undetectablelevels in the groundwater. Clearly, our samples reflected onlywhat was present in the groundwater itself and, therefore, probablyunderestimated the biomass in thesystem.

The results of our investigations support the hypothesis that the ability to degrade CB was not present initially but aroseonce, relatively recently, in the microorganisms at site S1. TheCB degradation pathway in the form that is present in strainsat KAFB probably arose by relatively simple horizontal gene transferand gene recombination between different ancestral strains. Thehost that finally obtained the CB pathway genes gained a selectiveadvantage and colonized most of the CB-contaminatedarea.

Our arguments that support this hypothesis and not the alternative hypotheses described in the introduction are as follows.First, the CB-degrading bacteria predominant in the groundwaterat the site, as exemplified by Ralstonia sp. strain JS705, allhad the same genetic organization of the genes for CB degradation.This organization was unique and clearly different from the geneticorganizations observed in CB-degrading bacteria from other sites,such as Robins Air Force Base (Fig. 5), or in Pseudomonas sp.strain P51 (47). Second, some of the CB degradation genes instrain JS705 were identical to genes found in indigenous bacteriaat the site. Thus, the possibility that the bacterium degradingCBs at site S1 arose elsewhere and was transported to KAFB seemshighlyunlikely.

Third, our results indicate that CB-degrading bacteria were not present in low numbers at the site before contamination. Despiteseveral attempts, we could not consistently isolate CB-degradingbacteria from wells outside the contaminated zone by direct platingand enrichment techniques or by colony hybridization with heterotrophicallygrown bacterial colonies; CB-degrading bacteria were isolatedonly from wells within the contaminated zone. Clearly, it is impossibleto prove unequivocally that there were no CB-degrading bacteriaoutside the contaminated zone or at site S1 before CB contaminationwas present. Furthermore, we did not sample the subsurface solids,which may harbor a larger population of bacteria, including theancestors of the CB pathway bacteria or other CB-degrading bacteria.However, within the limits of our analyses (the detection limitswere 0.02 CFU/ml for the enrichment technique and 1 in 10⁵ culturable microorganisms for colony hybridization), no CB degraderswere detected in uncontaminated subsurfacematerial.

The temporal and spatial variability in the water levels at the site during the study period probably resulted in some anomalousfindings. For example, one of the wells sampled in this study(well S1-16) could be considered formerly contaminated. This welldid not yield CB-degrading bacteria, which was consistent withthe hypothesis that the presence of CBs is required to supporta detectable population of CB-degrading bacteria in the waterphase. We examined DNA isolated from well S1-180 in 1996 and detectedthe typical CB pathway genes of strain JS705 by PCR; this findingwas not confirmed by isolation of CB degraders. In 1996 well S1-2also contained CB degraders and was positive for the CB pathwaygenes of strain JS705 as determined by PCR. However, samples collectedat other times yielded no culturable CB degraders from wells S1-2and S1-180, both of which were outside the CB-contaminated zone.The 1996 results, therefore, can be interpreted only in the contextof the observations made in otheryears.

The genes for CB degradation in strain JS705 were composed of three distinct regions (Fig. 2), two of which (the genes forchlorocatechol degradation) were partial duplicates of each other.The duplicated regions contained genes for chlorocatechol degradationin strain JS705 that were almost identical to genes describedpreviously in bacteria that degrade 3-CBA (7). However, theclc genes could not be traced directly in indigenous non-CB-degradingmicroorganisms by classical plating and enrichment on 3-CBA or2,4-D; they could be traced only by PCR performed with DNA samplesfrom uncontaminated groundwater obtained at site S1 (Table 1).This result suggests that the clc genes are present in indigenousbacteria at the site; however, they may be in a cryptic form ormay encode parts of an unknown metabolic pathway. Alternatively,more sensitive radiolabeling and isolation techniques (9) mighthave to be used to detect the metabolic activities of indigenousbacteria that are able to use 3-CBA, 2,4-D, or a related compound.Such techniques have been used to detect oligotrophic microorganismscarrying genes for 2,4-D and 3-CBA metabolism in pristine environments(8, 9, 15).

The third region of CB pathway genes in strain JS705, which encodes the CB ring dioxygenase and dihydrodiol dehydrogenase,was found in a benzene and toluene degrader at site S1. This DNAregion, which contained the mcbFAB genes, was identical in JS705and the benzene and toluene degrader. Since the genetic backgroundof the benzene and toluene degraders was different from the geneticbackground of JS705, this is the best evidence which we have atpresent that the genes for the CB pathway originated from existinggenes in two different ancestral strains, were recombined to formone large gene region, and were horizontally transferred at leastonce to the present host. The dramatic reduction in the size ofthe contaminant plume over the last 6 years and the distributionof CB degraders in groundwater of the contaminated wells providecompelling evidence for the activity of the CB-degrading bacteria.This is the first strong evidence for adaptation due to geneticrecombination among bacteria in a groundwater aquifer, resultingin the formation of a novel pathway for chlorobenzene degradation,and the subsequent disappearance of chlorobenzenes from thatenvironment.

	ACKNOWLEDGMENTS

We thank Chuck Somerville and Gene Madsen for helpful technical discussions and Glenn Johnson and Rik Eggen for reviewingthemanuscript.

We thank the Air Force Office of Scientific Research for financialsupport.

	FOOTNOTES

^* Corresponding author. Mailing address: Air Force Research Laboratory/MLQR, 139 Barnes Dr., Ste. 2, Tyndall AFB, FL 32403-5323.Phone: (850) 283-6058. Fax: (850) 283-6090. E-mail: JSpain{at}ccmail.aleq.tyndall.af.mil.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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1.	Alexander, M. 1981. Biodegradation of chemicals of environmental concern. Science 211:132-138[Abstract/Free Full Text].
2.	Audus, L. J. 1952. The decomposition of 2:4-dichlorophenoxyacetic acid and 2-methyl-4-chlorophenoxyacetic acid in soil. J. Sci. Food Agric. 3:268-275.
3.	Bouwer, E. J. 1992. Bioremediation of organic contaminants in the subsurface, p. 287-318. In R. Mitchell (ed.), Environmental microbiology. Wiley-Liss, Inc., New York, N.Y.
4.	Chaudhry, G. R., and S. Chapalamadugu. 1991. Biodegradation of halogenated organic compounds. Microbiol. Rev. 55:59-79[Abstract/Free Full Text].
5.	Don, R. H., and J. M. Pemberton. 1981. Properties of six pesticide degradation plasmids isolated from Alcaligenes paradoxus and Alcaligenes eutrophus. J. Bacteriol. 145:681-686[Abstract/Free Full Text].
6.	Dorn, E., M. Hellwig, W. Reineke, and H.-J. Knackmuss. 1974. Isolation and characterization of a 3-chlorobenzoate degrading pseudomonad. Arch. Microbiol. 99:61-70[Medline].
7.	Frantz, B., and A. M. Chakrabarty. 1987. Organization and nucleotide sequence determination of a gene cluster involved in 3-chlorocatechol degradation. Proc. Natl. Acad. Sci. USA 84:4460-4464[Abstract/Free Full Text].
8.	Fulthorpe, R. R., C. McGowan, O. V. Maltseva, W. E. Holben, and J. M. Tiedje. 1995. 2,4-Dichlorophenoxyacetic acid-degrading bacteria contain mosaics of catabolic genes. Appl. Environ. Microbiol. 61:3274-3281[Abstract].
9.	Fulthorpe, R. R., A. N. Rhodes, and J. M. Tiedje. 1996. Pristine soils mineralize 3-chlorobenzoate and 2,4-dichlorophenoxyacetate via different microbial populations. Appl. Environ. Microbiol. 62:1159-1166[Abstract].
10.	Haigler, B. E., S. F. Nishino, and J. C. Spain. 1988. Degradation of 1,2-dichlorobenzene by a Pseudomonas sp. Appl. Environ. Microbiol. 54:294-301[Abstract/Free Full Text].
11.	Hallier-Soulier, S., V. Ducrocq, N. Mazure, and N. Truffaut. 1996. Detection and quantification of degradative genes in soils contaminated by toluene. FEMS Microbiol. Ecol. 20:121-133.
12.	Herrick, J. B., K. G. Stuart-Keil, W. C. Ghiorse, and E. L. Madsen. 1997. Natural horizontal transfer of a naphthalene dioxygenase gene between bacteria native to a coal tar-contaminated field site. Appl. Environ. Microbiol. 63:2330-2337[Abstract].
13.	Hickey, W. J., and D. D. Focht. 1990. Degradation of mono-, di-, and trihalogenated benzoic acids by Pseudomonas aeruginosa JB2. Appl. Environ. Microbiol. 56:3842-3850[Abstract/Free Full Text].
14.	Ka, J. O., W. E. Holben, and J. M. Tiedje. 1994. Genetic and phenotypic diversity of 2,4-dichlorophenoxyacetic acid (2,4-D)-degrading bacteria isolated from 2,4-D-treated field soils. Appl Environ Microbiol. 60:1106-1115[Abstract/Free Full Text].
15.	Kamagata, Y., R. R. Fulthorpe, K. Tamura, H. Takami, L. J. Forney, and J. M. Tiedje. 1997. Pristine environments harbor a new group of oligotrophic 2,4-dichlorophenoxyacetic acid-degrading bacteria. Appl. Environ. Microbiol. 63:2266-2272[Abstract].
16.	Karns, J. S., J. J. Kilbane, S. Duttagupta, and A. M. Chakrabarty. 1983. Metabolism of halophenols by 2,4,5-trichlorophenoxyacetic acid-degrading Pseudomonas cepacia. Appl. Environ. Microbiol. 46:1176-1181[Abstract/Free Full Text].
17.	Kröckel, L., and D. D. Focht. 1987. Construction of chlorobenzene-utilizing recombinants by progenitive manifestation of a rare event. Appl. Environ. Microbiol. 53:2470-2475[Abstract/Free Full Text].
18.	Leahy, J. G., and R. R. Colwell. 1990. Microbial degradation of hydrocarbons in the environment. Microbiol. Rev. 54:305-315[Abstract/Free Full Text].
19.	Leveau, J. H. J., and J. R. van der Meer. 1997. Genetic characterization of insertion sequence ISJP4 on plasmid pJP4 from Ralstonia eutropha JMP134. Gene 202:103-114[Medline].
20.	Maidak, B. L., G. J. Olsen, N. Larsen, R. Overbeek, M. J. McCaughey, and C. R. Woese. 1996. The Ribosomal Database Project (RDP). Nucleic Acids Res. 24:82-85[Abstract/Free Full Text].
21.	Menn, F. M., G. J. Zylstra, and D. T. Gibson. 1991. Location and sequence of the todF gene encoding 2-hydroxy-6-oxohepta-2,4-dienoate hydrolase. Gene 104:91-94[Medline].
22.	Nishino, S. F., J. C. Spain, L. A. Belcher, and C. D. Litchfield. 1992. Chlorobenzene degradation by bacteria isolated from contaminated groundwater. Appl. Environ. Microbiol. 58:1719-1726[Abstract/Free Full Text].
23.	Nishino, S. F., J. C. Spain, and C. A. Pettigrew. 1994. Biodegradation of chlorobenzene by indigenous bacteria. Environ. Toxicol. Chem. 13:871-877.
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