Development of Catechol 2,3-Dioxygenase-Specific Primers for Monitoring Bioremediation by Competitive Quantitative PCR

doi:10.1128/AEM.66.2.678-683.2000

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Applied and Environmental Microbiology, February 2000, p. 678-683, Vol. 66, No. 2
0099-2240/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Development of Catechol 2,3-Dioxygenase-Specific Primers for Monitoring Bioremediation by Competitive Quantitative PCR

Matthew B. Mesarch,¹ Cindy H. Nakatsu,² and Loring Nies¹^,^*

School of Civil Engineering, Purdue University, West Lafayette, Indiana 47907-1284,¹ Department of Agronomy, Purdue University, West Lafayette, Indiana 47907-1150²

Received 13 August 1999/Accepted 29 November 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results and Discussion References

Benzene, toluene, xylenes, phenol, naphthalene, and biphenyl are among a group of compounds that have at least one reportedpathway for biodegradation involving catechol 2,3-dioxygenaseenzymes. Thus, detection of the corresponding catechol 2,3-dioxygenasegenes can serve as a basis for identifying and quantifying bacteriathat have these catabolic abilities. Primers that can successfullyamplify a 238-bp catechol 2,3-dioxygenase gene fragment from eightdifferent bacteria are described. The identities of the ampliconswere confirmed by hybridization with a 238-bp catechol 2,3-dioxygenaseprobe. The detection limit was 10² to 10³ gene copies, which was lowered to 10⁰ to 10¹ gene copies by hybridization. Using the dioxygenase-specificprimers, an increase in catechol 2,3-dioxygenase genes was detectedin petroleum-amended soils. The dioxygenase genes were enumeratedby competitive quantitative PCR with a 163-bp competitor thatwas amplified using the same primers. Target and competitor sequenceshad identical amplification kinetics. Potential PCR inhibitorsthat could coextract with DNA, nonamplifying DNA, soil factors(humics), and soil pollutants (toluene) did not impact enumeration.Therefore, this technique can be used to accurately and reproduciblyquantify catechol 2,3-dioxygenase genes in complex environmentssuch as petroleum-contaminated soil. Direct, non-cultivation-basedmolecular techniques for detecting and enumerating microbial pollutant-biodegradinggenes in environmental samples are powerful tools for monitoringbioremediation and developing field evidence in support of naturalattenuation.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results and Discussion References

Bioremediation is a low-cost treatment alternative for the cleanup of petroleum-contaminated soils and groundwater. Monitorednatural attenuation (MNA) is one form of bioremediation wherenatural processes are used to treat petroleum contamination. Inorder to establish whether MNA is feasible, several lines of evidencemust be evaluated to demonstrate the types of in situ attenuationmechanisms active onsite (37). Precise and accurate enumerationof aromatic-hydrocarbon-degrading microorganisms would providesuchevidence.

Despite the well-known biases of cultivation-based techniques, standard culture methods are used for site evaluation to determinewhether indigenous bacteria are capable of degrading the contaminants.Molecular genetic techniques allow researchers to examine microbialcommunities without cultivation using universal 16S rRNA geneprimers (5). PCR has been particularly useful for detectinggenes involved in the degradation of xenobiotic compounds (13,18, 23, 24). There are potential biases associated withmolecular techniques (32, 38). However, conditions and experimentscan be designed to minimize suchbiases.

In order to enumerate gene copy number, competitive quantitative PCR techniques have been developed. Competitive quantitativePCR techniques were initially used in medicinal research to measureviral loads in humans (15, 31). More recently these techniqueshave been used to measure numbers of plant pathogens (20), fungalpopulations (2), 4-chlorobiphenyl degraders (10), and uncultivatedbacterial strains in soils (27).

Competitive quantitative PCR would be a significant improvement over cultivation-based techniques for monitoring bioremediation.Greater catabolic gene copy numbers within a contaminated area(relative to those in uncontaminated soils) could be used as evidenceof natural attenuation or of the effectiveness of exogenouslysupplied growth amendments in engineered bioremediation. Bacteriathat aerobically degrade aromatic hydrocarbons use dioxygenaseenzymes to activate and cleave the aromatic ring (3, 7);therefore, the corresponding genes are excellent targets on whichto base a competitive quantitative PCR assay. Most aerobic aromatic-hydrocarbonbiodegradation pathways converge through catechol-like intermediatesthat are typically cleaved by ortho- or meta-cleavage dioxygenases(7). Meta-cleavage dioxygenases, or catechol 2,3-dioxygenases(C23DO), are believed to be more capable than ortho-cleavage dioxygenasesof degrading alkyl-substituted aromatics such as xylenes (9).C23DO genes also have a well-characterized phylogeny (12) thatallows for the systematic design of dioxygenase-specific primers.The I.2.A dioxygenase subfamily is involved in the degradationof benzene, toluene, xylenes (BTX), and naphthalene. Due to theirtoxicity and mobility in the environment, BTX cleanup endpointsare more stringent than those of other petroleum constituents.The ability to specifically and accurately detect BTX-biodegradingbacteria in the environment is desirable to establish the feasibilityofMNA.

In this study we describe a single set of C23DO-specific primers and use them to detect and enumerate the genes that makeup the I.2.A subfamily of C23DO genes (12). This subfamily containsa broad spectrum of C23DO genes that are involved in the biodegradationof aromatic compounds of environmental concern. NonamplifyingDNA, toluene, and soil factors such as humics, which are potentialinhibitors of PCR, are shown to have no effect on dioxygenasegeneenumeration.

(A portion of this work was presented at the 99th General Meeting of the American Society for Microbiology [M. Mesarch, C.Nakatsu, and L. Nies, Abstr. 99th Gen. Meet. Am. Soc. Microbiol.1999, abstr. Q-429, p. 615, 1999].)

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results and Discussion References

Bacterial strains and culture conditions. The organisms and their carbon sources used in this study are listed in Table 1. Cells were grown overnight at room temperaturein sterile defined minimal medium (29). Biphenyl or naphthalenewas added as solid crystals to the liquid medium or on the invertedlids of petri plates. Phenol or meta-toluic acid (for toluene-degraders)was added to a final concentration of 0.250 g liter¹. The medium was solidified with 15 g of agar liter¹.

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TABLE 1. Organisms used to design C23DO-specific primers and their carbon sources

DNA extraction. Genomic DNAs were extracted from pure cultures of all eight isolates using a total genomic DNA isolation method (28) ora FastDNA Kit (Bio 101). Soil DNA extractions were performed usingthe FastPrep System and the FastDNA Spin Kit for Soil (Bio 101).DNA was quantified by fluorometry using a model TKO100 DNA fluorometer(Hoefer Scientific Instruments, San Francisco, Calif.) calibratedwith calf thymusDNA.

PCR primer design. PCR primers (Table 2) were constructed based upon conserved amino acid sequences (12) and nucleic acid alignments of theseregions (DNAman version 2.7). The primers 23CAT-F and 23CAT-Rwere selected based upon conserved nucleotide regions for sixof the eight isolates listed in Table 1. Pseudomonas sp. strainCF600 had one mismatch with 23CAT-R, and Pseudomonas sp. strainPpG7 had two mismatches with 23CAT-F and three with 23CAT-R. PrimersDEG-F and DEG-R are identical to 23CAT-F and 23CAT-R except forfive positions where degenerate bases were used to account forprimer-target mismatches with Pseudomonas sp. strain PpG7 (Table2). We searched GenBank and found that the primer sequences matchedonly other C23DO sequences, from Pseudomonas stutzeri AN10 (AF039534)and OM1 (AB001722), which fit into the I.2.A subfamily of dioxygenasegenes. Primer QUANT-F was designed for use as the competitor toamplify a 163-bp sequence from Pseudomonas putida HS1 or mt-2when it was used with primer 23CAT-R or DEG-R. Primers were synthesizedat the Laboratory for Macromolecular Structure, Purdue University(23CAT-F and 23CAT-R), and Integrated DNA Technologies, Inc.,Coralville, Iowa (DEG-F, DEG-R, and QUANT-F).

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TABLE 2. Primers developed to enumerate dioxygenase gene copy number^a

PCR conditions. Optimization of PCR conditions using primers DEG-F and DEG-R were tested for P. putida HS1 and Pseudomonas sp. strain PpG7because they were either identical to the nondegenerate primers(HS1) or had the most mismatches (PpG7). Annealing temperaturesof 52 to 63°C were tested using a Robocycler Gradient 96 thermalcycler (Stratagene, La Jolla, Calif.). The PCR temperature programbegan with an initial 5-min denaturation step at 95°C; 30 cyclesof 94°C for 1 min, 52 to 63°C for 1 min, and 72°C for 2 min; anda final 10-min extension step at 72°C. All reaction mixtures wereheld at 4°C until analyzed. Magnesium chloride (Promega, Madison,Wis.) concentrations (1.5, 3.0, 4.0, and 5.0 mM), primer concentrations(0.125, 0.250, and 0.375 µM), and template DNA concentrations(10, 1, and 0.1 ng) were tested individually. All reaction mixturesalso included 1× PCR buffer (Promega), 0.2 mM each deoxynucleosidetriphosphate (Amersham Pharmacia, Piscataway, N.J.), and 1 U ofTaq DNA polymerase. Following optimization, all reactions wereperformed in a PTC-100 programmable thermal cycler (MJ Research,Inc.). All experiments included controls without any added DNA.Ten microliters of each PCR mixture was run on a 1.5% agarosegel (Bio-Rad, Richmond, Calif.) in 1× Tris-acetate-EDTA (TAE)buffer stained with ethidium bromide (0.0001%) and visualizedunder UV light. PCR was performed on DNAs extracted from all eightisolates using both primer sets: DEG-F and DEG-R and CAT-F andCAT-R (Table 1). To determine the detection limit of this protocol,a 10-fold dilution series of P. putida HS1 and Pseudomonas sp.strain PpG7 (from 1 ng to 1 fg of DNA per reaction) was createdand amplified using DEG-F and DEG-R. For competitive quantitativePCR experiments both target and competitor DNAs were added toreactiontubes.

Hybridization experiments. Confirmation of the eight amplicons as dioxygenase fragments was made through hybridization with a digoxigenin-labeled probe.The probe was a 238-bp P. putida HS1 dioxygenase gene fragment(hereafter described as an HS1 probe) labeled by PCR incorporationof digoxigenin-labeled dUTP (Roche Molecular Biochemicals, Indianapolis,Ind.). The probe was also tested on a dilution series of HS1 orPpG7 DNA amplified with the dioxygenase-specific primers to determineif further amplification occurred that was not visible on an agarosegel.

Southern transfer, hybridization, and detection were carried out according to the instructions of the manufacturer (RocheMolecular Biochemicals). Hybridization was performed under low-,medium-, and high-stringency conditions by varying the temperaturesof posthybridization washes (65, 80, and 85°C, respectively).Wash solutions contained 0.5× SSC (1× SSC is 0.15 M NaCl plus0.015 M sodium citrate) and 0.1% sodium dodecyl sulfate (34).

Detection of C23DO genes in petroleum-amended soils. To determine whether C23DO genes can be detected in environmental samples, DNAs were extracted from unamended and petroleum-amendedsoils (<2% organic carbon). Uncontaminated soil was amended with30,000 mg of diesel fuel kg¹, 20,000 mg of motor oil kg¹, and 200 mg (each) of naphthalene, phenanthrene, anthracene,pyrene, and chrysene kg¹ and aged for 12 months. PCR was performed on the soil DNA extracts(500 mg of soil extracted, 10 ng of DNA used per reaction) usingprimers DEG-F and DEG-R.

Construction of competitor. The competitor was constructed based upon the approach of Jin et al. (22). A 163-bp sequence was amplified from P. putidaHS1 or mt-2 using QUANT-F and DEG-R. The 163-bp amplicon was purifiedusing a MERmaid prep kit (Bio 101). The purified amplicon wasligated with pGEM-T (Promega) and transformed into competent Escherichiacoli DH5 $alpha$ (34). The presence of the correctly sized insert wasconfirmed by PCR (using DEG-F and DEG-R), plasmid isolation, andrestriction enzyme (SphI and NdeI) digestion (34). By multiplyingthe competitor plasmid concentration (in nanograms per microliter)by the fraction of plasmid constituted by the competitor fragment(163 bp of a total of 3,166 bp) and performing the appropriateunit conversions, we were able to calculate the competitor genecopy number used in each competitive quantitative PCR experiment.All quantitative competitive PCR results were subsequently expressedin terms of C23DO gene copynumber.

Evaluation of competitive quantitative PCR protocol. Competitive PCR was first performed with pure cultures using a 10-fold dilution series of competitor plasmid ranging from1 ng to 1 fg of DNA per reaction as standards. PCR products wereseparated on 1.5% agarose gels. Target and competitor band intensitieswere analyzed and compared using Scion Image software (Scion Corp.,Frederick, Md.). To kinetically validate the quantitative PCRprotocol, equal amounts of target and competitor were amplifiedin the same reaction mixture in triplicate for 20, 25, 30, and35 cycles. Log ratios of target to competitor band intensitieswere plotted as a function of cycle number, and the data wereanalyzed using linearregression.

To evaluate how well this protocol might work on field samples, the effects of three potential PCR inhibitors were examined.In order to simulate the effects of nonamplifying DNA (such asDNA extracted from a microbial community) on competitive PCR,E. coli DH5 $alpha$ DNA was spiked into each reaction tube and PCR wasperformed. E. coli DNA/HS1 DNA ratios of 1:0, 1:1, 10:1, 100:1,1000:1, and 10,000:1 weretested.

To determine the effects of soil factors on competitive quantitative PCR, soil (Chalmers silty loam, 4% organic carbon, sievedwith a 2-mm screen) was sterilized by autoclaving. PpG7 grownin liquid culture was concentrated by centrifugation for 2 minat 14,000 × g, resuspended in 100 µl of sterile Tris-EDTA (tominimize changes to soil moisture content), added to 500 mg ofsterile soil, and allowed to sit for 30 min. Uninoculated sterilesoil was used as a control. Following incubation, total DNA wasextracted and DNA extraction efficiency was determined by comparingconcentrations of soil DNA extracts to the concentration of DNAextracted from an equivalent amount of cells not inoculated insoil. Quantitative PCR was then performed on soil DNA extractsand pure-culture DNA extracts. All extractions were performedin triplicate. A serial dilution of cells was also plated ontominimal medium plates, with naphthalene crystals added as a solesource of carbon. Plate counts were also performed on soils thathad already been extracted to determine the lysis efficiency ofthe DNA extraction protocol. Cell lysis efficiency was determinedby comparing plate counts of uninoculated pure cultures to platecounts of the extractedsoil.

Environmental contaminants are also potential PCR inhibitors. Therefore, the effects of high levels of one potential inhibitor,toluene, in soil were examined. Toluene was spiked into sterilesoils to a concentration of 10,000 mg kg¹. These soils were spiked with PpG7 cells as described above,allowed to incubate 30 min, and processed identically to the unpollutedsoilsamples.

	RESULTS AND DISCUSSION

Top Abstract Introduction Materials and Methods Results and Discussion References

PCR conditions. Primers 23CAT-F and 23CAT-R were capable of amplifying the expected 238-bp product from seven of the eight isolates, includingPseudomonas sp. strain CF600, which had a one base pair mismatchwith 23CAT-R. The only isolate not detected was Pseudomonas sp.strain PpG7, which contained the most mismatches with 23CAT-Fand 23CAT-R. DEG-F and DEG-R were able to amplify the expected238-bp fragment from pure cultures of all eight isolates, includingPpG7 (Fig. 1A). Amplification using a gradient of annealing temperaturesindicated optimal annealing temperatures of 55 and 57°C for PpG7and HS1, respectively. An annealing temperature of 56°C was usedin all subsequent experiments. Based on PCR product intensity,optimal amplification was achieved using concentrations of 1 ngof DNA, 3.0 mM MgCl₂, and 0.250 µM each primer using either HS1DNA or PpG7 DNA. Until now, PCR conditions have not been optimizedfor an entire subfamily of C23DO genes. Optimization using C23DOgenes from HS1 and PpG7, which have the greatest sequence differencefrom one another in their respective primer sequences, indicatedthat identical PCR conditions can be used to monitor dioxygenasegene copy number in all I.2.A C23DO subfamily members withoutsacrificing accuracy.

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FIG. 1. Detection of 238-bp dioxygenase amplicons by PCR and hybridization using primers DEG-F and DEG-R. Lane M, 100- to 3,000-bp marker (Bio-Rad); lanes 1 to 8, P. putida HS1, P. putida mt-2, P. aeruginosa JI104, Pseudomonas sp. strain IC, P. putida P35X, Pseudomonas sp. strain CF600, P. putida H, and Pseudomonas sp. strain PpG7, respectively. Agarose gel (1.5% agarose) of the amplicons with approximately equal amounts of DNA in each lane; (B, C, and D) membranes hybridized under high (B)-, medium (C)-, and low (D)-stringency conditions using an exposure time of 2 to 3 h.

The broad target spectrum of our primers allows identification and enumeration of dioxygenase genes involved in the degradationof a variety of aromatic hydrocarbons, which allows site investigatorsto detect catabolic genes from organisms with both single-ring(HS1, mt-2, H, P35X, and CF600) and double-ring (IC, JI104, andPpG7) substrate specificities. Often primers are designed forsite-specific needs such as identification of genes involved inthe degradation of polychlorinated biphenyls (13), 2,4-dichlorophenoxyaceticacid (4), or naphthalene (17). While such primers proveduseful in investigating the distribution of specific catabolicgenes, their exclusive nature limits their usefulness in characterizingthe bacteria in petroleum-contaminated environments that containseveral different environmentally regulated aromaticcompounds.

Other dioxygenase-specific primers have previously been described for C23DO genes. However, none of the previously describedC23DO primers were developed to detect members of the entire I.2.AC23DO subfamily. A set of C23DO primers has been described forquantifying organisms harboring this gene in toluene-contaminatedsoils, but they can detect only isolates mt-2, JI104, and IC (16).A different set of primers used to monitor phenol-degrading P.putida strains in an industrial wastewater process would be ableto detect only isolates mt-2 and JI104 (39). C23DO primers identicalto mt-2 genes alone have been used as a molecular marker for theidentification of a fish pathogen in lakewater using PCR (30).Primers based upon an alignment of six I.2.A C23DO genes weresuccessful in detecting the three organisms in the I.2.A subfamilyon which they were tested (41). However, these primers requiredmore degenerate positions than primers DEG-F and DEG-R yet stillcontained a mismatch with two of the I.2.A subfamilymembers.

Hybridization experiments. Hybridization of the digoxigenin-labeled probe to 238-bp amplicons from all eight isolates under high-stringency conditionsdetected P. putida HS1 (100% identical to probe), P. putida mt-2(95% identical), P. aeruginosa JI104 (89% identical), and Pseudomonassp. strain IC (89% identical) (Fig. 1B, lanes 1 to 4), althoughthe signals were very weak from JI104 and IC. These ampliconswere more easily seen under medium-stringency conditions (80°C).In addition to JI104 and IC, P. putida P35X (87% identical), Pseudomonassp. strain CF600 (86% identical), and P. putida H (90% identical)were detected (Fig. 1C, lanes 5 to 7) under medium-stringencyconditions. Amplicons from all eight isolates were detected underlow-stringency conditions (65°C) (Fig. 1D, lanes 1 to 8), confirmingthe identities of all amplicons as C23DOfragments.

Detection limit. We were capable of detecting from 10² to 10³ dioxygenase gene copies from either HS1 or PpG7 DNA (Fig. 2A and B). Hybridizationwith a C23DO probe allowed us to detect PCR products resultingfrom the use of as few as 10⁰ to 10¹ dioxygenase gene copies per reaction (Fig. 2C and D), which compareswell with literature values for similar systems (1, 16).A single detection limit for multiple organisms ensures that PCRresults will be accurate regardless of the target sequence amplified.This is not true for all primer sets; primers for the gyrB genehad different detection limits for two different phenol-degradingorganisms (40). The low detection limit of our primers willalso allow for more sensitive detection of C23DO-harboring organismsin uncontaminated or extreme environments, where their numbersare apt to be low, and can provide ecologists with informationregarding their distribution in these systems.

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FIG. 2. PCR detection limit. Lane M, 100- to 3,000-bp marker; lanes 1 to 8, amplification products resulting from the use of 1 ng (containing 10⁶ copies of C23DO), 0.1 ng (10⁵ copies), 0.01 ng (10⁴ copies), 0.001 ng (10³ copies), 0.0001 ng (10² copies), 0.00001 ng (10¹ copies), 0.000001 ng (10⁰ copies), and no DNA, respectively. (A and B) Agarose gels (1.5% agarose) of PCR products of P. putida HS1 and Pseudomonas sp. strain PpG7, respectively, amplified with primers DEG-F and DEG-R; (C and D) membranes corresponding to the gels in panels A and B, respectively, hybridized with a C23DO probe under low-stringency conditions using an exposure time of 18 to 20 h.

Detection of C23DO genes in petroleum-amended soils. Using the DEG-F and DEG-R primers, amplification of DNA extracted from the petroleum-amended soils resulted in the anticipated238-bp product (data not shown). No PCR products were seen fromDNA samples extracted from the unamended soils as determined byvisualization on agarose gels (detection limit of 10² to 10³ copies). This demonstrates that our C23DO primers will detectthe expected enrichment of aromatic-hydrocarbon degraders uponexposure to petroleum. This detection is direct evidence thatC23DO genes can be amplified from native soil organisms and thatthey represent good marker genes for monitoring bioremediationinsoils.

Competitive quantitative PCR. Construction of competitor DNA was confirmed by restriction enzyme digestion of the recombinant plasmid and PCR amplificationof the expected 163-bp competitor fragment. Quantitative PCR wasfirst run with equal concentrations of competitor and target DNAfrom HS1 or PpG7. The logarithms of the ratios of target to competitorband intensities were approximately zero and did not vary withcycle number (n = 12 samples, r² = 0.01), indicating that target and competitor sequences amplifiedequally regardless of cycle number or DNA source used (PpG7 orHS1). The identical amplification kinetics exhibited by the targetand competitor sequences allows quantification of dioxygenasegene copy number to be based solely upon the ratio of target andcompetitor sequences (27).

A number of factors can render results of competitive quantitative PCR inaccurate. These factors can originate from the sensitivityof the PCR protocol itself, where inhibition due to high concentrationsof nonamplifying DNA relative to target DNA can occur (1).E. coli DNA was used to dilute HS1 DNA in order to simulate backgroundDNA that would be coextracted from environmental samples. No PCRproducts resulted from E. coli DNA amplified alone using primersDEG-F and DEG-R. Enumeration of dioxygenase copy number of HS1DNA was not affected by dilution with E. coli DNA using E. coliDNA/HS1 DNA ratios as high as 10,000:1 (approximately 10 ng oftotal DNA per reactionmixture).

Other potential sources of PCR inhibition include impurities such as humic acids that can coextract with DNA (36) and interferewith reaction components (43) or bind DNA (8) and organicchemicals such as toluene, although there has been no examinationas to their potential for inhibition. PpG7 cells spiked into sterilesoils were accurately enumerated using the quantitative PCR protocol(Fig. 3). Soil DNA extracts were clear and appeared free of humicmaterial. No DNA was measured in extracts from autoclaved soilsby fluorometry, and amplification was not evident using primersDEG-F and DEG-R. In seeded soils the DNA extraction procedurerecovered 99% of the DNA and was successful in lysing 94% of seededcells in clean soils and 96% of seeded cells in toluene-amendedsoils. Using seeded soils, high extraction efficiencies such asours obtained by the same DNA extraction procedure have been previouslyreported (5). There was no significant difference between thelysis efficiencies of toluene-amended and unamended soils or betweenthe DNA extraction efficiencies (P = 0.05). The dioxygenase genecopy number in seeded soils did not differ significantly (P =0.05) from the dioxygenase gene copy number in toluene-spiked,seeded soils and pure-culture extracts (Table 3). This resultindicates that the DNA extraction technique prevented potentiallyinhibitory compounds such as toluene and soil factors such ashumic acids from coextracting with DNA. Additional structurallysimilar compounds should behave in the same manner as toluene.The number of cells as determined by competitive quantitativePCR were greater by a factor of 10 than plate counts of an equivalentpreparation of cells (Table 3).

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FIG. 3. Competitive quantitative PCR performed on Pseudomonas sp. strain PpG7 cells using primers DEG-F and DEG-R. Lane M, 100- to 3,000-bp marker; lanes 1 to 6, 1 ng of target DNA (each lane) plus 1.1 × 10⁸, 1.1 × 10⁷, 1.1 × 10⁶, 1.1 × 10⁵, 1.1 × 10⁴, and 1.1 × 10³ copies of competitor per reaction mixture, respectively. Lane 7 is a control (no DNA) lane.

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TABLE 3. Comparison of C23DO gene copy numbers and plate counts for Pseudomonas sp. strain PpG7

The C23DO-specific primers we have described are capable of detecting bacteria that can degrade both one- and two-ringed aromatichydrocarbons, including BTX. Thus, they can detect a broader subsetof environmentally important aromatic-hydrocarbon-degrading bacteriathan previously described primers while retaining their specificityfor dioxygenase genes. When coupled with a quantitative competitivePCR approach these primers can be used to accurately quantifyaromatic-hydrocarbon-degrading bacteria in soils, which makesit an ideal method for determining the feasibility of MNA. Dueto the current available phylogenetic information about C23DO,all of the organisms tested are of the Pseudomonas genera. Someresearch has suggested that the importance of Pseudomonas in soilis overestimated (5). However, evidence using culture-basedmethods (25, 33) and culture-independent methods (35) indicatesthat Pseudomonas organisms are present in contaminated environmentsand are important in the in situ biodegradation of environmentalcontaminants. It is true that the presence of a single gene doesnot ensure that the entire catabolic pathway will be present orthat these genes will be expressed. However, primers for othergenes in these catabolic pathways are being developed in our laboratoryand can be used to determine whether multiple pathway genes arepresent. We are also experimenting with mRNA extraction techniquesto try to detect gene expression in environmental samples. Giventhe known nucleotide sequence diversity of meta-cleavage dioxygenasegenes (12), it is also possible that uncultured organisms otherthan Pseudomonas contain dioxygenases with identical or sufficientlysimilar sequences that could be amplified with DEG-F and DEG-R.Future research will allow development of primers outside of theI.2.A subfamily of C23DOgenes.

	ACKNOWLEDGMENTS

We thank Daniel Kunz, Michael Roberts, Heidrun Hermann, Victoria Shingler, and Atsushi Kitayama for generously providing theorganisms used in this research and Bob Kim for the amended andunamendedsoils.

This work was funded by the Joint Transportation Research Program of the School of Civil Engineering, Purdue University, andthe Indiana Department of Transportation, and the ShowalterTrust.

	FOOTNOTES

^* Corresponding author. Mailing address: School of Civil Engineering, Civil Engineering Building, Purdue University, West Lafayette,IN 47907-1284. Phone: (765) 494-8327. Fax: (765) 496-1107. E-mail:nies{at}ecn.purdue.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results and Discussion
References

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13. Erb, R. W., and I. Wagner-Döbler. 1993. Detection of polychlorinated biphenyl degradation genes in polluted sediments by direct DNA extraction and polymerase chain reaction. Appl. Environ. Microbiol. 59:4065-4073[Abstract/Free Full Text].

14. Frey, J., M. Bagdasarian, D. Feiss, F. C. Franklin, and J. Deshusses. 1983. Stable cosmid vectors that enable the introduction of cloned fragments into a wide range of Gram-negative bacteria. Gene 24:299-308[CrossRef][Medline].

15. Gilliland, G., S. Perrin, K. Blanchard, and H. F. Bunn. 1990. Analysis of cytokine mRNA and DNA: detection and quantitation by competitive polymerase chain reaction. Proc. Natl. Acad. Sci. USA 87:2725-2729[Abstract/Free Full Text].

16. 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[CrossRef].

17. 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].

18. Herrick, J. B., E. L. Madsen, C. A. Batt, and W. C. Ghiorse. 1993. Polymerase chain reaction amplification of naphthalene-catabolic and 16S rRNA gene sequences from indigenous sediment bacteria. Appl. Environ. Microbiol. 59:687-694[Abstract/Free Full Text].

19. Hopper, D. J., P. J. Chapman, and S. Dagley. 1971. The enzymatic degradation of alkyl-substituted gentisates, maleates, and malates. Biochem. J. 122:29-40[Medline].

20. Hu, X., F.-M. Lai, S. N. Reddy, and C. A. Ishimaru. 1995. Quantitative detection of Clavibacter michiganensis subsp. sepedonicus by competitive polymerase chain reaction. Phytopathology 85:1468-1473[CrossRef].

21. Janke, D., R. Pohl, and W. Fritsche. 1981. Regulation of phenol degradation in Pseudomonas putida. Z. Allg. Mikrobiol. 21:295-303[Medline].

22. Jin, C., M. Mata, and D. J. Fink. 1994. Rapid construction of deleted DNA fragments for use as internal standards in competitive PCR. PCR Methods Appl. 3:252-255[Medline].

23. Joshi, B., and S. Walia. 1996. PCR amplification of catechol 2,3-dioxygenase gene sequences from naturally occurring hydrocarbon degrading bacteria isolated from petroleum hydrocarbon contaminated groundwater. FEMS Microbiol. Ecol. 19:5-15.

24. Joshi, B., and S. K. Walia. 1996. Detection of metapyrocatechase homologous genes in petroleum hydrocarbon contaminated groundwater by polymerase chain reaction. J. Microbiol. Methods 27:121-128[CrossRef].

25. Kämpfer, P., M. Steiof, and M. Dott. 1991. Microbiological characterization of a fuel-oil contaminated site including numerical identification of heterotrophic water and soil bacteria. Microb. Ecol. 21:227-251[CrossRef].

26. Kunz, D. A., and P. J. Chapman. 1981. Isolation and characterization of spontaneously occurring TOL plasmid mutants of Pseudomonas putida HS1. J. Bacteriol. 146:952-964[Abstract/Free Full Text].

27. Lee, S., J. Bollinger, D. Bezdicek, and A. Ogram. 1996. Estimation of the abundance of an uncultured soil bacterial strain by a competitive quantitative PCR method. Appl. Environ. Microbiol. 62:3787-3793[Abstract].

28. Marmur, J. 1961. A procedure for the isolation of deoxyribonucleic acid from micro-organisms. J. Mol. Biol. 3:209-218.

29. Mesarch, M. B., and L. Nies. 1997. Modification of heterotrophic plate counts for assessing the bioremediation potential of petroleum-contaminated soils. Environ. Technol. 18:639-646[CrossRef].

30. Morgan, J. A. W., G. Rhodes, and R. W. Pickup. 1993. Survival of nonculturable Aeromonas salmonicida in lake water. Appl. Environ. Microbiol. 59:874-880[Abstract/Free Full Text].

31. Piatak, M., Jr., K. Luk, B. Williams, and J. D. Lifson. 1993. Quantitative competitive polymerase chain reaction for accurate quantitation of HIV DNA and RNA species. BioTechniques 14:70-80[Medline].

32. Power, M., J. R. van der Meer, R. Tchelet, T. Egli, and R. Eggen. 1998. Molecular-based methods can contribute to assessments of toxicological risks and bioremediation strategies. J. Microbiol. Methods 32:107-119.

33. Ridgway, H. F., J. Safarik, D. Phipps, P. Carl, and D. Clark. 1990. Identification and catabolic activity of well-derived gasoline-degrading bacteria from a contaminated aquifer. Appl. Environ. Microbiol. 56:3565-3575[Abstract/Free Full Text].

34. Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

35. Shen, Y., L. G. Stehmeier, and G. Voordouw. 1998. Identification of hydrocarbon-degrading bacteria in soil by reverse sample genome probing. Appl. Environ. Microbiol. 64:637-645[Abstract/Free Full Text].

36. Tsai, Y., and B. H. Olson. 1992. Rapid method for separation of bacterial DNA from humic substances for polymerase chain reaction. Appl. Environ. Microbiol. 58:2292-2295[Abstract/Free Full Text].

37. U.S. Environmental Protection Agency. 1999. Use of monitored natural attenuation at Superfund, RCRA corrective action, and underground storage tank sites. Directive 9200.4-17P. U.S. Environmental Protection Agency, Washington, D.C.

38. van Elsas, J. D., G. F. Duarte, A. S. Rosado, and K. Smalla. 1998. Microbiological and molecular biological methods for monitoring microbial inoculants and their effects in the soil environment. J. Microbiol. Methods 32:133-154.

39. Wand, H., T. Laht, M. Peters, P. M. Becker, U. Stottmeister, and A. Heinaru. 1997. Monitoring of biodegradative Pseudomonas putida strains in aquatic environments using molecular techniques. Microb. Ecol. 33:124-133[CrossRef][Medline].

40. Watanabe, K., S. Yamamoto, S. Hino, and S. Harayama. 1998. Population dynamics of phenol-degrading bacteria in activated sludge determined by gyrB-targeted quantitative PCR. Appl. Environ. Microbiol. 64:1203-1209[Abstract/Free Full Text].

41. Wikström, P., A. Wiklund, A. Andersson, and M. Forsman. 1996. DNA recovery and PCR quantitation of catechol 2,3-dioxygenase genes from different soil types. J. Biotechnol. 52:107-120[CrossRef][Medline].

42. Williams, P. A., and K. Murray. 1974. Metabolism of benzoate and the methylbenzoates by Pseudomonas putida (Arvilla) mt-2: evidence for the existence of a TOL plasmid. J. Bacteriol. 120:416-423[Abstract/Free Full Text].

43. Wilson, I. G. 1997. Inhibition and facilitation of nucleic acid amplification. Appl. Environ. Microbiol. 63:3741-3751[Medline].

44. Yarmoff, J., Y. Kawakami, T. Yago, H. Maruo, and H. Nishimura. 1988. cis-benzeneglycol production using a mutant Pseudomonas strain. J. Ferment. Bioeng. 66:305-312.

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1.	Alvarez, A. J., M. P. Buttner, and L. D. Stetzenbach. 1995. PCR for bioaerosol monitoring: sensitivity and environmental interference. Appl. Environ. Microbiol. 61:3639-3644[Abstract].
2.	Baek, J., and C. M. Kenerley. 1998. Detection and enumeration of a genetically modified fungus in soil environments by quantitative competitive polymerase chain reaction. FEMS Microbiol. Ecol. 25:419-428[CrossRef].
3.	Bayly, R. C., and M. G. Barbour. 1984. The degradation of aromatic compounds by the meta and gentisate pathways, p. 253-294. In D. T. Gibson (ed.), Microbial degradation of organic compounds. Marcel Dekker, Inc., New York, N.Y.
4.	Berthelet, M., and C. Greer. 1995. Detection of catabolic genes in the soil using the polymerase chain reaction, p. 635-644. In M. Moo-Young (ed.), Environmental biotechnology: principles and applications. Kluwer Academic Publishers, Dordrecht, The Netherlands.
5.	Borneman, J., P. W. Skroch, K. M. O'Sullivan, J. A. Palus, N. G. Rumjanek, J. L. Jansen, J. Nienhuis, and E. W. Triplett. 1996. Molecular microbial diversity of an agricultural soil in Wisconsin. Appl. Environ. Microbiol. 62:1935-1943[Abstract].
6.	Carrington, B., A. Lowe, L. E. Shaw, and P. A. Williams. 1994. The lower pathway operon for benzoate catabolism in biphenyl-utilizing Pseudomonas sp. strain IC and the nucleotide sequence of the bphE gene for catechol 2,3-dioxygenase. Microbiology 140:499-508[Abstract/Free Full Text].
7.	Cerniglia, C. E. 1984. Microbial metabolism of polycyclic aromatic hydrocarbons. Adv. Appl. Microbiol. 30:31-71[Medline].
8.	Crecchio, C., and G. Stotzky. 1998. Binding of DNA on humic acids: effect on transformation of Bacillus subtilis and resistance to DNase. Soil Biol. Biochem. 30:1061-1067[CrossRef].
9.	Dagley, S. 1986. Biochemistry of aromatic hydrocarbon degradation in pseudomonads, p. 527-555. In J. R. Sokatch, and L. N. Ornston (ed.), The bacteria. Academic Press, Inc., New York, N.Y.
10.	Ducrocq, V., P. Pandard, S. Hallier-Soulier, E. Thybaud, and N. Truffaut. 1999. The use of quantitative PCR, plant and earthworm bioassays, plating and chemical analysis to monitor 4-chlorobiphenyl biodegradation in soil microcosms. Appl. Soil Ecol. 12:15-27.
11.	Dunn, N. W., and I. C. Gunsalus. 1973. Transmissable plasmid coding early enzymes of naphthalene oxidation in Pseudomonas putida. J. Bacteriol. 114:974-979[Abstract/Free Full Text].
12.	Eltis, L. D., and J. T. Bolin. 1996. Evolutionary relationships among extradiol dioxygenases. J. Bacteriol. 178:5930-5937[Abstract/Free Full Text].
13.	Erb, R. W., and I. Wagner-Döbler. 1993. Detection of polychlorinated biphenyl degradation genes in polluted sediments by direct DNA extraction and polymerase chain reaction. Appl. Environ. Microbiol. 59:4065-4073[Abstract/Free Full Text].
14.	Frey, J., M. Bagdasarian, D. Feiss, F. C. Franklin, and J. Deshusses. 1983. Stable cosmid vectors that enable the introduction of cloned fragments into a wide range of Gram-negative bacteria. Gene 24:299-308[CrossRef][Medline].
15.	Gilliland, G., S. Perrin, K. Blanchard, and H. F. Bunn. 1990. Analysis of cytokine mRNA and DNA: detection and quantitation by competitive polymerase chain reaction. Proc. Natl. Acad. Sci. USA 87:2725-2729[Abstract/Free Full Text].
16.	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[CrossRef].
17.	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].
18.	Herrick, J. B., E. L. Madsen, C. A. Batt, and W. C. Ghiorse. 1993. Polymerase chain reaction amplification of naphthalene-catabolic and 16S rRNA gene sequences from indigenous sediment bacteria. Appl. Environ. Microbiol. 59:687-694[Abstract/Free Full Text].
19.	Hopper, D. J., P. J. Chapman, and S. Dagley. 1971. The enzymatic degradation of alkyl-substituted gentisates, maleates, and malates. Biochem. J. 122:29-40[Medline].
20.	Hu, X., F.-M. Lai, S. N. Reddy, and C. A. Ishimaru. 1995. Quantitative detection of Clavibacter michiganensis subsp. sepedonicus by competitive polymerase chain reaction. Phytopathology 85:1468-1473[CrossRef].
21.	Janke, D., R. Pohl, and W. Fritsche. 1981. Regulation of phenol degradation in Pseudomonas putida. Z. Allg. Mikrobiol. 21:295-303[Medline].
22.	Jin, C., M. Mata, and D. J. Fink. 1994. Rapid construction of deleted DNA fragments for use as internal standards in competitive PCR. PCR Methods Appl. 3:252-255[Medline].
23.	Joshi, B., and S. Walia. 1996. PCR amplification of catechol 2,3-dioxygenase gene sequences from naturally occurring hydrocarbon degrading bacteria isolated from petroleum hydrocarbon contaminated groundwater. FEMS Microbiol. Ecol. 19:5-15.
24.	Joshi, B., and S. K. Walia. 1996. Detection of metapyrocatechase homologous genes in petroleum hydrocarbon contaminated groundwater by polymerase chain reaction. J. Microbiol. Methods 27:121-128[CrossRef].
25.	Kämpfer, P., M. Steiof, and M. Dott. 1991. Microbiological characterization of a fuel-oil contaminated site including numerical identification of heterotrophic water and soil bacteria. Microb. Ecol. 21:227-251[CrossRef].
26.	Kunz, D. A., and P. J. Chapman. 1981. Isolation and characterization of spontaneously occurring TOL plasmid mutants of Pseudomonas putida HS1. J. Bacteriol. 146:952-964[Abstract/Free Full Text].
27.	Lee, S., J. Bollinger, D. Bezdicek, and A. Ogram. 1996. Estimation of the abundance of an uncultured soil bacterial strain by a competitive quantitative PCR method. Appl. Environ. Microbiol. 62:3787-3793[Abstract].
28.	Marmur, J. 1961. A procedure for the isolation of deoxyribonucleic acid from micro-organisms. J. Mol. Biol. 3:209-218.
29.	Mesarch, M. B., and L. Nies. 1997. Modification of heterotrophic plate counts for assessing the bioremediation potential of petroleum-contaminated soils. Environ. Technol. 18:639-646[CrossRef].
30.	Morgan, J. A. W., G. Rhodes, and R. W. Pickup. 1993. Survival of nonculturable Aeromonas salmonicida in lake water. Appl. Environ. Microbiol. 59:874-880[Abstract/Free Full Text].
31.	Piatak, M., Jr., K. Luk, B. Williams, and J. D. Lifson. 1993. Quantitative competitive polymerase chain reaction for accurate quantitation of HIV DNA and RNA species. BioTechniques 14:70-80[Medline].
32.	Power, M., J. R. van der Meer, R. Tchelet, T. Egli, and R. Eggen. 1998. Molecular-based methods can contribute to assessments of toxicological risks and bioremediation strategies. J. Microbiol. Methods 32:107-119.
33.	Ridgway, H. F., J. Safarik, D. Phipps, P. Carl, and D. Clark. 1990. Identification and catabolic activity of well-derived gasoline-degrading bacteria from a contaminated aquifer. Appl. Environ. Microbiol. 56:3565-3575[Abstract/Free Full Text].
34.	Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
35.	Shen, Y., L. G. Stehmeier, and G. Voordouw. 1998. Identification of hydrocarbon-degrading bacteria in soil by reverse sample genome probing. Appl. Environ. Microbiol. 64:637-645[Abstract/Free Full Text].
36.	Tsai, Y., and B. H. Olson. 1992. Rapid method for separation of bacterial DNA from humic substances for polymerase chain reaction. Appl. Environ. Microbiol. 58:2292-2295[Abstract/Free Full Text].
37.	U.S. Environmental Protection Agency. 1999. Use of monitored natural attenuation at Superfund, RCRA corrective action, and underground storage tank sites. Directive 9200.4-17P. U.S. Environmental Protection Agency, Washington, D.C.
38.	van Elsas, J. D., G. F. Duarte, A. S. Rosado, and K. Smalla. 1998. Microbiological and molecular biological methods for monitoring microbial inoculants and their effects in the soil environment. J. Microbiol. Methods 32:133-154.
39.	Wand, H., T. Laht, M. Peters, P. M. Becker, U. Stottmeister, and A. Heinaru. 1997. Monitoring of biodegradative Pseudomonas putida strains in aquatic environments using molecular techniques. Microb. Ecol. 33:124-133[CrossRef][Medline].
40.	Watanabe, K., S. Yamamoto, S. Hino, and S. Harayama. 1998. Population dynamics of phenol-degrading bacteria in activated sludge determined by gyrB-targeted quantitative PCR. Appl. Environ. Microbiol. 64:1203-1209[Abstract/Free Full Text].
41.	Wikström, P., A. Wiklund, A. Andersson, and M. Forsman. 1996. DNA recovery and PCR quantitation of catechol 2,3-dioxygenase genes from different soil types. J. Biotechnol. 52:107-120[CrossRef][Medline].
42.	Williams, P. A., and K. Murray. 1974. Metabolism of benzoate and the methylbenzoates by Pseudomonas putida (Arvilla) mt-2: evidence for the existence of a TOL plasmid. J. Bacteriol. 120:416-423[Abstract/Free Full Text].
43.	Wilson, I. G. 1997. Inhibition and facilitation of nucleic acid amplification. Appl. Environ. Microbiol. 63:3741-3751[Medline].
44.	Yarmoff, J., Y. Kawakami, T. Yago, H. Maruo, and H. Nishimura. 1988. cis-benzeneglycol production using a mutant Pseudomonas strain. J. Ferment. Bioeng. 66:305-312.