Attached and Unattached Bacterial Communities in a 120-Meter Corehole in an Acidic, Crystalline Rock Aquifer

doi:10.1128/AEM.67.5.2095-2106.2001

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Applied and Environmental Microbiology, May 2001, p. 2095-2106, Vol. 67, No. 5
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.5.2095-2106.2001

Attached and Unattached Bacterial Communities in a 120-Meter Corehole in an Acidic, Crystalline Rock Aquifer

R. Michael Lehman,¹^,^* Francisco F. Roberto,¹ Drummond Earley,²^, Debby F. Bruhn,¹ Susan E. Brink,² Sean P. O'Connell,¹ Mark E. Delwiche,¹ and Frederick S. Colwell¹

Idaho National Engineering and Environmental Laboratory, Biotechnologies Department, Idaho Falls, Idaho 83415-2203,¹ and Twin Cities Research Center, U.S. Bureau of Mines, Minneapolis, Minnesota 55417²

Received 17 October 2000/Accepted 5 March 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The bacteria colonizing geologic core sections (attached) were contrasted with those found suspended in the groundwater (unattached)by examining the microbiology of 16 depth-paired core and groundwatersamples using a suite of culture-independent and culture-dependentanalyses. One hundred twenty-two meters was continuously coredfrom a buried chalcopyrite ore hosted in a biotite-quartz-monzoniteporphyry at the Mineral Park Mine near Kingman, Ariz. Every fourth1.5-m core was acquired using microbiologically defensible methods,and these core sections were aseptically processed for characterizationof the attached bacteria. Groundwater samples containing unattachedbacteria were collected from the uncased corehole at depth intervalscorresponding to the individual cores using an inflatable straddlepacker sampler. The groundwater was acidic (pH 2.8 to 5.0), withlow levels of dissolved oxygen and high concentrations of sulfateand metals, including ferrous iron. Total numbers of attachedcells were less than 10⁵ cells g of core material¹ while unattached cells numbered about 10⁵ cells ml of groundwater¹. Attached and unattached acidophilic heterotrophs were observedthroughout the depth profile. In contrast, acidophilic chemolithotrophswere not found attached to the rock but were commonly observedin the groundwater. Attached communities were composed of lownumbers (<40 CFU g¹) of neutrophilic heterotrophs that exhibited a high degree ofmorphologic diversity, while unattached communities containedhigher numbers (ca. 10³ CFU ml¹) of neutrophilic heterotrophs of limited diversity. Sulfate-reducingbacteria were restricted to the deepest samples of both core andgroundwater. 16S ribosomal DNA sequence analysis of attached,acidophilic isolates indicated that organisms closely relatedto heterotrophic, acidophilic mesophiles such as Acidiphiliumorganovorum and, surprisingly, to the moderately thermophilicAlicyclobacillus acidocaldarius were present. The results indicatethat viable (but possibly inactive) microorganisms were presentin the buried ore and that there was substantial distinction inbiomass and physiological capabilities between attached and unattachedpopulations.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Compositional differences between attached and unattached (suspended in associated aqueous phase) microbial communities maydevelop due to selective advantages conferred on some populationsby attachment to environmental surfaces (28). Attachment ofindividual bacterial cells (of a single population) has frequentlybeen associated with substantial changes in cell physiology, althoughthe direction of change for a given physiological parameter isnot predictable and the causal factors of these changes are unclear(42). Accordingly, several recent publications have describedboth structural and functional differences between attached andunattached bacterial communities in marine and freshwater aquaticenvironments (7, 12, 37). Although similar distributionsof microbial biomass and activities in geologic media and groundwatermay impact solute transport in aquifers (19, 33, 43), fewstudies have systematically compared the microbial communitiesin paired core and groundwatersamples.

Studies examining the microbiology of core and groundwater samples from unconsolidated sedimentary aquifers generally haveindicated a predominance of attached biomass (5, 13, 16,17, 25, 40). Therefore, it has been suggested that coreis more representative of the subsurface microflora than groundwater(1, 14, 17, 32). However, numerical dominance of unattachedorganisms has been observed in some of these reports (5, 40),and differences in composition between attached and unattachedcommunities are common to all of these studies (5, 13, 16,17, 25, 40). The studies cited above are not all directlycomparable because there are differences in formation lithology,degree of nutrient enrichment, factors related to sample pairing(e.g., same depth and same corehole), methods used to acquiresamples, the type of analyses performed, and the units of thereported results. Given the constraints for interpreting currentdata regarding attached and unattached subsurface bacteria, itseems premature to limit the study of subsurface bacteria to coreor groundwater alone. Under a stable set of conditions, it isprobable that a dichotomy between attached and unattached organismswill be established (18) which may be reflected in significantdifferences in the functional capabilities of attached and unattachedpopulations. There is a particular lack of data from paired rockand groundwater samples from crystalline, fractured rockaquifers.

In order to evaluate potential differences between attached and unattached subsurface bacterial communities, we applied avariety of culture-independent and -dependent techniques to characterizecore and groundwater samples that were closely paired in depthof origin from a single corehole in a biotite-quartz-monzoniteporphyritic intrusive. This igneous rock hosts a low-grade sulfidicore that was under study by the U.S. Bureau of Mines for the developmentof advanced in situ leach mining techniques prior to the eliminationof the Bureau of Mines in 1996 (R. D. Schmidt and D. Earley, U.S.Bureau of Reclamation open file report, 1998). Deeply buried,low-grade sulfidic ores comprise most of world's remaining copperreserves (8), and the microbial ecology of these intact, crystallineore bodies is largely unknown. The microbiological assays wereaimed at populations that were expected to exist in this acidicenvironment and are involved in sulfide mineral oxidation (i.e.,acidophilic chemolithotrophs and heterotrophs) and those thathave been widely detected in subsurface environments (i.e., aerobicchemoheterotrophs).

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Site description. The Mineral Park mine (operated by Cyprus Mineral Park, a subsidiary of Cyprus Mining Corporation) is located in the centralpart of the Wallapai mining district of the Cerbat Mountains,26 km north of Kingman, Ariz., and 6.5 km east of Highway 95 (3,916,900m northing, 759,600 m easting; Universal Transverse Mercator grid,zone 11; North American Datum 1927) (Fig. 1). The 122-m-deep coreholewas sited slightly north of Turquoise Mountain, midway down intoIthaca Pit (formerly Ithaca Peak). The geology of the corehole(C-1024) site is characterized by a thin layer of avalanche andmudslide debris (1 m thick) overlying the Ithaca Peak stock, whichis a biotite-quartz-monzonite porphyry of the late Cretaceousperiod (ca. 71.5 million years ago) that intruded into the surroundingPrecambrian hornblende metadiorite. The igneous host rock washeavily fractured with hydrothermal mineralization, creating numerouscross-cutting veins filled with quartz, pyrite, chalcopyrite,and molybdenite; the average grade for the ore is 0.067% Cu and0.049% Mo (46). A stratigraphic profile of the corehole basedon the geologic field log of the core includes a description ofthe rock type and dominant alteration features (Fig. 2). Bulkformation permeabilities are on the order of millidarcies (Schmidtand Earley, U.S. Bureau of Reclamation open file report). Theelevation at the wellhead is 1,274 m above sea level. The localwater table at this location is about 6.4 m below land surface,which was the approximate depth of the surface casing. The hydrologiccomputer program MINEFLO has been used to construct a hydrologicmodel for the Mineral Park mine (R. D. Schmidt, L. J. Dahl, K.Kim, F. Paillet, and D. Earley, presented at the SME-AIME AnnualMeeting, Denver, Colo., 1995). According to the MINEFLO model,the groundwater table varies from 15.2 m below the surface to3.1 m above the surface along the cross section shown in Fig.1. The locations of artesian head conditions predicted by themodel correlate with natural springs, which flow almost year round,observed on the east highwall of the pit.

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FIG. 1. One-kilometer cross-section (W-E) locating the corehole (C-1024) at the Mineral Park Mine north of Kingman, Ariz., and its relationship with local geology, topography, and groundwater table.

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FIG. 2. Lithological profile of borehole derived from field log observations, vertical profile of electrochemistry results, and depths from which cores and groundwater samples were retrieved. The depth indicated for groundwaters is the midpoint of the 3-m packed-off zone. Eleven cores were taken within the 3-m span of their corresponding groundwater sample; five cores (CM102.7, CM66.1, CM59.7, CM41.8, and CM11.0) were taken just outside the 3-m packed-off interval of their corresponding groundwater sample.

Core sample acquisition and processing. One hundred twenty-two continuous meters of rock was cored with conventional rotary methods over a 2-week period in February1995. Cores (1.5 m long, 6.11 cm in diameter) were retrieved bywireline. Groundwater pumped from the downgradient SacramentoValley regional aquifer was amended with sodium hypochlorite toa concentration of 60 mg liter¹ and used as drilling fluid. Drilling fluid was continually discharged(not recirculated) during coring. Nineteen of the seventy-sixcores required to advance the hole past the surface casing tototal depth were processed for microbiological analyses (everyfourth core). Sixteen of these cores could be closely matchedin depth with groundwater samples obtained by straddle packersampling (described below) (Fig. 2). No groundwater samples couldbe taken to compare with three cores taken between 102.7 and 122.0m because of the length of the straddle packer sampler and accumulateddebris in the corehole. Control and assessment of contaminationintroduced during coring were consistent with procedures reviewedby Fredrickson and Phelps (11) and Griffin et al. (15), includingthe use of carboxylated, fluorescent microspheres (0.9-µm diameter;Polysciences, Inc., Warrington, Pa.) (38) and soluble perfluorocarbontracers (30) to assess drilling fluid intrusion. New drillingrods were purchased and dedicated to this project. All drill steelwas steam cleaned prior to insertion into the corehole, and theinner core barrel was similarly cleaned prior to each trip downhole.The inner barrel was handled only with clean cotton gloves byresearchers and drillers, and no lubricant was used on the pipethreads. For microbiological cores, a Lexan liner that had beencleaned with 10% bleach solution, rinsed with distilled water,and air dried was placed inside the inner corebarrel.

Extruded cores (in liners) were immediately capped and transported to an on-site laboratory trailer for aseptic processingin a glovebag under an argon atmosphere (11). From each 1.5-msection of core, an intact 0.3-m section was chosen as a "commoninterval" which was pared, homogenized, and distributed into sterilebags which were sealed in mason jars under argon and held in arefrigerator (4°C) for cultural analyses or in a freezer ( $-$ 20°C)for noncultural analyses. Core samples are referred to in thetext by the depth in meters from which they were retrieved precededby the project designation, CM (e.g., CM11.0). Results of microbiologicalanalyses of core samples were considered to represent attachedportions of the subsurface community. Subsamples of pared coreand parings were placed in methanol in tared volatile organiccarbon bottles for perfluorocarbon tracer analysis. Outer paringsfrom the common interval were bagged for microsphere analysesand petrologic and geochemical characterization. A "blank" coreconsisting of Berea sandstone fired repeatedly at 550°C was processedand analyzed in the same manner as other cores to estimate thecontamination due to sample handling. Samples from potential sourcesof contamination included groundwater used as drilling fluid (MW1[start of coring] and MW2 [end of coring]), surface rubble, andwater accumulated in the adjacent Ithaca Pit; these samples werecollected aseptically and analyzed like the core samples. Allsamples were mailed in insulated boxes to the analysis laboratoryby overnight express mail on ice or dry ice (depending on theanalyses).

Groundwater sampling and geochemistry. Groundwater sampling occurred 4 to 6 months following core sampling to allow subsidence of the disturbance to ambient groundwatercomposition introduced during coring activities (18). Groundwatersamples were collected from discrete 3-m intervals in the open(uncased) corehole by sealing off portions of the corehole aboveand below the sampling interval with an inflatable straddle packer(Schmidt and Earley, U.S. Bureau of Reclamation open file report).The straddle packer consisted of two inflatable bladders connectedto a riser pipe that was screened in the interval between thetwo bladders (39). The straddle packer was lowered to the desiredsampling point, and the bladders were inflated to isolate thesampling interval. A pump was lowered through the riser pipe topump water from this screened interval to the surface. In theintervals where recharge rates allowed, three interval bore volumeswere purged from the isolated zone before sampling. In all cases,the interval was purged prior to sampling until the electrochemistry(e.g., pH, temperature, dissolved oxygen, etc.) of the groundwaterhad stabilized. The isolation of the sampling interval was confirmedby monitoring pressure (head) in pressure transducers placed aboveand below the packed-off interval. A second indicator of successfulisolation was the speed of recovery within the sampling intervalafter pumping was discontinued. If the head between the packers(monitored by a transducer) recovered more quickly than expectedgiven the aquifer properties, then the packer was reseated. Twomethods were used to collect the samples following isolation andpurging of the sample interval. In the first method, groundwaterwas pumped from the isolated interval directly to a sampling port(flowthrough method). In the second method, samples were collectedwith a bailer after the pump was pulled (pump-and-retreatmethod).

A total of 32 groundwater samples were collected from 3-m intervals isolated by the straddle packer; 16 of these intervaldepths corresponded to the depths of cores. Interval groundwatersare referred to by the designation SP followed by the depth inmeters of the midpoint of the 3-m packed-off interval. Groundwatercollected from packed-off intervals for microbiological analyseswas pumped or collected from the bailer into sterile, polypropylenecontainers and held on ice prior to shipment as was done for thecore samples. Results of microbiological analyses of groundwatersamples were considered to represent unattached portions of thesubsurface community. Geochemistry samples were filtered througha 0.2-µm-pore-size filter, acidified with 0.5 ml of 1:1 HCl, andplaced on ice. The concentration of Fe²⁺ was determined within 12 h by titration with KMnO₄. Comprehensivegeochemical analysis of the samples was performed at the USBMTwin Cities Research Center laboratory using inductively coupledplasma atomic emission spectrometry for total sulfur and all cationsexcept K, Pb, Se, As, and Hg. Potassium was determined using flameatomic absorption spectrometry, and the remaining cations weredetermined using graphite furnace atomic absorption spectrometry.Ion chromatography was used for anion concentrationdeterminations.

The pH, temperature, E_h, dissolved oxygen content, and conductivity of the interval groundwater samples were determined foreach interval sample with a calibrated H20G multiprobe (HydrolabCorp., Austin, Tex.). In the flowthrough mode the water was pumpeddirectly through an acrylic chamber and past the sensors of theHydrolab multiprobe. With the bailer sampling method, the multiprobewas lowered into the well until it was less than 1 m above thepipe-packer fitting following sample collection with the bailer.The electrodes were allowed to equilibrate with the groundwaterfor 15 to 20 min before the reading was taken. A low-flow membrane(developed by Hydrolab) was used on the dissolved-oxygen sensorin order to facilitate readings in standing water prior to thecollection of bailer samples. The standard membrane was used whenthe instrument was used in the flowthrough mode. In addition tothe electrochemistry performed on interval samples, a calibratedmultiprobe (Hydrolab H20G) was used to profile the entire columnof groundwater in the uncased well prior to straddle packer pumpsample collection in August and September 1995. The temperature,dissolved oxygen content, conductivity, pH, and E_h were recordedat approximately 1-mintervals.

Microbiological analyses. (i) Sample preparation Rock fragments from the pared core and surface rubble samples were reduced in particle size to a fine dust by a Spex mill(model 8500; Spex Industries, Inc., Edison, N.J.) in the laboratory.The crushing was performed aseptically, with the critical componentsbeing wiped with 1% bleach solution and dried under vacuum betweensamples. Pilot studies using samples spiked with Pseudomonas chlororaphisand Acidithiobacillus ferrooxidans indicated no biological carryoverbetween samples and no ill effect of the crushing process or disinfectionon the viability of these organisms (data not shown). Dilutionsof crushed rock and groundwaters were made in phosphate-bufferedsaline (1.18 g of Na₂HPO₄, 0.223 g of NaHPO₄·H₂0, and 8.5 g ofNaCl per liter; pH 7.0) for neutrophilic organisms and in a pH3 salts solution [1.25 g of (NH₄)₂SO₄, 0.5 g of MgSO₄ · 7H₂O,and 0.25 g of tryptone soy broth per liter] for acidophilicorganisms.

(ii) Total cell counts and PLFA analysis. Acridine orange direct cell counts were performed on all core and groundwater samples to estimate the total number of bacterialcells per gram of rock or milliliter of water by the method ofKieft et al. (24). Phospholipid fatty acid (PLFA) analyses wereperformed on rock and groundwater samples using standardized methodsby Microbial Insights (Knoxville, Tenn.) (45). Biomass was estimatedby measurement of the quantity of ester-linked phospholipid fattyacids in the samples, and a structural community profile was generatedfor each sample by community-level PLFA analyses (45). The molarpercentages of the different classes of PLFA were compared bymultivariate techniques, and sample profiles were examined forsignature markers for specific taxonomic groups ofmicroorganisms.

(iii) Enumeration and enrichment of culturable heterotrophs $---$ aerobic, anaerobic, iron-reducing, and sulfate-reducing. Standard spread plate count methods for aerobic heterotrophic organisms at circumneutral pH were performed with sample dilutionson triplicate plates of 10% TSA (29) and R2A (36) media incubatedat room temperature for 2 weeks. Because of the low neutrophilic,heterotrophic biomass anticipated in the rock samples, supplementarydirect contact plates were created by sprinkling solid materialacross the agar surface. Fermenters and facultative anaerobicheterotrophs were assayed by incubation of triplicate spread platesof R2A under a 95% N₂-5% CO₂ atmosphere at room temperature for4 weeks prior to counting. Aerobic and anaerobic heterotrophicplate counts on interval groundwaters were performed using 10%TSA only. Estimates of culturable heterotrophic diversity wereobtained by isolating morphologically distinct colonies (usingsize, color, edge, elevation, and consistency as parameters) fromeach group of samples (i.e., core or groundwater). The presenceof dissimilatory-iron-reducing bacteria was determined by enrichmentof 1 g or 1 ml of sample in iron oxyhydroxide media in anoxicserum vials at pH 7.0 (27). The presence of sulfate-reducingbacteria was determined by enrichment of 1 g or 1 ml of samplein lactate media (35) in anoxic serum vials at pH 7.0. Primaryenrichments of iron- or sulfate-reducing bacteria that were positiveby presumptive evidence (i.e., precipitates) were transferredto fresh medium. Secondary enrichments that were positive by presumptiveevidence were examined for the presence of high numbers of cellsby direct observation of acridine orange-stained smear preparations.Secondary enrichments with confirmed presence of high numbersof cells were recorded aspositive.

(iv) Acidophiles cultured on solid media. Acidophilic heterotrophs and acidophilic chemolithotrophs were enumerated from crushed cores and groundwater by spread platingon glycerol (0.1%)- and yeast extract (0.02%)-amended basal salts-0.025%tryptone soy broth medium (solidified with 0.5% agarose) (22)and tetrathionate-ferrous iron-amended overlay medium (20),respectively. Media were prepared at pH 3.0. Crushed rock sampleswere prediluted with basal salts medium, mixed, and shaken forseveral hours prior to plating. Enumerations were performed onboth media after 2 weeks and reported as acidophilic heterotrophsand chemolithotrophs, respectively. Colony morphology was usedto distinguish different physiologies growing on the sulfur-ferrousiron-amended plates, i.e., iron-oxidizing chemotrophs versus sulfur-oxidizingchemotrophs versus iron-oxidizing heterotrophs (20). Representativesof distinct colony morphologies of heterotrophic and iron-oxidizingacidophilic bacteria were isolated and purified for genetic analysis.Genomic DNA was obtained from the isolates after lysis with lysozyme-proteinaseK (4), and 16S ribosomal DNA (rDNA) was amplified by PCR performedusing Tfl DNA polymerase (Thermus flavus; Epicentre Technologies,Madison, Wis.), a Thermolyne PTC-100 thermocycling apparatus,and eubacterial 8F and 1492R primers (44). PCR products werecloned into plasmid pUC18 using the CloneAMP pUC18 system (GIBCOBRL, Bethesda, Md.) and transformed into Escherichia coli DH5 $alpha$ .Plasmid DNA was isolated from transformed colonies and purifiedby CsCl density gradient centrifugation. The resulting DNA wassequenced (4000L automated DNA sequencer; LiCor, Inc., Lincoln,Nebr.), manually aligned, and compared with 16S rRNA sequencesdeposited in the Ribosomal Database Project. Sequence analysisand determination of phylogenetic position were performed by themethod of De Soete (9), and the sequences are presented relativeto their nearest neighbors as indicated by BLAST analysis (2).

(v) Autotrophic acidophilic liquid enrichments. The presence or absence of acidophilic chemolithotrophs using specific electron donors was determined by inoculating 1 g or1 ml of samples into five different types of basal salts liquidenrichment medium [1.5 g of (NH₄)₂SO₄, 0.5 g of KCl, 5.0 g ofMgSO₄ · 7H₂O, and 0.1 g of Ca(NO₃)₂ per liter] containing a traceelement solution (23) and either 20 mM ferrous sulfate, 0.1%(wt/vol) pyrite, 0.1% (wt/vol) elemental sulfur, 5 mM tetrathionate,or 5 mM tetrathionate plus 20 mM thiosulfate as a donor, withthe medium pH ranging from 1.8 to 2.5. Liquid acidophilic enrichmentswere incubated at room temperature in the dark with shaking. Primaryenrichments that were positive by presumptive evidence (i.e.,precipitates or turbidity) were transferred to fresh medium. Secondaryenrichments that were positive by presumptive evidence were examinedfor the presence of high numbers of cells by direct observationof acridine orange-stained smear preparations. Secondary enrichmentswith confirmed presence of high numbers of cells were recordedas positive. For all culture assays, uninoculated media and solidmedia spread with sterile dilution buffer were maintained underincubation conditions as negative controls; positive controlsconsisted of media inoculated with a culture of the target physiologicaltype and maintained under similarconditions.

(vi) Direct extraction of bulk DNA. Direct extraction of DNA from core materials was attempted using a variation of the method of Tsai and Olson (41). Fivegrams of pulverized core material was mixed with 10 ml of 120mM sodium phosphate buffer, pH 8.0. The slurry was shaken for15 min at room temperature, after which the mixture was centrifugedat 6,000 × g for 10 min, and the resulting pellet was resuspendedin 10 ml of lysis solution (0.15 M NaCl, 0.1 M Na₂EDTA [pH 8.0],5 µg of proteinase K ml¹). After incubation for 2 h with agitation at 30-min intervals,10 ml 0.1 M NaCl-0.5 M Tris HCl (pH 8.0)-10% sodium dodecyl sulfatewas added. The resulting suspension was subjected to three cyclesof freeze-thawing, freezing in a dry ice-ethanol bath, and thawingin a 65°C water bath. The lysed suspension was centrifuged foran additional 10 min at 6,000 × g, after which sodium dodecylsulfate was removed from solution using detergent absorber beads(Boehringer Mannheim) according to manufacturer's instructions.Nucleic acids were precipitated with the addition of 0.6 volumeof isopropanol and overnight incubation of the solution at $-$ 20°C,followed by centrifugation at 10,000 × g for 20 min at 4°C. Thenucleic acid-containing pellet was dried briefly under vacuumand resuspended in sterile, 0.2-µm filtered TE buffer (10 mM TrisHCl, 1 mM EDTA [pH 8.0]). 16S rDNA amplification was subsequentlyperformed as described above, and gel electrophoresis was usedto screen forproducts.

Nucleotide sequence accession numbers. Partial 16S rDNA sequences (ca. 1,250 bases) for the following isolates have been deposited in the GenBank nucleotide sequencedatabase (accession numbers in parentheses): MPH2 (AF352793),MPH3 (AF352794), MPH5 (AF352792), and MPH6 (AF352791).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Geochemistry. The groundwater electrochemical profiles taken from the uncased, unpacked corehole showed sharp fluctuations in parametersas a function of depth, most likely a result of fracture-controlledflow (Fig. 2). All groundwater samples were acidic (pH ~2.8 to5.0) and contained high concentrations of dissolved solids withrespect to groundwater compositions upgradient from the mine pitin undisturbed areas (data not shown). However, the groundwatersamples are dilute in ionic strength compared with the surfacewater found in the mine pits, which is constantly being recirculatedthrough copper-bearing dumps and drill and blast areas (data notshown). Through most of the profile the dissolved oxygen levelswere below detection (<0.5 mg liter¹) except at the top and at the bottom of the well. The high dissolvedoxygen levels in the bottom of the well may be attributed to highflow from a large fracture detected at 100 m. The deeper intervalsalso showed anomalous pH, E_h, and conductivity values that aresimilar to those for upgradient groundwater that has not beenaffected by mining activity. Temperatures recorded in the undisturbedwell before interval pumping climbed steadily from 18°C at thetop of the well to 23°C at the bottom. The temperatures at thebottom of the unpacked corehole are consistent with measurementsmade with the downhole multiprobe using the pump-and-retreat methodfor interval groundwater sampling. Temperature measurements madein the flow cell at the surface were unreliable due to solar heatingof the pumphose.

The two sampling methods (flowthrough and pump-and-retreat) yielded equivalent concentrations of groundwater constituentsand enumerations of acidophilic and neutrophilic bacteria on thesame interval sampled consecutively (SP52.8; data not shown).To control for temporal effects on the two episodes of intervalgroundwater sampling (August and September 1995), a single interval(SP75.0/75.8) was sampled on both occasions, and concentrationsof groundwater constituents and enumerations of acidophilic andneutrophilic bacteria were consistent (data not shown). The geochemistryof groundwater samples from several representative intervals spanninga range of compositions encountered is provided in Table 1. Thegeochemical speciation model, EQ3 (UCRL-MA-110662 PT1; LawrenceLivermore National Laboratory, Livermore, Calif.), indicated ahigh quality of the analyses and complete coverage of the majoranalytes as the respective maximum and minimum charge imbalanceswere 1% and $-$ 5% of the total charge. The majority of the calculatedcharge imbalances were within ±1% of the total charge. Ferrousiron represented over 95% of the total dissolved iron (ca. 200to 300 mg liter¹) found in the interval groundwaters. EQ3 speciation of the watersshowed that approximately 64% of the ferrous iron was "free" (unassociatedwith ligands) and 36% was associated with sulfate as FeSO₄(aq).The activities of other ferrous iron species were negligible.The EQ3 speciation results showed that the potential of the ferrous-ferriciron couple was 0.5 to 1.9 V greater than the electrode potential(E_h). Iron-oxidizing bacteria could be responsible for maintainingthis disequilibrium. The cations Si, Al, Mn, Na, Cu, and Zn werepresent at concentrations in the tens to hundreds of milligramsper liter. The predominant anion was sulfate, which ranged fromapproximately 3,000 to 4,000 mg liter¹. This result along with EQ3 speciation results showed that otherforms of dissolved sulfur occurred only in minute amounts. Chlorideand fluoride levels ranged from 10 to 80 mg liter¹, while nitrate and phosphate levels were below detection (<6mg liter¹).

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TABLE 1. Representative interval groundwater compositions from well C-1024

Exogenous tracer analyses. A reduction of one or more orders of magnitude in microsphere counts was typically observed in the subcores relative to thecore parings (Table 2). Residual microsphere counts in the subcoresand the combusted sandstone core were generally less than 2,550spheres g (wet weight)¹, which compares to values of ca. 10⁵ spheres g¹ reported during similar deployment of microspheres in anotherfractured rock aquifer (6). Core CM41.8, noted to have thehighest abundance of veins in the geologic log, and core CM72.2had high residual microsphere counts. Since several cross sectionsfrom a single common interval were pared in the same sterilizedpan, there was a possibility of smearing of microspheres fromparings onto subsequent subcore sections. Microspheres appearingin the subcore via this mechanism do not necessarily representinfiltration of contaminant organisms; this effect has been notedin other subsurface studies (J. K. Fredrickson, personal communication).It is unclear if the methods for biological disinfection of processingpans between samples (washing with bleach, rinsing with distilledwater, and flaming with a propane torch) effectively remove allmicrospheres. Perfluorocarbon analyses for all drilling fluid,subcore, and paring samples were below method detection limits(ca. 30 ng ml¹ or g¹). The failure to detect this analyte may have been due to theextended holding time (3 to 4 mo) prior to analyses.

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TABLE 2. Core quality assessed by microsphere analysis

Microbiology. (i) Total cells. Total cell counts for attached bacteria in all core samples, the combusted blank core and the surface rubble were at or belowthe detection limit (ca. 10⁵ cells g [wet weight]¹) for this method. For the unattached bacteria present in thegroundwaters, direct counts were all around 10⁵ cells ml¹, with relatively little variability (mean ± standard deviation[SD], 3.14 × 10⁵ ± 1.56 × 10⁵; n = 16). Total cell counts were 6.6 × 10⁵ cells ml¹ and 6.4 × 10⁵ cells ml¹ for MW1 and MW2, respectively. The water in the pit had 2.7 ×10⁵ cells ml¹ and contained filamentous microalga species not observed in othersamples.

(ii) PLFA. The amount of attached and unattached biomass as measured by total PLFA was at or below the detection limits for the assayas performed on these core and groundwater samples ( $<=$ 4 pmol g¹ or ml¹). The greatest overall biomass was observed in the surface sampleof weathered outcrop (90 pmol of PFLA g¹). Based on prior studies, this amount of biomass can be convertedto roughly 5 × 10⁶ viable cells (45). The drilling fluid makeup groundwaters (MW1and MW2) contained 4.5 pmol of PLFA ml¹ (3 × 10⁵ cells ml¹), and the pit water contained 11 pmol of PLFA ml¹ (7 × 10⁵ cells ml¹). The molar percentages of PLFA in the drilling fluid makeupgroundwaters indicated a community composed of gram-negative bacteria,possibly Pseudomonas spp., that contain high proportions of monoenoicfatty acids such as 18:1 $omega$ 9c and 18:1: $omega$ 7c (D. Ringelberg, personalcommunication). In the weathered surface rubble, the PLFA signaturesuggested that Actinomycetes might be the dominant organisms dueto the abundance of mid-chain-branched saturates, while in theIthaca Pit surface water samples, the high percentages of 18:1 $omega$ 7cand 17:0 suggested gram-negative organisms (like A. ferrooxidans)(D. Ringelberg, personalcommunication).

(iii) Neutrophilic heterotrophs. The numbers of attached aerobic and anaerobic neutrophilic heterotrophs were below method detection limits (ca. 40 CFU g [wetweight]¹) for all 16 core samples and the combusted blank core which werespread on 10% TSA and R2A media. However, occasional coloniesresulting from inoculation of core samples onto the spread andsprinkle plates (both 10% TSA and R2A) were isolated and morphologicallycharacterized. By streaking out distinct colony types for eachcore sample, a total of 40 morphologically distinct aerobic neutrophilicheterotrophs were isolated from the sum of all plates from all16 cores. A maximum of five morphologically distinct colonieswere found in a single core; not all cores were represented. Similarly,four anaerobic heterotrophic isolates were obtained from the sumof all plates from all 16 cores spread on R2Amedia.

The numbers of unattached aerobic and anaerobic neutrophilic heterotrophs ranged from below detection (<10 CFU ml¹) to more than 10⁴ CFU ml¹, depending on the groundwater interval sampled (Fig. 3). Themean numbers of unattached aerobic and anaerobic heterotrophswere 3.80 × 10³ CFU ml¹ (1 SD, 8.67 × 10³; n = 16) and 9.32 × 10² CFU ml¹ (1 SD, 1.14 × 10³; n = 9), respectively (Fig. 3). There was no significant differencebetween the mean numbers of aerobes and anaerobes for the groundwatersamples possessing both enumerations (P = 0.199, Student's two-tailedpaired t test; n = 9). A total of eight morphologically distinctaerobic heterotrophs were isolated from the sum of all platesfor all 16 interval groundwaters spread on 10% TSA media; no morethan one isolate type was observed per sample. Four anaerobicchemoheterotrophic isolates were recovered from 10% TSA from thesum of all plates from nine interval groundwaters.

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FIG. 3. Results of microbiological analyses using solid media plating. Populations cultured from the core ("attached") are juxtaposed with populations cultured from the groundwater ("unattached"). Depth is expressed in meters (m) below land surface. BD, below detection limits; TNTC, too numerous to count. a, neither acidophilic enumeration was performed on this sample; b, no enumeration of neutrophilic anaerobes was done for this sample.

Aerobic neutrophilic heterotrophic plate counts for the makeup waters taken at the start (MW1) and end (MW2) of the 2-weeksampling period were both 2.3 × 10⁵ CFU ml¹. No colonies were apparent on makeup water samples after sodiumhypochlorite was added, indicating effectiveness of the drillingfluid pretreatment. Weathered surface rubble from the drillingsite contained 7.7 × 10⁴ CFU g (wet weight)¹ and acidic pit waters (pH 2.5) contained 3.0 × 10² CFU of aerobic neutrophilic heterotrophs ml¹. Only two morphologically distinct aerobic neutrophilic heterotrophicisolates were cultured from the groundwater samples, MW1 and MW2(same two isolates at both sampling times). These two aerobicchemoheterotrophs cultured from the drilling makeup water (priorto disinfection) were never cultured from any cores. Four morphologicallydistinct isolates were cultured from both the surface rubble andthe pit water. No colonies were formed from spread plate inoculationsof the combustedcore.

(iv) Iron and sulfate reducers. Enrichments for heterotrophic iron-reducing bacteria were negative for all cores and groundwater samples and positive onlyfor Ithaca Pit surface water. Enrichments for sulfate-reducingbacteria were successful only for samples MW1, CM72.2, CM96.9,CM102.7, and SP105.2.

(v) Culturable acidophiles on solid media. Attached acidophilic heterotrophs (i.e., Acidiphilium spp.) were commonly recovered through out the depth profile, with CFUranging from 10² to 10⁴ g (wet weight)¹. In contrast, attached iron- or sulfur-oxidizing chemolithotrophswere never recovered (detection limit, 10 CFU g [wet weight]¹) (Fig. 3). While no strictly chemolithotrophic iron oxidizerswere recovered from any of the core samples, there was evidenceof iron-oxidizing heterotrophs which grew sparingly on iron mediaalone, presumably utilizing contaminants in the agarose-gelledmedia as a carbon source. These organisms were grown much moreefficiently after transfer to heterotrophic acidophile media.In the groundwaters, however, unattached chemolithotrophs werepresent in numbers from 10 to 10² CFU ml¹ in addition to acidophilic heterotrophs numbering 10 to 10⁴ CFU ml¹. Based on characteristic colony morphologies, at least threedifferent iron-oxidizing types were identified, including A. ferrooxidans,iron-oxidizing heterotrophs of the T21 type, i.e., "Ferromicrobiumacidophilus " (as described by Johnson et al. [21]), and noveliron oxidizers producing irregular colony margins, often withheavy zones of oxidized iron precipitation surrounded by areasof more uniform ferric iron deposition. Another unusual morphologyobserved was a colony type in which white sulfur compounds crystallizedin a background of regular ferric precipitate. The sulfur-oxidizingA. thiooxidans was also identified at several groundwater intervaldepths by an absence of iron precipitates accumulating aroundcolonies.

In an effort to definitively identify the various bacteria which have been provisionally identified based on behavior on thevarious acidophilic media utilized in this study, single colonieswith unique morphologies, as well as those with similar morphologiesfrom different depths, were grown to allow large-scale isolationof genomic DNA for subsequent amplification of 16S rDNA sequencesand phylogenetic analysis. As expected, several of the acidophilicheterotrophs (MPH2 and MPH3) cultivated from core samples (non-iron-oxidizingisolates) appear to be closely related to previously describedmembers of the genus Acidiphilium (Fig. 4A). However, other acidophilicheterotrophs (MPH5 and MPH6) yielded 16S rDNA sequences most similarto those of gram-positive, moderately thermophilic Alicyclobacillusacidocaldarius (Fig. 4B). These isolates have been grown at elevatedtemperatures (47°C).

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FIG. 4. (A) Phylogenetic positions of Mineral Park mesophilic heterotrophic acidophiles, MPH2 and MPH3, relative to Acidiphilium and Acidocella species of the alpha subclass of Proteobacteria (unrooted). Scale bar, 1% sequence divergence. (B) Phylogenetic position of Mineral Park moderately thermophilic acidophiles, MPH5 and MPH6, relative to other sulfobacilli of the high-G+C DNA content gram-positive bacteria (unrooted). From the positions of MPH5 and MPH6, they would be predicted to be non-iron-oxidizing sulfobacilli. Quotation marks indicate nonauthoritative nomenclature.

(vi) Liquid acidophilic, autotrophic enrichments. For attached bacteria, liquid enrichments with ferrous sulfate were positive from the lower portion of the corehole, and twocores, CM36.3 and CM78.9, were positive with elemental sulfuras an energy source (Table 3). In contrast, liquid enrichmentsfor unattached acidophilic chemoautotrophic bacteria were widelysuccessful with elemental sulfur, tetrathionate, tetrathionate-thiosulfate,and, to a lesser extent, ferrous sulfate. No enrichments withpyrite as the electron donor were positive for either attachedor unattached bacteria, although organisms closely associatedwith the pyrite surface may have been overlooked in examinationof the liquid. Liquid enrichments were more favorable for theinitial cultivation of sulfur oxidizers than the solid overlaymedia. Once grown in the liquid enrichment media, sulfur-oxidizingorganisms could be transferred successfully to solid overlay mediaamended with ferrous iron and tetrathionate (data not shown).

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TABLE 3. Results of acidic liquid media enrichments with different electron donors for paired core and groundwater samples

(vii) Direct extraction of bulk DNA. In an effort to reconstruct the in situ microbial community structure using phylogenetically informative sequences (i.e.,16S rDNA gene sequences), DNA was extracted directly from coresamples, CM17.7 and CM41.8, and amplification of 16S rDNA sequenceswas attempted. Estimates of the sensitivity of this techniquesuggest that as little as 1 pg of target DNA can serve as an efficienttemplate for the technique (10, 41). Due to interfering materials(possibly high concentrations of cations), our limit of detectionwas 100 pg. Based on an estimate of the DNA content of a "typical"bacterial cell (E. coli) of about 1 × 10¹⁴ g of DNA cell¹ (31), our limit of detection would be on the order of 2 × 10³ cells g¹, given that the isolation procedure was scaled to handle 5 gof core material. In no case were we able to detect amplified16S rDNA fragments from the two samples tested, even after a secondround of amplification, except in positive controls spiked withcontrol bacterial genomic DNA. This result is consistent withdata from PLFA analyses and acridine orange direct counts alsoperformed on core materials, which suggests that cell numberswere below the limits of detection of those techniques as well(again on the order of 10⁴ cells g¹). DNA extraction on groundwater samples was not attempted dueto the limited volume retrieved, the low biomass, and the highconcentrations ofcations.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this study of 16 paired core and groundwater samples from a single corehole in a crystalline, fractured rock aquifer, themajority of organisms were suspended in the groundwater and notattached to rock surfaces. There were decided compositional differencesbetween attached and unattached communities with respect to acidophilicand neutrophilic organisms. Acidophilic chemolithotrophs wereabsent in attached communities and commonly present in unattachedcommunities. Since over 95% of the dissolved iron in the groundwaterwas in the ferrous state and core surfaces were largely unoxidized,it is likely that the activity of these unattached chemolithotrophswas limited, probably by available oxygen, nitrogen, or CO₂. Therewere quantitative differences between the numbers of attachedand unattached neutrophilic chemoheterotrophs, and qualitativedifferences in these populations were suggested by the greatermorphologic diversity of colonies cultured from cores than ofthose from groundwater. The in situ activity (at low pH) of theneutrophilic chemoheterotrophs is uncertain. The isolation ofmoderately thermophilic organisms related to Alicyclobacillusacidocaldarius raises the interesting question of how these organismhave come to reside in subsurface mineral deposits and what rolethey may play in the microbial ecology of such anenvironment.

Since the report of Harvey et al. (16), researchers have generally concluded that attached bacteria dominate subsurfaceenvironments in biomass and activity and that planktonic cellsare inactive subsets of the attached organisms or transients (17,34). Our finding of higher numbers and diversity of unattachedbacteria than of attached bacteria appears to be at odds withthis general conclusion. However, there are only limited microbiologicaldata on multiple observations of authentic, defensible, depth-pairedcore and water from the same corehole to support this generalization.A review of the studies that fulfill these criteria yields thefollowing observations. Koebel-Boelke et al. (25) found moreattached biomass in a sandy aquifer with some differences betweenculturable organisms in the groundwater and those colonizing thesediment. Godsy et al. (13) reported more biomass attached tosandy sediments than in the comparative groundwater, althoughsome physiological groups (methanogens) were found mostly in thegroundwater. Bekins et al. (5) found a bimodal distributionof the relative abundance of planktonic bacteria (the modes were15 and 100% of the total cells) in a set of cores and groundwaterfrom a sedimentary aquifer. Those authors also reported that methanogenswere recovered more often in the groundwater than from the sediments.Therefore, when comparisons are carefully controlled, it doesseem that there are organisms that are unique to the groundwaterand are probably not transients (i.e., methanogens) and that unattachedbiomass may predominate over attached biomass under somecircumstances.

The three studies cited above were all conducted in unconsolidated sedimentary aquifers which have been the sites for otherstudies that have concluded that the majority of subsurface biomassis attached (16, 17, 40). In contrast, our data were takenfrom a crystalline, fractured rock aquifer where groundwater flowis not through true porous media but largely confined to fracturesin the low-permeability matrix. Because organisms might be expectedto concentrate on surfaces of fracture faces, aseptic dissectionof fracture surfaces for independent characterization was attempted,but it was not technically feasible, and the attached biomasswas expressed per unit of mass of bulk rock. It may be appropriateto express attached biomass in fractured rock aquifers in otherunits (i.e., surface area or unit of volume of aquifer), as suggestedby Pederson and Ekendahl (32, 34), who used colonized artificialsubstrata to assess attached microbes in a crystalline rock aquifer.A limited number of samples (one groundwater and three rock samples)were compared in the only (to our knowledge) study that comparedattached and unattached bacteria in actual samples taken froma crystalline, fractured rock formation (3). Those authorsfound about equal numbers of attached (per gram) and unattached(per milliliter) heterotrophs in ashfall tuff and the correspondinggroundwater accessed from tunnels at the Nevada Test Site butfound that the identities of these groups of isolates were verydifferent. Colwell and Lehman (unpublished data) have observedlittle biomass and activity associated with basalt cores comparedto groundwater taken from the same depth in a single corehole.While there is difficulty in equitably comparing attached andunattached biomass in crystalline, fractured rock aquifers, theexisting data support compositional differences between attachedand unattached communities in thesesettings.

Another factor which may differentiate shallow, unconsolidated sedimentary aquifers and deeper, crystalline, fractured rockaquifers is the amount of organic matter that is present. Ghiorseand Wilson (12a) discussed the paradigm that organisms shouldbe attached in proximity to large amounts of surface area in porousmedia. This expectation is generated by the knowledge that surfacesalso tend to concentrate metabolizable organic matter. The studiesthat have reported the dominance of attached biomass have beenconducted in sedimentary aquifers which contain particulate organiccarbon deposited in the geologic media, as opposed to the quartz-monzoniteporphyry investigated in this study. Further it might be expectedthat shallow groundwaters passing through porous media may containgreater amounts of dissolved carbon than are present in deeper,crystalline rock aquifers such as the one in the present study(groundwater total organic carbon, ca. 2 to 3 mg liter¹). However, the effect of carbon and nutrient enrichment on thedistribution of aquifer organisms between attached and unattachedstates is controversial. Nutrient enrichment of groundwaters isthought by some researchers to favor increased planktonic biomass(16, 17), while the opposite finding has been reported inone case (5) and suggested by literature on ultramicrobacteria(26). Therefore, it is difficult to conclude if the relativelysmall amount of organic carbon in the aquifer studied contributedto the lower numbers and diversity of attachedorganisms.

The partitioning of populations and physiologies between attached and unattached communities underscores the need to sampleboth core and groundwater to achieve comprehensive microbiologicalcharacterization of aquifers. The segregation of functional potentialbetween attached and unattached communities and the known changesin cell enzyme expression associated with surface attachment indicatea probable impact of microbial partitioning on solute transportin aquifers. The partitioning of in situ function between attachedand unattached microorganisms in this and other aquifers remainsunknown and represents the critical information for applications.Plans for in situ manipulation of saturated subsurface environmentsfor mining, fossil fuel extraction, bioremediation, or waste repositorypurposes should reflect knowledge of the location and mobilityof indigenous organisms, attached or unattached, and theiractivities.

	ACKNOWLEDGMENTS

This research was supported by funding provided by the former U.S. Bureau of Mines to the Idaho National Engineering and EnvironmentalLaboratory (INEEL), operated at that time by Lockheed Martin IdahoTechnologies Co. under contract DE-AC07-94ID13223, and by fundingprovided by the Department of Energy, Office of EnvironmentalManagement to the INEEL operated by Bechtel BWXT, LLC., undercontract DE-AC07-99ID13727.

	FOOTNOTES

^* Corresponding author. Mailing address: Idaho National Engineering and Environmental Laboratory, Biotechnologies Department,P.O. Box 1625, Idaho Falls, ID 83415-2203. Phone: (208) 526-3917.Fax: (208) 526-0828. E-mail: mik4{at}inel.gov.

Present address: Daniel B. Stephens & Associates, Albuquerque, NM87109.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Alfreider, A., M. Krossbacher, and R. Psenner. 1997. Groundwater samples do not reflect bacterial densities and activity in subsurface systems. Water Res. 31:832-840[CrossRef].

2. Altschul, S. F., W. Gish, W. Miller, E. W. Myers, and D. J. Lipman. 1990. Basic local alignment search tool. J. Mol. Biol. 215:403-410[CrossRef][Medline].

3. Amy, P. S., D. L. Haldeman, D. Ringelberg, D. H. Hall, and C. Russell. 1992. Comparison of identification systems for classification of bacteria isolated from water and endolithic habitats within the deep subsurface. Appl. Environ. Microbiol. 58:3367-3373[Abstract/Free Full Text].

4. Ausubel, F. M., R. Brent, R. E. Kingston, D. D. Moore, J. G. Seldman, J. A. Smith, and R. Sturtert (ed.). 1999. Current protocols in molecular biology. John Wiley and Sons, Inc., New York, N.Y.

5. Bekins, B. A., E. M. Godsy, and E. Warren. 1999. Distribution of microbial physiologic types in an aquifer contaminated by crude oil. Microb. Ecol. 37:263-275[CrossRef][Medline].

6. Colwell, F. S., G. J. Stormberg, T. J. Phelps, S. A. Birnhaum, J. P. McKinley, S. A. Rawson, C. Veverka, S. Goodwin, P. E. Long, B. F. Russell, T. Garland, D. Thompson, P. Skinner, and S. Grover. 1992. Innovative techniques for collection of saturated and unsaturated subsurface basalts and sediments for microbiological characterization. J. Microbiol. Methods 15:279-292[CrossRef].

7. Crump, B. C., E. V. Armbrust, and J. A. Baross. 1999. Phylogenetic analysis of particle-attached and free-living bacterial communities in the Columbia River, its estuary, and the adjacent coastal ocean. Appl. Environ. Microbiol. 65:3192-3204[Abstract/Free Full Text].

8. Debus, K. H. 1989. Identifying the biohydrometallurgical processes with the greatest probability of commercial adoption, p. 487-498. In J. Salley, R. G. L. McCready, and P. Wichlacz (ed.), Biohydrometallurgy '89. Canmet, Ottawa, Canada.

9. De Soete, G. 1983. A least squares algorithm for fitting additive trees to proximity data. Psychometrika 48:621-626[CrossRef].

10. Erlich, H. A. 1989. PCR technology: principles and applications for DNA amplification. Stockton Press, New York, N.Y.

11. Fredrickson, J. K., and T. J. Phelps. 1997. Subsurface drilling and sampling, p. 526-540. In C. J. Hurst, G. R. Knudsen, M. J. McInerney, L. D. Stetzenbach, and M. V. Walter (ed.), Manual of environmental microbiology. ASM Press, Washington, D.C.

12. Friedrich, U., M. Schallenberg, and C. Holliger. 1999. Pelagic bacteria-particle interactions and community-specific growth rates in four lakes along a trophic gradient. Microb. Ecol. 37:49-61[CrossRef][Medline].

12a. Ghiorse, W. C., and J. T. Wilson. 1988. Microbial ecology of the terrestrial subsurface. Adv. Appl. Microbiol. 33:107-172[Medline].

13. Godsy, E. M., D. F. Goerlitz, and D. Grbic Galic. 1992. Methanogenic biodegradation of creosote contaminants in natural and simulated groundwater ecosystems. Ground Water 30:232-242[CrossRef].

14. Gounot, A. M. 1994. Microbial ecology of groundwaters, p. 189-504. In J. Gibert, D. L. Danielopol, and J. A. Stanford (ed.), Groundwater ecology. Academic Press, San Diego, Calif.

15. Griffin, W. T., T. J. Phelps, F. S. Colwell, and P. E. Long. 1997. Methods for obtaining deep subsurface microbiological samples by drilling, p. 23-44. In P. S. Amy, and D. L. Haldeman (ed.), The microbiology of the terrestrial deep subsurface. CRC Press, Boca Raton, Fla.

16. Harvey, R. W., R. L. Smith, and L. George. 1984. Effect of organic contamination upon microbial distributions and heterotrophic uptake in a Cape Cod, Mass., aquifer. Appl. Environ. Microbiol. 48:1197-1202[Abstract/Free Full Text].

17. Hazen, T. C., L. Jimenez, G. L. de Victoria, and C. B. Fliermans. 1991. Comparison of bacteria from deep subsurface sediment and adjacent groundwater. Microb. Ecol. 22:293-304.

18. Hirsch, P., and E. Rades-Rohkohl. 1988. Some special problems in the determination of viable counts of groundwater microorganisms. Microb. Ecol. 16:99-113[CrossRef].

19. Holm, P. E., P. H. Nielsen, H.-J. Albrechtsen, and T. H. Christensen. 1992. Importance of unattached bacteria and bacteria attached to sediment in determining potentials for degradation of xenobiotic organic contaminants in an aerobic aquifer. Appl. Environ. Microbiol. 58:3020-3026[Abstract/Free Full Text].

20. Johnson, D. B. 1995. Selective solid media for isolating and enumerating acidophilic bacteria. J. Microbiol. Methods 23:205-218[CrossRef].

21. Johnson, D. B., P. Bacelar-Nicolau, D. F. Bruhn, and F. F. Roberto. 1995. Iron-oxidizing heterotrophic acidophiles: ubiquitous novel bacteria in leaching environments, p. 47-56. In T. Vargas, C. A. Jerez, J. V. Wiertz, and H. Toledo (ed.), Biohydrometallurgical processing '95, vol. 1. University of Chile, Santiago, Chile.

22. Johnson, D. B., J. H. M. Macvicar, and S. Rolfe. 1987. A new solid medium for the isolation and enumeration of Thiobacillus ferrooxidans and acidophilic heterotrophic bacteria. J. Microbiol. Methods 7:9-18.

23. Johnson, D. B., and S. McGinness. 1991. A highly efficient and universal solid medium for growing mesophilic and moderately thermophilic, iron-oxidizing, acidophilic bacteria. J. Microbiol. Methods 13:113-122.

24. Kieft, T. L., P. S. Amy, F. J. Brockman, J. K. Fredrickson, B. N. Bjornstad, and L. L. Rosacker. 1993. Microbial abundance and activities in relation to water potential in the vadose zones of arid and semiarid site. Microb. Ecol. 26:59-78.

25. Kolbel-Boelke, J., E.-M. Anders, and A. Nehrkorn. 1988. Microbial communities in the saturated groundwater environment. II. Diversity of bacterial communities in a Pleistocene sand aquifer and their in vitro activities. Microb. Ecol. 16:31-48[CrossRef].

26. Lappin-Scott, H. M., and J. W. Costerton. 1990. Starvation and penetration of bacteria in soils and rocks. Experientia 46:807-812[CrossRef].

27. Lovley, D. R., and E. J. P. Phillips. 1986. Organic-matter mineralization with reduction of ferric iron in anaerobic sediments. Appl. Environ. Microbiol. 51:683-689[Abstract/Free Full Text].

28. Marshall, K. C. 1992. Planktonic versus sessile life of prokaryotes, p. 262-275. In A. Balows, H. G. Truper, M. Dworkin, W. Harder, and K.-H. Schleifer (ed.), The Prokaryotes: a handbook on the biology of bacteria: ecophysiology, isolation, identification, applications, 2nd ed. Springer-Verlag, New York, N.Y.

29. Martin, J. K. 1975. Comparison of agar media for counts of viable soil bacteria. Soil Biol. Biochem. 7:401-402[CrossRef].

30. McKinley, J. P., and F. S. Colwell. 1996. Application of perfluorocarbon tracers to microbial sampling in subsurface environments using mud-rotary and air-rotary drilling techniques. J. Microbiol. Methods 26:1-9.

31. Neidhardt, F. C., J. C. Ingraham, and M. Schaechter. 1990. Physiology of the bacterial cell: a molecular approach. Sinauer Associates, Sunderland, Mass.

32. Pedersen, K. 1993. The deep subterranean biosphere. Earth-Sci. Rev. 34:243-260.

33. Pedersen, K. 1996. Investigations of subterranean bacteria in deep crystalline bedrock and their importance for the disposal of nuclear waste. Can. J. Microbiol. 42:382-391.

34. Pedersen, K., and S. Ekendahl. 1990. Distribution and activity of bacteria in deep granitic groundwaters of southeastern Sweden. Microb. Ecol. 20:37-52.

35. Postgate, J. R. 1979. The sulphate-reducing bacteria. Cambridge University Press, Cambridge, United Kingdom.

36. Reasoner, D. J., and E. E. Geldreich. 1985. A new medium for the enumeration and subculture of bacteria from potable water. Appl. Environ. Microbiol. 49:1-7[Abstract/Free Full Text].

37. Riemann, L., G. F. Steward, and F. Azam. 2000. Dynamics of bacterial community composition and activity during a mesocosm diatom bloom. Appl. Environ. Microbiol. 66:578-587[Abstract/Free Full Text].

38. Russell, B. F., T. J. Phelps, W. T. Griffin, and K. A. Sargent. 1992. Procedures for sampling deep subsurface microbial communities in unconsolidated sediments. Ground Water Monit. Rev. 12:96-104.

39. Shuter, E., and R. R. Pemberton. 1978. Inflatable straddle packers and associated equipment for hydraulic fracturing and hydraulic testing USGS Water-Investigations 78-55.

40. Thomas, J. M., M. D. Lee, and C. H. Ward. 1987. Use of ground water in assessment of biodegradation potential in the subsurface. Environ. Toxicol. Chem. 6:607-614.

41. Tsai, Y.-L., and B. H. Olson. 1991. Rapid method for direct extraction of DNA from soils and sediments. Appl. Environ. Microbiol. 57:1070-1074[Abstract/Free Full Text].

42. Van Loosdrecht, C. M. M., J. Lyklema, W. Norde, and A. J. B. Zehnder. 1990. Influence of interfaces on microbial activity. Microbiol. Rev. 54:75-87[Abstract/Free Full Text].

43. Van Schie, P. M., and M. Fletcher. 1999. Adhesion of biodegradative anaerobic bacteria to solid surfaces. Appl. Environ. Microbiol. 65:5082-5088[Abstract/Free Full Text].

44. Weisburg, W. G., S. M. Barns, D. A. Pelletier, and D. J. Lane. 1991. 16S ribosomal DNA amplification for phylogenetic study. J. Bacteriol. 173:697-703[Abstract/Free Full Text].

45. White, D. C. 1979. Lipid analysis of sediments for microbial biomass and community structure, p. 87-103. In C. D. Litchfield, and P. L. Seyfreid (ed.), Methodology for biomass determinations and microbial activities in sediments. ASTM STP 673. American Society for Testing and Materials, Philadelphia, Pa.

46. Wilkinson, W. H., L. A. Vega, and S. R. Titley. 1982. Geology and ore deposits at Mineral Park, Mohave County, Arizona, p. 523-542. In S. R. Titley (ed.), Advances in geology of the porphyry copper deposits, southwestern North America. University of Arizona Press, Tucson.

Applied and Environmental Microbiology, May 2001, p. 2095-2106, Vol. 67, No. 5
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.5.2095-2106.2001

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	Articles by Colwell, F. S.

1.	Alfreider, A., M. Krossbacher, and R. Psenner. 1997. Groundwater samples do not reflect bacterial densities and activity in subsurface systems. Water Res. 31:832-840[CrossRef].
2.	Altschul, S. F., W. Gish, W. Miller, E. W. Myers, and D. J. Lipman. 1990. Basic local alignment search tool. J. Mol. Biol. 215:403-410[CrossRef][Medline].
3.	Amy, P. S., D. L. Haldeman, D. Ringelberg, D. H. Hall, and C. Russell. 1992. Comparison of identification systems for classification of bacteria isolated from water and endolithic habitats within the deep subsurface. Appl. Environ. Microbiol. 58:3367-3373[Abstract/Free Full Text].
4.	Ausubel, F. M., R. Brent, R. E. Kingston, D. D. Moore, J. G. Seldman, J. A. Smith, and R. Sturtert (ed.). 1999. Current protocols in molecular biology. John Wiley and Sons, Inc., New York, N.Y.
5.	Bekins, B. A., E. M. Godsy, and E. Warren. 1999. Distribution of microbial physiologic types in an aquifer contaminated by crude oil. Microb. Ecol. 37:263-275[CrossRef][Medline].
6.	Colwell, F. S., G. J. Stormberg, T. J. Phelps, S. A. Birnhaum, J. P. McKinley, S. A. Rawson, C. Veverka, S. Goodwin, P. E. Long, B. F. Russell, T. Garland, D. Thompson, P. Skinner, and S. Grover. 1992. Innovative techniques for collection of saturated and unsaturated subsurface basalts and sediments for microbiological characterization. J. Microbiol. Methods 15:279-292[CrossRef].
7.	Crump, B. C., E. V. Armbrust, and J. A. Baross. 1999. Phylogenetic analysis of particle-attached and free-living bacterial communities in the Columbia River, its estuary, and the adjacent coastal ocean. Appl. Environ. Microbiol. 65:3192-3204[Abstract/Free Full Text].
8.	Debus, K. H. 1989. Identifying the biohydrometallurgical processes with the greatest probability of commercial adoption, p. 487-498. In J. Salley, R. G. L. McCready, and P. Wichlacz (ed.), Biohydrometallurgy '89. Canmet, Ottawa, Canada.
9.	De Soete, G. 1983. A least squares algorithm for fitting additive trees to proximity data. Psychometrika 48:621-626[CrossRef].
10.	Erlich, H. A. 1989. PCR technology: principles and applications for DNA amplification. Stockton Press, New York, N.Y.
11.	Fredrickson, J. K., and T. J. Phelps. 1997. Subsurface drilling and sampling, p. 526-540. In C. J. Hurst, G. R. Knudsen, M. J. McInerney, L. D. Stetzenbach, and M. V. Walter (ed.), Manual of environmental microbiology. ASM Press, Washington, D.C.
12.	Friedrich, U., M. Schallenberg, and C. Holliger. 1999. Pelagic bacteria-particle interactions and community-specific growth rates in four lakes along a trophic gradient. Microb. Ecol. 37:49-61[CrossRef][Medline].
12a.	Ghiorse, W. C., and J. T. Wilson. 1988. Microbial ecology of the terrestrial subsurface. Adv. Appl. Microbiol. 33:107-172[Medline].
13.	Godsy, E. M., D. F. Goerlitz, and D. Grbic Galic. 1992. Methanogenic biodegradation of creosote contaminants in natural and simulated groundwater ecosystems. Ground Water 30:232-242[CrossRef].
14.	Gounot, A. M. 1994. Microbial ecology of groundwaters, p. 189-504. In J. Gibert, D. L. Danielopol, and J. A. Stanford (ed.), Groundwater ecology. Academic Press, San Diego, Calif.
15.	Griffin, W. T., T. J. Phelps, F. S. Colwell, and P. E. Long. 1997. Methods for obtaining deep subsurface microbiological samples by drilling, p. 23-44. In P. S. Amy, and D. L. Haldeman (ed.), The microbiology of the terrestrial deep subsurface. CRC Press, Boca Raton, Fla.
16.	Harvey, R. W., R. L. Smith, and L. George. 1984. Effect of organic contamination upon microbial distributions and heterotrophic uptake in a Cape Cod, Mass., aquifer. Appl. Environ. Microbiol. 48:1197-1202[Abstract/Free Full Text].
17.	Hazen, T. C., L. Jimenez, G. L. de Victoria, and C. B. Fliermans. 1991. Comparison of bacteria from deep subsurface sediment and adjacent groundwater. Microb. Ecol. 22:293-304.
18.	Hirsch, P., and E. Rades-Rohkohl. 1988. Some special problems in the determination of viable counts of groundwater microorganisms. Microb. Ecol. 16:99-113[CrossRef].
19.	Holm, P. E., P. H. Nielsen, H.-J. Albrechtsen, and T. H. Christensen. 1992. Importance of unattached bacteria and bacteria attached to sediment in determining potentials for degradation of xenobiotic organic contaminants in an aerobic aquifer. Appl. Environ. Microbiol. 58:3020-3026[Abstract/Free Full Text].
20.	Johnson, D. B. 1995. Selective solid media for isolating and enumerating acidophilic bacteria. J. Microbiol. Methods 23:205-218[CrossRef].
21.	Johnson, D. B., P. Bacelar-Nicolau, D. F. Bruhn, and F. F. Roberto. 1995. Iron-oxidizing heterotrophic acidophiles: ubiquitous novel bacteria in leaching environments, p. 47-56. In T. Vargas, C. A. Jerez, J. V. Wiertz, and H. Toledo (ed.), Biohydrometallurgical processing '95, vol. 1. University of Chile, Santiago, Chile.
22.	Johnson, D. B., J. H. M. Macvicar, and S. Rolfe. 1987. A new solid medium for the isolation and enumeration of Thiobacillus ferrooxidans and acidophilic heterotrophic bacteria. J. Microbiol. Methods 7:9-18.
23.	Johnson, D. B., and S. McGinness. 1991. A highly efficient and universal solid medium for growing mesophilic and moderately thermophilic, iron-oxidizing, acidophilic bacteria. J. Microbiol. Methods 13:113-122.
24.	Kieft, T. L., P. S. Amy, F. J. Brockman, J. K. Fredrickson, B. N. Bjornstad, and L. L. Rosacker. 1993. Microbial abundance and activities in relation to water potential in the vadose zones of arid and semiarid site. Microb. Ecol. 26:59-78.
25.	Kolbel-Boelke, J., E.-M. Anders, and A. Nehrkorn. 1988. Microbial communities in the saturated groundwater environment. II. Diversity of bacterial communities in a Pleistocene sand aquifer and their in vitro activities. Microb. Ecol. 16:31-48[CrossRef].
26.	Lappin-Scott, H. M., and J. W. Costerton. 1990. Starvation and penetration of bacteria in soils and rocks. Experientia 46:807-812[CrossRef].
27.	Lovley, D. R., and E. J. P. Phillips. 1986. Organic-matter mineralization with reduction of ferric iron in anaerobic sediments. Appl. Environ. Microbiol. 51:683-689[Abstract/Free Full Text].
28.	Marshall, K. C. 1992. Planktonic versus sessile life of prokaryotes, p. 262-275. In A. Balows, H. G. Truper, M. Dworkin, W. Harder, and K.-H. Schleifer (ed.), The Prokaryotes: a handbook on the biology of bacteria: ecophysiology, isolation, identification, applications, 2nd ed. Springer-Verlag, New York, N.Y.
29.	Martin, J. K. 1975. Comparison of agar media for counts of viable soil bacteria. Soil Biol. Biochem. 7:401-402[CrossRef].
30.	McKinley, J. P., and F. S. Colwell. 1996. Application of perfluorocarbon tracers to microbial sampling in subsurface environments using mud-rotary and air-rotary drilling techniques. J. Microbiol. Methods 26:1-9.
31.	Neidhardt, F. C., J. C. Ingraham, and M. Schaechter. 1990. Physiology of the bacterial cell: a molecular approach. Sinauer Associates, Sunderland, Mass.
32.	Pedersen, K. 1993. The deep subterranean biosphere. Earth-Sci. Rev. 34:243-260.
33.	Pedersen, K. 1996. Investigations of subterranean bacteria in deep crystalline bedrock and their importance for the disposal of nuclear waste. Can. J. Microbiol. 42:382-391.
34.	Pedersen, K., and S. Ekendahl. 1990. Distribution and activity of bacteria in deep granitic groundwaters of southeastern Sweden. Microb. Ecol. 20:37-52.
35.	Postgate, J. R. 1979. The sulphate-reducing bacteria. Cambridge University Press, Cambridge, United Kingdom.
36.	Reasoner, D. J., and E. E. Geldreich. 1985. A new medium for the enumeration and subculture of bacteria from potable water. Appl. Environ. Microbiol. 49:1-7[Abstract/Free Full Text].
37.	Riemann, L., G. F. Steward, and F. Azam. 2000. Dynamics of bacterial community composition and activity during a mesocosm diatom bloom. Appl. Environ. Microbiol. 66:578-587[Abstract/Free Full Text].
38.	Russell, B. F., T. J. Phelps, W. T. Griffin, and K. A. Sargent. 1992. Procedures for sampling deep subsurface microbial communities in unconsolidated sediments. Ground Water Monit. Rev. 12:96-104.
39.	Shuter, E., and R. R. Pemberton. 1978. Inflatable straddle packers and associated equipment for hydraulic fracturing and hydraulic testing USGS Water-Investigations 78-55.
40.	Thomas, J. M., M. D. Lee, and C. H. Ward. 1987. Use of ground water in assessment of biodegradation potential in the subsurface. Environ. Toxicol. Chem. 6:607-614.
41.	Tsai, Y.-L., and B. H. Olson. 1991. Rapid method for direct extraction of DNA from soils and sediments. Appl. Environ. Microbiol. 57:1070-1074[Abstract/Free Full Text].
42.	Van Loosdrecht, C. M. M., J. Lyklema, W. Norde, and A. J. B. Zehnder. 1990. Influence of interfaces on microbial activity. Microbiol. Rev. 54:75-87[Abstract/Free Full Text].
43.	Van Schie, P. M., and M. Fletcher. 1999. Adhesion of biodegradative anaerobic bacteria to solid surfaces. Appl. Environ. Microbiol. 65:5082-5088[Abstract/Free Full Text].
44.	Weisburg, W. G., S. M. Barns, D. A. Pelletier, and D. J. Lane. 1991. 16S ribosomal DNA amplification for phylogenetic study. J. Bacteriol. 173:697-703[Abstract/Free Full Text].
45.	White, D. C. 1979. Lipid analysis of sediments for microbial biomass and community structure, p. 87-103. In C. D. Litchfield, and P. L. Seyfreid (ed.), Methodology for biomass determinations and microbial activities in sediments. ASTM STP 673. American Society for Testing and Materials, Philadelphia, Pa.
46.	Wilkinson, W. H., L. A. Vega, and S. R. Titley. 1982. Geology and ore deposits at Mineral Park, Mohave County, Arizona, p. 523-542. In S. R. Titley (ed.), Advances in geology of the porphyry copper deposits, southwestern North America. University of Arizona Press, Tucson.