Phylogenetic Diversity of Bacterial and Archaeal Communities in the Anoxic Zone of the Cariaco Basin

doi:10.1128/AEM.67.4.1663-1674.2001

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Applied and Environmental Microbiology, April 2001, p. 1663-1674, Vol. 67, No. 4
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.4.1663-1674.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Phylogenetic Diversity of Bacterial and Archaeal Communities in the Anoxic Zone of the Cariaco Basin

Vanessa M. Madrid, Gordon T. Taylor, Mary I. Scranton, and Andrei Y. Chistoserdov^*

Marine Sciences Research Center, State University of New York at Stony Brook, Stony Brook, New York 11794-5000

Received 11 September 2000/Accepted 24 January 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Microbial community samples were collected from the anoxic zone of the Cariaco Basin at depths of 320, 500, and 1,310 m ona November 1996 cruise and were used to construct 16S ribosomalDNA libraries. Of 60 nonchimeric sequences in the 320-m library,56 belonged to the $varepsilon$ subdivision of the Proteobacteria ( $varepsilon$ -Proteobacteria)and 53 were closely related to ectosymbionts of Rimicaris exoculataand Alvinella pompejana, which are referred to here as epsilonsymbiont relatives (ESR). The 500-m library contained sequencesaffiliated with the fibrobacteria, the Flexibacter-Cytophaga-Bacteroidesdivision, the division Verrucomicrobia, the division Proteobacteria,and the OP3 candidate division. The Proteobacteria included membersof the $gamma$ , $delta$ , $varepsilon$ and new candidate subdivisions, and $gamma$ -proteobacterialsequences were dominant (25.6%) among the proteobacterial sequences.As in the 320-m library, the majority of the $varepsilon$ -proteobacteriabelonged to the ESR group. The genus Fibrobacter and its relativeswere the second largest group in the library (23.6%), followedby the $delta$ -proteobacteria and the $varepsilon$ -proteobacteria. The 1,310-mlibrary had the greatest diversity; 59 nonchimeric clones in thelibrary contained 30 unique sequences belonging to the planctomycetes,the fibrobacteria, the Flexibacter-Cytophaga-Bacteroides division,the Proteobacteria, and the OP3 and OP8 candidate divisions. Theproteobacteria included members of new candidate subdivisionsand the $beta$ , $gamma$ , $delta$ , and $varepsilon$ -subdivisions. ESR sequences were stillpresent in the 1,310-m library but in a much lower proportion(8.5%). One archaeal sequence was present in the 500-m library(2% of all microorganisms in the library), and eight archaealsequences were present in the 1,310-m library (13.6%). All archaealsequences fell into two groups; two clones in the 1,310-m librarybelonged to the kingdom Crenarchaeota and the remaining sequencesin both libraries belonged to the kingdom Euryarchaeota. The lattergroup appears to be related to the Eel-TA1f2 sequence, which belongsto an archaeon suggested to be able to oxidize methane anaerobically.Based on phylogenetic inferences and measurements of dark CO₂fixation, we hypothesized that (i) the ESR are autotrophic anaerobicsulfide oxidizers, (ii) sulfate reduction and fermentative metabolismmay be carried out by a large number of bacteria in the 500- and1,310-m libraries, and (iii) members of the Euryarchaeota foundin relatively large numbers in the 1,310-m library may be involvedin anaerobic methane oxidation. Overall, the composition of microbialcommunities from the Cariaco Basin resembles the compositionsof communities from several anaerobic sediments, supporting thehypothesis that the Cariaco Basin water column is similar to anaerobicsediments.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The Cariaco Basin is the second largest of the world's anoxic pelagic systems and is the only large, truly marine, permanentlyanoxic basin (32). Because of the basin depth (1,400 m) andthe restricted circulation caused by a sill at 90 to 140 m, theCariaco Basin contains no oxygen below depths of about 240 to320 m. Previous studies of the geochemistry of the Cariaco Basinhave shown that the system is not in steady state, because theconcentrations of silica, phosphate, sulfide, and methane haveincreased over the last 25 years (32, 36, 37, 51). However,Cariaco Basin waters are partially flushed from time to time,but the processes that trigger flushing and its frequency arestill poorly understood. In the past, the major focus of researchin the Cariaco Basin and similar systems has been on the transitionzone (2, 12, 14, 16, 51). Chemoautotrophy in the transitionzone has been previously reported for both the Black Sea (15,38, 44) and the Cariaco Basin (40, 44, 45). The prokaryoticcommunities and the chemical environment of many permanently stratifiedbasins have been investigated by traditional cultivation-dependentmethods (31, 44). Tuttle and Jannasch (44) isolated severalsulfide- and thiosulfate-oxidizing bacteria from the redox interfacesof the Cariaco Basin and the Black Sea. Clearly, this environment,like the ocean at large, is undersampled with respect to bacterialdiversity because the culturability of marine bacteria is presentlyless than 0.1% (17).

Molecular biological approaches for studying microbial diversity have opened new perspectives for microbial ecology. Novel,cultivation-independent methods for studies of marine bacteriaand archaea have revealed large numbers of unknown microorganisms,which appear to be largely unaffiliated with previous isolatesfrom the same environment (5, 48). Most of the research inmarine molecular ecology has been directed toward microbial populationsof the water column (5, 6, 47, 48), marine sediments(10, 19, 30, 50), arctic ice (4), and salt marsh sediments(24, 33). Molecular ecological methods have also been usedto study the distribution of bacterial populations in a fjordthat is stratified and anoxic most of the time (Mariager Fjord,Denmark) (29, 41). However, comprehensive descriptions ofmicrobial communities in anoxic water columns have not been reportedpreviously.

This study focused on microbial communities in the anoxic zone of the Cariaco Basin, which has the advantage of being a relativelystable environment in which only the amount of substrate deliveredfrom surface waters varies (40). Thus, analysis of 16S ribosomalDNA (rDNA) libraries obtained from one cruise has a high probabilityof being representative of the Cariaco Basin system in general.We postulate that the microbial community in the anoxic zone ofthe Cariaco Basin should resemble that of sediments more thanthat of oxic water columns. Using the 16S rDNA library approach,we examined vertical distributions of prokaryotic populationswith depth for samples collected at the CARIACO time series stationon 8 November 1996 (CAR25). Compositions of prokaryotic communitiesin the oxic water column have been more or less well studied (5,6, 9, 47, 48), and many species appear to be cosmopolitanin distribution. Therefore, further study of surface waters inthe Cariaco Basin seemed to be unwarranted, and previously publishedphylogenetic libraries were used in ourcomparisons.

The commonly observed distribution patterns of redox-sensitive elements and microbial abundance suggest that microorganismsin the Cariaco Basin (40) proliferate in response to gradientsof specific sources of energy (reduced organic and inorganic compounds)and terminal electron acceptors (oxygen, nitrate, elemental sulfur,and oxidized metal). The identities and physiological capabilitiesof the prokaryotes in the layers are very poorly understood. Acensus of community diversity is the initial step towards thechallenging goal of assigning specific microorganisms to particularbiogeochemicalprocesses.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Water sampling and analyses. Three water column samples were collected during a cruise on 8 November 1996 at a single sampling site located in the easternbasin of the Cariaco Basin system (10°30'N, 64°40'W) at depthsof 320, 500, and 1,310 m. The samples were collected by usingstandard 8-liter Niskin bottles. For DNA extraction, 2 litersof seawater was filtered through Durapore membrane filters (diameter,47 mm; pore size, 0.2 µm; Millipore). The membrane filters werethen shredded and immediately immersed in 4.5 ml of autoclavedDNA extraction buffer (20 mM Tris-HCl [pH 7.5 to 8.2], 50 mM EDTA,20 mM NaCl) and stored frozen ( $-$ 20°C) until DNA was extracted.Complete depth profiles for physical properties, nutrients, sulfide,oxygen, bacterial counts, biomass, production, and dark CO₂ fixationfor this cruise have been published elsewhere (40).

DNA extraction and purification. The procedure used for extraction of chromosomal DNA is a modification of a procedure described by Xu and Tabita (49). Thisprocedure employs enzymatic and detergent-based lysis, which isa relatively gentle method that avoids excessive shearing of DNA,produces DNA of suitable quality for PCR, and reduces the riskof chimera formation during PCR. DNA was extracted from thawedmembranes by adding 0.5 ml of 10% sodium dodecyl sulfate and 250µl of a proteinase K solution (10 mg/ml), followed by incubationat 50°C for 10 min and freezing for 15 min. This freeze-thaw procedurewas repeated two more times. The thawed mixture was extractedtwice with water-saturated phenol (neutralized with 0.5 M Tris-HClbuffer, pH 7.8 to 8.5) and extracted once with a chloroform-isoamylalcohol (24:1) solution. Nucleic acids were precipitated by adding0.1 volume of 3 M sodium acetate (pH 5.2) and 2 volumes of chilled95% (vol/vol) ethanol. The mixture was incubated at $-$ 80°C forat least 20 min and then centrifuged at 21,000 × g for 10 min.The DNA pellet was washed with 70% ethanol, left to dry in a desiccatorfor 10 to 15 min, and then dissolved in 100 µl of sterile high-performanceliquid chromatography grade water (Sigma) and stored at $-$ 20°C.

PCR amplification. Amplification of 16S rRNA genes from the samples was carried out by performing PCR by the procedure of Borneman et al. (3),with modifications. Either Taq DNA polymerase (Promega, Madison,Wis.) or Deep Vent DNA polymerase (New England Biolabs, Beverley,Mass.) was used. For amplification, each 50-µl reaction mixturecontained the following components (final concentration or totalamount): 1 µl of DNA (concentration, 100 to 200 ng/µl), 1× reactionbuffer provided by each manufacturer, 2.5 mM MgCl₂ for Taq polymeraseor 7 mM MgSO₄ for Deep Vent polymerase, 1 mM concentrations ofdeoxynucleoside triphosphates, 2.5 µM primer 530F, 2.5 µM primer1494R, and 1.5 U of Taq polymerase or 1 U of Deep Vent polymerase.After all reagents were mixed and kept at 0°C, DNA was amplifiedby using a microprocessor-controlled heating block (CrocodileIII; Appligene SA, Illkirch, France). Prior to amplification,DNA was denatured at 92°C for 5 min. Forty cycles of PCR werethen performed at 92°C for 1 min (95°C for Deep Vent polymerase),50°C for 30 s, and 72°C for 1 min, followed by 72°C for 3 min(3).

The universal primers used to amplify small-subunit ribosomal genes were as follows: 530F (5'-GCTCTAGAGCTGACTGACTGAGTGCCAGCMGCCGCGG-3';position 530 to 546 [Escherichia coli numbering]) and 1494R (5'-GCTCTAGAGCTGACTGACTGAGGYTACCTTGTTACGACTT-3';positions 1494 to 1523 [E. coli numbering]). Each primer containedan additional sequence (underlined) that has the stop codon TGAin all three reading frames. The sequence TCTAGA (restrictionsite of endonuclease XbaI) was introduced into the 5' end of eachprimer. PCR products were purified by using a Wizard PCR PrepsDNA purification system (Promega) according to the manufacturer'sinstructions.

The 530F and 1494R primers chosen for this research are universal primers which preferably amplify a 1-kb portion of the bacterialand archaeal 16S rRNA gene. The resulting PCR fragment containsa conserved region (nucleotides 531 to 785 [E. coli numbering],adjacent to the 530F primer binding sequence), hypervariable regionV9, and a portion of region V8 (nucleotides 1253 to 1492 [E. colinumbering], adjacent to the 1494R primer bindingsequence).

16S rDNA library construction. In order to generate the 320-m 16S rDNA library, three different cloning strategies were used. If Deep Vent DNA polymerasewas used for PCR amplification, blunt end ligation was carriedout with pBluescript II SK(+) digested with restriction endonucleaseEcoRV and PCR products. Thirty-eight clones in the library weregenerated by using this approach. Since Deep Vent DNA polymerasehas a proof-reading activity, we made sure that inserts from theclones contained the complete primer sequences; i.e., the primer-templateduplex was not proof read by Deep Vent DNA polymerase. For PCRproducts obtained from PCR performed with Taq polymerase, eithercohesive end ligation was performed by digestion with restrictionenzyme XbaI and ligation into the commercial vector pBluescriptII SK(+)(Stratagene, La Jolla, Calif.) linearized with XbaI (fourclones in the library) or PCR products were directly cloned intothe pGEM-T vector (18 clones in the library). The four XbaI-generatedclones in the library were chosen at random and not on the basisof the correct size (1 kb) of the insert. Each ligation mixtureconsisted of 7.5 µl of purified PCR product, 5 Weiss units ofT4 ligase, 1× ligation buffer (Boehringer, Indianapolis, Ind.),and 25 ng of linear pBluescript II SK(+) or pGEM-T. Ligation mixtureswere incubated at 16°C overnight. For the 500- and 1,310-m 16SrDNA libraries, only Taq DNA polymerase was used. Purified PCRproducts were ligated directly into the pGEM-T vector by usinga 2× rapid ligation kit according to the instructions of the manufacturer(Promega). Ligation mixtures were used to transform competentcells of E. coli XL-1 Blue MRF' [F' (Tn10 proA⁺B⁺ lacI^q $Delta$ lacZM15) recA1 endA1 gyrA96 (Nal^r) thi hsdR17 (r_k m_k⁺) supE44 relA1 lac] by the procedure of Sambrook et al. (35)or by using commercially available high-efficiency competent cellsof E. coli JM109 according to the suggestions of the manufacturer(Promega).

Template preparation and sequencing. Plasmid DNA was isolated from randomly picked white colonies by a boiling method (35). Restriction fragment length polymorphism(RFLP) analysis of isolated plasmids was carried out by digestionwith HinfI and HaeIII (New England Biolabs). DNA band patternswere visualized by electrophoresis in 2% Tris-borate-EDTA (TBE)-agarosegels (35). Single-stranded DNA was isolated from each clonerepresenting an individual HinfI/HaeIII pattern according to Stratageneinstructions and by using the VCM13 helper phage (Stratagene).Single- and double-stranded DNA sequencing was carried out withan ABI Prism BigDye terminator cycle sequencing ready reactionkit (Perkin-Elmer, Foster City, Calif.). Plasmids which were pGEM-T-derivativeswere sequenced with primer $-$ 21 M13 (5'-GTAAAACGACGGCCAGT-3').Plasmids which were pBluescript II SK(+) derivatives were sequencedwith primer KS (5'-GAGCTCCAGCTGCCATAG'-3). Sequences obtainedwith primers $-$ 21 M13 and KS were ~500 bp long. In order to completesequences of all or parts of the 1-kb fragment (amplified withprimers 530F and 1494R), the following additional primers wereused for sequencing: 16SF (5'-ACRGGATTAGATACCCVGG-3'; positions781 to 799 [E. coli numbering]) and 16SR (5'-CCATTGTAVACAGGTGTDGCCC-3';positions 1219 to 1241 [E. coli numbering]).

Preparation of phylogenetic trees and phylogenetic assignment. Sequences retrieved from the Cariaco Basin 16S rDNA libraries were compared to the 16S rDNA sequences available in the 16SrRNA database by using the SEQUENCE_MATCH program from the RibosomalDatabase Project (RDP) (20) and to sequences in the GenBankdatabase by using the FASTA program (Wisconsin Package, version9.1, of the Genetics Computer Group). The presence of chimericsequences in the libraries was determined by using the CHECK_CHIMERAprogram fromRDP.

For alignment, the rDNA clone sequences were separated into the following three groups: (i) sequences sequenced through aconserved region (adjacent to the primer 530F sequence) (groupA), (ii) sequences sequenced through hypervariable region V9 anda portion of V8 (adjacent to the primer 1494R sequence) (groupB), and (iii) sequences with the complete 1-kb sequence (groupC). Sequences from each group were then aligned with their closestrelatives by using the programs PILEUP (Genetics Computer Group)and ClustalW (J. Thompson and T. Gibson, European Molecular BiologyLaboratory, Heidelberg, Germany) and representatives of the majorphylogenetic taxa. Portions of the complete 1-kb sequences werealso introduced into the alignments of the group A and B sequences.Trees were constructed by using two independent algorithms: distanceanalyses with Jukes-Cantor corrections (DNAdist) and FITCH fromthe PHYLIP package (J. Felsenstein, PHYLIP [Phylogeny InferencePackage], version 3.57c) and maximum likelihood (DNAml program,also from PHYLIP). In order to determine confidence values forindividual branches of each final tree, bootstrap analysis wasapplied to each tree generated by using the SEQBOOT and CONSENSEprograms from the PHYLIPpackage.

Nucleotide sequence accession numbers. The sequences of the Cariaco Basin rDNA clones have been deposited in the GenBank database under accession numbers AF224775to AF224872.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Construction and analysis of 16S rDNA gene libraries. DNA extracted from samples harvested from three anoxic depths in the Cariaco Basin was amenable to direct PCR amplification.The highest yield of chromosomal DNA was obtained with the 320-msample, which agrees with the bacterial abundance trends measuredfor the cruise (40). Several independent sublibraries (independentrepetitions of PCR and ligation reactions and transformations)were created for each depth. Clones of all sublibraries from agiven depth were mixed to create three final libraries representingthe threedepths.

From the 320-, 500-, and 1,310-m libraries, 61, 56, and 65 colonies, respectively, with 1-kb inserts were randomly selectedand screened by RFLP analysis. From these clones, 32, 45, and59 unique RFLP band patterns, respectively, were identified. Furthersequencing analysis confirmed that only 10, 32, and 44 clones,respectively, contained unique DNA sequences. Sequences whichdiffered by less than 0.1% were consider identical. Thus, the1,310-m library had the highest percentage of unique sequencesamong the three libraries, and the 320-m library had the lowest.The presence of chimeric sequences was determined by using theCHECK_CHIMERA program from RDP. The chimeric sequences identified(Table 1) were not included in further phylogenetic analyses.The 16S rDNA sequences are summarized in Table 1; sequences fromthe 320-, 500-, and 1,310-m libraries have the suffixes "a," "b,"and "c," respectively, in their designations.

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TABLE 1. 16S rDNA sequences identified in anoxic water column of the Cariaco Basin in three clone libraries

Close relatives of the nonchimeric sequences identified by searches in the RDP and GenBank databases are shown in Table 1.Since the 1-kb 16S rDNA fragments were not directionally clonedinto pGEM-T and pBluescript II SK(+), the sequences were dividedinto two groups: sequences containing the more conserved regions(group A) and sequences containing more variable regions (groupB). For several clones, the complete sequence of the 1-kb insertwas determined (group C). In Table 1, group A clones are identifiedby the suffix "f" and group B clones are identified by the suffix"r". Clones whose complete 1-kb inserts were sequenced (groupC) have no "f" or "r" suffix. Three separate trees were constructed(see Materials and Methods) for each group of sequences by usingtwo independent algorithms. Comparable portions of the group Csequences were also introduced into the alignments of the groupA and B sequences. The positions of group C sequences were identicalin all three trees, and therefore, trees containing only thesesequences are not shown. Trees for the bacterial group A and Csequences and for the bacterial group B and C sequences are shownin Fig. 1A and B, respectively. Archaea and members of the $varepsilon$ subdivisionof the division Proteobacteria ( $varepsilon$ -proteobacteria) were placedon separate trees, and only trees for the group A and C sequencesare shown in Fig. 2 and 3. Distance and maximum-likelihood algorithmsgenerated essentially identical trees, and only trees constructedwith distance-based methods are shown.

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FIG. 1. Phylogenetic relationships of partial 16S rDNA sequences from 56 unknown bacterial clones in the 320-m (designations with the suffix "a"), 500-m (designations with the suffix "b"), and 1,310-m (designations with the suffix "c") Cariaco Basin libraries and 44 sequences from RDP and GenBank databases. Sequences from nucleotide 531 to nucleotide 1040 (A) and from nucleotide 952 to nucleotide 1480 (B) (E. coli 16S rRNA numbering) were aligned and placed in the trees. The sequences were aligned with ClustalW; distance matrices and phylogenetic trees were constructed by using the Jukes-Cantor and Fitch-Margoliash algorithms, respectively. Division level groupings are indicated on the right. New candidate subdivisions of proteobacteria are designated NC1 and NC2. Bar = 0.02 change per sequence position. The numbers at the nodes are bootstrap confidence values expressed as percentages of 100 bootstrap replications. Bootstrap values less than 50% are not shown.

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FIG. 2. Phylogenetic relationships of partial 16S rDNA sequences from 10 unknown $varepsilon$ -proteobacterial clones in the 320-m (designations with the suffix "a"), 500-m (designations with the suffix "b"), and 1,310-m (designations with the suffix "c") Cariaco Basin libraries and 14 $varepsilon$ -proteobacterial sequences from RDP and GenBank databases. Sequences from nucleotide 531 to nucleotide 1040 (E. coli 16S rRNA numbering) were aligned and placed in the tree. The sequences were aligned with ClustalW; distance matrices and phylogenetic trees were constructed by using the Jukes-Cantor and Fitch-Margoliash algorithms, respectively. Bar = 0.01 change per sequence position. The numbers at the nodes are bootstrap confidence values expressed as percentages of 100 bootstrap replications. Bootstrap values less than 50% are not shown.

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FIG. 3. Phylogenetic relationships of partial 16S rDNA sequences from six unknown archaeal clones in the 500-m (designations with the suffix "b") and 1,310-m (designations with the suffix "c") Cariaco Basin libraries and 25 archaeal sequences from RDP and GenBank databases. Sequences from nucleotide 531 to nucleotide 1040 (E. coli 16S rRNA numbering) were aligned and placed in the tree. The sequences were aligned with ClustalW; distance matrices and phylogenetic trees were constructed by using the Jukes-Cantor and Fitch-Margoliash algorithms, respectively. Division level groupings are indicated on the right. Bar = 0.02 change per sequence position. The numbers at the nodes are bootstrap confidence values expressed as percentages of 100 bootstrap replications. Bootstrap values less than 50% are not shown.

In many cases, our phylogenetic placement of a sequence on a tree coincided with the placement of the sequence based on theclosest relative found in databases. However, in a few cases,such as Car33fb, Car40rc, Car116rc, Car121rc, and Car124rc, thelevel of similarity with a close relative was low, and these sequenceswere affiliated based on their positions in the phylogenetic trees.In many cases (Car60fc, Car11fa, Car136b, Car30c, Car40rc, Car119rc,Car124rc, Car731c, Car63a, and Car33fb), Cariaco Basin cloneswere affiliated with candidate divisions and subdivisions, whichmade it impossible to hypothesize about their nearest cultivablerelatives and their possible physiology. Surprisingly, severalsequences in the Cariaco Basin 16S rDNA libraries were relatedto cultivable bacteria. 16S rDNA sequences of clones Car56rc,Car114fc, Car117fc, Car39fc, Car123rc, and Car2a appeared to beaffiliated with the genera Sphingobacterium, Flavobacterium, Alcaligenes,Citrobacter, Photobacterium, and "Thiomicrospira," respectively.Sequences of clones Car70c, Car43fc, Car140fb, and Car92rb wereaffiliated with Pseudoalteromonas and Moritella spp. In addition,several sequences retrieved from different environmental samplesby other researchers exhibited relatively high levels of identity(up to 96%) with Cariaco Basinsequences.

Bacteria in the Cariaco Basin anoxic zone. The majority (95%) of the sequences retrieved belonged to bacteria, and the division Proteobacteria was the dominant division.Bacterial sequences belonging to the following major divisionswere identified: Cytophaga-Flexibacter-Bacteroides, fibrobacteria,planctomycetes, Verrucomicrobia, the OP8 and OP3 candidate divisions,and the $beta$ , $delta$ , $gamma$ , and $varepsilon$ subdivisions of the Proteobacteria (Fig.1A and 1B). Only three of the proteobacterial sequences (Car33fb,Car63a, and Car731c) could not be affiliated with any known proteobacterialsubdivision. Therefore, these sequences appear to represent twonew candidate subdivisions in the proteobacteria. Car33fb wastentatively assigned to the NC1 subdivision, and Car731c and Car63awere tentatively assigned to the NC2 subdivision. Only representativesof OP3 and the $gamma$ , $delta$ , and $varepsilon$ subdivisions of the Proteobacteriawere found at all threedepths.

Bacteria in the 320-m library. Of the 60 nonchimeric sequences in the 320-m 16S rDNA library, 56 (93.2%) belonged to the $varepsilon$ subdivision. One of the remainingfour sequences belonged to each of the following groups: candidatedivision OP3 and the NC2, $gamma$ , and $delta$ subdivisions of the Proteobacteria.Within the $varepsilon$ -proteobacteria, most of the sequences belonged toan as-yet-uncultured group first identified by Polz and Cavanaugh(28) as ectosymbionts of the shrimp Rimicaris exoculata (Fig.2). Below, this group is referred to as the epsilon symbiont relatives(ESR). Three remaining $varepsilon$ -proteobacteria clustered with Arcobacterand "Thiomicrospira" spp. The only chimera found in the 320-mlibrary also contained a portion of ESR 16SrDNA.

Bacteria in the 500-m library. The 500-m library was more diverse, containing sequences from members of the fibrobacteria, the Flexibacter-Cytophaga-Bacteroidesdivision, the Verrucomicrobia, the Proteobacteria, and the OP3candidate division. The proteobacteria included representativesof the $gamma$ , $delta$ , $varepsilon$ , and NC2 subdivisions, and $gamma$ -proteobacteria weredominant (25.6%). As in the 320-m library, the majority of the $varepsilon$ -proteobacteria appeared to be ESR. Fibrobacter and its relativescomprised the second largest group in the library (23.6%), followedby $gamma$ -proteobacteria, $delta$ -proteobacteria, and $varepsilon$ -proteobacteria.

Bacteria in the 1,310-m library. The 1,310-m library had the highest percentage of unique sequences; 59 nonchimeric clones in the library contained 38 uniquesequences belonging to members of the planctomycetes, the fibrobacteria,the Flexibacter-Cytophaga-Bacteroides division, the Proteobacteria,and the OP3 and OP8 candidate divisions. The proteobacteria includedrepresentatives of the NC2, $beta$ , $gamma$ , $delta$ , and $varepsilon$ subdivisions. ESR sequenceswere present in the 1,310-m library but comprised a much lowerproportion of the clones (8.5%). Compared to the 500-m library,the 1,310-m library contained a lower proportion of fibrobacterialand $delta$ -proteobacterial sequences. The largest group of bacteriaat this depth was the $gamma$ -proteobacterial group, particularly Pseudoalteromonas/Moritellasp. strain Car70c. The 500- and 1,310-m libraries shared severalidentical sequences (including Car53c, Car56rb, Car92rb, and Car54fc),two groups of nearly identical sequences (represented by Car129rcand Car70c), and a group of closely related sequences (Car128fc,Car91fb, Car141fb, and Car149fc). ESR found in all three librarieswere closely related to each other and did not comprise threedifferent subgroups corresponding to three individuallibraries.

Archaea in the anoxic zone of the Cariaco Basin. No archaeal sequences were retrieved from the 320-m library. One archaeal sequence was present in the 500-m library (2% ofall microorganisms in the library) and eight archaeal sequenceswere present in the 1,310-m library (13.6%). All archaeal sequencesfell into two groups; one group was represented by two clonesbelonging to the kingdom Crenarchaeota, and the other includedthe remaining archaeal sequences in both libraries. The formergroup is closely related to the clone Archaeon C20 (Table 1 andFig. 3) from Irish coastal waters, whose metabolism is unknown(22). The latter group is distantly related to cultured membersof the kingdom Euryarchaeota. However, in the archaeal tree (Fig.3) all sequences in this group appear to be related to the Eel-TA1f2sequence retrieved from methane seep sediments in the Eel Riverbasin (13). All Euryarchaeota sequences from the Cariaco Basinclustered together on the trees, forming a monophyletic cladeconfirmed by bootstrap analysis (Fig. 3).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Investigations of the compositions of microbial communities are important steps in understanding the role of bacterial andarchaeal populations in biogeochemical processes. Due to poorculturability of natural bacteria, particularly anaerobic bacteria,we used molecular approaches based on rDNA sequences to investigatemicrobial community structure in the anoxic Cariaco Basin. However,we caution that the 16S rDNA library strategy for sequence retrievalcontains several sources of potential bias. A bias caused by thereannealing kinetics of product molecules can skew gene frequencieswhen PCR product concentrations exceed threshold values (39).Another important potential bias is that organisms belonging tothe domain Archaea have been found to have only one or a few genecopies of the 16S rRNA gene, while members of the domain Bacteriacan have from one to seven or more copies, which may bias amplificationtowards the Bacteria (26). Therefore, the frequency of rDNAclones should be regarded as qualitative information on communitycomposition. Nonetheless, 16S rDNA libraries have provided valuablequalitative descriptions of microbial diversity that allow comparisonsbetween communities in different environments (39).

We created 16S rDNA libraries for three microbial community samples collected at depths of 320, 500, and 1,310 m. Oxygen measurements(40) have shown that all three samples were collected from theanoxic zone of Cariaco Basin. The composition of the 320-m librarywas markedly different from the compositions of the other twolibraries. Theoretically, the differences in composition may havearisen from differences in the PCR and/or cloning strategies usedin the construction of the three libraries. Unlike the 500- and1,310-m libraries, the 320-m library was constructed by usingthree cloning strategies. Thirty-eight clones in this librarywere generated by blunt-end cloning of DeepVent polymerase-generatedPCR products, and 18 clones were generated by cloning Taq polymerase-generatedPCR products into pGEM-T. In contrast, all clones in the 500-and 1,310-m libraries were generated by using only the lattercloning technique. However, we observed that the compositionsof the two 320-m sublibraries were identical, indicating thatuse of either of the two cloning strategies does not introduceartifacts during library construction. Since the diversity ofthe 320-m library is so low, the 18-clone sublibrary alone appearsto be large enough to claim that the microbial community at thisdepth is substantially different from the communities in the 500-and 1,310-msamples.

The difference between the 320-m sample and the two other samples may be explained by different chemical conditions at thethree depths. Nitrogen cycling and particularly iron and manganesecycling may be important for bacterial populations at 320 m sincesome oxidized forms of these elements may be available (40).Hastings and Emerson (12) have shown that concentration of elementalsulfur peaks immediately above the O₂-H₂S interface, suggestingthat S⁰ may also be available as an oxidant below this interface. Furthermore,several sources may supply energy to communities at 320 m; theseinclude sedimenting organic detritus from above, H₂S from belowto fuel chemoautotrophy, and organic by-products from chemoautotrophy(40). Thus, the presence of several electron acceptors and donorsis likely to be the reason why the 320-m microbial community isso different from the communities at the two other depths. Thechemical conditions at 500 and 1,310 m appear to be very similar;the H₂S concentration only increases from 23 to 70 µM and theconcentrations of terminal electron acceptors (SO₄² and CO₂) remain fairly constant. Indeed, there is some similarityin the compositions of the microbial communities at these depths.In both libraries $gamma$ -, $delta$ -, and $varepsilon$ -proteobacteria are present. However,the number of $delta$ - and $varepsilon$ - proteobacterial clones decreases withdepth whereas the proportion of $gamma$ -proteobacterial clones increases.The major differences between the 500- and 1,310-m libraries arethat (i) fibrobacterial sequences are dominant in the 500-m libraryand they almost disappear at 1,310 m and (ii) the number of archaealsequences in the libraries substantially increases withdepth.

Overall, the diversity of 16S rDNA sequences in the 1,310-m sample is not typical of a water column but rather resembles thatof a sediment or soil (10, 18, 19, 30, 50). One possibleexplanation is that the 1,310-m sample area is approximately 60m off the bottom and motile sediment bacteria migrate up in thewater column. Another possible explanation is that seismic activityor mass wasting on the basin's walls causes turbidity flows andthereby resuspends sediments and associated microorganisms (42).Resuspended bacteria and small particles may remain in the watercolumn long after the sediment settles because of their negligiblesettlingvelocities.

The compositions of microbial communities from the deep Cariaco Basin resemble the compositions of microbial communities fromseveral anoxic sediments. For example, Cariaco Basin sequencesare related to sequences from deepwater sediments collected aroundthe Japanese islands (19). Members of the OP3 candidate division,Car136r and BD3-9, are found in Cariaco Basin water and Japaneseisland sediments, respectively. Sequences belonging to membersof the planctomycetes division in the Cariaco Basin libraries(Car65rc, Car68rc, and Car122fc) are similar to the sequence ofclone BD2-3 from Suruga Bay sediments (19). The Cariaco Basin $delta$ -proteobacterial sequence Car86rb is 93.5% similar to the sequenceof clone BD7-15 from the Calyptogena community in the Japan Trench(18). ESR closely related to the Cariaco Basin ESR have beenfound at other locations, including the sediments around the Japaneseislands (18, 19). Thus, our results support the hypothesisthat the deep Cariaco Basin water column is similar to anoxicsediment, but vertical distribution gradients vary over tens ofmeters rather than millimeters tocentimeters.

$varepsilon$ -Proteobacteria. ESR bacteria belonging to the $varepsilon$ -proteobacterial subdivision are found in all three Cariaco Basin libraries. The closest relativesof the ESR are groups of bacteria found in the Sulfur River (1)and deepwater sediments (18, 19). Cariaco Basin, Sulfur River,and deepwater sediment sequences exhibit 94 to 96% identity forbases 530 to 1494 (E. coli numbering) of 16S rRNA. Other closerelatives include clone SB-17 from a sulfate-reducing consortium(27) and ectosymbionts of R. exoculata (28) and Alvinellapompejana (11). Our phylogenetic analysis showed that all thesesequences comprise a distinct taxonomic group, which is more relatedto the Thiovulum-Campylobacter group than to the Helicobacter-Wolinellagroup (Fig. 3).

Little is known about the biology of ectosymbionts and their relatives. The R. exoculata and A. pompejana symbionts, as wellas Thiovulum spp., are apparently aerobic autotrophic sulfideoxidizers. The ectosymbiont of R. exoculata forms a mat at a Mid-AtlanticRidge hydrothermal vent site, colonizes shrimp bodies, and isa dominant bacterium in this environment (28). The environmentof Sulfur River is conducive to sulfide oxidation, suggestingthat local ESR are also involved in sulfide oxidation. Severalcultured $varepsilon$ -proteobacteria are able to oxidize sulfide anaerobically(8, 25, 43). Thus, we hypothesize that ESR are sulfide-oxidizingbacteria. Their presence in the 320-m library also suggests thatthey are responsible for dark CO₂ fixation observed at this depth(40). Several potential electron acceptors may be availableat 320 m for ESR. Although oxygen is not present at this depth,these organisms may respire nitrate or manganese or iron oxides.ESR were also found in the 500- and 1,310-m libraries. If theywere anaerobic sulfide oxidizers, they would not have any electronacceptors available at these depths. Consistent with the absenceof electron acceptors, no dark CO₂ fixation was detected at depthsbelow 350 m during the November 1996 cruise (40). One possibleexplanation is that the ESR at 500 and 1,310 m are transportedfrom 320 m by sinking organic debris and are not members of thelocal active microbialcommunity.

Another interesting possibility is that ESR in the Cariaco Basin may be ectosymbionts of larger eukaryotic organisms. Zubkovet al. (52) reported that in the Black Sea one group of ciliates(species belonging to the order Scuticociliatida) populated theupper layer of the H₂S zone and that a significant proportionof them possessed ectosymbiotic bacteria. In the Cariaco Basinduring the November 1996 cruise, elevated concentrations of flagellatedand ciliated protozoans were evident both in the oxygenated upper200 m and in the anoxic water of the transition zone (Taylor,unpublished data). The depth distributions of both groups of protozoansmirrored the profiles obtained for total bacterial numbers andproductivity. The dark CO₂ uptake peak (330 m) coincided withelevated numbers of flagellates but not ciliates (data not shown).No large ciliates or ciliates with ectosymbionts have been documentedfor the Cariaco Basinyet.

The sequences Car2a and Car107fb came from bacteria closely related to "Thiomicrospira denitrificans." "T. denitrificans"is a strictly anaerobic, autotrophic, sulfide-oxidizing denitrifier(25, 43). A bacterium with this metabolism would be well adaptedto the Cariaco Basin environment just below the O₂-H₂S interface.Nitrate and nitrite typically penetrate 10 to 20 m deeper thanO₂ in the Cariaco Basin water column, so potentially sulfide canbe oxidized at the expense of nitrate by chemoautotrophicbacteria.

Two sequences in the 320-m library belonged to members of the genus Arcobacter. The genera Arcobacter and Campylobacter areclosely related and are both microaerophiles (21). Althoughsome Campylobacter spp. are able to use elemental sulfur as anelectron acceptor, the ability of Arcobacter species to respireelemental sulfur has never been studied; however, this genus hasother respiratory pathways similar to those of the genus Campylobacter(dimethyl sulfoxide, succinate, and nitratepathways).

Microbial communities in the Cariaco Basin at depths of 500 and 1,310 m. Many sequences in the 500- and 1,310-m libraries belong to members of candidate divisions or subdivisions or show low levelsof similarity with their closest sequenced relatives. This makesany inferences concerning their possible metabolism or role inthe microbial community impossible. Other sequences came frombacteria which could be phylogenetically affiliated rather accurately,but these sequences occurred at low frequencies in the librariesand are likely to be insignificant for Cariaco Basin ecosystemfunctioning. Of the sequences in the 500-m library, the SAR406-OSC307-relatedsequences comprise the largest group. SAR406 and OCS307 sequenceswere initially identified as cosmopolitan sequences found in oxicpelagic systems (9). The Cariaco Basin relatives of SAR406and OCS307 are relatively distantly related to each other andto cultured Fibrobacter representatives, which are strictly anaerobicfermentative bacteria. Therefore, it is impossible to make anymetabolic inferences about them. $gamma$ -Proteobacterial and $delta$ -proteobacterialsequences comprise two other large groups found in the 500-m library.Based on levels of identity to their closest relatives, it isreasonable to speculate that at least some of them belong to fermentativebacteria and sulfate reducers, respectively. Close associationof these two physiological groups is ecologically advantageous;fermenters can supply sulfate reducers with electron donors, andin turn sulfate reducers can remove inhibiting products of fermentation,such as molecular hydrogen andformate.

There were fewer sulfate reducers and fermenters in the 1,310-m library than in the 500-m library. Another relatively largegroup of sequences in the 1,310-m library belongs to the Euryarchaeota.Although these sequences are distantly related to sequences retrievedfrom a methane seep in the Eel River basin (13), they clustertogether on our trees. Hinrichs et al. (13) have suggested thatunusual Eel River Euryarchaeota are able to oxidize methane anaerobically.The Cariaco Basin is rich in methane (37), and therefore, thistype of metabolism might be expected in thisenvironment.

Sequences related to operational taxonomic group PVB18 (23) were present in large numbers in both the 500- and 1,310-m libraries.PVB18, which initially was discovered as a member of the mat communityof the underwater volcano Mount Pele (23), and its Cariaco Basinrelatives are closely affiliated with Pseudoalteromonas haloplanktisand Moritella marina and are more distantly related to Shewanellaspp. and Ferrimonas spp. (34). Despite the fact that the P.haloplanktis and M. marina 16S rRNA sequences exhibit 98% identity(34; unpublished data), these organisms were classified in twodifferent genera (7). The majority of bacteria belonging tothe genus Pseudoalteromonas are strictly nonfermentative aerobes(8), whereas M. marina is a facultative fermenter (46). Thus,we can only speculate that the Cariaco Basin PVB18 relatives possessfermentativemetabolism.

Further research is required to corroborate our hypothesis about the role of ESR in sulfur cycling in the Cariaco Basin. Weare planning to amplify ribulose-1,5-bisphosphate carboxylasegenes from the 320-m DNA sample and to verify that they are indeedlinked to the 16S rRNA gene(s) of ESR. Direct measurements ofsulfur cycling also must be made to test the hypothesis that thereis coupling of sulfur to metal (iron and manganese) cycles inthe CariacoBasin.

	ACKNOWLEDGMENTS

We are grateful to the captain and crew of the B/O Hermano Gines and to the staff of the Estación de Investigaciones Marinasde Margarita (Fundación la Salle de Ciencias Naturales, Puntade Piedras, Edo. Nueva Esparta, Venezuela) for their assistancein thisstudy.

This research was supported in part by grants OCE-941570, OCE-9711318, and OCE-9730278 (to M.I.S. and G.T.T.).

	FOOTNOTES

^* Corresponding author. Mailing address: Marine Sciences Research Center, State University of New York at Stony Brook, StonyBrook, NY 11794-5000. Phone: (631) 632-9233. Fax: (631) 632-8820.E-mail: andrei{at}notes.cc.sunysb.edu.

Contribution no. 1184 from Marine Sciences Research Center, State University of New York at StonyBrook.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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