Dynamics of marine bacterial and phytoplankton populations ... · Dynamics of marine bacterial and...
Transcript of Dynamics of marine bacterial and phytoplankton populations ... · Dynamics of marine bacterial and...
Dynamics of marine bacterial and phytoplanktonpopulations using multiplex liquid beadarray technologyemi_2142 975..989
Xavier Mayali,*† Brian Palenik and Ronald S. BurtonScripps Institution of Oceanography, University ofCalifornia San Diego, 9500 Gilman Drive, La Jolla, CA92093-0202, USA.
Summary
Heterotrophic bacteria and phytoplankton dominatethe biomass and play major roles in the bio-geochemical cycles of the surface ocean. Here, wedesigned and tested a fast, high-throughput and mul-tiplexed hybridization-based assay to detect popula-tions of marine heterotrophic bacteria andphytoplankton based on their small subunit riboso-mal DNA sequences. The assay is based on estab-lished liquid bead array technology, an approach thatis gaining acceptance in biomedical research butremains underutilized in ecology. End-labelled PCRproducts are hybridized to taxon-specific oligonucle-otide probes attached to fluorescently coded beadsfollowed by flow cytometric detection. We used ribo-somal DNA environmental clone libraries (a total of450 clones) and cultured isolates to design and test26 bacterial and 10 eukaryotic probes specific tovarious ribotypes and genera of heterotrophic bacte-ria and eukaryotic phytoplankton. Pure environmen-tal clones or cultures were used as controls anddemonstrated specificity of the probes to their targettaxa. The quantitative nature of the assay was dem-onstrated by a significant relationship between thenumber of target molecules and fluorescence signal.Clone library sequencing and bead array fluores-cence from the same sample provided consistentresults. We then applied the assay to a 37-day timeseries of coastal surface seawater samples from theSouthern California Bight to examine the temporaldynamics of microbial communities on the scale ofdays to weeks. As expected, several bacterial phylo-types were positively correlated with total bacterialabundances and chlorophyll a concentrations, but
others were negatively correlated. Bacterial taxabelonging to the same broad taxonomic groups didnot necessarily correlate with one another, confirm-ing recent results suggesting that inferring ecologi-cal role from broad taxonomic identity may notalways be accurate.
Introduction
Planktonic microbial communities, with cell numbers onthe order of one million cells per ml, play a central role incontrolling carbon cycling in the surface ocean (Azam,1998; Azam and Long, 2001). These communities consistof a diverse assemblage of prokaryotes and eukaryoticprotists, often with hundreds or thousands of speciespresent in a single ml of seawater. Understanding thedynamics of these communities requires that we can iden-tify and quantify the abundance of component taxa.Although large phytoplankton cells can often be identifiedby morphological features, smaller eukaryotes as well asbacteria and archaea are identified primarily by their DNAsequences, typically based on small-subunit ribosomalRNA genes (Woese et al., 1985). Even for large phy-toplankton, cultivation-independent characterization byrDNA sequencing is now part of the standard methodol-ogy to describe organisms (Metfies et al., 2006). The useof these (and other) genes has further led to the design ofmethods for the rapid characterization of microbial com-munity structure. Some of the most widely used includedenaturing gradient gel electrophoresis (DGGE, Muyzeret al., 1993), terminal restriction fragment length polymor-phism (TRFLP, Liu et al., 1997), and automated ribosomalintergenic spacer analysis (ARISA, Brown et al., 2005).These methods are able to separate (by electrophoresis)different ribosomal RNA types (ribotypes) based onsequence length or base pair composition and allow rapidfingerprinting of microbial communities for comparisonacross space and time.
New, and potentially faster and more high-throughputmicrobial community fingerprinting methods are nowbeing developed, based on competitive hybridizationbetween environmental DNA (or RNA) and targetoligonucleotides. One approach utilizes solid microarraytechnology that detects successful hybridization with
Received 12 November, 2008; accepted 26 November, 2009. *Forcorrespondence. E-mail [email protected]; Tel. (+1) 925 423 3892;Fax (+1) 925 423 9719. †Present address: Lawrence LivermoreNational Laboratory, 7000 East Ave, Livermore, CA 94550, USA.
Environmental Microbiology (2010) 12(4), 975–989 doi:10.1111/j.1462-2920.2009.02142.x
© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd
fluorescence (Brodie et al., 2006) or electronic signal(Barlaan et al., 2007). Another approach utilizes liquidbead array technology followed by fluorescence detectionby flow cytometry (Spiro et al., 2000; Chandler et al.,2006). In the latter method, fluorescently labelled PCRproduct or nucleic acid extract is hybridized to oligonucle-otide probes attached to polystyrene beads that them-selves contain different ratios of two fluorescent dyes.Each type of bead is conjugated to a distinct oligonucle-otide that acts as a probe for a specific taxon. The mixtureis then passed through a flow cytometer able to quantifythe amount of hybridized PCR product (or labelled DNA orRNA) and the type of bead. This offers several advan-tages over solid phase arrays, including favourable liquidhybridization kinetics, the capacity to analyse hundreds ofsamples in a short amount of time, and the ability toquickly alter the assay (by adding or removing bead typesand their associated probes).
Thus far, multiplex liquid array technology has beenused in environmental microbiology with PCR for thedetection of fungal (Diaz et al., 2006) and bacterial patho-gens (Baums et al., 2007). It has also been used directlywith extracted RNA to examine metal contaminated soil(Chandler et al., 2006). In marine ecology, this technologyhas been used for the detection of abundant phytoplank-ton groups, with direct labelling of extracted DNA and noPCR step (Ellison and Burton, 2005). Here, we report onthe development of a PCR-based liquid array method todetect bacteria and eukaryotes in coastal marinesamples. We first sequenced 16S and 18S clone librariesfrom water samples and identified bacterial and phy-toplankton target taxa. We then designed and testedprobes for those taxa in multiplex format, after which weapplied the assay on DNA extracts from a time series toillustrate its usefulness for high-throughput populationdynamics studies.
Results
Clone libraries and probe design
Using universal rRNA primers amplifying both 16S and18S ribosomal genes, a total of 449 clones weresequenced from the four libraries, comprising 394bacterial, 1 archaeal, 10 chloroplast and 44 eukaryoticsequences. This indicates that the universal primers weresuccessful in amplifying all domains of life; the dominanceof bacterial sequences over the other domains andtheir relative abundances seem consistent with thecoastal marine surface-water origin of the samples.The bacterial sequence data were dominated by a-and g-Proteobacteria as well as cyanobacteria andBacteroidetes. There were also several sequences fromthe Verrucomicrobia, Firmicutes and Actinobacteria
groups. Many eukaryotic sequences were similar (oridentical) to copepods and dinoflagellates, while somesequences were most similar to uncharacterizedeukaryotes from the alveolate and stramenopile groups.Chloroplasts were from diatoms, dinoflagellates andchlorophytes. Although many taxa, particularly bacteria,were shared among several of the libraries, there werenotable differences among the four libraries. Whileecologically important, a detailed analysis of thesedifferences is beyond the scope of this report.
Bacterial probes were designed for groups that includedat least one of our clones and one or more sequencesfrom GenBank and/or from the Global Ocean Surveymetagenomic database. In this study we focused on het-erotrophic bacteria as bacterial autotrophs are part of aseparate ongoing study (V. Tai, R. Burton and B. Palenik,unpubl. data). The heterotrophic bacterial taxa targeted inthis study can be divided into two general groups. The firstincluded 16S phylotypes identified as being abundant insurface temperate marine waters by previous studies(Brown et al., 2005; Rusch et al., 2007 and others),including members of the SAR11, SAR86, SAR116,Roseobacter, Bacteroidetes and Acidomicrobia groups.We targeted these ubiquitous and abundant taxa becausetheir numerical dominance suggests they are the primarymediators of biogeochemical reactions in these environ-ments. The second group of bacterial targets includedphylotypes less commonly encountered in rRNA data-bases but found abundant in our clone libraries from algalbloom waters and from other studies of algal bloomsin temperate waters. We targeted this second groupbecause of our interest in algal–bacterial interactions inmediating carbon flux and algal bloom dynamics. Targettaxa (from either group) did not always comprise the samelevel of 16S nucleotide diversity because the degree of16S diversity is not constant among different phylogeneticgroups. For example, one probe might target a group ofsequences that share 99% similarity at the 16S level,while another probe might target a group sharing 97%similarity. We report only probes that exhibited a signal tonoise ratio over 20 and little to no non-specific signal fromclones outside the target group (Table 1). Signal to noisewas defined as the ratio of the fluorescence signal fromthe target clone divided by the fluorescence signal from anegative PCR control reaction. In terms of signal strength,the bacterial probes could be divided into two types. Thefirst, consisting of 10 probes, exhibited acceptable (~20)or better signal/noise and no non-specific signal fromtested clones outside the target taxon (an example isshown in Fig. 1A). The second group, consisting of 16probes, exhibited non-specific signal from two clones orless with a signal of at most 50% of the positive signal (anexample is shown in Fig. 1B). An additional 12 probes thatexhibited excessive non-specific signal (or no signal with
976 X. Mayali, B. Palenik and R. S. Burton
© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd, Environmental Microbiology, 12, 975–989
Tabl
e1.
Sum
mar
yst
atis
tics
for
prob
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ecifi
cfo
rco
asta
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ine
bact
eria
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robe
sw
ere
test
edag
ains
ta
suite
of70
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esof
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eria
l(n=
66)
and
euka
ryot
ic(n
=4)
orig
in.
Pro
be#a
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nena
me
Gen
Ban
kac
cess
ion
No.
Pro
bese
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ceG
ener
alta
xon
Clo
sest
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Ban
kac
cess
ion
No.
(%16
Ssi
mila
rity)
Pro
be16
Sdi
vers
ityb
Sig
nal/n
oise
Non
-spe
cific
sign
al/n
oise
cN
on-s
peci
ficcl
oned
32B
_E02
EU
7339
66AT
TT
CT
CC
AG
TT
TT
TC
CC
TATA
TG
TA
ctin
obac
teria
AF
0016
52(9
9.9)
9933
92A
_H01
EU
7339
36T
CA
CTA
GAT
TC
CC
GA
AG
GC
AC
TC
CC
Gam
ma
AF
2351
20(9
9.3)
9920
332C
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EU
7338
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AA
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CT
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TAA
GT
TT
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374
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CT
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(99.
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Bacteria and phytoplankton bead array 977
© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd, Environmental Microbiology, 12, 975–989
their intended target) are not reported and were discardedfrom any further analyses. In addition, we designed andtested several probes that showed positive signal withtheir intended targets but did not show signal from fieldsamples (Table S1).
Due to the short length of the PCR product (desirablefor probe hybridization), it was difficult to design morethan one probe for each taxon. We successfully achievedthis for one of the bacterial target taxa to demonstratereproducibility and specificity of the assay. Probe #45specific to clone 2A_D08 (g-Proteobacteria, SAR86group) demonstrated good signal against its target cloneas well as clone 1_E04, which has identical probe bindingsequence and is 99% similar over the entire 16Ssequence (Fig. 1C). Probe #73 is also specific to clone2A_D08, located 13 bp downstream, but has a 3 bp mis-match with clone 1_E04. As expected, this probe gives apositive signal with clone 2A_D08 but very little signal withclone 1_E04 (Fig. 1D).
Eukaryotic probes were designed to differentiate phy-toplankton genera commonly found off the Southern Cali-fornia coast as well as smaller eukaryotes with cultures
available (Table 2). Due to the smaller number of culturesand clones to test specificity, probes that displayed anynon-specific signal were not studied further. For example,a probe theoretically specific for the dinoflagellate genusAlexandrium was discarded due to non-specific signalwith several other dinoflagellates (data not shown). Suc-cessful probes targeted large dinoflagellates (genera Lin-gulodinium, Scrippsiella, Akashiwo, Prorocentrum andCeratium), large diatoms (Chaetoceros, Cylindrothecaand Skeletonema) and the smaller autotrophic protistsMicromonas and Ostreococcus. In general, probes werespecific at the genus level, although several exceptionsoccurred, particularly among the diatoms (Table 2).
Sensitivity and specificity
The first step to determine the ability of the method toquantify different targets simultaneously was to mixknown quantities of PCR products from single clonesbefore analysis with the Luminex. Clones 2A_F06 and2D_C12 were amplified separately, their PCR productsquantified, and analysed with the Luminex on their own
Fig. 1. Representative data from multiplex Luminex assay for bacteria using up to 70 clones as targets (arrow indicates target clone).A. Probe #3 specific for clone 2B_E02 and relatives shows no non-specific signal among the clones tested.B. Probe #7 specific for clone 1_E09 and relatives shows some non-specific signal with clone 1_CO3 (signal/noise = 9).C. Probe #45 specific to clone 2A_D08 also hits clone 1_E04 which has identical probe sequence and is 99% similar in 16S sequence.D. Probe #73 specific to clone 2A_D08 does not give signal with clone 1_E04.
978 X. Mayali, B. Palenik and R. S. Burton
© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd, Environmental Microbiology, 12, 975–989
(including 2D_C12 in two different concentrations), aswell as mixed together in equal concentrations. Variabilityamong replicate PCR reactions was low (CV = 7–10%),demonstrating good reproducibility. Luminex signal wasconsistent whether the target clones were analysed sepa-rately or mixed together (Fig. 2), and the quantified targetof lower concentration exhibited lower Luminex signal, asexpected.
The next step to validate the assay for use with mixedcommunity DNA was to investigate the potential to followthe population dynamics of individual target taxa within amixed assemblage. The experimental design was to makeserial dilutions of two clones over a range of concentra-tions that we would expect to encounter in naturalsamples. We spiked these dilutions into DNA extractedfrom a field sample (rather than simply into sterile water)before PCR to mimic conditions that might affect theamplification. This also allowed us to control for well-to-well variation in overall fluorescence that we believe to becaused by variations during the PCR as well as during thehybridization and washing steps of the Luminex assay.For example, variable staining intensity was partiallycaused by some liquid being left in the wells after washingsteps due to the gentle manual pipetting necessary toavoid removing beads. To account for these variations,these standard curves (as well as all field data) werenormalized according to the overall fluorescence signal ofthe well, calculated by adding the Luminex fluorescencevalues of all the bead colours in each well.
We also found that amplifying with too many cycles ofPCR (> 30) resulted in poor dynamic range of standardcurves and potentially overestimated the abundance ofrare members of the community (data not shown). Thus,we used 25 cycles of PCR for these standard curves andthe field sample analyses. Over the range of 104–108
rDNA copies, the Luminex assay resulted in remarkablyconsistent reproducibility (CV ranging from 2% to 12%,with one exception; see below) and a linear relationshipbetween log-transformed target abundance and normal-ized fluorescence signal (Fig. 3). For one of the clones(2A_F12, Fig. 3B), signal inhibition occurred at thehighest concentration tested (108 rDNA copies;CV = 38%). Repeats of this experiment resulted in thesame finding, suggesting the presence of a PCR inhibitorin the clone 2A_F12 DNA sample.
After testing specificity and sensitivity of the probes withsingle clones or mixtures of two clones, the subsequentstep was to validate the multiplex Luminex assay withknown field samples. The four Scripps Pier water samplesoriginally used to construct clone libraries were analysedwith Luminex but results were not always consistent withsequencing data, with sometime high signal for targettaxa that were rare or below detection by clone librarysequencing, and vice versa (data not shown). One caveatTa
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Bacteria and phytoplankton bead array 979
© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd, Environmental Microbiology, 12, 975–989
of this analysis is that we had relatively few sequencesper library (< 150), implying that further sequencing wouldlikely produce more target taxa. Another likely reason,however, was that the PCR primers used for sequencingwere not the same as those used for the Luminex assay,as 1 kb amplicon was useful for taxonomic identificationsbut proved to be too large for efficient hybridization in thebead assay. We hypothesized that PCR primer bias couldbe at least partially responsible for the observed inconsis-tency between Luminex signal and sequence data. There-fore, we sequenced one additional library (95 clones, fromsample 5/21/07) using the same primers as for theLuminex assay (80 bp instead of 1 kb amplicons). Wecombined the two libraries from sample 5/21/07 anddetermined which bacterial taxa targeted by the Luminexassay were detected by sequencing and which were not.We considered a targeted taxon present in the sample ifany sequences matched the probe sequence with 1 bpmismatch or less (using a less stringent 2 or 3 bp mis-match criterion did not significantly change the analysis).The hypothesis was that if a taxon is not detectable bysequencing, it should have a low Luminex fluorescencesignal. Conversely, if a taxon is detectable by sequencing,it should have a higher Luminex signal. The taxa notdetectable by sequencing exhibited significantly lowerLuminex fluorescence signal than taxa detectable bysequencing (Fig. 4). There were no false positives (taxanot detected by sequencing with high Luminex signal),while taxa detected by sequencing exhibited a wide rangein Luminex signal.
Field samples
Total bacterial counts during the sampling period rangedfrom 1 to 5 ¥ 106 cells ml-1 (Fig. 5A) and extracted chlo-rophyll a from 2 to 12 mg l-1 (Fig. 5B). Not unexpectedly,
extracted chlorophyll a and bacterial abundances werepositively correlated (r = 0.54), consistent with bottom-upcontrol of bacterial growth. The data revealed temporaldynamics over the sampling period (Fig. 5C): some taxawere more abundant towards the end of the samplingperiod while others more abundant towards the beginning(red = high relative abundance, green = low relative abun-dance). Taxa were grouped by a hierarchical clusteranalysis (Fig. 5D) based on the similarity in their abun-dance patterns over the sampling period. We further per-formed pairwise correlation analyses to determine taxawith similar (positive correlation) and opposite (negativecorrelation) distributions over time, as well as correlationswith bacterial abundances and extracted chlorophyll a.Fifty-six pairwise correlations had correlation coefficientsgreater than 0.4 (Fig. 6, highlighted in green), represent-ing taxa with similar temporal distributions. Sixty-six pair-wise correlations had correlation coefficients less than-0.4 (Fig. 6, highlighted in red), representing taxa withopposite temporal distributions. Trends of positive andnegative temporal interactions existed among bacteria,among phytoplankton, and between bacteria and phy-toplankton. Six bacterial taxa were positively correlatedwith total bacterial abundances and four bacterial and twoalgal taxa were negatively correlated with bacteria (Fig. 6,column 1). A similar trend was found with extracted chlo-rophyll a (Fig. 6, column 2): eight bacterial and one algaltaxon were positively correlated with chlorophyll, andeight bacterial and three algal taxa were negatively cor-related with chlorophyll.
Discussion
Using technology previously established in biomedicalresearch (Dunbar, 2006) and environmental pathogendetection (Baums et al., 2007; Tracz et al., 2007), we
Fig. 2. Sensitivity analysis of the assay:clones 2A_F06 and 2D_C12 were mixed invarious ratios post PCR (number of moleculesare indicated below x-axis) and the assayshows consistent signal (median fluorescenceminus control, average of threereplicates ! standard deviation).
980 X. Mayali, B. Palenik and R. S. Burton
© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd, Environmental Microbiology, 12, 975–989
have developed a hybridization-based assay allowing thedetection of bacteria and phytoplankton in marine coastalwaters. The assay currently targets 26 bacterial and 10eukaryotic ribosomal RNA phylotypes, but can be easilyexpanded as more probes are designed and testedagainst new targets.
The method described in this report offers severalpotential advantages for monitoring microbial communitydynamics across many samples. First, it targets both bac-terial and eukaryotic taxa. To our knowledge, there existsno other molecular fingerprinting method currently usedto detect bacterial and eukaryotic microbes concurrently(the most recent version of the Phylochip is an exception;E. Brodie, pers. comm.). Since these two groups oforganisms interact very closely in aquatic ecosystems(Cole, 1982; Azam, 1998), such a method is clearly war-ranted to test ecological questions about their interac-
tions. Further, as we recover more gene sequence datafrom the marine (and other) environments, the Luminexbead array can be quickly altered by adding one orseveral new probes to an existing assay. Additionalprobes can be designed to detect other organisms ormore specific groups within currently targeted taxa. Othersegments of the 16S rRNA gene can also be amplified toprovide different phylogenetic resolution. This versatilityis especially valuable when working with highly dynamicecosystems such as the coastal ocean, where new infor-mation from deep sequencing efforts (Sogin et al., 2006;Rusch et al., 2007) adds to our sequence database on amonthly basis.
Two further advantages offered by the Luminex arehigh replication and high throughput capabilities. Hun-dreds of beads of each type (the equivalent of havinghundreds of identical spots on a microarray) are assayed
Fig. 3. Median Luminex fluorescence signalminus control, normalized to arrayfluorescence (see text) plotted against thenumber of target gene copies present beforePCR for clones 2D_B04 (A) and 2A_F12 (B)spiked into seawater, showing a significantregression; data represent the average andstandard deviations of three replicate PCRreactions.
b
a
pre-PCR # gene copies
103 104 105 106 107 108 109
103 104 105 106 107 108 109
clone 2D_B04
clone 2A_F12
Bacteria and phytoplankton bead array 981
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in every sample, providing statistical accuracy for eachprobe. The accuracy and reproducibility are alsoenhanced by the liquid phase kinetics of hybridization thatreduce the effects of steric hindrance from solid phase flatarrays (Dunbar, 2006). In addition, a well plate of 96samples can be assayed (for up to 100 probes) withinseveral hours, providing a large amount of data in a veryshort time. This combination of reproducibility, multiplexcapability, assay versatility and high-throughput capacitymakes this method a potentially useful complement toenvironmental genomics (Handelsman, 2004; Delong,2007). Due to the prohibitively high costs of deepsequencing, metagenomics is typically performed on rela-tively few samples to get a better understanding of thesequence diversity within one ecosystem. However, toconstrain hypotheses about ecosystem temporal dynam-ics (or spatial heterogeneity), a methodology that canassay hundreds of samples in a short period of time isequally valuable. In marine microbiology, the fingerprint-ing method ARISA (Brown et al., 2005) has revolutionizedour understanding of seasonal dynamics (Fuhrman et al.,2006) and latitudinal biogeography (Fuhrman et al., 2008)of planktonic marine bacteria. The Luminex assay offersthe opportunity to detect both bacteria and eukaryotes,and can also be altered to incorporate functional genesassociated with biogeochemical activity as well as for thedetection of taxa on different taxonomic levels, similar toprobes for fluorescent in situ hybridization (Pernthaleret al., 2001). In addition, although not carried out here,genes with known biogeochemical functions such as nifH(Moisander et al., 2006) and proteorhodopsin (Beja et al.,2001) can also be targeted by PCR and the Luminexassay used to provide functional information.
In order to validate the Luminex assay, each individualprobe was tested against a suite of pure clones (or cul-tures) to confirm signal intensity and specificity. Out ofover 40 bacterial probes designed to be specific to variousphylotypes, 15 probes exhibited too much signal withnon-targets and were discarded. In silico analyses did notreveal any patterns responsible for this non-specificsignal, such as lower numbers of base pair mismatches orhigher theoretical melting temperature. Based on thisresult, future probes should always be tested against bothtarget and non-target DNA before being used on environ-mental samples. If bead array technology is adopted byadditional laboratories, we anticipate that an ever-growingset of probes would become available and investigatorscould select those of particular interest for their respectiveanalyses while developing new probes as needed.Although the instrumentation employed here can only use100 different probes at a time, multiple sets of probes canbe utilized for a given sample and new Luminex instru-mentation has the capacity of targeting 500 probes.
In considering the relative merits of the bead arrayapproach, it is important to determine the objectives of theanalysis. Like all hybridization methods, bead array analy-sis only reveals taxa for which probes are included, i.e.the coverage of the community is only as complete as theprobe set. If a new species invades the system, its pres-ence (even if common) will go undetected unless alter-nate methods are used to complement the bead array. Onthe other hand, if the objective is to study the dynamics ofspecific taxa, the bead array approach appears to be quiteviable. Because individual probes are coupled to differentbead colours in separate reactions, signal intensity typi-cally varies among different beads when hybridized toequimolar concentrations of their targets (Diaz and Fell,2004; Chandler et al., 2006). Quantitative comparisonsamong taxa based on Luminex fluorescence signal willtypically require calibration curves for each taxon/probecombination. In our case however, an ANOVA comparingthe Luminex fluorescence signal between taxa detected inthe clone libraries and those not detected was statisticallysignificant (Fig. 4), suggesting these comparisons are atleast semi-quantitative. A more conservative approach isto compare fluorescence signal for a given taxon overmany samples to provide direct quantitative data on thepopulation dynamics of individual taxa (as in Chandleret al., 2006). We first validated this approach by analysingstandards consisting of pure target clones diluted into aDNA extract from a seawater sample. We tested the abilityof the Luminex assay to detect between 104 and 108 16SrDNA molecules in the PCR reaction (Fig. 3), whichresulted in robust quantification. For one clone, however,there appeared to be signal inhibition on the upper end ofthat scale (108 copies; Fig. 3B). Assuming two 16S genesper genome, 100 ml of seawater extracted, and 1/30 of
Fig. 4. Comparison of Luminex fluorescence values (minus control)from sample 5/21/07 between target taxa found by clone librarysequencing using two different primer sets versus those that werenot found, showing mean and 95% CI (grey diamonds). A one-wayANOVA was significant (P = 0.0018), showing that taxa not found bysequencing exhibited lower Luminex fluorescence values.
982 X. Mayali, B. Palenik and R. S. Burton
© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd, Environmental Microbiology, 12, 975–989
Fig. 5. Colour map representing temporal dynamics of 36 Luminex targeted taxa over the course of a 37-day time series (going from left toright) sampled from Scripps pier. Data have been colour-coded from low (green) to medium (black) to high (red) abundance for each taxon(C). Taxa are grouped together (left) based on a hierarchical cluster analysis (D). Chlorophyll a (B) and bacterial abundances (A) from flowcytometry counts are also plotted above.
Bacteria and phytoplankton bead array 983
© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd, Environmental Microbiology, 12, 975–989
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bacteria
Actino-54
Verruco-29
Beta-17
Alpha-7
Actino-3
chlorophylla
Alpha-56
Pyrami-97
Emili-90
Cylindro-95
Chaeto-84
Ceratium-93
Akashi-86
Proro-82
Lingulo-80
Scripps-65
Flavo-63
Bacter-50
Bacter-25
Polari-40
Polari-37
Polari-36
Polari-18
Polari-15
Gamma-58
Gamma-45
Gamma-33
Gamma-9
Roseo-67
Roseo-44
Roseo-19
Roseo-11
Rickett-60
Rickett-5
SAR116-32
SAR11-13
Fig.
6.P
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984 X. Mayali, B. Palenik and R. S. Burton
© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd, Environmental Microbiology, 12, 975–989
the extracted DNA used in the PCR reaction, this wasequivalent to detecting roughly 107 bacteria ml-1. Sincethe maximum total bacterial abundance detected duringour sampling period was 5 ¥ 106 ml-1, it appears thatLuminex signal inhibition occurred at abundances greaterthan that expected in our samples, particularly for a singlephylotype.
Another aspect of the methodology described here isthe data normalization procedure. As described by Chan-dler and colleagues (2006) in great depth, bead arrays(and all phylogenetic arrays generally) cannot provideabsolute abundance data, i.e. comparing the abundanceof taxon A versus taxon B in one sample. This is due to thedifferent signal intensities of individual probe–target com-binations caused by differences in the base pair compo-sition of the sequence that controls the melting behaviour.Therefore, the more conservative approach is to comparethe relative abundance of taxon A over many samples, oftaxon B over many samples, etc. In this study, the well-to-well variability of the total fluorescence signal was largein some cases, including the variability between replicatesof the same sample. Some wells displayed low signal forall the beads, while other wells displayed high signal for allthe beads. We attributed this variability partially to well-to-well differences in the effectiveness of PCR and/orpipetting inaccuracy but more importantly to variationduring the post-hybridization washes and staining steps.Artificially high signal can be caused by the stainingreagent (streptavidin-phycoerythrin) not being thoroughlywashed from a well, and artificially low signal by thestaining reagent not being well-mixed into the well. Thevariation of signal intensity among replicate microarrays iswell documented (Spruill et al., 2002) and various normal-ization procedures are commonly performed to comparethem (Do and Choi, 2006). Here, we performed a normal-ization procedure to account for well-to-well variability inoverall signal intensity. We normalized the fluorescencesignal of each bead type to the overall fluorescence of thewell, the latter calculated by summing the values of allbead types in that well. Although this method does notdetermine changes in the absolute abundances of taxa inthe environment, it allows for a meaningful comparison ofthe relative changes of taxa over time. In other words, thenormalized data represent how a given taxon’s abun-dance changes relative to the other taxa.
Following validation of the method, we analysed a37-day time series of surface seawater samples collectedfrom the Scripps pier in Southern California. We uncov-ered both positive and negative interactions among theLuminex-targeted taxa based on several types of statisti-cal methods including cross-correlations and clusteranalyses. Several bacterial phylotypes were found to cor-relate positively with both bacterial abundance andextracted chlorophyll a. These types of bacteria would
likely be considered copiotrophs, fast growers that preferhigh organic matter environments (Koch, 2001). Consis-tent with this idea, we found these sequences in our clonelibraries from algal bloom samples but not from our non-bloom library. Furthermore, 16S sequences that matchthese bacterial targets (Polari-37, Bacter-50, Flavo-63,Roseo-11 and Roseo-19) have been found in previousstudies of microbial community structure during algalblooms, including those of diatoms (Riemann et al., 2000;Morris et al., 2006; Rink et al., 2007), dinoflagellates(Fandino et al., 2001; Rooney-varga et al., 2005), andother phytoplankton types (Zubkov et al., 2002; Brus-saard et al., 2005; Barlaan et al., 2007). Conversely, threebacterial phylotypes were found to have negative corre-lations with bacterial abundance and chlorophyll, includ-ing SAR11-13, SAR116-32 and alpha-7. These bacteriawould be considered oligotrophs (Koch, 2001), in agree-ment with measured exponential growth rates of 0.7 day-1
from laboratory cultures of SAR11 isolates (Tripp et al.,2008). Consistent with this hypothesis, oligotrophic iso-lates targeted by probes SAR116-32 and alpha-7(HTCC8037 and HTCC7112 respectively) have been suc-cessfully cultured using low-nutrient media (Stingl et al.,2007).
One result worthy of note was that bacterial taxa fromdiverse large taxonomic groups correlated together ratherthan with members of the same group. For example, onlyone pair among the four Roseobacter phylotypes waspositively correlated (r = 0.52) with one another, one pairamong the five Polaribacter phylotypes (r = 0.52), and noRickettsia phylotypes (Fig. 6). This suggests that usinglarge taxonomic units to infer ecological role may be unre-liable, at least for certain groups. Further examinations ofthe population dynamics of phylotypes closely related toone another will be necessary to understand how well 16SDNA sequence similarity can predict ecology, in marinesystems as well as other environments.
The data presented here, obtained using a novel high-throughput method, exemplifies how little is currentlyknown about the dynamics of marine microbial communi-ties over space and time. Using an analysis of many morebacterial taxa than achieved here (171), Fuhrman andcolleagues (2006) found that bacterial communities wereseasonally recurring and predictable based on ocean con-ditions. Since phytoplankton primary production fuels thesurface ocean ecosystem, it is not surprising that includ-ing these taxa, as done here, provides valuable data tosuch analyses. Future work in our laboratory will exploitour newly developed assay to uncover temporal andspatial relationships among both bacterial and eukaryoticmicrobial taxa, many of the former remaining uncultivatedand whose ecosystem roles are unknown. Such data canreveal previously uncharacterized interactions that maybe an indication of syntrophy between these organisms.
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© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd, Environmental Microbiology, 12, 975–989
This information may become useful to help designoptimal conditions for growth in order to isolate andculture these microbes and subsequently uncover theirphysiology and biogeochemical activities.
Experimental procedures
Clone libraries
Surface water from the Scripps Institution of Oceanography(SIO) Pier (32.86634°, -117.25481°) was collected during (ora few days after) several algal bloom periods, including aperiod several days after a Pseudo-nitzschia diatom bloom(23 March 2006; SIO pier chlorophyll programme), during aSynechococcus bloom (May 11, 2006; P. Palenik, unpubl.data), and during a mixed species dinoflagellate bloom (21May 2007; SIO pier chlorophyll programme). To sample non-bloom communities from a different time of the year, wecollected water from eight dates between August andOctober 2004 and pooled them (after DNA extraction) for afourth library. Water samples (200 ml) were filtered through47 mm 0.22-mm-pore-size polycarbonate filters (Millipore)and frozen at -80°C until extraction. DNA was extractedusing a DNeasy Blood & Tissue kit (Qiagen) according toinstructions for bacteria. Universal primers (to amplify botheukaryotic and prokaryotic ribosomal RNA genes) weremodified from two previous studies (Hovanec et al., 1998;Rivas et al., 2004) using the ARB software (Ludwig et al.,2004): 530F 5!-GTGCCAGCMGCCGCGG-3! and 1390R5!-CGGGCGGTGTGTRCAARRSSC-3!. A total of 18 cyclesof PCR amplification were run to increase sensitivity andminimize PCR artefacts (Acinas et al., 2005), with an anneal-ing temperature of 57°C. Amplified products were cloned witha TOPO® TA Cloning Kit (Invitrogen) and positive cloneswere sequenced uni-directionally with the M13 forwardprimer (Agencourt Bioscience). Sequences were trimmedautomatically and manually checked using Sequencher(Gene Codes Corp., Ann Arbor, MI). The sequences havebeen deposited in GenBank under Accession No.EU733720–EU734168. Additional sequences cloned fromsample 5/24/07 using Luminex primers (resulting in a shorteramplicon) have been deposited under Accession No.FJ223033–FJ223127. Sequenced clones were frozen at-80°C, regrown in LB (Luria Bertani) broth, and plasmid DNAwas isolated with a QIAprep spin miniprep kit (Qiagen).These plasmid samples, containing the partial 16S or 18SrDNA inserts from the clones, were used to subsequently testthe probes after PCR (see below). Protist cultures were alsoused as controls for the eukaryotic probes, and their DNAwas isolated as above.
Phylogenetic analysis and probe design
Sequences were added to a ribosomal RNA database in ARB(Jan04 version), which included additional environmentalsequences from marine environments (both from GenBankand the Global Ocean Survey, the latter available at theCAMERA website http://camera.calit2.net/). This databaseincluded approximately 59 000 aligned sequences in a globalphylogenetic tree (data available from X.M.). Clone library
sequences were aligned with the ARB internal aligner, manu-ally checked, and added to the global tree using parsimony.Probes were designed with the ARB ‘probe design’ function.This function takes a phylogenetic approach rather than aphenetic one because it groups sequences according toinferred evolutionary relationships rather than simply bysequence similarity. As such, probes were not always specificto the same degree of 16S or 18S sequence diversity (seeresults and Tables 1 and 2). Sequence diversity for eachprobe was defined as the amount of 16S or 18S diversityamong all the taxa matching the probe sequence within onebase pair. For bacteria, the 25 bp probes were designed forthe region between Escherichia coli numbers 967 and 1046,which is a hyper-variable region commonly used for diversitystudies (Sogin et al., 2006). We chose such a small region(< 100 bp) because initial experiments showed that shortPCR amplicons significantly increased fluorescent signal onthe Luminex flow cytometer (data not shown). This regionwas also variable enough to differentiate closely related bac-terial phylotypes. For eukaryotes, the probes were designedfor the region between E. coli numbers 1193 and 1380, as the967–1046 region was not variable enough to differentiatemany phytoplankton species. Probes were manufacturedwith a C-12 spacer at the 5! end (Bioneer Corporation).
Assay development
Probes were conjugated to different coloured LuminexxMAP® carboxylated beads (5.6 m diameter) according tomanufacturer’s instructions. Each oligonucleotide type is con-jugated to approximately one million beads in a single reac-tion. For the bacterial assay, environmental DNA wasamplified by PCR (product size ~80 bp) with primers modifiedfrom a previous study (Sogin et al., 2006), and the forwardprimers were biotinylated (Table 3). Eukaryotic primers(product size ~150 bp) were designed with ARB (Table 3).Amplification was initially performed for 35 cycles with 94°Cdenaturation (30 s), 52°C annealing (45 s) and 72°C exten-sion (1 min) steps. Subsequently, PCR was decreased to 25cycles of amplification (see Results). Products were checkedon agarose gels, and analysed on a Luminex 100 flow cytom-eter according to published protocols (Lowe et al., 2004), withmodifications. Briefly, amplicons were denatured (95°C) for5 min and incubated in 1¥ TMAC buffer [3 M tetramethylam-
Table 3. Primers used for Luminex assay to detect bacteria (967Fand 1046R) and eukaryotes (1193F and 1380R).
Primer name Sequence
Bac967F-1 CAACGCGMARAACCTTACCBac967F-2 ATACSCGHRGAACCTTACCBac967F-3 ATACGCGAGAAACCTTACCBac1046R-1 CGACTYCCATGCTSCACCTBac1046R-2 CGACRGCCATGCASCACCTBac1046R-3 CGACAGCCATGCAACACCTEuk1193F AACAGGTCTGTGATGCCCEuk1380R GTGTACAAAGGGCAGGGA
Three different bacterial primers (labelled 1–3 each for forward andreverse) were mixed in equal concentrations to eliminate mismatchesand used to amplify all bacterial groups. Numbers refer to E. coli 16Snucleotides, and forward primers (denoted by F) were biotinylated.
986 X. Mayali, B. Palenik and R. S. Burton
© 2010 Society for Applied Microbiology and Blackwell Publishing Ltd, Environmental Microbiology, 12, 975–989
monium chloride, 0.1% SDS, 50 mM Tris-HCl (pH 8.0) and4 mM EDTA (pH 8.0)] at 52°C for 2 h with approximately 1000beads of each colour (each colour bead carrying a differentprobe). Incubations were performed in skirted PCR platescovered with plastic film in a thermal cycler. After incubation,samples were washed with fresh TMAC buffer and spundown at 2000 g for 3 min. After removing the supernatant, thebeads were incubated for 10 min with streptavidin-phycoerythrin (Invitrogen; 250¥ dilution, in 1¥ TMAC buffer) inthe dark at 52°C, washed, and resuspended in 50 ml of 1¥TMAC buffer. Data acquisition on the Luminex instrumentwas performed with Luminex software v 1.7, and a minimumof 50 beads of each colour were analysed. Unless otherwisenoted, all Luminex signal values are reported as medianfluorescence minus control, the latter defined as the medianfluorescence from a negative PCR reaction. In addition, datafrom field samples and standards spiked in seawater (seebelow) were normalized to the total array fluorescence ofeach well. This was achieved by summing the fluorescencevalues for all the bead colours in each well, and normalizingthe value of each bead colour to that value with the followingcalculation:
FF
F
n
p
n
normalized fluorescenceprobe fluorescence control
== "
=
;;
FFF
F F F Fp
ww p1 p2 p3; . . .= + +
This procedure was necessary to account for well-to-wellvariations in overall signal intensity, analogous to variationsamong replicate microarray analyses. After this normalizationprocedure, data represent relative rather than absolute abun-dances in a sample.
Sensitivity and accuracy
The first set of bacterial probes was tested against relativelyfew clones (~20) to determine optimal hybridization tempera-ture yielding highest signal/noise. Hybridization temperaturesbetween 65°C and 45°C were tested every two degrees. Afteran optimal temperature of 52°C was found, these and allsubsequent bacterial probes were tested against 70 differentclones from the libraries, including four clones of eukaryoticorigin. Eukaryotic probes were tested against 17 taxa (amixture of clones and cultured isolates).
Two experiments were performed to ascertain the quanti-fication potential of the method. The first experiment was toassay mixtures of rDNA from two different clones quantifiedpost PCR. The number of rDNA copies was calculated basedon DNA concentration from purified PCR products (measuredwith a Nanodrop spectrophotometer, Thermo) and the lengthof the plasmid plus insert. The second experiment was todetermine if the method can detect changes in the abun-dance of a known target (quantified before PCR) within amixed sample. This type of spiking experiment more accu-rately mimics the types of natural samples that we ultimatelywanted to be able to analyse. Two different clones wereserially diluted over five orders of magnitude into a fieldsample, PCR amplified, and analysed as described above(using the normalization procedure). All experimental treat-ments were performed in triplicate, defined here as separatePCR reactions.
Field sample collection and analysis
In addition to testing the Luminex assay on the four samplesfor which we obtained clone library sequences, we appliedthe assay to a 37-day time series of surface seawatersamples collected from the Scripps Pier between 18 Marchand 23 April 2008. Surface samples were collected between12:00 and 16:00 daily, filtered onto 47 mm polycarbonatefilters (0.22 mm pore size) and frozen at -80°C within 30 minof collection. DNA was extracted from thawed half-filters asabove with a DNeasy Blood & Tissue kit (Qiagen). DuplicatePCR reactions were set up and analysed with the Luminexassay. Since similar volumes of water were filtered (and thenextracted) during the time series, we loaded equal volumes(not concentrations) of DNA extracts in the PCR reactions inan attempt to be as quantitative as possible. Data werebackground subtracted and normalized to array fluorescence(as described above), and the two replicates were averaged.Cross-correlation and cluster analyses among samples andtaxa were performed with the statistical software packageJMP v.5.0. Correlation coefficients greater than 0.4 were con-sidered strong as in Ideker and colleagues (2001). Extractedchlorophyll a data were obtained from the SCCOOS (South-ern California Coastal Ocean Observing System) website(http://www.sccoos.org). We also quantified total bacterialabundances using flow cytometry. Briefly, a 1 ml subsamplewas fixed with 0.2 mm filtered formalin (2% final concentra-tion) and frozen at -80°C. Samples were thawed on ice,duplicates diluted 10- or 100-fold (depending on the sample)in 1¥ PBS, and stained with SYBRgreen II nucleic acid dye(Invitrogen) for 15 min in the dark. Samples were enumeratedwith a FACScalibur (BD Biosciences) based on forwardscatter and green fluorescence. Controls included stained 1¥PBS and unstained seawater samples.
Acknowledgements
We thank M. Latz and M. Hildebrand for protist cultures andP. Huh, C. Tat and A. Yamamoto for assistance in the labo-ratory. We are grateful for insightful discussions with V. Tai, E.Brodie and R. Mueller. This work was supported by a grantfrom the National Science Foundation to R.S.B. and B.P.
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Supporting information
Additional Supporting Information may be found in the onlineversion of this article:
Table S1. List of probes successfully tested against targetand non-target clones (or cultures) but omitted from fieldanalyses due to lack of signal in field samples, too few beadcolours available for multiplex analysis, or duplicate probe.
Please note: Wiley-Blackwell are not responsible for thecontent or functionality of any supporting materials suppliedby the authors. Any queries (other than missing material)should be directed to the corresponding author for thearticle.
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