Distribution of Typical Freshwater Bacterial Groups Is Associated with pH, Temperature, and Lake Water Retention Time

The distribution of 15 typical freshwater bacterial groups in15 diverse lakes in northern Europe was investigated using reverseline blot hybridization. Statistical evaluation of the datain relation to the characteristics of the lakes showed thatpH, temperature, and the theoretical hydrological retentiontime of the lakes were most strongly related to variations inthe distribution of bacterial taxa. This suggests that pH andtemperature are steering factors in the selection of taxa andsupports the notion that communities in lakes with short waterturnover times are influenced by the input of bacterial cellsfrom the drainage areas. Within the beta subdivision of theProteobacteria (Betaproteobacteria), as well as within the divisionsActinobacteria and Verrucomicrobia, different subgroups wereassociated differently with environmental variables.

INTRODUCTION

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Introduction

While huge efforts to explore the diversity of the bacterialkingdom have been made, very little understanding of the factorsthat drive the actual composition of bacterial communities hasbeen gained. A number of studies have sought associations betweenmolecular community fingerprints, such as those obtained bydenaturing gradient gel electrophoresis, and environmental factors.In studies of lakes, multivariate analyses showed that factorssuch as the biomass of other plankton groups (11, 15, 16, 22,26), pH (24, 28), nutrient concentrations (24, 26, 29), temperature(11, 22, 24, 26, 28, 29), and water flow (11, 24) covary withbacterioplankton fingerprints. Such associations suggest thatthese environmental factors are important in determining thedistribution of taxa. However, fingerprinting methods are notwell suited for revealing the identities of the various taxa.An alternative method for characterizing bacterial communitiesis fluorescence in situ hybridization (FISH), in which taxon-specificprobes are used, which improves identification. In addition,FISH provides information on cell number and shape. However,the amount of work involved in FISH soon prohibits analysisof a set of taxa in a set of habitats, a requirement for findingtaxon-environment associations. Therefore, little informationabout which environmental variables determine the abundanceof individual bacterial groups is available.

The aims of this study were to further explore possible determinativefactors for bacterioplankton community composition in lakesand, in particular, to identify factors that influence the appearanceof individual bacterial groups. We used reverse line blot hybridizationwith probes targeted at the 16S rRNA gene in order to analyzethe distribution of 15 bacterial groups in relation to environmentalgradients. The groups chosen were previously designated "putativetypical freshwater bacterial clusters" since they were shownto occur in several freshwater bodies and the 16S rRNA genesequences in the database for these groups contained more sequencesfrom freshwater sources than from terrestrial or marine sources(30, 31).

MATERIALS AND METHODS

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Materials and Methods

Study sites and sampling.
Fifteen lakes were included in the study (Table 1 and Fig. 1).Eleven of these lakes are located in three different regionsin Sweden. The five Lappland lakes (northeast Sweden; 64°N,19°E) are mesotrophic acidic and humic. Three of these lakescan even be designated polyhumic (16). All Lappland lakes havea relatively short (2) theoretical hydrological retention time(THRT), which expresses the average time that it takes for aparcel of water to pass through a lake. The lake in Jämtland(northwest Sweden; 63°N, 12°E) is an oligotrophic, slightlyalkaline clearwater lake with a long THRT (calculated as describedby Algesten et al [1]). The five lakes in Uppland (east centralSweden; 60°N, 17°E) have diverse characteristics andrange from oligomesotrophic to hypereutrophic and from unstainedto humic, and they are more or less alkaline (15). The THRTof the Uppland lakes range from approximately 2 months to morethan 2 years (3, 4).

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TABLE 1. Characteristics of the 15 lakes included in this study

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FIG. 1. Map of Scandinavia showing the locations of the lakes sampled. The abbreviations for the lakes are defined in Table 1.

Four lakes are located close to the Ny-Ålesund researchstation on the Arctic Norwegian Svalbard islands (79°N,15°E). These four lakes are all oligotrophic, slightly alkaline,clearwater lakes (20). The maximum depths of the lakes wereestimated during sampling. Lake areas were obtained from mapsavailable from the Norwegian Polar Institute (http://npweb.npolar.no/).By assuming a cone-shaped morphometry for all lakes except themost shallow lake (lake ST [see Table 1 for lake abbreviations]),which was assumed to be box shaped, approximate lake volumescould be calculated. The sizes of the drainage areas were estimatedusing the maps mentioned above. The average water flow (m³ year^–1)into a lake was calculated using the average yearly precipitationin the area during the years from 1961 to 1990, 385 mm (http://met.no/observasjoner/svalbard/),multiplied by the size of the drainage area. The average airtemperature at the sampling sites from 1961 to 1990 was –6.3°C.Since the vegetation at the sites is scarce, we assumed thatthe evapotranspiration was low and that the precipitation wasa reasonable estimate of the water flow. THRT was calculatedby dividing the lake volume by the average water flow rate.We estimated that three of the Svalbard lakes, which were smalland shallow, had a short water retention time, which did notexceed 100 days. The fourth lake (lake SA), which was deeperand larger, had an estimated THRT of almost 2 years.

Most of the lakes are small, and only three of them, lake ÖRin Lappland, lake VA in Uppland, and lake ÅN inJämtland, have a surface area that exceeds 1 km²; lakeÅN is the largest lake by far. There was a north-southgradient for temperatures of the lakes; i.e., the Svalbard lakeswere the coldest lakes, with temperatures of 3 to 7°C, thetemperatures of the Lappland and Jämtland lakes were 11to 14°C, and the temperatures of the Uppland lakes were15 to 20°C. Only two lakes are in the same catchment area;lake UB flows into lake LB.

All samples were collected in the summer; Lappland samples werecollected on 25 to 28 June 1996, Jämtland samples werecollected on 12 July 1996, Uppland samples were collected on22 to 26 July 1996, and Svalbard samples were collected on 14to 21 July 1997. In general, composite samples were collectedfrom the whole water column (lakes in Uppland, Jämtland,and Svalbard) or the epilimnion (lakes in Lappland). Chemistryand temperature data for the lakes have been published previously(15, 16, 20).

Analysis of bacterioplankton communities.
Bacterioplankton cells were collected on 0.2-µm Duraporefilters after prefiltration through a 1-µm glass fiberfilter, and DNA was extracted as described previously by celllysis in sodium dodecyl sulfate and subsequent extraction withphenol and chloroform (14). This protocol has previously beenshown to efficiently extract DNA from lake bacterioplankton(14), although underrepresentation of larger cells and colonies(e.g., cyanobacteria) is expected for the most eutrophic lakes(lakes ÄP, HÅ, and VA) due to the prefiltration step(15).

Reverse line blot hybridization with oligonucleotide probestargeted at 16S rRNA gene sequences was performed as describedpreviously (31). This is a fairly simple method which allowsrapid screening of multiple samples with multiple probes (12,31). In short, the extracted DNA to be tested was first subjectedto PCR using universal bacterial primers targeting positions27 to 518 in the 16S rRNA gene. The amplified DNA of all sampleswas then tested simultaneously with 15 different oligonucleotideprobes by hybridization and stringent washing. Bound productswere subsequently visualized through a chemiluminescence reaction.The signals were quantified by adding all pixel values withinthe signal dot boundaries after subtraction of the backgroundvalue. The reactivity values used were the averages of the valuesfor two reactions.

The probes used (Table 2) were designed to specifically bindbacterial 16S rRNA genes from previously described putativefreshwater clusters (30, 31). Tests with PCR products that hadeither perfect matches or one or more mismatches showed thatthe discrimination was at approximately the single-mismatchlevel (31). The probes and conditions were optimized such thatsignal levels with equal amounts of perfectly matching PCR productswere comparable (31).

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TABLE 2. Results from reverse line blot hybridization with 15 probes specific for freshwater bacterial groups

Targeted bacterial groups.
We have optimized the reverse line blot assay with 15 16S rRNAgene oligonucleotide probes that target a selection of the "putativefreshwater bacterial clusters" (30, 31). The targeted groups,to which the probes exhibit perfect matches, have within-grouplevels of similarity for known 16S rRNA gene sequences of 91to 99% (Table 2). Actinobacterial cluster ACK-M1 and verrucomicrobialcluster FukuN18 have 91 and 93% within-group similarity, respectively;these levels are around genus-level similarity. At the otherend of the spectrum is cluster LD12, in which there is morethan 99% similarity among all of the 16S rRNA gene sequencescollected (from at least 12 freshwater systems worldwide); thisis probably species-level similarity.

The CR-FL23-464 probe covers a small subgroup (designated PnecA1,with 98% within-group similarity) of the Polynucleobacter necessariuscluster (which has 93% within-group similarity). With one sequencefrom Toolik Lake (Alaska) and three sequences from the ColumbiaRiver (31), this PnecA1 subgroup is in fact a monophyletic branchwithin the PnecA subcluster of the P. necessarius cluster (9).

The Oagardhii-425 probe targets the Planktothrix agardhii cluster,which contains Planktothrix agardhii, Planktothrix rubescens,Planktothrix mougeotii, and Planktothrix pseudagardhii. TheAflosaquae-199 probe targets both Aphanizomenon strains andAnabaena strains. More information on the phylogeny of targetedgroups and probe design has been published previously (30, 31).

Statistics.
In order to reveal patterns among lakes regarding the distributionof bacterial groups, detrended correspondence analysis (DCA)(10) was performed using CANOCO 4.53 (Biometris-Plant ResearchInternational). DCA was chosen instead of correspondence analysisto avoid the arch effect, which is a distortion in the ordinationdiagram. In DCA the correspondence analysis axes are dividedinto segments, and the sample scores of the second axis arereassigned to be centered around the centroid to remove distortion.The hybridization signals of the different probes were firstconverted to proportions of the signal of the universal probe,UNI518 (31), for the same sample (expressed as a percentage)and transformed as log(1 + x). The two bacterial groups thatdid not show a positive signal for any lake were excluded fromthe analyses.

In order to reveal relationships between the appearance of bacterialgroups and environmental variables from the lakes, a redundancyanalysis (RDA) was used with the software CANOCO. This methodrequires a linear species-environment relationship (25), whichcan be assumed in cases in which the length of the first DCAaxis is <2, which was the case in our data set (Fig. 2).The environmental factors that best described the most influentialgradients were identified by forward selection. This proceduregives information about the importance of individual variables(25). Explanatory variables were added until addition of furthervariables failed to improve significantly (P < 0.05) themodel's explanatory power. This was assessed in permutationtests with 499 unrestricted Monte Carlo permutations.

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FIG. 2. DCA of the hybridization data from the 15 lakes. Open circles, lakes in Svalbard; solid circles, lakes in Lappland; open square, lake in Jämtland; solid squares, lakes in Uppland. The abbreviations for the lakes are defined in Table 1.

The environmental variables tested were pH, water color (measuredby measuring the absorbance of the water at 420 nm), total phosphorusconcentration, total nitrogen concentration, concentration ofdissolved organic carbon, temperature, and THRT. All of theenvironmental data except pH data were also transformed as log(1+ x). In a separate analysis a qualitative variable "region"was included in addition to the set of environmental variables.This was done by including three binary dummy variables (Svalbard,Lappland, and Uppland).

RESULTS

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Results

Distribution of bacterial groups among lakes and in relation to environmental variables.
In each lake 3 to 10 of the bacterial groups were detected;the average was 7.9 bacterial groups per lake (Table 2). Therewas no apparent connection between the number of groups detectedper lake and geographic location.

The DCA showed that the samples from the lakes in Lappland hadsimilar reactivities to the probe panel, since the samples fromthese lakes clustered together (Fig. 2). Otherwise, there wasno apparent clustering consistent with the geographic locationsof the lakes.

In the RDA model pH, THRT, and temperature were found to bethe environmental variables that statistically best explainedthe variations in distribution of bacterial groups among lakes(Fig. 3 and Table 3). Including region with the variables testeddid not significantly improve the explanatory power of the model,and none of the regions was among the best environmental variables.Thus, geographic region in itself did not "explain" more ofthe variation in the hybridization data set than the environmentalvariables included. The RDA model (i.e., pH, THRT, and temperature)statistically explained 64% of the variation of the hybridizationdata (Table 3). The first axis explained 44% of the variation(Table 3). The first axis also had a considerably better eigenvaluethan the second and third axes, and, thus, the first axis mustbe considered the most important. The variable that correlatedmost strongly with this axis was pH, while temperature and THRTwere more strongly correlated with axis 2 or 3; i.e., pH wasthe environmental variable that was most strongly related topatterns in the distribution of bacterial groups (Table 3).

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FIG. 3. RDA biplots. (A) Different samples in relation to the strongest environmental variables. Open circles, lakes in Svalbard; solid circles, lakes in Lappland; open square, lake in Jämtland; solid squares, lakes in Uppland. (B) Different bacterial groups in relation to the strongest environmental variables. ${alpha}$ , Alphaproteobacteria; ß, Betaproteobacteria; ${gamma}$ , Gammaproteobacteria; A, Actinobacteria; C, Cyanobacteria; V, Verrucomicrobia. The abbreviations for the lakes are defined in Table 1.

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TABLE 3. Results from RDA^a

Appearance of individual bacterial groups.
Nine bacterial groups were detected in more than eight lakes(i.e., had a rather ubiquitous distribution) (Table 2). Allof these groups except PnecA1, which was not found in Svalbard,were detected in lakes in all of the geographic regions sampled.Two probes, targeting the Rhodoferax sp. strain BAL 47 and ACK-M1groups or clusters, gave positive results for all lakes.

The remaining six bacterial groups were detected in less thanthree lakes (Table 2), and two of these groups were not detectedin any lake.

All five groups in the beta subdivision of the Proteobacteria(Betaproteobacteria) were detected in more than eight lakes(Table 2). All these groups were clearly associated very differentlywith the environmental variables included (Fig. 3b). For instance,PnecA1 was negatively correlated with pH, and Ralstonia pickettiiwas negatively correlated with temperature and THRT.

The three Actinobacteria groups were detected in 2, 13, and15 lakes. These three groups were correlated completely differentlywith environmental variables. ACK-M1 was associated with highpH, Sta2-30 was associated with low pH, and the third group,Urk-014, appeared to be not correlated with pH.

Verrucomicrobia group CL0-14 was detected in 14 lakes and wasassociated with low pH and high THRT and temperature. The otherVerrucomicrobia group screened for (FukuN18) was detected inonly three lakes.

The only Alphaproteobacteria group screened for, LD12, was detectedin 12 lakes, and it was associated with high temperature andlong THRT.

Thus, the different bacterial groups, even within major bacterialgroups, showed different patterns in terms of abundance andrelationship to environmental variables.

The only Gammaproteobacteria group investigated was rare andwas detected in only one lake. No signals were obtained fortwo of the cyanobacterial groups. The third cyanobacterial group,Synechococcus cluster 6b, was detected in only two lakes. Therarity of cyanobacterial signals is consistent with microscopicobservations since cyanobacteria were observed in only fourlakes (15, 16).

DISCUSSION

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Discussion

The 15 bacterial groups that were targeted in this study areputative typical freshwater bacterial clusters that were describedpreviously on the basis of 16S rRNA gene sequence analysis (30).The probe set is not comprehensive for all freshwater clustersthat have been described, and probably many common freshwaterbacteria have not been described yet. Still, a number of verycommon groups were included, and the set allowed testing forenvironmental associations of subgroups within important bacterialdivisions.

Hybridization of PCR products to solid-phase-bound probes doesnot allow absolute quantification. We assumed that biases inDNA extraction, PCR efficiency, and probe binding efficiencyare constant in the sense that preferences for one group overanother are equal for different ecosystems. In this manner weused the relative proportions of hybridization signals as quantitativemeasures to monitor bacterial groups along environmental gradients.

The results indicated that pH, retention time, and temperaturewere strong explanatory variables and together explained 64%of the variation in probe signals among lakes.

The relatively strong relationship to pH is not an unexpectedfinding. In a study in which the bacterial communities in 30lakes in Wisconsin were investigated by a fingerprinting method,automated ribosomal intergenic spacer analysis, pH was one ofthe factors that were most strongly related (28). In experimentalstudies in which lake bacteria were inoculated into media havinga neutral or alkaline pH, it was shown that growth of bacteriaoriginating from acidic lakes was inhibited (13), suggestingthat different taxa could be selected in acidic and alkalineenvironments.

Especially obvious from our hybridization results was the greateroccurrence of PnecA1 in environments with low pH (Fig. 3b).This result was supported to some extent by a previous combinedfield and experimental study in which bacteria belonging tothe P. necessarius cluster were favored by humic and acidicconditions (5), although our probe covered only a relativelynarrow subcluster of the P. necessarius group (9, 31); thus,comparisons should be made with caution.

Temperature was another environmental variable that covariedwith the appearance of bacterial groups. The betaproteobacterialtaxon R. pickettii was negatively associated with temperature.There was a clear north-south gradient for temperature, andR. picketii was generally more abundant in the northern lakes.Several field investigations have shown that temperature covarieswith bacterioplankton community composition (24, 28, 29). Sincemechanistic relationships cannot be revealed by statisticalrelationships alone, it cannot be proven that a temperaturedifference of about 15°C, such as that between the warmestand coldest lakes in this study (Table 1), could select differenttaxa. Whether individual bacteria from such lakes have differenttemperature optima remains to be shown experimentally.

It was also not unexpected that THRT was an important explanatoryvariable. The development of a "complete" community adaptedto lake conditions takes time. Previous field studies have shownthat bacterioplankton community composition can be related towater flow and the import of bacterial cells from the drainagearea (6, 11, 17-19, 24). Therefore, in a system with a shortretention time, the community can be expected to be shaped bythe import of river and/or terrestrial bacteria, while a communityin a system with a long retention time is shaped by processesin the lake (19). The two types of lakes could, therefore, harbordifferent bacteria to some extent.

The type of bacteria being imported from the drainage area shoulddepend on the position of the lake in the landscape; i.e., headwaterlakes should receive a larger share of terrestrial bacteria,while lakes further down in the drainage area should receiveaquatic bacteria from lakes upstream. Therefore, it is interestingthat the betaproteobacterial group R. pickettii, which was associatedwith a short THRT, was especially abundant in the Svalbard lakes,which are all headwater lakes. Thus, these bacteria may originateto a greater extent from soils in the drainage areas. The factthat this cluster contains several terrestrial sequences (30)and the fact that members of this group are often particle associated(31) and thus can be supposed to be easily transported in riverssupport this idea to some extent, but it needs further verification.

In contrast to R. picketti, alphaproteobacterial group LD12was associated with long THRT and high temperature; i.e., theprobe gave a stronger signal in lakes with longer THRT and hightemperatures (Fig. 3b). It was not detected at all in four ofthe lakes with the shortest retention times (lakes ÄP,ST, TV, and ØV, all of which are headwater lakes). Ina study of a delta system, bacteria belonging to the LD12 clusterwere found to be associated with low water flow (24). Thesecombined observations further support designation of bacteriain the LD12 cluster as typical pelagic freshwater bacteria.The previously proposed relationship between the appearanceof this bacterium and high pH (alkalinity), based on denaturinggradient gel electrophoresis data from the lakes (20), was,not supported by the results of this study (Fig. 3b).

Thus, in summary, we conclude however, that both local and regionalfactors appear to have influenced the distribution of bacterialgroups among the lakes. This result is in agreement with theresults from a study of 30 Wisconsin lakes (28), as well asexperimental evidence (13), introducing stochastic componentinto the shaping of lake bacterioplankton communities (7).

One other important finding of this study is that subgroupswithin major groups are distributed differently among the lakesand along environmental gradients. Sometimes the different subgroupseven show opposite patterns; one example of this is actinobacterialgroups ACK-M1 and Sta2-30 (Fig. 3 and Table 2). The differentsubgroups within the Betaproteobacteria and Verrucomicrobiawere also differently correlated with the environment. Thus,in order to investigate determinative factors for bacterioplanktoncommunity composition, general probes designed to cover bacterialgroups at the division or subdivision level have too littleresolution. We expect that in order to understand more aboutthe distribution of individual bacterial groups in nature, theuse of more specific probes (for instance, in reverse line blothybridization) will be of interest in the future.

Clearly, the relative proportions of the hybridization signalsused here are hampered by the methodological biases mentionedabove. However, some of the results obtained here by reverseline blot hybridization are in agreement with results of FISHand the analyses of clone libraries, such as the generally wideoccurrence of bacteria belonging to the LD12, LD28, Rhodoferaxsp. strain BAL47, ACK-M1, and STA2-30 clusters (27, 30) andthe fact that Betaproteobacteria are generally common in freshwater(8, 21). Also, the finding that cyanobacteria were uncommonin our lakes was in agreement with microscopic observations.Thus, we expect that reverse line blot hybridization shouldgive a relatively good picture of the situation in the lakes,especially when a larger number of probes can be used, althoughexact quantification of bacterial populations is not possible.

ACKNOWLEDGMENTS

We thank Dag Hessen for information about the Norwegian lakes.

This work was supported by grants from the Olsson-Borgh andYMER-80 foundations and from the Training and Mobility of Researchersprogram of the Commission of the European Communities.

FOOTNOTES

* Corresponding author. Mailing address: Limnology/Department of Ecology and Evolution, Evolutionary Biology Centre, Uppsala University, Norbyv. 20, SE-75236 Uppsala, Sweden. Phone: 46-18-471 64 97. Fax: 46-18-53 11 34. E-mail: Eva.Lindstrom{at}ebc.uu.se.

REFERENCES

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