Physicochemical sample collection and processing

Water samples, conductivity, temperature and depth (CTD; Sea-Bird SBE­911) profiles were taken during missions (2002–2010) to the Amundsen Gulf, Beaufort Sea region using a rosette system aboard the CCGS Amundsen. Additional CTD and nutrient data were collected in 2007 aboard the CCGS Louis St. Laurent and 2008 from the CCGS Sir Wilfred Laurier. Water samples were collected for nutrient analysis every 10 m to 100 m and additional samples taken at the depth of the SCM and the nitracline. These were detected on the downward cast from the output of the fluorometer (SeaPoint) for chlorophyll (Chl) and an in situ ultraviolet spectrometer (ISUS) for relative nitrate concentrations (Satlantic MBARI-ISUS). Irradiance as photosynthetically-active radiation (PAR) was estimated in situ with a PAR sensor (Biospherical Instruments) also mounted on the rosette. Salinity values from the CTD profiles were calibrated using a salinometer (Guideline Model 8400B). Samples for nutrient determinations were collected into acid-cleaned polyethylene tubes after thorough rinsing and pre-filtration; stored at 4°C in the dark and analyzed within a few hours for NO₂⁻, NO₃⁻ + NO₂⁻, PO₄³⁻ and Si(OH)₄ using standard colorimetric methods adapted for the AutoAnalyzer 3 (Bran+Luebbe).

To characterize the change of Pacific-origin water in central Amundsen Gulf, we extracted salinity and nutrient data collected from stations deeper than 300 m water depth in ice-free months (July, Aug., Sep., Oct.) for all years. The number of stations included in the analysis varied by year as follows: 2002 (n = 10), 2003 (n = 16), 2004 (n = 14), 2005 (n = 4), 2006 (n = 16), 2007 (n = 13), 2008 (n = 29), 2009 (n = 40), and 2010 (n = 16). The time-series trends were calculated by linear regression of year-based station averages of samples within the salinity range of 31–33, approximating the water mass defined by the T_max of the PSW, and the T_min of the Pacific Winter Water, which lies just below the PSW [15]. Chlorophyll a (Chl a) samples were collected, filtered and analyzed on board using standard techniques as previously reported [16].

Arctic Ocean sea ice extent data was obtained from the IARC-JAXA website (http://www.ijis.iarc.uaf.edu/en/home/seaice_extent.htm) and the 30 daily values for September (month of minimum yearly extent) were averaged as a representation for each year from 2003–2010.

Biological sample collection and processing

Samples were collected from the Amundsen Gulf, Beaufort Sea, between October 2003 and October 2010 (Fig. 1) in conjunction with 8 different research expeditions aboard the CCGS Amundsen (all years, except 2008) and CCGS Sir Wilfred Laurier (2008). The SCM forms in the Amundsen Gulf following the spring bloom and, although surface nitrate concentrations are near detection limits throughout summer, concentrations of nitrate in PSW remain relatively high. Since the aim was to compare SCM communities from different years in the Amundsen Gulf, samples were selected to represent typical post-spring-bloom, light-limited communities; in addition, sufficient biomass for amplification was needed. Two samples met this criteria for three (2003, 2004, 2009) of the eight years, but only one sample for each of the other years was available. Five to 7 liters of seawater were collected as previously described [7] from the SCM. Filters were preserved at −80°C until DNA was extracted using lysozyme, proteinase K, SDS and a salt-based separation as previously described [17].

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Figure 1. Sampling sites and dates.

Locations, physicochemical parameters, and chlorophyll a concentrations of the samples used for tag pyrosequencing.

https://doi.org/10.1371/journal.pone.0027492.g001

PCR primer design for 454 pyrosequencing

PCR primers targeting the SSU rRNA gene within the 16S V6-8 region of Bacteria and Archaea, and the 18S V4 region for Eukaryotes, were adapted from existing rRNA primers and designed de novo to ensure amplicon sizes appropriate for 454-Roche™ chemistry (Table S1). Care was taken to design 95% consensus primers, as determined using ARB (http://www.arb-home.de/) with the SILVA 100-SSU-Ref database, and their specificities were checked against the RDP database (http://rdp.cme.msu.edu/). Forward primers included Roche's A adaptor and MIDs (“multiplex identifiers”) in the form of: 5′-[A-adaptor]+[MID1 to 10]+[specific F primer]-3′; reverse primers included Roche's B adaptor in the form of: 5′-[B-adaptor]+[specific R primer]-3′. Full sequences of all 39 primers are listed in Table S2. Final amplicon lengths were 508 bp for the Bacteria and Eukarya, and 516 bp for the Archaea.

SSU rDNA gene amplification and 454 pyrosequencing

Extracted DNA from the 0.2–3 µm size-fraction was amplified in three independent 50 µL aliquots per domain using full-length 454 primers. PCR reactions contained: 1X HF buffer (NEB), 200 µM of each dNTP (Feldan Bio), 0.4 mg/mL BSA (Fermentas), 0.2 µM of each 454 primer (Invitrogen), 1 U of Phusion High-Fidelity DNA polymerase (NEB), and 1–3 µL of template DNA. Three separate DNA concentrations were used for each sample: 1/0.5/0.1X for Bacteria and Eukarya; and between 3X and 0.1X for Archaea that represent the smallest proportion of microbial biomass in the Beaufort [18]. Cycling conditions were as follows: an initial denaturation at 98°C for 30 s, followed by 30 cycles of denaturation at 98°C for 10 s, annealing at 55°C for 30 s, extension at 72°C for 30 s, and a final extension at 72°C for 5 min. The triplicate reactions for the separate domains were pooled, purified using the QIAquick PCR purification kit (QIAGEN), and quantified spectrophotometrically (Nanodrop ND-1000). The 11 sample-coded amplicons were mixed in equal quantity and 1/8^th plate for each domain was sequenced on a Roche 454 GS-FLX Titanium platform at the McGill University/Génome-Québec Innovation Centre for Bacteria and at the IBIS/Université Laval Plate-forme d'Analyses Génomiques for Archaea and Eukaryotes. The raw pyrosequencing reads have been deposited in the NCBI Sequence Read Archive with accession number SRA029114 and a “Minimal Information about a MARKer gene Sequence” (MIMARKS) compliant table is included with the data and given here in Table S3.

Pyrotag pre-processing and quality control

Raw 454 reads were processed to remove low-quality reads defined using the following criteria: (i) presence of uncertain bases, one or more Ns; (ii) short reads, reads <150 bp after adaptor and MID removal; (iii) unusually long reads, reads of greater than expected amplicon size; and (iv) reads with incorrect F primer sequence. Reads were also trimmed of all bases beyond the R primer. These quality-control steps have been shown to reduce 454 sequencing error rates to <0.2% [19] without the need for more involved “denoising” applications [20] that can be computationally prohibitive and whose theoretical assumptions are not universally accepted [21]. The above, high-quality “final reads” were then aligned by domain using Mothur [22], [23] (http://www.mothur.org/) against the provided SILVA reference alignments using the ksize = 9 parameter. The resulting alignments were manually refined by removing those reads that were misaligned, generating the high-quality “final aligned reads” used for all downstream analyses (Table S4). The number of input reads for each bar-code was also randomly re-sampled from the total reads available to have the same number in all bar-codes, equal to the lowest number present in any one bar-code resulting in: 2474 per sample for Bacteria, 8700 per sample for Eukarya and 1118 per sample for Archaea.

OTU and taxonomy analyses

The final aligned reads were clustered into Operational Taxonomic Units (OTUs) at the ≥97% similarity level for Bacteria and Archaea and at the ≥98% similarity level for Eukarya using Mothur (furthest-neighbor clustering). The former approximates a common species definition for prokaryotes, while the latter is a compromise between the preferred ≥99% species level and the recent recommendation for using a maximum of 98% with 454 GS-FLX Titanium chemistry to avoid misidentifying V4 Eukarya tags [21]. Singletons, OTUs comprised of single sequences occurring only once in the datasets, were removed at this step.

Measures of diversity, rarefaction, and community similarity analyses (shared OTUs and Bray-Curtis trees) were carried out in Mothur. Bacterial OTUs were taxonomically identified using the Classifier tool of the RDP database [24] using the 50% bootstrap cut-off value that has been shown to be >95% accurate at the genus level [25], even for V6 amplicons that are much shorter than ours (∼80 bp). Archaea and Eukarya OTUs were taxonomically identified within Mothur (using 50% bootstrap cut-off) using user-designed reference sequence databases and taxonomy outlines (both available upon request), based upon a modification of the NCBI taxonomies and included our curated Arctic-specific sequences. Common “unclassified OTUs” generated from the above techniques were further identified using BLASTn at the NCBI. Fungi, Metazoa (except Choanoflagellates) and Streptophyta (plants) were ignored for the Eukarya, as were chloroplasts for the Bacteria.

Statistical analyses

Because of limited ship time and logistic constraints on multidisciplinary missions, sampling was not carried out at a single site at the same time of the year for all the years – there is no routine monitoring of the Canadian Arctic at this time or previously. We therefore tested the significance of confounding factors that could potentially influence community structure. In addition to ice extent before and after 2007 and time (year), we tested for significant effects due to: 1) geography, notably Franklin Bay, which is less directly linked to dominant current systems, versus offshore Amundsen Gulf; 2) season, by comparing summer (July, August and Sept) versus autumn (Oct and Nov) samples; 3) irradiance as PAR levels binned as <0.1 µE m⁻² s⁻¹, 0.1–1.0 µE m⁻² s⁻¹ and >1.0 m⁻² s⁻¹ at the depth sampled; and 4) the community size distribution estimated from Chl a concentrations of small (0.7–3 µm) and large (>3 µm) fractions of filtered biomass. The percent distribution of Chl a in the small versus large fractions was taken as a proxy for successional stage, since larger cells are favoured when growth conditions are more favourable. Communities were binned as >60%, 40–60%, or <40% in the large fraction. Details of the distribution of all samples into the above categories are given in Table S5. Differences between two categories were tested with either the two-sample t-test (normal distributions) or Mann-Whitney test (non-normal distributions). Trends with three categories were tested using the Kruskal-Wallis test (non-parametric version of ANOVA). The temporal trends over 8 years, 2003–2010, were tested using linear regression (normal distributions) or the Spearman Rank correlation (non-normal distributions). Correspondence analysis (CA) was performed on the taxonomic distribution data at the level showing the most significance: phylum-level for Bacteria, major group-level for Eukarya, and “group” equal to genus-level for Archaea that have inherent reduced taxonomic complexity at higher levels. These ordination plots and all statistical analyses were carried out in PAST (http://folk.uio.no/ohammer/past/).

Physical changes in the Amundsen Gulf and Beaufort Sea

The data compiled from stations greater than 300 m maximum depth over the study region indicated that Pacific waters reaching the Amundsen Gulf had freshened consistently since 2002 (Fig. 2A). Overall nitrate values in this layer had also significantly decreased with average values of 9.4 mmol m⁻³ from 2002–2004 to a minimum value of 6.5 mmol m⁻³ 2010 (Fig. 2B). Silica concentrations, while trending downward, did not change significantly (Fig. 2C). No change in phosphate concentrations were detected (Fig. 2D). Minimum annual sea ice extent occurred in 2007 and remained below the previous long-term average for the following 4 years (Fig. 2E), as has been extensively reported elsewhere [26], including over the Beaufort Sea and Amundsen Gulf region [2].

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Figure 2. Physicochemical trends in the Arctic Ocean.

(A–D) Salinity and nutrient concentrations in the central Amundsen Gulf. Values are from within the salinity layer bounded by 31 and 33 psu, approximating the Pacific water mass defined by the T_max of the summer water and the T_min of the winter water [15]. Values are averaged over all stations in waters deeper than 300 m; station variability is indicated by standard deviation. Time series trend is indicated by linear regression of year average, n = 9. (E–F) September minimum sea ice extent in the Arctic Ocean from the IARC-JAXA. Values for each year (E) are the averages of the 30 daily values of September and variability is indicated by standard deviation. The boxplot (F) indicates the medians, 1^st and 3^rd quartiles, and ranges (whiskers) of the data in (E) for the 4 years before the major melt of 2007 and the four subsequent years (n = 120 for each case). The statistical result indicated is the two-sample t-test (unequal variance).

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Pyrosequencing and analysis overview

The numbers of final reads (and average length) following quality filters was: 44,287 (386 bp) for Bacteria, 74,775 (382 bp) for Archaea and 173,549 (402 bp) for Eukarya (Table S4). Once reads were re-sampled and singleton OTUs removed, all three domains showed saturation in the rarefaction analysis, with the Bacteria roughly twice as diverse as the Archaea (both at the 97% similarity level) and the Eukarya representing near 12,000 OTUs at the 98% level (Fig. S1). Samples were then grouped (Table S5) to test for the influences of geography (Franklin Bay [n = 3] vs. offshore Amundsen Gulf stations [n = 8]), season (summer [n = 5] vs. fall [n = 6]), PAR at the time of sampling (binned as high [n = 3], medium [n = 3] and low [n = 5]) and size-fractionated Chl a results (binned as >60% [n = 5], 40–60% [n = 3], and <40% [n = 3] of the Chl a in the large fraction).

We tested the likelihood that the above factors, apart from before and after the 2007 ice minimum, may have influence our assessment of community changes using two different methods. Firstly, we constructed correspondence analysis ordination plots (Fig. S3) based upon the proportions of the different groups in each sample at different taxonomic levels. Secondly, Bray-Curtis similarity trees were constructed based on total OTU composition in the samples at the level of individuals, independent of taxonomic assignments, where samples that group together share more OTUs than those further apart. The taxonomy ordination plots showed relatively clear patterns along the primary axes with separation for the influence of ice extent, with only one 2003 sample, not grouping with the earlier years (Fig. S2). The OTU Bray-Curtis topologies showed similar separation, with one sample each for Bacteria and Eukarya not consistent with the before-and-after 2007 categorization. The Archaea communities were well segregated and the before-and-after sea ice minimum samples showed no overlap. These Bray-Curtis trends can be tested statistically since the existence of a cluster in the tree implies that the numbers of shared OTUs are higher among those members of the cluster than with members outside the cluster, anywhere else in the tree. Therefore, we tested for a difference between the numbers of shared OTUs within the low ice (<2007) and high ice (>2007) clusters compared to between the two clusters. Significance was found for the Bacteria for this before-and-after 2007 grouping (p = 0.04), and for a linear decrease of shared OTUs over time (p<0.01). Similarly, trends were significant for Archaea for before-and-after 2007 (p = 0.03) and for the linear decrease over time (p<0.01). With the exception of a geographic influence on the Archaea (p = 0.02), no significant effects were uncovered after segregating the OTUs into the other categories tested: season, PAR, and Chl a size distribution. Finally, there was no statistical support for the Eukarya topologies.

Overall community diversity

Bacterial richness, based on the total number of OTUs, declined significantly after 2007 with total diversity also affected (Fig. 3). The Shannon and Simpson indices showed significant changes in community evenness; there were fewer rare OTUs and more high frequency ones, defined as the top 50 OTUs representing the most sequences (Fig. 4B). Additional regression analysis indicated that the linear decrease in richness and evenness were statistically significant (Table 1). In contrast Archaea and Eukarya diversity indices showed no temporal trends or significant differences for before and after 2007. The potential influence of coastal samples (geography) on diversity indices was investigated by removing Franklin Bay samples. This reanalysis did not affect the significant levels for the Bacteria; Archaea and Eukarya results were also unchanged. The remaining factors (season, PAR, proportion of Chl a) did not significantly influence the diversity indices among the three domains (Table 1).

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Figure 3. α-Diversity measures for Bacteria (97% OTU level), Eukaryotes (98% OTU level) and Archaea (97% OTU level).

The boxplots indicate, as in Fig. 2, the medians, 1^st and 3^rd quartiles, and ranges (whiskers) of the data from 2003–2006 (<2007; n = 6) vs. 2007–2010 (>2007; n = 5) for Bacteria (Bact), Eukaryotes (Euk) and Archaea (Arch). The statistical results indicated are from either the two-sample t-tests (normal data) or Mann-Whitney tests (non-normal data). (A) Total richness (OTUs) per 1000 reads (to normalize for bar-code differences). The Bacteria also show a significant linear decrease (r² = 0.75, p<0.01) over the 8 years. (B) Proportion of reads in top 50 dominant OTUs. The Bacteria also show a significant linear increase (r² = 0.82, p<0.01) over the 8 years. (C) Shannon diversity index. The Bacteria also show a significant linear decrease (r² = 0.82, p<0.01) over the 8 years. (D) Simpson diversity index. Note that the index should behave in the opposite direction of the other indices since it nears 0 as diversity increases. The Bacteria also show a significant linear increase (r² = 0.86, p<0.01) over the 8 years.

https://doi.org/10.1371/journal.pone.0027492.g003

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Figure 4. Taxonomic distribution of all OTUs.

(A) Distribution of major Bacteria phyla and orders (97% level). (B) Distribution of non-Metazoan (retaining Choanoflagellates) Eukarya major groups (98% level). (C) Distribution of Archaea groups (97% level). ThaumA, Thaumarchaeota; EuryA, Euryarchaeota.

https://doi.org/10.1371/journal.pone.0027492.g004

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Table 1. Comparison of the significant trends (p ≤ 0.05) when analyzed for 6 different factors.

https://doi.org/10.1371/journal.pone.0027492.t001

Specific taxonomic changes

Alphaproteobacteria consistently represented the largest proportion of OTUs (Fig. 4A), the majority of which (78%) were Pelagibacter (the SAR11 clade). Among the dominant OTUs (Fig. S4), Pelagibacter was the also the most abundant, sometimes representing over 25% of all bacterial sequences. The Gammaproteobacteria accounted for 10–20% of the bacterial OTUs, with little change over time. Among the other major bacterial groups, the proportion of Bacteroidetes sequences decreased prior to 2007 (Fig. 4A) and were significant fewer after 2007 compared to before (Fig. 5A), irrespective of whether or not the coastal samples were included. The majority of the Bacteroidetes sequences belonged to Flavobacteria (87%), with Polaribacter being the most commonly encountered genus, accounting for one fourth of the Flavobacteria OTUs. Verrucomicrobia and Planctomycetes were often recovered, but no trends were detected. After 2007, unclassified Proteobacteria, defined as taxonomically unknown to the RDP classifier and potential novel sequences or non-curated environmental groups, appeared to be more frequent, but this was not statistically significant. Separate BLASTn analysis indicated that some of these were possibly mitochondrial sequences with closest matches to Prasinophytes, especially Micromonas, however the similarity was only ∼88% and we could not rule out the possibility of them representing novel bacteria. We found no significant effect of season, PAR, Chl a size fraction or geography on the bacterial taxa recovered (Table 1).

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Figure 5. Taxonomic groups showing changes.

Boxplots of select taxonomic groups, with parameters as in Fig. 3 and colors corresponding to Fig. 4. Lighter shades indicate 2003–2006 and darker shades indicate 2007–2010. Those parameters that became non-significant (ns) when the coastal Franklin Bay (FB) samples were removed are indicated. Conversely, those that became significant when analyzed geographically (GEO; coastal Franklin Bay vs. open-ocean sites) are also indicated. (A) Various bacterial taxa (97% level). Pelagi., Pelagibacter spp.; Bact., Bacteroidetes phylum; Flavo., Flavobacteria class. (B) Archaea groups (97% level). The MG-I and MG-II show significant linear trends (r² = 0.65, p = 0.02 and r² = 0.64, p = 0.02) over the 8 years. (C) Various Eukarya taxa (98% level). Stram., stramenopiles; Rhiz., Rhizaria; Hapto., Haptophytes; Cili., Ciliates.

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There were some significant changes for several eukaryotic groups over time (Fig. 4B, 5C, S6). After 2007, the proportion of sequences with closest matches to stramenopiles fell significantly, independent of geography or other factors. These sequences had matches mostly to diatoms and uncultured marine heterotrophic flagellates (MASTs [27]; Fig. S5A). The Chl a concentration in the September 2005 sample was 2.14 µg L⁻¹, whereas all other samples were below 1 µg L⁻¹ (Fig. 1). Visually, the sample was dominated by the small diatom Chaetoceros socialis (onboard microscopy) and many of the 18S rRNA gene OTUs had best matches to Chaetoceros socialis and related species (Fig. S6). However, the overall decrease in the proportion of stramenopiles over time was driven primarily by the MASTs. Other groups changed as well, with Cryothecomonas (Rhizaria, Cercozoa) significantly less represented after 2007 when Franklin Bay samples were included. Alveolates, mostly small dinoflagellates and ciliates (Fig. S5B), were common in all years (Fig. 4B), however ciliate sequences, represented primarily by four genera (Strombidium, Novistrombidium, Codonellopsis and Pseudotontonia; Fig. S6), significantly increased after 2007 (Fig. 5C) even when excluding Franklin Bay samples. Haptophytes, with best matches to Phaeocystis and Chrysochromulina, significantly increased after 2007 when Franklin Bay samples were included. The dominant OTUs (Fig. S6) mirrored the whole community, showing a significant overall reduction (p = 0.05) in the numbers of stramenopiles and overall increase (p = 0.02) of ciliates after 2007. There was no significant trend in the OTU occurrences of Micromonas strain CCMP2099, a ubiquitous Arctic ecotype, over time. Similar to the bacterial analysis, among Eukarya we did not detect any significant influences by season, PAR or Chl a size distribution (Table 1).

Except for 2004, the majority of Archaea OTUs belonged to Euryarchaeota Marine Group-II (Eury-MG-II; Fig. 4C and 5B) and they showed a significant linear increase over the 8 years (Table 1). Over the same period, the Thaumarchaeota MG-I (Thaum-MG-I; formally classified within the Crenarchaeota), showed the inverse trend. This striking pattern was repeated amongst the dominant OTUs (Fig. S7), where the two Thaum-MG-I OTU groups represented up to ∼60% of all Archaea sequences before 2007 (p = 0.04 and 0.05 for decrease). Afterwards, the situation was inversed, with Eury-MG-II OTUs representing 70% of all archaeal sequences in 2010 (p = 0.05 for increase). With the exception of a geographic influence, no other significant effects due to the other factors were noted (Table 1).