Effects of Increasing Nitrogen and Phosphorus Concentrations on

May 20, 2015 - Sandusky Bay experiences annual toxic cyanobacterial blooms dominated by Planktothrix agardhii/suspensa. To further understand the ...
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Effects of increasing nitrogen and phosphorus concentrations on phytoplankton community growth and toxicity during Planktothrix blooms in Sandusky Bay, Lake Erie Timothy W. Davis, George S. Bullerjahn, Taylor Tuttle, Robert Michael McKay, and Susan B Watson Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.5b00799 • Publication Date (Web): 20 May 2015 Downloaded from http://pubs.acs.org on May 27, 2015

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Effects of increasing nitrogen and phosphorus concentrations on phytoplankton

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community growth and toxicity during Planktothrix blooms in Sandusky Bay, Lake Erie

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Timothy W. Davis1†*, George S. Bullerjahn2, Taylor Tuttle2, Robert Michael McKay2,

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Susan B. Watson1

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1: Canadian Centre for Inland Waters, Environment Canada, Burlington, ON, L7S 1A1,

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Canada

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2: Department of Biological Sciences, Bowling Green State University, Bowling Green, OH, 43403, USA

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†: Current Address: NOAA Great Lakes Environmental Research Laboratory, Ann

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Arbor, MI 48108, USA

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*Corresponding author

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4840 South State Road

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Ann Arbor, MI 48108-9719

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Phone: (734) 741-2286

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Fax: (734) 741-2055

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Email: [email protected]

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Running title: N promotes Planktothrix growth and bloom toxicity

 

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Abstract:

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Sandusky Bay experiences annual toxic cyanobacterial blooms dominated by

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Planktothrix aghardhii. To further understand the environmental drivers of these events,

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we evaluated changes in the growth response and toxicity of the Planktothrix-dominated

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blooms to nutrient amendments with phosphate (PO4) and inorganic and organic forms of

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dissolved nitrogen (N; ammonium (NH4), nitrate (NO3) and urea) over the bloom season

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(June – October). We complemented these with a metagenomic analysis of the planktonic

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microbial community. Our results showed that bloom growth and microcystin (MC)

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production responded more frequently to additions of dissolved N than PO4, and that the

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dual addition of NH4 + PO4 and Urea + PO4 yielded the highest MC concentrations in

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54% of experiments. Metagenomic analysis confirmed that P. aghardhii was the primary

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MC producer. The phylogenetic distribution of nifH revealed that both heterocystous

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cyanobacteria and heterotrophic proteobacteria had the genetic potential for N2 fixation in

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Sandusky Bay. These results suggest that as best management practices are developed for

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P reductions in Sandusky Bay, managers must be aware of the negative implications of

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not managing N loading into this system as N may significantly impact cytanobacterial

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bloom size and toxicity in Sandusky Bay.

 

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Table of Contents Graphic:

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Key words: Lake Erie, microcystins, nitrogen limitation, Planktothrix, harmful algal

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bloom

 

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Introduction:

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Cyanobacterial harmful algal blooms (CHABs) threaten the Laurentian (North

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American) Great Lakes, a major freshwater resource containing roughly 18% of Earth’s

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available surface freshwater (1). Over the past several decades these ecosystems have

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been subject to many anthropogenic pressures such as nutrient over-enrichment

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(eutrophication), contaminant inputs, structural engineering (impoundments, shoreline

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development and dredging), wetland loss, invasive species (e.g., dreissenid mussels and

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round gobies). Lake Erie is the most socio-economically important of the Great Lakes

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(1,2,3), serving the recreational, commercial, and drinking water needs of over 11.5

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million people (3). Lake Erie is also is the smallest and shallowest Great Lake, making it

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the most susceptible to increased nutrient loading. Lake Erie has been impacted by poor

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water quality, including CHABs, as far back as the 1960s (4,5,6). However, with the

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introduction of phosphorus reduction programs in 1972 as part of the Great Lakes Water

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Quality Agreement (7), the water quality (e.g. reduction in cyanobacterial biomass) in

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Lake Erie improved significantly throughout the late 1970s and 1980s (6,8). However,

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since the mid-1990s, Lake Erie and its watershed have been increasingly affected by

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toxic CHABs, largely fuelled by agricultural nonpoint nutrient sources (9,10,11). To date

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there has been no consensus on the key factors driving HAB occurrence, extent and

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timing, even in well-studied systems such as Lake Erie (12).

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Traditionally, it has been thought that phosphorus (P) was the primary limiting

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nutrient in freshwater systems (13,14), including Lake Erie (9,15). However, recently,

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the importance of nitrogen (N) in the control of eutrophication and CHAB events has

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been gaining attention (16,17,18).

 

Previous studies on Lake Erie blooms have

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investigated bottom-up controls such as nutrient availability and light (19,20,21),

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physical factors like wind strength (22) and top-down controls including pelagic (23) and

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benthic grazing (25). Furthermore, differences and dynamics among the genetic strains

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of cyanobacteria within Lake Erie blooms have been investigated through field and

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laboratory experiments. (11,26,27).

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Planktothrix, a globally distributed genus, (28), is less common than Microcystis

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in the offshore Lake Erie blooms but can predominate in bays and tributaries, notably

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Sandusky Bay (29) and the Maumee River (30). Anabaena (currently called

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Dolichospermum; 31) spp. blooms also occur in the western and central basins of Lake

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Erie (21,23,32) but to date, the ecology and toxicity of these events have been largely

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overlooked.

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Only a few studies have investigated the phytoplankton population in Sandusky

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Bay, (29), bloom phylogenetics (33) and the growth response of the Planktothrix

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community to N or P additions (34).

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Planktothrix spp. as the primary MC-producers in Sandusky Bay.

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Bridgeman (34) have investigated the short-term growth response of the total

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phytoplankton community to N and P amendments, but did not examine toxins and their

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study was limited to a single experiment (July) in Sandusky Bay. Furthermore, even

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though it has been demonstrated that DIN in Sandusky Bay decreases rapidly during the

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summer months, the non-diazotrophic cyanobacterium, Planktothrix, dominates

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throughout the growing season. However little is known about the Sandusky Bay N-

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fixing community, except that the diazotrophic cyanobacterium, Cylindrospermopsis

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raciborskii, can be present at significant densities (23,29). A better understanding the

 

Rinta-Kanto and Wilhelm (33) identified

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composition of the N-fixing community may provide significant insight into the

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ecological reasons why a non-diazotrophic cyanobacterium can dominate a chronically

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N-limited system. Therefore, our study aimed to evaluate changes in the growth response

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of the Planktothrix-dominated blooms to increases in inorganic phosphorus and inorganic

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and organic forms of nitrogen over the growing season (June – October) while

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complementing these results with measurements of microcystin production and

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metagenomic data on the planktonic microbial community.

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Methods:

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Study Sites:

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Sandusky Bay is a shallow (mean depth: 2.6 m; 29), well-mixed drowned river

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mouth at the southeast corner of the western basin of Lake Erie (Fig. 1). Sandusky Bay

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has an hourglass shape and is divided into the outer bay (eastern half) and the inner bay

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(western half; Fig. 1).

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amendment experiments were conducted on samples from the outer bay at two

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Environment Canada sites (EC 1198; EC 1163, Fig. 1). Samples were collected from a

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small boat (EC1198) or from the CCGS Limnos (both sites); EC 1163 was accessible

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only from the CCGS Limnos, and due to ship scheduling no sampling or experiments

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were conducted between early June and mid-July (Supplemental Table 1 & 2,

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respectively).

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Sample collection:

During May through October 2013, short-term nutrient

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Physicochemical data were measured at each site at approximately the same time

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each sampling trip using a calibrated water quality probe (YSI 6600, Yellow Springs,

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OH, USA), measuring surface water temperature, dissolved oxygen concentration, pH,

 

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and conductivity. Water samples (60L) were collected using a rosette from a depth of 1 m

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and either processed immediately when onboard CCGS Limnos or kept at room

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temperature until returned to Bowling Green State University (BGSU) for processing

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within two hours. From each site, subsamples were processed for total chlorophyll a (chl

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a; 47 mm GF/F), particulate microcystins (MCs; 1.2 µm polycarbonate membrane) and

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cell-bound DNA analysis (0.22µm Sterivex filter cartridge; Millipore Corp., Billerica,

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MA, USA). The filter cartridges were immediately frozen with chl a and MC samples

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stored at -20 °C and the Sterivex filter cartridges stored at -80 °C until analysis. Samples

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for phytoplankton community composition and biomass determination were preserved

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with Lugol’s iodine solution (1% v/v. final conc.). Rainfall data for the area surrounding

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Sandusky

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(http://www.usclimatedata.com/).

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through October 2013.

Bay

were

collected

from

the

U.S.

Climate

Data

website

Weekly average rainfall was calculated from May

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Duplicate water samples for the analyses of dissolved nutrients (nitrate/nitrite

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[NO3- + NO2-], ammonia [NH3] and soluble reactive phosphorus [SRP]) were collected by

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filtering lake water through a 0.45µm polycarbonate filter into triple-rinsed 20 mL plastic

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bottles and stored at -20 °C until analysis. Water samples for total phosphorus [TP]

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analysis were collected by filling a triple-rinsed 20 mL plastic vial with whole lake water

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followed by storage at -20 °C. All samples were analyzed at the National Center for

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Water Quality Research, Heidelberg University, Tiffin, OH, USA using standard

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techniques (35).

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Nutrient amendment experiments: Short-term nutrient enrichment experiments were conducted to assess the impact

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of increased organic and inorganic N or PO4 concentrations on the Planktothrix

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populations in Sandusky Bay. During the summer of 2013, a total of 13 experiments

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were conducted on samples from sites EC 1163 and EC 1198.

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experiments, sets of triplicate, 1L clear polycarbonate bottles (n = 24) were filled with

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surface water from each experimental site and were either left unamended to serve as a

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control, or amended with various forms of N: nitrate (combination of Ca(NO3)2 plus

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KNO3), ammonium (NH4Cl), urea, orthophosphate (KH2PO4) or a combination of each

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individual N form and KH2PO4 (referred to as PO4 from hereon). All N treatments were

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amended to a final concentration of 178.9µM and all P treatments were spiked to a final

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concentration of 1µM. In order to facilitate comparisons between these field experiments

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and planned laboratory experiments, the N concentration of 178.9µM was chosen because

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it represented 10% of the total N concentration in the growth media used in our

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laboratory. Experiments were conducted in two locations (See Supplemental Table 2).

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Those carried out onboard the CCGS Limnos were incubated in a flow-through deck

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incubator under ambient water and light conditions. Neutral density screening was used

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to achieve light levels similar to in situ conditions. The experiments conducted at BGSU

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were incubated in a stand-alone incubator using temperatures, light levels (50 µmol m-2 s-

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1

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photoperiods (14:10 h: June, July and August; 12:12 h: September and October).

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Incubator temperatures during all experiments were measured every five minutes with in

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situ loggers (Onset Computer Corporation, Bourne, MA, USA) and indicated that

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incubation temperatures and light levels remained within the same range (i.e. light: 50 -

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100 µmol m-2 s-1; temperature ambient ± 1 o C) as those found at each site. All bottles

 

To commence

) similar to measured field conditions on each sampling date and seasonally appropriate

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were gently inverted every 4 to 6 h. After 48 h, each bottle was sampled as described

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above to quantify chl a, phytoplankton community composition and biomass and

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particulate concentrations of MCs. The effects of P and inorganic and organic N on the chl a concentration, MCs

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concentration were analyzed with one-way ANOVAs.

Post-hoc comparisons of

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significant impacts were elucidated with Tukey’s multiple comparison tests. For all

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results, the standard variance presented is ± one standard error (SE). Since only one

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replicate per treatment was enumerated for phytoplankton community composition and

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biomass, statistical tests could not be preformed.

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Extraction and analysis of microcystins:

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Particulate MCs were extracted from samples using a combination of physical and

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chemical lysis techniques. All samples were resuspended in 1mL molecular grade water

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(pH = 7; Sigma Aldrich, St. Louis, MO, USA) and subjected to three freeze/thaw cycles

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before the addition of the QuikLyse™ reagents (Abraxis LLC; Warminster, PA, USA) as

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per the manufacturer’s instructions. The samples were then centrifuged for five minutes

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at 2 ×103 × g to pellet cellular debris. The concentrations of microcystins (reported as

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microcystin-LR equivalents) were measured using an enhanced sensitivity microcystin

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enzyme-linked immunosorbent assay (Abraxis LLC) following the methodologies of

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Fischer et al. (36). This assay is congener-independent as it detects the ADDA moiety,

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which is found in almost all MCs. These analyses yielded a detection limit of 0.04 µg L-

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1

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Phytoplankton community composition and biomass:

 

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After evaluating the chlorophyll a data, one replicate per treatment in each of the

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seven representative seasonal experiments (Figures 2 & 3) was chosen for enumeration to

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support the pigment-based results. Further, since the initial chlorophyll a concentrations

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and control bottles after 48 hours were statistically similar in all but one experiment we

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only enumerated the control from each experiment and not the initial. Aliquots of the

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preserved samples from were allowed to settle overnight in sedimentation chambers

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following the procedure of Lund et al. (37). Algal units were counted from randomly

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selected transects on a Zeiss Axiovert 40 CFL inverted microscope. Counting units were

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individual cells, filaments or colonies depending on the organization of the algae. A

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minimum of 400 units were counted for each sample. The bulk of the counts are made at

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600X magnification. The large and rare organisms (such as Ceratium) were scanned for

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at 350X magnification. Fresh weight biomass was calculated from recorded abundance

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and specific biovolume estimates, based on geometric solids (38), assuming unit specific

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gravity (1.0 g = 1.0 cm3). The biovolume (mm3 m-3 fresh weight) of each species was

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estimated from the average dimensions of 10 to 15 individuals. The biovolumes of

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colonial taxa were based on the number of individuals in a colony. All calculations for

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cell concentration and biomass were performed with Hamilton’s (39) computer program.

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Sandusky Bay metagenome:

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Microbial biomass from 200 mL surface water collected on 17 June 2013 at EC

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1198 was concentrated on Sterivex cartridge filters (0.22 µm) and immediately frozen in

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liquid nitrogen. DNA was extracted from the Sterivex cartridges using the PowerWater

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Sterivex DNA Isolation Kit (MO BIO Laboratories, Inc, Carlsbad, CA, USA) following

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manufacturer’s instructions. The metagenome was obtained by Illumina sequencing on a

 

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HiSeq platform at the DOE-Joint Genome Institute (Walnut Creek, CA, USA). The

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annotated metagenome dataset comprised 7.3 x 109 total bases and 3.8 x 107 total

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sequences.

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interest (ntcA, nifHDK, mcyA) were identified via BLAST (40), followed by alignment by

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CLUSTAL W and phylogenetic analysis in MEGA (41). Trees were constructed by

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neighbor-joining with 1000 bootstrap replicates.

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Accession numbers:

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Sequences were deposited into the JGI IMG database (accession numbers 10000275,

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10348616, 10111557, and 100007422).

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Results:

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Water quality and rainfall data

Cyanobacterial and bacterial metagenome scaffolds containing genes of

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The Sandusky Bay bloom persisted from May through October, 2013. At both

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sites, surface water temperatures ranged from 16.6 – 27.0 °C, dissolved oxygen

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concentrations were generally supersaturating (mean: 10.7 ± 1.1 mg L-1) and the pH and

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conductivity were consistent throughout the sampling period (mean: 8.4 ± 0.1 and 401 ±

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20 µS cm-1, respectively).

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ranged from 18.4 ± 0.2 µg L-1 to 66.4 ± 7.7 µg L-1 (Supplemental Table 1). Cyanobacteria

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dominated the phytoplankton community biomass (95-99%) at all times except during

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mid-July when cyanobacteria only comprised 11% and 32% of the total phytoplankton

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biomass at stations 1163 and 1198, respectively (Figures 2 & 3). Planktothrix agardii

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dominated the cyanobacterial community comprising > 73% of the biomass on all but

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one date (July 16) at site 1163 (Figures 2 & 3). In spring and early summer,

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concentrations of MCs frequently exceeded the State of Ohio’s Public Health Advisory

 

Chlorophyll a concentrations of all samples at both stations

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guideline level of 6 µg L-1 with values falling below this limit in mid-summer

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(Supplemental Table 1). May and June samples ranged from 5.2 ± 1 µg L-1 to 11.7 ± 2.6

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µg L-1, peaking on June 19 at EC 1198 (Supplemental Table 1). By contrast, July –

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October concentrations of MCs ranged from a mid-summer low of 0.4 ± 0.1 µg L-1 on

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July 16 at EC 1198 and increased to 5.3 ± 0.5 µg L-1 on October 9 (Supplemental Table

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1).

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Profiles of nutrient concentrations (SRP and DIN) measured at the time of each

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experiment indicated that whereas SRP remained well above DL and showed only

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moderate changes with time (EC 1163: 0.08 ± 0.03 – 0.41 ± 0.06 µM; EC 1198: 0.06 ±

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0.02 – 1.21 ± 0.03, Figure 4B), DIN was highly variable (Figure 4A). DIN declined at

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both stations in late August – October, and at EC 1198 in late May and early June.

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However, DIN concentrations peaked in late June and early July at values almost 100

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fold higher, following a series of mid-summer rain events and increased runoff (Figure 4;

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www.usclimatedata.com/climate/sandusky/ohio/united-states/usoh0855/2013/8).

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Nutrient amendment experiments In total, seven experiments were conducted at EC 1163 and six at EC 1198.

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A

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representative experimental date was chosen from early spring, early summer mid-

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summer and early fall for a visual comparison of seasonal responses both within and

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between stations. 1163 had no early summer experiment (Figures 2 & 3). Both stations

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showed similar overall responses in algal growth, (as inferred by increasing chl a

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concentrations) and concentrations of MCs as both were primarily stimulated by N in

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experiments conducted during the summer of 2013 (Figures 5 & 6; Supplemental Table

 

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2). However, each station yielded different responses to nutrient additions at different

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points throughout the summer.

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During early summer (late May - early June), concentrations of chl a and MCs did

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not exhibit significantly positive responses from the control in any treatment (p > 0.05;

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Figures 5 & 6; Supplemental Table 2). Phytoplankton biomass response was consistent

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with the overall chl a response and no shift in community composition was observed

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(Figures 2 & 3). No experiments were conducted at EC 1163 during June, but all

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experiments conducted throughout this month at 1198 indicated that by mid-June, algal

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growth was strongly N-limited, with additions of any form of N yielding chl a

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concentrations that were nearly double the control treatments (Figure 6; Supplemental

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Table 2). MC concentrations responded to the addition of any form of N in two of the

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three experiments, suggesting that bloom toxigenicity was also strongly N-limited (p