Dataset: Metagenomic Time Series of Winam Gulf, Lake Victoria from 2022-2023 (ASI Lake Victoria project)

ValidatedFinal no updates expectedDOI: 10.26008/1912/bco-dmo.931936.1Version 2 (2024-07-09)Dataset Type:Cruise Results

Principal Investigator: George S. Bullerjahn (Bowling Green State University)

Co-Principal Investigator: Robert Michael McKay (University of Windsor)

Student: Lauren Hart (University of Michigan)

Student, Contact: Brittany N. Zepernick (University of Tennessee Knoxville)

BCO-DMO Data Manager: Sawyer Newman (Woods Hole Oceanographic Institution)

Project: IRES Track II: Advanced studies institute on water quality and harmful algal blooms in Lake Victoria (ASI Lake Victoria)

Abstract

Compared to the other "Great Lakes" (Laurentian Great Lakes of North America and Lake Baikal of Russia) the African Great Lakes have remained widely unstudied. This serves as a substantial research gap within the limnological literature given the African Great Lakes contribute approximately 25% of all global, accessible freshwater. Lake Victoria of the African Great Lakes is notable for its large size - serving as the second largest freshwater lake in the world by surface area. Yet, Lake Victor...

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Water samples were collected from Lake Victoria were depth discrete (1.0 meters) collections performed using a Van Dorn sampler. Samples were collected on 0.22 micron sterivex filters for subsequent DNA extraction and stored at room temperature in DNA/RNA Shield (Zymo). Concurrently, a multiparameter sonde was deployed to record temperature, pH, dissolved oxygen, conductivity, turbidity etc. In addition, sterivex filtrate was collected and stored at -20 degrees Celsius for subsequent dissolved nutrient analysis at the Ohio State Stone Laboratory.

In turn, samples were collected for chlorophyll a and processed using a 24 hour 90% acetone extraction performed at -20 degrees Celsius followed by quantification using a fluorometer. Samples for toxin analysis (microcystin) were collected and stored at -20C until processing using standard ELISA kits. 

In situ analysis was performed with a field Algae Torch (bbe Moldaenke) fluorometer, which was equipped with chlorophyll a and phycocyanin probes. We collected data in the form of cells per liter by lowering the fluorometer into the water column at the same depths where water samples were collected. We then converted the data to percentages to determine the relative abundance of cyanobacteria in the context of the full phytoplankton community (Brown, et al. 2024).

The toxin data was collected and processed as follows: whole water samples were collected at the designated sample depth (refer to the “Sampling_depth” column within the primary data file of this dataset) and lysed using three freeze / thaw cycles. The lysate was investigated for the presence of the cyanobacterial toxin / secondary metabolite “microcystin” using the Microcystins/Nodularins (ADDA) ELISA kit (Gold Standard Diagnostics, Warminster, PA) (Brown, et al. 2024). Absorbance was read at 450 nm on a Multiskan FC Microplate Photometer (Thermo Fisher Scientific Inc).

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Results
Hart, L.N., Zepernick, B.N., Natwora, K.N., Brown, K.M., Obuya, J.A., Lomeo, D., Barnard, M., Owino, E., 2022-2023 NSF-IRES Lake Victoria Research Consortium, Kiledal, E. A., Uyl, P.D., Olokotum, M., McKay, R. M. L., Drouillard, K.G., Sherman, D.H., Sitoki.L., Achiya, J., Getabu, A., Otiso, K.M., Bullerjahn, G.S., Dick, G.J., (2024 in prep). Metagenomics Reveals Temporal Variation in Cyanobacterial Composition, Function, and Biosynthetic Potential in the Winam Gulf, Lake Victoria, Kenya.
Results
Zepernick, B.N., Hart, L.N., Chase, E.E., Natwora, K.N., Obuya, J.A., Olokotum, M., Houghton, K., Kiledal, E. A., 2022 NSF-IRES Lake Victoria Research Consortium., Sheik, C.S., Sherman, D.H., Dick, G.J., Wilhelm, S.W., Sitoki, L., Otiso, K.M., McKay, R. M. L., Bullerjahn, G.S., (2024 in prep). Molecular investigation of toxigenic cyanobacteria reveals risks and niche partitioning in three anthropogenically and ecologically important Kenyan lakes.
Results
Zepernick, B.N., Hart, L.N., Natwora, K.N., Brown, K.M., Obuya, J.A., Olokotum, M., Owino, E., Keating, N.G., Lomeo, D., Tebbs, E.J., 2022-2023 NSF-IRES Lake Victoria Research Consortium, Sheik, C.S., Sherman, D.H., Dick, G.J., Wilhelm, S.W., Sitoki, L., Otiso, K.M., McKay, R. M. L., Bullerjahn, G.S., (2024 awaiting submission). Metagenomic Sequencing of Cyanobacterial-Dominated Lake Victoria - an African Great Lake.
Methods
Brown, K. M., Barker, K. B., Wagner, R. S., Ward, C. S., Sitoki, L., Njiru, J., Omondi, R., Achiya, J., Getabu, A., McKay, R. M., & Bullerjahn, G. S. (2024). Bacterial community and cyanotoxin gene distribution of the Winam Gulf, Lake Victoria, Kenya. Environmental Microbiology Reports, 16(3). Portico. https://doi.org/10.1111/1758-2229.13297

Bullerjahn, G. S. (2024) Metagenomic Time Series of Winam Gulf, Lake Victoria from 2022-2023 (ASI Lake Victoria project). Biological and Chemical Oceanography Data Management Office (BCO-DMO). (Version 1) Version Date 2024-07-09 [if applicable, indicate subset used]. doi:10.26008/1912/bco-dmo.931936.1 [access date]

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This dataset is licensed under Creative Commons Attribution 4.0.


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Funded by the U.S. National Science Foundation