A Novel Approach To Monitoring Fresh Water Health
Published on by Water Network Research, Official research team of The Water Network in Case Studies
Monitoring Microbial Species In Fresh water Can Help Indicate Presence Of Disease-Causing Microorganisms & Even Water Pollution.
Researchers have used the world’s smallest, smartphone-sized DNA sequencing device to monitor hundreds of different bacteria in a river ecosystem. Writing in the journal eLife, the interdisciplinary team from the University of Cambridge, UK, provide practical and analytical guidelines for using the device, called the MinIONTM (from Oxford Nanopore Technologies), to monitor fresh water health. Their guidelines promise a significantly more cost-effective and simple approach to this work outside the lab, compared to existing methods.
Rowers and swimmers in Cambridge are regularly affected by waterborne infections such as Weil’s disease, sometimes leading to public closures of the city’s iconic waterways. Monitoring the microbial species in fresh water can help indicate the presence of disease-causing microorganisms and even water pollution. But traditional tests for fresh water bacteria often require well-equipped laboratories and complex methods for growing colonies of individual bacterial species. “The direct measurement of all bacterial DNA traces in fresh water, an approach known as metagenomics, is a valuable alternative, but still requires large, expensive equipment that can be hard to operate,” says Andre Holzer, co-first author and PhD student at the Department of Plant Sciences, University of Cambridge. “We aimed to describe the bacterial species present in the River Cam using the new portable DNA sequencing technology.”
The team used the MinION device to sequence the DNA of entire groups of microorganisms found in water samples from the River Cam. But before they could use the sequence data, they needed to optimise their experimental methods and analysis software. “It was essential to account for the quality of this new type of bacterial DNA sequence information,” Holzer explains. “We tested many different algorithms for processing the data to find the most accurate methods.” The researchers then used their optimised guidelines to analyse the data and successfully measure the proportions of hundreds of different bacterial species present in the water. They took samples from nine different sites along the river, often sampling the sites at three different time points so they could compare the proportions of species in different locations and seasons.
The team was also able to distinguish closely related, harmful microbial species from non-harmful ones. By comparing the samples from different locations, they found that there were more potentially harmful bacteria and those associated with wastewater downstream of the most built-up, urban areas of the river. Chemical follow-up analyses of the water samples collected from the same urban areas revealed a matching trend of increasing wastewater pollution in those areas. “Our work shows how MinION and the associated DNA sequencing technology can be used in the effective monitoring of fresh water health,” says Lara Urban, co-lead investigator of the work and now an Alexander von Humboldt Research Fellow at the University of Otago, New Zealand. “This expands on the technology’s existing applications which include the accurate tracing of viral transmissions between patients during the recent Ebola, Zika and SARS-CoV-19 virus outbreaks.”
“We hope our results will encourage other independent scientists and collectives to engage in simplified fresh water management and biodiversity tests around the globe,” concludes senior author Maximilian Stammnitz, a PhD student at the Department of Veterinary Medicine, University of Cambridge.
Taxonomy
- Micropollutants
- Microbiology
- Genomics
- Water microbiology