Lauren McKee

One of the great biotechnological advances of recent years is the development of affordable and accessible methods for genome sequencing. In the field of metagenomics, we can sequence the genomes of all the microbes in a community, by extracting DNA directly from an environmental sample such as soil or water. There are many different sequencing techniques that can be used for this, depending on the amount of time available for a project and the depth of information that is required. The genius of metagenome sequencing is that we don’t need to isolate microbes from the environment to know that they are there – we can find their genomes through the sequencing data! Such tools can be used to track the quality and health of urban waterways and to look for species that might be pathogenic or that may indicate the presence of pollution.

An advanced course introduction to metagenome sequencing

On the Medical, Industrial, and Environmental Biotechnology Master’s degree programmes at KTH, students can choose to take the course BB2560 Advanced Microbiology and Metagenomics. In this course, we give an introduction to the concept of metagenome sequencing, and the students read case studies about the various ways the technology can be used. A special feature of the course is that students get to perform a real research project that runs throughout the course, and the resulting lab report serves as their final exam. As a group, the students choose a research topic and select an environment to sample. Then we arrange a field trip to collect samples, and the students work in labs at AlbaNova to extract and amplify microbial community DNA. The DNA samples are sent for sequencing and, when we get the results back, the students analyse the data themselves and draw their own conclusions.

Water sampling from different locations in Stockholm

This year, the students chose to investigate waterways in the city of Stockholm. They selected sites that vary in their proximity to industry, traffic, human residence, and more protected natural areas. Specifically, we collected samples from the lake Laduviken at a site close to AlbaNova where we often see swimmers in the summer. We collected from a small lake in a quiet area on Djurgården. We took samples from the home garden pond of one of our teachers. And finally, we collected from two different sites along the Bällstaån, a small river running between Bromma and Sundbyberg. The Bällstaån has a history of heavy pollution, and there are still industrial areas, a boat club, and several building sites along its length. But it has been undergoing passive remediation for many years, and there is clear evidence of diverse plant and animal life close to some of the more residential stretches.

Human activity was expected to cause disturbance in microbial activity

The students developed the hypothesis for this project that proximity to human activity, particularly industrial activities that can cause pollution, would lead to a difference or disturbance in the microbial community of the water or the sediment beneath it. At some sites, there were clear indicators of pollution, such as plastic waste in the water, an oily sheen, or an unpleasant odour. As I live alongside the Bällstaån, I was particularly intrigued – and a bit nervous – about what they might find in the microbiome!

Waste detected in most sites

In short, the results were not very good. Microbial taxa that are typically found in wastewater were detected at almost every site, suggesting that waste is being released and finding its way even to the more pristine parts of our city. Sadly, there was not as much of a difference between the microbiome at the supposedly pristine sites and those that we expected to show signs of pollution. During a literature search, students found reports that pipe misconnections and other errors are known to have caused wastewater leakages into Laduviken in previous years, but the data from this our student project indicate that there may be similar problems at many sites.

The study should be followed up with more water quality monitoring

There were of course some limitations to our study. For example, due to the scheduling of our course, we collected our samples in early February, when the top few centimetres of water were frozen. The cold temperatures probably had an impact on the diversity of microbes we could find, as cell counts were likely lower. This could mean that our data give an inaccurate picture of water quality by over-emphasising the abundance of some microbes. Nonetheless, this student projects could serve as motivation for a wider initiative using metagenome sequencing to monitor water quality throughout the city, both in places we expect to be polluted and in the areas we think of as being better protected from human impact.

I want to thank all of the students who took course BB2560 this year for proposing a really interesting and useful project, and for being brave enough to collect water and sediment samples from frozen rivers and lakes!

Lauren McKee is a docent in biotechnology and a researcher at the KTH Division of Glycoscience

Isaac Owusu-Agyeman

Sjöstadsverket Water Innovation Centre (SWIC) is owned and operated by IVL Swedish Environmental Research Institute and KTH. Sjöstadsverket is Sweden’s leading and internationally prominent research and development facility in water purification technology.

Many lack clean water

Water is the core of life and an important indicator of sustainable development. However, an increasing proportion of the world’s population does not have access to safe water. The lack of clean water is a growing problem in the world. It is said that access to safe water is a human right that many people lack today. UNICEF estimates that 1 out of 4 children will be living in extreme water stress areas by 2040 due to climate change.

SWIC bridges the gap between research and implementation

SWIC as a research and development facility plays an important role in solving global water and climate problem by driving problem-solving ideas to implementation. SWIC is an excellent example of how to bridge the gap between research and implementation in a real-world application. Water and energy issues can be mitigated not only with innovative and efficient water treatment technologies but also strategies for recovering resources from wastewater and other waste streams. There is a need to transition into a fossil-free society due to the alarming adverse effects of petroleum-based products on the climate. Material and energy recovery from waste and industrial residues is integral in the circular economy concept that will help create value and contribute to the UN sustainability goals by reducing virgin materials’ consumption and decreasing waste generation.

A place to test new technologies and innovative solutions

SWIC is a unique pilot- and demonstration facility for the development of innovative and sustainable techniques to ensure clean water and a better environment for the present and future generations. The focus of SWIC includes but is not limited to resource-efficient water/wastewater treatment technologies, recovery and reuse technologies, and energy production & carbon neutral processes. SWIC is very well suited for testing new technology and innovative solutions in water treatment and environmental technology. The pilot plant is built in a way that enables flexible control and interaction with various water treatment technologies and processes for resource recovery from waste.

Relocating to new facilities in Loudden

SWIC, formerly called Hammarby Sjöstadverket, was built around 2002–2003 by Stockholm Vatten och Avfall and was situated on top of Henriksdalsberget at the Henriksdal wastewater treatment plant. The R&D facility was handed over to KTH and IVL in 2007 and since then several innovative and world-changing projects have been carried out in the facility. Beyond the research, SWIC is used for educational purposes including PhD, bachelor, and master’s degree practical coursework, internship, and field trips. Since September 2022, SWIC’s operations are relocating to new premises in Loudden, Stockholm, which is about 15 minutes from the main KTH campus. Preparation and installation of pilot plants at the new location at Loudden are ongoing and operation will start after the summer of 2023.

Workshop with KTH researchers

In April 2023, a workshop was held for KTH researchers and IVL staff to discuss future opportunities to initiate innovative projects at the new SWIC. The workshop included the presentation of successful projects that have been carried out at the SWIC and a site visit to SWIC’s new location at Loudden. There was a lot of excitement about the new place and KTH and IVL researchers are looking forward to having their teaching and research activities at the innovation centre. Participants of the workshop see degree projects, product development, course, and site visits as some of the activities befitting for the new location.

• Hammarby Sjöstadsverk on the WaterCentre@KTH website
• SWIC, Sjöstadsverket Water Innovation Centre on IVL’s website (In Swedish)

Isaac Owusu-Agyeman is a researcher at the Department of Industrial Biotechnology and the deputy coordinator and KTH responsible person for the Hammarby Sjöstadsverket