Pioneering University Of Brighton Genome Mapping Provides Seas Breakthrough

Researchers from the University of Brighton have completed the world’s first-ever genome sequencing of the dog whelk, a crucial marine species used to monitor sea pollution.

The ground-breaking research was led by Rameen Shakur, Professor of Genomics and Precision Medicine at the University of Brighton.

Professor Shakur and his team successfully mapped the genetic blueprint of the dog whelk, a sea snail that plays a crucial role in both marine ecosystems and the human food chain.

Known scientifically as Nucella lapillus, dog whelks are widely used to assess the presence of toxic pollutants such as raw sewage, tributyltin (TBT) and other chemicals that interfere with the hormone systems of organisms in marine environments.

Chronic exposure to these pollutants causes imposex – a condition in which female dog whelks develop male sexual characteristics, leading to dog whelk sterility and population decline.

Many marine organisms, including shellfish consumed by humans, are affected by the same pollutants harming dog whelks. Despite its ecological importance, no reference genome for dog whelk was previously available, limiting the ability of researchers to apply modern genomic tools to study its biology and response to pollution.

Now, thanks to the work done by University of Brighton scientists at the Brighton Integrated Genomics (BIG) Unit, the first-ever genome assembly for the dog whelk has been completed.

The study sampled wild dog whelks collected from the Isle of Islay in Scotland over a period of 18 months, providing an essential foundation for future genomic and environmental research.

By discovering how harmful chemicals alter the dog whelk’s reproductive system, the study presents new insights into potential risks for the seafood industry and similar disruptions to human health.

Professor Rameen Shakur, Director of the Brighton Integrated Genomics Unit at the University of Brighton, said:

The study was conducted in collaboration with researchers from the University of Edinburgh.

The team led by Professor Shakur also included Andrew Hesketh from the University of Brighton with Juned Kadiwala, and Heleen De Weerd and Helen Ritch from the University of Edinburgh.

They utilised state-of-the-art sequencing technologies, including PacBio HiFi and Oxford Nanopore sequencing, to generate a highly accurate and complete genome with 84% assembly completeness.

This achievement is particularly significant given the challenges associated with extracting and sequencing DNA from marine invertebrates, which often contain substances that interfere with sequencing processes.

The genome assembly is now publicly available in Springer Nature, providing a valuable resource for marine biologists, ecotoxicologists, and conservationists worldwide.

Lessons from the study may shed light on potential genetic adaptations that could inform environmental risk assessments and pollution mitigation strategies.

About the Brighton Integrated Genomics (BIG) Unit

The Brighton Integrated Genomics (BIG) Unit at the University of Brighton specialises in cutting-edge genomic research with a focus on precision health, environmental genomics, and translational medicine.

The unit collaborates with academic and industry partners worldwide to apply genomics in addressing global health and environmental challenges.