Select your localized edition:

Close ×

More Ways to Connect

Discover one of our 28 local entrepreneurial communities »

Be the first to know as we launch in new countries and markets around the globe.

Interested in bringing MIT Technology Review to your local market?

MIT Technology ReviewMIT Technology Review - logo

 

Unsupported browser: Your browser does not meet modern web standards. See how it scores »

Researchers at the University of Edinburgh, in Scotland, have genetically modified the bacteria E. coli to detect trace amounts of arsenic in drinking water. They hope that the bacteria-based technology will eventually lead to safe, precise, and easy-to-use field arsenic test kits. Chris French, professor of microbial biotechnology at Edinburgh, says that such tests could be as easy to use as home pregnancy tests and would not require a trained technician.

Arsenic poisoning affects millions of people worldwide. One of the hardest hit countries is Bangladesh, where up to 35 million people get their drinking water from arsenic-contaminated wells, according to the World Health Organization. In recent years there has been a concerted effort to map the distribution of arsenic and flag contaminated wells. In some cases, scientists and aid workers have sent water samples to be tested in labs using fluorescence techniques–an expensive and time-consuming process. In other cases, they have used portable test kits. Most of these field tests, however, require training to operate and produce toxic chemicals, such as arsine gas.

“There’s definitely some drawbacks of existing field kits, and one is toxic disposal,” says Gregory Miller, an arsenic geochemist at Subsurface Technologies, an environmental remediation company in Socorro, NM. “An ideal detector should have a low detection limit, high precision, and no waste stream involved with it.”

The arsenic detector developed at Edinburgh is one of the first practical examples of a device built using the principles of synthetic biology. The aim of synthetic biology is, first, to identify the precise function of particular DNA sequences, or genetic parts. Some parts may control certain proteins. Others may act as switches for cellular processes. Then researchers mix and match to see how different parts fit together to form new genetic circuits, creating novel biological functions within living organisms, such as bacteria.

Drew Endy, assistant professor of biological engineering at MIT, likens synthetic biology to building with Lego. He has helped assemble a registry of standard genetic parts as a resource for scientists to borrow from, build on, and add to. Endy is also cofounder of iGEM, the annual International Genetically Engineered Machine competition, at which Edinburgh’s bacteria-based arsenic biosensor won the prize as best real-world application in 2006.

The Edinburgh group found that the bacterium E. coli possesses two seemingly unrelated genetic sequences that, in combination, form an effective arsenic-detection device. First, E. coli possesses a natural arsenic detoxification system that is switched on only in the presence of arsenic. The bacterium also naturally breaks down lactose to produce acid. The researchers isolated the arsenic-switch gene and attached it to the first gene involved in the breakdown of lactose.

0 comments about this story. Start the discussion »

Credit: University of Edinburgh

Tagged: Biomedicine, diagnostics, bacteria, toxicity, drinking water

Reprints and Permissions | Send feedback to the editor

From the Archives

Close

Introducing MIT Technology Review Insider.

Already a Magazine subscriber?

You're automatically an Insider. It's easy to activate or upgrade your account.

Activate Your Account

Become an Insider

It's the new way to subscribe. Get even more of the tech news, research, and discoveries you crave.

Sign Up

Learn More

Find out why MIT Technology Review Insider is for you and explore your options.

Show Me