News Release

Desert plant may hold key to surviving food shortage

Peer-Reviewed Publication

University of Liverpool

The plant, Kalanchoe fedtschenkoi, is unique because, unlike normal plants, it captures most of its carbon dioxide at night when the air is cooler and more humid, making it 10 times more water-efficient than major crops such as wheat. Scientists will use the latest next-generation DNA sequencing to analyse the plant's genetic code and understand how these plants function at night.

The project will generate a genome sequence database that will be used as an Internet resource for plant biologists throughout the world.

The research comes at a time when farmland across the globe normally used for growing food such as rice and wheat is being taken over by bio-fuel crops used for bioethanol production as a petrol substitute. Scientists believe that the novel genes found in Kalanchoe could provide a model of how bio-fuel plants could be grown on un-utilised desert and semi-arid lands, rather than on fertile farmland needed for producing food.

Biological scientist, Dr James Hartwell, said: "There is a lot of concern over food shortage at the moment, with more farmland being commandeered for bio-fuels. As a result of changes in our climate the Intergovernmental Panel on Climate Change has predicted a large expansion of arid regions so there is an increasing need for new crop varieties that can be productive in deserts.

"Kalanchoe is a good example of how plants can flourish in harsh environments. If we can understand how it is able to photosynthesise using much less water than current crops, we may be able to use its genetic code to develop a crop able to withstand harsh environmental conditions. It is essential that farmland be returned to food production."

The genetic code of the plant will be deciphered using a DNA sequencing machine that uses an enzyme found in fireflies as a flash light to help read the DNA strand.

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Liverpool is one of only two universities in the UK with the technology, which can read up to half a billion DNA letters in a few hours compared to more widely used technology that can only process 50,000.

The project is funded by the Biotechnology and Biological Sciences Research Council (BBSRC),

Notes to editors:

1. The University of Liverpool is a member of the Russell Group of leading research-intensive institutions in the UK. It attracts collaborative and contract research commissions from a wide range of national and international organisations valued at more than £108 million annually.

For further information:

Kate Spark, Media Relations Manager
Tel: 0151 794 2247, Mobile: 07970 247391, E-mail: kate.spark@liv.ac.uk

Samantha Martin, Senior Press Officer
Tel: 0151 794 2248, Mobile: 07970 247836, E-mail: samantha.martin@liv.ac.uk

Laura Johnson, Press Officer
Tel: 0151 794 2026, Mobile: 07807 106562, Email: laura.johnson@liv.ac.uk


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