Scientists engineer produce crops that need less fertiliser


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The team of plant scientists used synthetic biology techniques to design and then engineer a molecular dialogue between plants and the bacteria surrounding their roots in a zone called the rhizosphere. 

This synthetic signalling system could be a vital step towards successfully engineering nitrogen-fixing symbiosis in crops like wheat and maize. 

Enhancing the root microbiota has enormous potential for improving crop yields in nutrient-poor soils and reducing chemical fertiliser use.  

The interdisciplinary research collaboration was between the Universities of Oxford and Cambridge. 

Joint lead author, Dr Barney Geddes, said: “Plants influence the microbiota of their rhizosphere by sending out chemical signals that attract or suppress specific microbes. 

“Engineering cereal plants to produce a signal to communicate with and control the bacteria on their roots could potentially enable them to take advantage of the growth-promoting services of those bacteria, including nitrogen fixation. 

“To do this we selected a group of compounds normally produced by bacteria in legume nodules, called rhizopines. 

“First we had to discover the natural biosynthetic pathway for rhizopine production, and then design a synthetic pathway that was more readily transferred to plants. 

“We were able to transfer the synthetic signalling pathway to a number of plants, including cereals, and engineer a response by rhizosphere bacteria to rhizopine.” 

Dr Ponraj Paramasivan, joint lead author at Cambridge’s Sainsbury Laboratory, explained how the team transferred the rhizopine synthesis genes into barley to assess whether they could engineer rhizopine synthesis in cereals. 

She said: “A key advantage of this synthetic signalling pathway is that only the specific crop plant that is engineered to produce the signal will benefit.

 “This means that weeds that currently benefit just as much as the target crop from the application of chemical fertilisers, will not benefit from these enhanced plant-microbe associations as they do not produce this novel signalling molecule to communicate with bacteria.”  

Future work will focus on how plants can control key processes in root bacteria such as nitrogen fixation, phosphate solubilisation and plant growth promotion. 

This opens up the world of the bacterial microbiome and its diverse metabolism to control by plants and in particular the cereals.  

It is likely to be a key component in attempts to engineer nitrogen fixation into cereals