Crystallography Uncovers How Important Herbicide Works
Herbicide-resistant weeds are threatening food security, but University of Queensland researchers are one step closer to a solution after a new discovery.
A UQ School of Chemistry and Molecular Biosciences study led by Associate Professor Luke Guddat uncovered how penoxsulam, the active ingredient in the world’s largest-selling rice herbicide, works.
“Penoxsulam controls weeds such as key grass, broadleaf and sedge, and has become a focus of research due to an increased number of weeds that have developed resistance to herbicides,” Dr Guddat said.
“Understanding how it works will assist in managing herbicide resistance not only for rice growers but also for wheat, turf and wine producers globally.
“These compounds have been shown to have extremely low levels of toxicity to the environment.”
The researchers hope the discovery will contribute to the design of the next generation of safe and commercially effective herbicides to counter the growing number of weeds becoming resistant.
Herbicide-resistant weeds result in lost income for the world’s crop producers despite the $30 billion they spend globally on herbicides each year, threatening food security.
The research conducted by Dr Thierry Lonhienne and PhD student Mario Garcia used crystallographic studies, which show the precise structure of molecules at incredibly high resolutions, enabling them to capture the molecular mechanisms of the herbicide in action.
Dr Guddat said the team discovered penoxsulam combined with an enzyme in the weed and prevented it from carrying out its normal function - to produce amino acids, which are the fundamental building blocks of proteins.
“Luckily, humans and other animals don’t have that enzyme so penoxsulam compounds are relatively safe at the concentrations used in field applications.”
This article has been republished from materials provided by The University of Queensland. Note: material may have been edited for length and content. For further information, please contact the cited source.
Thierry Lonhienne, Mario D. Garcia, Gregory Pierens, Mehdi Mobli, Amanda Nouwens, Luke W. Guddat. Structural insights into the mechanism of inhibition of AHAS by herbicides. Proceedings of the National Academy of Sciences, 2018; 201714392 DOI: 10.1073/pnas.1714392115.
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