Triggers for food crop growth are complex and new research by South Australian plant scientists is investigating one way wheat responds to common stresses such as poor soil health.
Research led by Flinders University is aiming to understand how a signalling molecule, known as gamma aminobutyric acid (GABA), may regular proteins in wheat plants dealing with a range of extremes.
“This emerging research suggests that GABA is a signal in plants, not only regulating numerous normal developmental processes such as root growth, stomatal aperture and pollen tube germination but also responses to stresses such as aluminium toxicity and salinity,” says Dr Sunita Ramesh, lead author of the research published in the .
“We understand this signalling molecule in animals but not as much in plants,” she says.
“Earlier research showed that in response to stress, GABA regulates the activity of ion transport proteins and under certain conditions these proteins may also transport GABA in plants. To understand the role of GABA in stress tolerance, it is essential to distinguish between the two transport modes of these proteins.”
Using the aluminium-tolerant wheat variety (Triticum aestivum), researchers from Flinders University, the University of Adelaide and Waite Research Institute experimented with a plant derived pharmacological agent, picrotoxin, to distinguish between the transport capabilities of proteins involved in conferring aluminium tolerance.
Outcomes of this study indicate that picrotoxin blocks transport of negatively charged ions through the protein but allows transport of GABA and that the transport is dependent on the conformation of the protein.
The experiment is a stepping stone in understanding the role of other agents to reduce or enhance GABA activity in plant crops, says co-author Abolfazl Dashtbani-Roozbehani, also from the College of Science and Engineering at Flinders University.
Researchers hope new investigations into understanding the role of GABA could help identify wheat cultivars and other crops that are more resilient to common farm production problems such as extreme temperatures, salinity, aluminium toxicity in acid soils and even drought.
Acknowledgement: This study was supported by funding from the ARC Centre of Excellence, Plant Energy Biology (CE140100008).
Flinders University will launch a new in 2023.
The research – (2022) by Sunita A Ramesh, Yu Long, Abolfazl Dashtbani-Roozbehan, Matthew Gilliham, Melissa H Brown and Stephen D Tyerman – has been published in Biology. DOI:10.3390/biology11081162