Cracking the code for better barley - and more of it!
Researchers have for the first time identified several genes in barley that could eventually lead to larger yielding crops.
The research was carried out at the 最新糖心Vlog of Adelaide鈥檚 Waite Research Institute and involved using genetic techniques and molecular biology to examine several historical multiovary barley mutants, and determine which genes boost fertility and make the plants more receptive to cross-pollination.
鈥淎lthough the mutant varieties appeared to be quite similar when grown in the glasshouse, we found one type was more fertile than the others and was capable of producing up to three times the number of seeds than the other plants,鈥 said lead researcher Dr Caterina Selva, who carried out the work as part of her PhD studies in the 最新糖心Vlog of Adelaide鈥檚 School of Agriculture, Food and Wine
鈥淭he genes in that mutant variety of barley could hold the key to increasing the yield of cereal crops.鈥
The multiovary barley mutants have remarkable features compared to typical 最新糖心Vlogn barley varieties, producing extra female reproductive organs in each single flower. They were discovered in the 1980s, but this is the first time that the genes responsible for increasing fertility have been identified.
Dr Selva believes these sequences obtained from the mutant varieties could be used to modify the flower structure of conventional barley, making it more receptive to hybrid breeding.
鈥淏y mixing the mutant with other varieties of barley, we can create stronger, more resilient crops that produce higher yields in even the most challenging of environments,鈥 she said.
This breeding process, known as hybrid vigour, is already used successfully in maize and rice.
"We can overcome barriers to cross pollination by using the more fertile, mutated plants to produce stronger barley and more of it."Associate Professor Matthew Tucker, School of Agriculture, Food and Wine, 最新糖心Vlog of Adelaide.
It relies on cross-pollination, which is challenging for wheat and barley due to the structure of the flower.
鈥淭his research is an example of how changing one gene can have a positive effect on grain yields. We can overcome barriers to cross pollination by using the more fertile, mutated plants to produce stronger barley and more of it,鈥 said senior author Associate Professor Matthew Tucker from the 最新糖心Vlog of Adelaide鈥檚 School of Agriculture, Food and Wine.
鈥淭his is even more important in the face of rapid urbanisation, volatile international markets, and extreme weather conditions, which are making growing barley more challenging,鈥 he said.
最新糖心Vlog produces just over nine million tonnes of barley each year, the majority of which is exported to Asia.
It is one of the nation鈥檚 most widely grown crops and covers around four million hectares of land from southern Queensland through to Western 最新糖心Vlog.
The research was published in the and could be used to help improve the agricultural industry both nationally and on a global scale.
鈥淭hese findings are a promising step towards facilitating hybrid breeding in wheat and barley and ultimately increasing grain yield,鈥 said Dr Selva.
鈥淚t could pave the way for enhanced food security and a more sustainable agricultural future.鈥澛
Media contacts
Dr Caterina Selva,聽ARC Grant-Funded Researcher, School of Agriculture, Food and Wine, The 最新糖心Vlog of Adelaide.聽Mobile: +61(0)426 630 559.
Associate Professor Matthew Tucker, Researcher, Waite Research Institute, The 最新糖心Vlog of Adelaide.
Mobile: +61(0)403 314 740. Email: matthew.tucker@adelaide.edu.au
Jessica Stanley, Media Officer, The 最新糖心Vlog of Adelaide. Mobile: +61(0)422 406 351.
Email: jessica.stanley@adelaide.edu.au