Investment in science and industry development key to profitable agrifood sector 2
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- Bu səhifədəki naviqasiya:
- Funding and collaborators
- HIGHLIGHTS
- Managed Environment Facilities (MEF) enable putting the (index) finger on drought performance of wheat varieties
HIGHLIGHTS
Funding and collaboratorsGRDC, UA, Living Farm, Kalyx Australia Genetic research cuts losses from wheat leaf diseasesScience team: Dr Manisha Shankar (YS) and Dr Michael Francki (SNB) (project leaders), Dorthe Jorgensen, Donna Foster, Hossein Golzar, Esther Walker, Chris McMullan, George Moore Wheat diseases yellow spot (YS) and stagonospora nodorum blotch (SNB) frequently occur together and present important resistance breeding targets. Nationally, they can cause annual losses of up to $676 million (YS) and $230 million (SNB). Dr Manisha Shankar and Dr Michael Francki are leading national projects on YS and SNB, respectively. Their research focuses on understanding the genetic control and deployment of YS and SNB disease resistance in wheat that is suited to Australian production environments. Project outputs will deliver new germplasm, associated DNA markers to track resistance genes and associated genetic knowledge for adoption by commercial breeders to improve resistance. Yellow spot Achievements in combating YS were made across several facets of research through the national collaboration including:
Current research is focusing on elucidating the effects of individual resistance genes and gene combinations, evaluating effective resistance in multi-location and multiyear national trials, and developing resistance gene combination stocks in wheat relevant to northern, southern and western regions. Stagonospora nodorum blotch Significant progress has been made in SNB research to ascertain the genetic control of foliar and glume SNB resistance from different wheat origins and identification of DNA markers linked to genes. Single and combined genes are being deployed in Australian wheat varieties and evaluated for SNB response in WA production environments. Global wheat accessions are being evaluated to identify alternative genes for further improvement to SNB resistance. The project will deliver genetic products that enable commercial breeding companies to efficiently develop new varieties expressing improvements in SNB resistance. Grain growing will remain profitable when new wheat varieties are grown in paddocks under disease pressure. HIGHLIGHTS
Funding and collaboratorsGRDC, UA, USQ, DEDJTR, CCDM, MU, TIA 
DAFWA Research Officer Dr Michael Francki evaluates Stagonospora nodorum resistance at the Northam site Managed Environment Facilities (MEF) enable putting the (index) finger on drought performance of wheat varietiesScience team: Dr Bob French (project leader). Dr Ben Biddulph, Mike Baker, Dr Rebecca O’Leary, Glenn McDonald, Shahajahan Miyan, Michelle Murfit, Celia du Plessis Drought is an ever-present constraint to wheat production in Australia. It is of particular concern in WA because so much of our wheat is produced in low rainfall areas and because of projected rainfall declines under most climate change scenarios. Improving drought tolerance of wheat varieties is therefore an important priority for plant breeders. Equally important is for growers to know relative rankings of available varieties for water-stressed conditions. Our managed environment facilities (MEFs) provide researchers with the required flexibility to create a range of seasons within the same year so that germplasm can be compared for inherited drought tolerance and relevant associated traits (phenotyping). Research compared growth and yield of varieties currently in National Variety Trials and some advanced breeder’s lines at DAFWA’s Merredin MEF and two MEFs in New South Wales. Trials at each site were grown in two environments, one with natural rainfall and the other with supplementary irrigation applied after flowering. Crop modelling was used to carefully choose the amount and timing of this irrigation to mimic a realistic but wetter season for that location. A drought index was calculated for each variety in each season/location combination as the positive or negative deviation from the regression between irrigated and rain-fed yields (Figure 1). Figure . Grain yield with supplemented spring irrigation plotted against rainfed yield at Managed Environment Facility at Merredin in 2014 Like other quantitative traits, drought index also varies with seasons. In order to understand this and to enable breeding suitable varieties for the range of production environments in WA, we have analysed the relationships between drought index and crop traits, such as biomass production, harvest index, grain number and so on to determine which are important in different types of production environments. This information will help growers choose the most adapted varieties for their environment and help plant breeders decide which traits are most worth focusing on.
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