Report puts value on long-term sorghum breeding effort

On-farm impacts of sorghum RD&E spanning 20 years surface from economic analysis


Coarse Grains
Leader of the QAAFI sorghum pre-breeding program, Professor David Jordan from the University of Queensland. PHOTO QAAFI

Leader of the QAAFI sorghum pre-breeding program, Professor David Jordan from the University of Queensland. PHOTO QAAFI

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Cost-benefits of national sorghum breeding effort mainly stem from yield gains.

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Productivity gains made by the Australian sorghum industry are unmatched anywhere else in the world, according to a report by the Queensland Alliance for Agriculture and Food Innovation (QAAFI).

It says genetic material from the publicly-funded national breeding program has, over the past 20 years, been incorporated into every sorghum crop in Australia. This summer crop now encompasses on average 550,000 hectares of Queensland and northern New South Wales.

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University of Queensland's Professor David Jordan, who leads the pre-breeding program at QAAFI, says nearly 3000 sorghum lines have been licensed to the international sorghum industry since 1989.

"In recent years, we've licensed about ten times the amount of plant breeding material than all the other public sorghum breeding programs around the world combined," Professor Jordan says.

He says that underpinning this achievement is the program's emphasis on integrated research drawing on a range of scientific disciplines, such as plant physiology, molecular biology and entomology, as well as the private sector.

Now assessing the on-farm impacts of the sorghum research spanning 20 years is a report that puts a dollar figure on its contribution to the productivity, and ultimately profitability, of the major northern region crop.

In recent years, we've licensed about ten times the amount of plant breeding material than all the other public sorghum breeding programs around the world combined - University of Queensland Professor David Jordan

Professor Jordan says economic analysis of sorghum pre-breeding under five research projects from 1997 to 2017 shows investment over this period, totalling $78.4 million, has delivered a gross gain of $696.5 million to Australian sorghum growers.

He says it has delivered a cost-benefit of $8.90 for every $1 invested by the research funders, which include the GRDC, the Queensland Department of Agriculture and Food (DAF) and later QAAFI, a partnership between DAF and the University of Queensland (UQ).

Professor Jordan says the cost-benefits of the research mainly stem from yield gains, estimated at 2.1 per cent per annum.

This estimate is based on Australian Bureau of Agricultural and Resource Economics and Sciences (ABARES) data showing average sorghum yields increased from about 2 to 3.5 tonnes per hectare between 1996 and 2015.

Bags for collecting seed are attached to about 20,000 hybrid sorghum plants each year as part of pre-breeding trials across Queensland and New South Wales. PHOTO QAAFI

Bags for collecting seed are attached to about 20,000 hybrid sorghum plants each year as part of pre-breeding trials across Queensland and New South Wales. PHOTO QAAFI

However, he says only about 40 per cent of this yield lift is due to sorghum genetics. Agronomic and farming system improvements have also played a major part.

"About half of the genetic gain is due to pre-breeding germplasm improvements," he says.

"The other half is attributed to private sector breeding companies that use germplasm developed through our program to produce new sorghum hybrids.

"Nevertheless, all commercial sorghum hybrids currently on the market contain genetic material from the program."

Professor David Jordan attaches a seed-collecting bag to a sorghum plant. This plant is one of tens of thousands that are hand-pollinated each year through the sorghum pre-breeding program at QAAFI. PHOTO QAAFI

Professor David Jordan attaches a seed-collecting bag to a sorghum plant. This plant is one of tens of thousands that are hand-pollinated each year through the sorghum pre-breeding program at QAAFI. PHOTO QAAFI

Cost-saving traits

Genetic traits that have contributed to the high return on the research investment include insect and disease resistance.

One such trait is genetic resistance to sorghum midge - a mosquito-like fly known to cause total crop failure in susceptible varieties.

DAF senior plant breeder Alan Cruickshank says although development of midge resistance pre-dates the research from 1997 to 2017, emphasis on continual selection for this trait has secured significant, ongoing benefits.

In particular, incorporation of midge resistance into all Australian sorghum varieties has reduced insecticide-spraying costs for northern grain growers, Mr Cruickshank says.

By 2012, less than five per cent of the national crop was sprayed to control midge, compared with 40 per cent of the national crop in the mid-1990s.

The report says this sprayed area is expected to further decline to 2.5 per cent in the 10 years from 2012 to 2021, and then plateau at 2.5 per cent until 2042.

Putting this on-farm cost-benefit into perspective, sorghum generally requires two sprays a year, with an estimated application cost of $13/ha and a chemical cost of $1.70/ha.

"The crop damage that midge resistance prevents in all the hybrid varieties on the market would probably be generating $20 million to $30 million a year," Mr Cruickshank says.

Other traits contributing to the overall increase in sorghum productivity and profitability in the past 20 years are stay-green, which maintains the crop's green leaves and stems when water is limited during grain-filling, and resistance to ergot disease.

Professor David Jordan inspects a sorghum crop containing genetic material from the publicly-funded national breeding program. PHOTO QAAFI

Professor David Jordan inspects a sorghum crop containing genetic material from the publicly-funded national breeding program. PHOTO QAAFI

Professor Jordan says the next steps in the research effort aim to develop a suite of adaptive traits for better root architecture, water use efficiency, heat tolerance and grain quality.

More information: David Jordan, 07 4542 6722, david.jordan@uq.edu.au; Alan Cruickshank, 07 4542 6719, alan.cruickshank.daf.gov.au

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