plant breeding

Breeders and researchers unite to accelerate variety advances

Overview

Wheat variety development has been given an important boost through a new research hub that pairs three universities with three breeding companies to advance and potentially speed-up new trait discoveries. The hub pulls together advanced pre-breeding technology and fosters its utilisation by commercial breeding programs.

Included is technology that can rapidly screen a vast amount of biodiversity for traits that can potentially improve crop resilience, grain quality and yield.

First among the traits to be targeted by the hub is tolerance to the combined stress of heat and drought. This work is underway at the ARC Industrial Transformation Research Hub for Wheat in a Hot and Dry Climate, a five-year program that is co-funded by the Australian Research Council and the Grains Research & Development Corporation (GRDC). It is headed by Dr Delphine Fleury at the University of Adelaide’s Waite campus. Participant breeding companies LongReach, Australian Grain Technologies and InterGrain are running the field trials associated with typing and screening novel germplasm.

“We are seeing the most progress in the drone program,” Dr Fleury says. “This uses imaging technology to robotically screen plants and algorithms to convert plant growth data to physiological and genetic information. Collaboration between Uni SA, the Australian Plant Phenomics Facility (University of Adelaide Waite Campus) and breeders within the hub has vastly improved the image-processing algorithms, which expands the range of this technology and its capability.”

“With breeding companies running the field trials, breeders also have the opportunity to observe the plants and pick material of interest to them to progress further,” Dr Fleury says. “In the meantime, pre-breeding researchers can phenotype the material and
map genes of interest.”

To further advance heat and drought-tolerance research, 350 lines representing worldwide diversity of spring wheat are also being studied within a heat chamber, where it is possible to apply heat and drought stress at specific stages of the plant’s development.

Read the full article, by Dr Gio Braidotti, in the latest issue of GroundCover here.

To find out how technology at the Australian Plant Phenomics Facility can support your plant research, contact us.

Bumper funding to enhance national infrastructure and grains research

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Dean of the Waite Mike Keller, GRDC Managing Director Steve Jefferies, and GRDC Chairman John Woods in a greenhouse with DroughtSpotter system at the APPF’s Adelaide node.

 

National infrastructure at the Australian Plant Phenomics Facility’s (APPF) node at the University of Adelaide Waite Precinct will be enhanced as part of a $1.1 million grant announced by the Grains Research and Development Corporation (GRDC) today.

Deputy Prime Minister and Minister for Agriculture and Water Resources, Barnaby Joyce, said the funding was another important measure supporting the productivity and profitability of Australia’s grain industries through the development of more drought-resistant crops.

Almost $1 million will be invested at the APPF to build a specialised heat and drought phenotyping facility consisting of two new controlled environment rooms (CERs) fitted with LED lighting and gravimetric watering (DroughtSpotter system), and add further LED lighting in the facility’s greenhouses. The specially fitted CERs are the first of their kind in Australia, and will boost research into improving stress tolerant crops.

GRDC Chairman John Woods said the GRDC Grains R&D Infrastructure Grant was part of $15 million the GRDC Board had agreed to invest in key infrastructure, in a strategy to build national research capacity and to create enduring profitability for grain growers.

A co-contribution from the University of Adelaide supported the GRDC grant which will also add a polytunnel and birdproof enclosure to the Waite Precinct, expanding grains research capabilities.

These investments are expected to improve trait selection and increase trait delivery to breeders, facilitate simultaneous drought and heat experiments, expand bulking and selection capacity, reduce research costs and improve energy use efficiency.

For more information, visit grdc.com.au and the APPF.


What are CERs? CERs enable plants to be grown within precise temperature, light, humidity and other environmental parameters.

What is the DroughtSpotter system? DroughtSpotter is a fully automated gravimetric platform that was made to assess the transpiration dynamics of plants with a precision of up to 1 g. The integrated irrigation units allow precise and reproducible water application for drought stress or related experiments requiring accurate control of water volume to 1 ml.

Collaborating for the common good: CIMMYT and CSIRO meet to capitalise on strengths

Plant scientists around the world share a common goal:  understanding plants to improve their tolerance of environmental stresses, resist disease and ultimately, increase yield. Global collaborations that share knowledge and technology are rich in experience and are essential to help accelerate our understanding to meet future challenges.

A recent meeting in El Batán, Mexico, is an excellent example of great minds coming together. Three team members from the Australian Plant Phenomics Facility joined host institution, CSIRO, and CIMMYT in a two-day workshop aimed at achieving critical steps towards a common framework for field phenotyping techniques, data interoperability and sharing experience.

CSIRO at CIMMYT

Front row:  Warren Creemers (4th from left), Xavier Sirault (5th) and Michael Schaefer (7th)

“Capitalising on our respective strengths, we developed basic concepts for several collaborations in physiology and breeding, and will follow up within ongoing projects and through pursuit of new funding,” said Matthew Reynolds, CIMMYT wheat physiologist, signaling the following:

  • Comparison of technologies to estimate key crop traits, including GreenSeeker and hyperspectral images, IR thermometry, digital imagery and LiDAR approaches, while testing and validating prediction of phenotypic traits using UAV (drone) imagery.
  • Study of major differences between spike and leaf photosynthesis, and attempts to standardise gas exchange between field and controlled environments.
  • Work with breeders to screen advanced lines for photosynthetic traits in breeding nurseries, including proof of concept to link higher photosynthetic efficiency/performance to biomass accumulation.
  • Validation/testing of wheat simulation model for efficient use of radiation.
  • Evaluation of opportunities to provide environment characterisation of phenotyping platforms, including systematic field/soil mapping to help design plot and treatment layouts, considering bioassays from aerial images as well as soil characteristics such as pH, salinity, and others.
  • Testing the heritability of phenotypic expression from parents to their higher-yielding progeny in both Mexico and Australia.
  • Extraction of new remote sensed traits (e.g., number of heads per plot) from aerial images by machine learning (ML) of scored traits by breeders and use of ML to teach those to the algorithm.
  • Demonstrating a semantic data framework’s use in identifying specific genotypes for strategic crossing, based on phenotypes.
  • Exchanging suitable data sets to test the interoperability of available data management tools, focusing on the suitability of the Phenomics Ontology Driven Data (PODD) platform for phenotypic data exchanges, integration, and retrieval.

CSIRO and CIMMYT share a long history in crop modelling and physiology, spanning more than 40 years. CIMMYT works throughout the developing world to improve livelihoods and foster more productive, sustainable maize and wheat farming. The centre’s portfolio squarely targets critical challenges, including food insecurity and malnutrition, climate change and environmental degradation. Through collaborative research, partnerships, and training, the centre helps to build and strengthen a new generation of national agricultural research and extension services in maize- and wheat-growing nations. As a member of the CGIAR System composed of 15 agricultural research centres, CIMMYT leads the CGIAR Research Programs on Maize and Wheat, which align and add value to the efforts of more than 500 partners.

 

International consortia tackle the global challenge to increase wheat yields at the APPF

Field of ripe wheat

Two international consortia of scientists from the United States, Great Britain, Mexico and Australia are currently carrying out research projects of global importance at the Australian Plant Phenomics Facility’s (APPF) Adelaide node for the International Wheat Yield Partnership (IWYP).

The first research project, Improving Yield by Optimising Energy Use Efficiency, is phenotyping an Excalibur x Kukri RIL population to determine genetics controlling energy use efficiency (EUE) in wheat. The aim is to identify genetic loci and markers to enable breeding of high-yielding germplasm with:

  • low rates of leaf respiratory CO2 released per unit growth,
  • optimised levels of sugars, organic and amino acids for growth, and
  • increased biomass at anthesis.

More than 85-90% of the energy captured by plants is used in high-cost cellular processes, such as transport of nutrients and respiration, meaning about only 10-15% is allocated to yield. Thus, any small gain in energy redistribution and use for a costly process can have a marked positive impact on biomass accumulation and yield.

Improvements in EUE can be achieved at the cell, tissue and whole-plant level, with respiration being a prime target.

“Our initial screening of 138 Australian commercial cultivars revealed a two-fold variation in rates of leaf respiration, three-fold variation in the ratio of respiration to growth rate during early development, and significant heritability of 35%. This demonstrates there is untapped genetic variation in EUE amenable to fine-tuning and optimisation of biomass accumulation in the lead-up to anthesis, with concomitant positive knock-on effects on yield”, said Australian National University’s Barry Pogson, Project Lead and Director of the ARC Centre of Excellence in Plant Energy Biology (AUS).

The project has partners at University of Western Australia (AUS), CIMMYT (MEX) and  the University of Adelaide (AUS).

The second research project, AVP1, PSTOL1 and NAS – Three High-Value Genes for Higher Wheat Yield, aims to enhance wheat yield by exploiting and building synergy of three high value genes (AVP1, PSTOL1 and NAS) and enabling molecular breeding by:

  • developing two-gene and three-gene pyramiding combinations of AVP1, PSTOL1 and NAS using available transgenic wheat lines and quantifying the additive effects on yield in multi-location field and greenhouse trials (as a proof of concept),
  • identifying wheat orthologs and allelic variants of TaAVP1, TaPSTOL1 and TaNAS, and designing molecular markers to the best alleles for marker-assisted breeding,
  • providing basic understanding of the physiological and molecular mechanisms behind improved yield and selecting wheat lines with the best allelic combination and field performance, and
  • assessing the necessity for using genome editing technologies to optimise gene function and enhance positive effect on wheat yield by modifying expression of the wheat alleles.

The genes Vacuolar Proton Pyrophosphatase 1 (AVP1), Phosphorus Starvation Tolerance 1 (PSTOL1) and Nicotianamine Synthase (NAS) have been shown to improve plant biomass production and grain yield. Over-expression of these genes results in improved biomass production and grain yield in a range of plant species, including cereals (rice, barley, wheat), in optimal growing conditions. The enhanced yield of the plants is believed to be due to improved sugar transport from source to sinks (AVP1), enhanced root growth and nutrient uptake (AVP1, PSTOL1) and increase in shoot biomass and tiller number (AVP1, PSTOL1, NAS2).

“Identifying and pyramiding the wheat orthologues of these high-value genes provides a real opportunity to produce wheat with significantly improved field performance and higher grain yield,” said Project Lead, Stuart Roy, from the University of Adelaide (AUS).

The project has partners at University of Melbourne (AUS), Arizona State University (USA), Cornell University (USA), University of California, Riverside (USA) and Rothamsted Research (GBR).

These extensive projects will continue throughout 2017 and into 2018.

 

Why is this research so important?

Wheat is the most widely grown of any crop globally, providing 20% of daily calories and protein. By 2050 wheat demand is expected to increase by 60%. To meet this demand, annual potential wheat yield increases must effectively double – an exceptional challenge.

In November 2012, funding agencies and organisations from the G20 countries agreed to work together and formed the global Wheat Initiative to develop a strategic approach to supporting research that would lead to dramatically increasing the genetic yield potential of wheat.

An essential pillar of this strategy is the International Wheat Yield Partnership (IWYP), a novel collaborative approach, enabling the best scientific teams from across the globe to work together in an integrated program to address the challenge of raising the genetic yield potential of wheat by up to 50% in the next two decades all over the world. IWYP builds on the initial research concepts of the Wheat Yield Consortium established by CIMMYT.

To deliver increased wheat yield, a combination of fundamental bioscience and applied research will be needed. IWYP will deliver this through a focused program of research to develop new knowledge, models and wheat lines suited to multiple environments ensuring global gains in wheat yields are achieved.

IWYP will target six key research scope areas:

  • uncovering genetic variation that creates the differences in carbon fixation and partitioning between wheat lines,
  • harnessing genes from wheat and other species through genetic modification to boost carbon capture and fixation to increase biomass production,
  • optimising wheat development and growth to improve grain yields and harvest index,
  • developing elite wheat lines for use in other breeding programs,
  • building on discoveries in wheat relatives and other species, and
  • fostering breakthrough technology development that can transform wheat breeding.

The “IWYP Science Program” provides a unique plan to generate new discoveries and provides for their rapid incorporation into wheat crops grown throughout the world. IWYP’s overarching aims are to stimulate new research, amplify the output from existing programs and make scientific discoveries available to farmers in developing and developed nations.

 

The Australian Plant Phenomics Facility

The APPF provides state-of-the-art phenotyping tools and expertise to help academic and commercial plant scientists from Australia and around the world understand and relate the performance of plants to their genetic make-up. Research facilitated at the APPF is leading to the development of new and improved crops, more sustainable agricultural practices, improved maintenance and regeneration of biodiversity in the face of declining arable land area and the challenges of climate change. Our services.

Do you need access to plant phenotyping capabilities? The PIEPS scheme can help!

Do you have an exceptional plant science research project destined to deliver high impact outcomes for agriculture? The Phenomics Infrastructure for Excellence in Plant Science (PIEPS) scheme was announced in May and is open to all publicly funded researchers. Emphasis is placed on novel collaborations that bring together scientists preferably from different disciplines (e.g. plant physiology, computer science, engineering, biometry, quantitative genetics, molecular biology, chemistry, physics) and from different organisations, within Australia or internationally, to focus on problems in plant science.

The PIEPS scheme involves access to phenotyping capabilities at the Australian Plant Phenomics Facility (APPF) at a reduced cost to facilitate exceptional research projects. Researchers will work in partnership with the APPF to determine experimental design and optimal use of the equipment. Our team includes experts in agriculture, plant physiology, biotechnology, genetics, horticulture, image and data analysis, mechatronic engineering, computer science, software engineering, mathematics and statistics.

Applications are assessed in consultation with the APPF’s independent Scientific Advisory Board. Selection is based on merit.

Don’t miss this an outstanding opportunity to gain access to invaluable expertise and cutting edge technology to accelerate your research project and make a real impact in plant science discovery.

Applications close:  30 September 2017

For more information and to applyAPPF Phenomics Infrastructure for Excellence in Plant Science (PIEPS).

To find out how the APPF can support your research, contact us.

Learn more about projects at the Australian Plant Phenomics Facility and keep in touch.

 

 

Growing rice faster – uncovering the triggers behind early canopy closure

By combining high-resolution image-based phenotyping with functional mapping and genome prediction, a new study has provided insights into the complex genetic architecture and molecular mechanisms underlying early shoot growth dynamics in rice.

The more rapidly leaves of a plant emerge and create canopy closure, the more successful the plant, in establishment, resource acquisition and ultimately yield. An early vigor trait is particularly important in aerobic rice environments, which are highly susceptible to water deficits. The timing of developmental ‘triggers’ or switches that initiate tiller formation and rapid exponential growth are a critical component of this trait, however, searching for the switch that initiates this growth has proven challenging due to the complex genetic basis and large genotype-by-environment effect, and the difficulty in accurately measuring shoot growth for large populations.

“The availability of large, automated phenotyping platforms, such as those at Australian Plant Phenomics Facility (APPF), allow plants to be non-destructively phenotyped throughout the lifecycle in a controlled environment, and provide high resolution temporal data that can be used to examine these important developmental switches,” said PhD student, Malachy Campbell.

Malachy and team, including Bettina Berger and Chris Brien from the APPF, phenotyped a panel of ~360 diverse rice accessions throughout the vegetative stage (11-44 day old plants) at The Plant Accelerator® at APPF. A mathematical equation was used to describe temporal growth trajectories of each accession. Regions of the genome that may regulate early vigor were inferred using genome-wide association (GWA) mapping. However, many loci with small effects on shoot growth trajectories were identified, indicating that many genes contribute to this trait. GWA, together with RNA sequencing identified a gibberellic acid (GA) catabolic gene, OsGA2ox7, which could be influencing GA levels to regulate vigor in the early tillering stage.

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Dr Malachy Campell in The Plant Accelerator® at the Australian Plant Phenomics Facility’s Adelaide node

For some traits where genetic variation is controlled by a small number of loci, breeders can use MAS to identify individuals carrying the favourable locus/loci for the given trait, and select them for the next generation. For complex traits that are regulated by many loci, it becomes very difficult to detect loci that are associated with the trait. However, an alternative approach, genomic selection (GS), considers the total genetic contribution of all loci to the given trait. With this approach, loci across the genome can be used to predict the performance of individuals that have not yet been phenotyped (i.e. those in future generations). Since many loci were found to be contributing to early vigor, the team explored the possibility of using GS for improving this trait. Shoot growth trajectories could be predicted with reasonable accuracy, with greater accuracies being achieved when a higher number of markers were used. These results suggest that GS may be an effective strategy for improving shoot growth dynamics during the vegetative growth stage in rice. The approach of combining high-resolution image-based phenotyping, functional mapping and genome prediction could be widely applicable for complex traits across numerous crop species.

Read the full paper, published in The Plant Genome, here. (doi:10.3835/plantgenome2016.07.0064).

This is your chance! An invaluable opportunity to access phenotyping capabilities to further your plant science research

Do you have an exceptional plant science research project destined to deliver high impact outcomes for Australian agriculture? Do you need access to plant phenotyping capabilities?

The Phenomics Infrastructure for Excellence in Plant Science (PIEPS) scheme was announced in May and is open to all publicly funded researchers. Emphasis is placed on novel collaborations that bring together scientists preferably from different disciplines (e.g. plant physiology, computer science, engineering, biometry, quantitative genetics, molecular biology, chemistry, physics) and from different organisations, within Australia or internationally, to focus on problems in plant science.

The PIEPS scheme involves access to phenotyping capabilities at the Australian Plant Phenomics Facility (APPF) at a reduced cost to facilitate exceptional research projects. Researchers will work in partnership with the APPF to determine experimental design and optimal use of the equipment. Our team includes experts in agriculture, plant physiology, biotechnology, genetics, horticulture, image and data analysis, mechatronic engineering, computer science, software engineering, mathematics and statistics.

Applications are assessed in consultation with the APPF’s independent Scientific Advisory Board. Selection is based on merit.

Don’t miss this an outstanding opportunity to gain access to invaluable expertise and cutting edge technology to accelerate your research project and make a real impact in plant science discovery.

Applications close:  30 September 2017

For more information and to apply:  APPF Phenomics Infrastructure for Excellence in Plant Science (PIEPS)

To find out how we can support your research, contact us.

Supporting the agricultural industry through R&D to deliver successful new products to market

Developing and bringing new agricultural products to market can be costly and time consuming for industry. Nufarm Limited recently sought the technology and expertise of the Australian Plant Phenomics Facility (APPF) to provide independent testing on potential new foliar sprays under development.

“The full service approach at the APPF, from the technology to the specialist staff, really appealed to us”, said Chad Sayer from Nufarm’s Product Strategy Group.

“The non-destructive, high-throughput phenotyping technology at the APPF gave us the ability to gain insights into our products under development that we could not achieve anywhere else. Their highly skilled, specialist team helped us design our experiments and provided invaluable advice throughout the project, right through to the data analysis.

“This has been exciting for us. Our pilot project delivered such promising results, we already have a large project underway”.

Nufarm wheat 000335

(L) Plants undergoing spray treatment.  (R) Daily observation and analysis by the horticultural team

“We have a bespoke approach, working closely with our customers to design their experiments to deliver the best results”, said Dr Bettina Berger, Scientific Director at the Adelaide node of the APPF.

Dr Berger and her colleagues provide consultation on all projects carried out at the Adelaide node, supporting the development of the initial design and execution of the research. The specialist horticultural team set up the experiments and manage them through to completion. Customers can make use of online monitoring and access of projects throughout the experiment stage via Zegami (‘live processing’ which allows result checking on a day-to-day basis). On completion of experiments image analysis and data analysis are handled by our skilled engineering, software and statistics team. The research team then provide consultation on results and further follow-up as required.

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Plants in a Smarthouse at the Adelaide node of the APPF undergo daily image analysis throughout the experiment

The APPF is available to all publicly or commercially funded researchers. For further information or to discuss how we can support your research, please visit the APPF website for contact details. For more information about this project, contact Dr Berger.

Nufarm Limited is an Australian company. It is one of the world’s leading crop protection and specialist seeds companies, producing products to help farmers protect their crops against damage caused by weeds, pests and disease. With operations based in Australia, New Zealand, Asia, Europe and the Americas, Nufarm sells products in more than 100 countries around the world. Find out more about Nufarm here.

Zegami is a web application which allows users to filter, sort and chart data from experiments undertaken in the Smarthouses at the APPF Adelaide node, with the unique feature of being able to group that data with the corresponding images. To get a real feel for the application, we highly recommend you watch the video. Further reading here.