IWYP

Next gen chase research break-throughs with unrivalled access to plant phenotyping technology

Our latest round of Postgraduate Internship Award (PIA) students have kicked off their research projects at the Australian Plant Phenomics Facility (APPF)!

All our student interns have the unique opportunity to access the APPF’s cutting-edge phenotyping capabilities at no cost, learning about experimental design, and image and data anaylsis in plant phenomics while undertaking collaborative projects with the highly skilled APPF team. This experience allows our next generation of aspiring plant scientists to explore key research questions, reveal new data and make a real contribution to the global challenge of feeding future generations.

Julian montage test

Yue Qu (Julian) with his soybean plants in an automated, high-throughput plant phenotyping Smarthouse at the Australian Plant Phenomics Facility’s Adelaide node

Yue Qu (Julian)

In his project ‘Investigating novel mechanisms of abiotic stress tolerance in soybean’ Julian seeks to answer two questions, (1) Does GmSALT3, a protein linked to improved salt tolerance, also confer tolerance to drought and oxidative stress in soybean, and (2) Does GmSALT3 improve growth under standard conditions. He will use a non-destructive, high-throughput plant phenotyping Smarthouse, hyperspectral leaf phenotyping, leaf ion content, ROS activity/detoxification of roots, and gas exchange to investigate 8 lines of soybean in combination with 4 treatments (control, drought, 100mM NaCl, 150mM NaCl).

“For my PhD I have been functionally characterising GmSALT3. I have used heterologous expression systems to examine transport activity, as well as phenotyping salt tolerance in the NILs,” said Julian.

However, more recent phenotyping data and RNA-seq analysis has led us to the hypothesis that the salt tolerance phenotype of GmSALT3 plants is a consequence of their improved ability to detoxify reactive oxygen species, and therefore they may be more stress tolerant in general. This is contrary to the prevailing hypothesis that the protein is directly involved in salt transport and directly, rather than indirectly confers salt exclusion. To test this hypothesis we need to properly phenotype the Near Isogenic Lines (NILs). We believe that the phenotyping capabilities of the APPF will give unparalleled insights into the stress tolerance of soybean that would not otherwise be possible. Such a finding will be a significant breakthrough and likely result in a high impact publication when added to our existing data.”

Supervisor, Professor Matthew Gilliham, from the ARC Centre of Excellence in Plant Energy Biology agreed. “The experience the APPF team offer while conducting these experiments will add a great deal to the impact of the papers Julian is preparing and reveal a new layer of complexity that would not be possible without their expertise.”

Daniel montage

Daniel Menadue watches over his wheat plants in a Smarthouse at the Australian Plant Phenomics Facility’s Adelaide node

Daniel Menadue

Daniel is investigating a proton pumping pyrophosphatase (PPase) gene family in wheat and the role these genes play in the wheat plant’s response to environmental stress in and enhancing yield.

Vacuolar pyrophosphatase have been known for a while to be involved in a plant’s adaptation to the environment, however, the majority of the work on these genes has been using the gene from Arabidopsis, AVP1. Daniel’s research has identified the 12 wheat orthologs of AVP1 and from the sequence and expression data he has to date, he hypothesises that different PPases have different roles depending on their protein sequence and tissue localisation. To this end Daniel has generated transgenic bread wheat, cv Fielder, expressing two of the wheat genes (TaVP1-B and TaVP2-B) to further characterise the role of the PPase protein. Excitingly, Daniel has observed a growth phenotype, in the second generation of transgenic plants, with the transgenic plants appearing to grow faster and have larger biomass than wild type or null segregant plants. This is a phenotype previously seen in transgenic barley expressing the Arabidopsis AVP1 gene, plants which went on to show enhanced yield under salinity in the field (Schilling et al. 2014, Plant Biotech J.).

Given the very promising phenotype of these lines, Daniel will dissect this mechanism further using the non-destructive imaging capabilities at the APPF as an ideal platform for such experiments. He will investigate when the transgenic lines exhibit their enhanced growth, dissect whether they grow faster throughout the vegetative period or just for a short while at the start of their growth. He will also investigate the possibilities of following the growth of leaves through time and determine if the plants have enhanced resistance to salinity tolerance.

“In many ways we would like to replicate the study that we did in one of the APPF’s Adelaide Smarthouses which produced the barley data for the Schilling et al. 2014 paper, but in much more detail and using wheat plants with wheat genes,” said supervisor, Dr Stuart Roy from the University of Adelaide’s School of Agriculture, Food and Wine.

“We envision that the data obtained from Daniel’s study will form the basis of at least one research publication and, if the results are promising, open up new areas of research and delivery for bread wheat with altered PPases expression levels through my International Wheat Yield Partnership project, AVP1, PSTOL1 and NAS – Three high-value genes for higher wheat yield.” – shared in our recent blog story ‘International consortia tackle the global challenge to increase wheat yields at the APPF’.

It’s a pleasure to welcome Julian and Daniel to the team!

The next round of Postgraduate Internship Awards at this APPF will close 30 November, 2017 – Apply now!

Internships are offered at the APPF in Adelaide and Canberra for enthusiastic, highly motivated postgraduate students with a real interest in our research and technology. Current postgraduate students in the following areas are encouraged to apply:

  • Agriculture
  • Bioinformatics
  • Biology
  • Biotechnology
  • Computer Science
  • Genetics
  • Mathematics
  • Plant physiology
  • Science
  • Software engineering
  • Statistics

Interstate students are strongly encouraged to apply!

We offer postgraduate internship grants which, in general, comprise:

  • $1,500 maximum towards accommodation in Adelaide or Canberra, if required
  • $500 maximum towards travel / airfare, if required
  • $10,000 maximum toward infrastructure use

The APPF has identified a number of priority research areas, each reflecting a global challenge and the role that advances in plant biology can play in providing a solution:

  • Tolerance to abiotic stress
  • Improving resource use efficiency in plants
  • Statistics and biometry
  • Application of mechatronic engineering to plant phenotyping
  • Application of image analysis techniques to understanding plant form and function

Students proposing other topics will also be considered.

APPF postgraduate internship grants involve access to the facility’s phenotyping capabilities to undertake collaborative projects and to work as an intern with the APPF team to learn about experimental design, image and data analysis in plant phenomics.

Selection is based on merit. Applications are assessed on the basis of academic record, research experience and appropriateness of the proposed research topic. Interviews may be conducted.

Postgraduate students are encouraged to contact APPF staff prior to submitting their application to discuss possible projects.

For more information and to apply click here.

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.