1. Water use efficiency and barley production on the Canadian Prairies
Dr. Anthony Anyia Senior Scientist & Acting Manager, Bioresource Technologies, Alberta Innovates – Tech Futures
June 23, 2010
Development of barley with improved nitrogen and water use efficiencies
21st BMBRI Triennial Barley Improvement Meeting held in Guelph

2. Challenges of Crop Production on the Prairies –demonstrated through News Releases by CWB
June 11, 2010: Wet weather severely impairs crop prospects across the Prairies
June 11, 2009: Cold spring, dry fields lower 2009 crop prospects in Western Canada
June 12, 2008: Rains help boost 2008 crop estimates, cold spring a concern
June 14, 2007: Wet spring lowers Prairie wheat acres, increases barley
June 10, 2004: Moisture conditions improve across Western Canada but dry pockets remain
June 12, 2003: Improved moisture conditions good news for prairie farmers
August 6, 2003: Hot, dry July plays havoc with crops across the prairies

3. Characteristics of Canadian Prairies
Vegreville AB, April 2007
Short and dry growing season
Insufficient growing season rainfall
Drought and heat stress in summer
Long and cold winter
Spring and fall frost common
Occasional flooding and water logging in spring
Seeding delayed due to water logged field
Fields may be abandoned due to water logged soils or drought
Vegreville AB, 2002, courtesy AAFC

4. Canada is a major producer of barley
Despite the challenges, Canada is a major world producer of barley
Canada is a major producer of barley
Canadian yields are lower than most other leading producers

5. Canadian barley and wheat yields in comparison to yields in China
China: W = 50%; B = 60%
Canada: W = 5%; B = 0%
Source: FAOStat
Severe drought year in Alberta
Breeding progress is masked by genotype by location variation in yield
Low yields can be attributed to poor growing conditions prevalent on the prairies

6. Barley yield depend on both moisture and temperature
Yield (data label = tonnes/ha)
Weather conditions, Vegreville
Low moisture + high temp = very low yield
Good moisture + high temp = below average yield
Good moisture + moderate temp = above average yield

7. Can we further improve yield and yield stability?
Improved management of the cropping systems (Agronomic research still essential)
Genetic improvement (direct vs. indirect selection)
Experience show that targeting of underlying physiological traits that limit yield can contribute to substantial yield improvements (there are only few successful examples)
To be useful, physiological traits should be easy to score and have no yield penalty under favorable conditions
Many breeders are already taking advantage of advances in genomics and genetic mapping in breeding programs (more still need to be done)
Bridging the gap between breeders, physiologists & ‘omics

8. Life-cycle of a typical cereal crop
Phase:
Vegetative
Reproductive
Stages:
Establishment & Growth Foundation for future yield
Pre-Anthesis Formation of yield potential
Post-Anthesis determinant of actual yield
Growth Conditions
Usually good moisture
Moisture is limiting
Drought and heat stress
Adapted from Anyia et al., 2008
Adapted from Anyia et al., 2008

9. Genetic improvement of crops
Can we design new smart varieties that:
Use more of the water supply - Increase water use - Decrease soil evaporation
Early seedling vigour (Leaf area, SLA, LAI)
Better exchange of water for CO2 -Increase water use efficiency
Increase TE (carbon isotope discrimination)
Increase stem reserves (non structural CH2O)
Convert more biomass into grain - Increase harvest index

10. Wheat lines selected for low CID (Rebetzke et al. 2002)

11. Relationship between WUE and CID (Adapted from Anyia et el., 2007)
Well watered
Well watered
Well stressed
Well stressed
Two-row barley
Six-row barley

12. Rank stability of leaf-CID across locations & years
Data from Chen et al. 2010, in-press
Two years
Two-row barley
Two locations
Six-row barley

13. CID & protein distribution of F5 RIL population

14. Discriminant Analyses on Merit x H93174006 RIL population
Variables; DM and Seed Weight and HI
Variables: Protein, DM, and Seed weight
Variables; DM and Seed Weight
Canonical correlations were 0.58 and 0.55 for the first and second canonical discriminate variates, respectively. The first canonical variate accounted for 42% of the variance, whereas the second canonical discriminate accounted for 36% of the variance. Because of the variance attributed to both canonical variates, we conclude that genetic variance was detected by the first and second canonical variates. The loadings on both canonical discriminant functions indicated that lines differed in seed yield and harvest index.
*** Protein had a significant –ve corr with HI

15. Merit x H93174006 RIL population
Summary DArT diversity in a population of 188 RILs and the two parental lines
Wheat DH population
Parent 1
Parent 2
# markers 1
184 6 - 5
221 2
418
Merit x H RIL population
Parent 1
Parent 2
# markers 1
193
254 ?? -
140 ??
146 6 4
743
Canonical correlations were 0.58 and 0.55 for the first and second canonical discriminate variates, respectively. The first canonical variate accounted for 42% of the variance, whereas the second canonical discriminate accounted for 36% of the variance. Because of the variance attributed to both canonical variates, we conclude that genetic variance was detected by the first and second canonical variates. The loadings on both canonical discriminant functions indicated that lines differed in seed yield and harvest index.

16. Relationship between water/nitrogen use efficiencies & protein
We tested the following hypotheses
For the same nitrogen supply, higher levels of soil moisture will lower protein content, whereas drier conditions lead to higher protein content.
When moisture is limiting, water use efficient varieties will improve yield and hence decrease nitrogen concentration leading to lower protein content (implies a negative correlation)

17. The Results of greenhouse studies
Two N levels under WW and WD conditions

18. Correlations amongst WUE, NUE and protein under drought in GH
Two N levels under WD conditions

19. Results of field studies with 7 varieties

20. Conclusions
To maintain/improve on the yield progress already made by our breeders, new tools are needed to target specific traits and growth conditions that limit yield
The new tools must be complementary to existing tools and easy to deploy in existing breeding programs
Although several physiological traits have been proposed, only a few have been successfully used to improve yield
Improvement in one trait can have the unintended consequence of leading to a decline in another

21. Pyramiding of several traits such as WUE and NUE related traits may lead to progress in achieving yield stability
Narrow genetic base of modern varieties may impede progress (new sources of variations are necessary to overcome this)
Advances in genomics and genetic mapping are making it faster and cheaper to combine several polygenetic traits in new varieties
Identifying QTLs and their linked markers will potentially reduce time and cost to make the use of physiological traits more attractive in barley breeding

22. Acknowledgements Collaborators/Institutions: Funding:
Brewing & Malting Barley Res. Institute
Alberta Agricultural Research Institute
Alberta Crop Industry Development Fund
Alberta Barley Commission
Project Staff:
Jing Chen
Ludovic Capo-Chichi
Sharla Eldridge
Collaborators/Institutions:
FCDC Lacombe
Dr. Pat Juskiw
Dr. Joseph Nyachiro
Jennifer Zantinge
University of Alberta
Dr. Scott Chang