Post on 07-May-2015
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Challenges, Progress & State-of-art in Breeding for Iron/Zinc
First Global Conference on BiofortificationNovember 9-11, 2010, Washington, DC
Merideth BonierbaleInternational Potato Center
Wolfgang Pfeiffer HarvestPlus
HarvestPlus Crop Leaders
3.5 billion people in the developing world are Fe deficient Women and children are most affected
Micronutrient Deficiencies ”Hidden Hunger”
http://www.micronutrient.org
Prevalence of IDA among children <5 years old• Maternal mortality
• Impaired mental development & capacity for labor
• Growth failure• Susceptibility to
infections
Outline
• Genetic Variation in Crop Gene pools
• Setting Breeding Targets• Genetic Gains Achieved• Molecular and Biotechnologies• Product Delivery• Research Needs
Genetic Variation in Crop Gene pools:Varieties, Landraces,
Breeding Populations, Wild Relatives
Qualitative (HPLC)
Semi-Quantitative
NIRS
XRF Bench-topHand-held
Colorimetric
Image-Analyzer
Near-InfraredReflectance
Spectroscopy
X-Ray
Year 20102005
Samplesday-1
1000
500
$US Costsample-1
0.25
1.00(0.5 - 3.0)
• High-throughput• Fast & economical• No contamination
> 305-10
e.g. Worldwide NIRS Quality Network for Sweetpotato (and other crops)
Progress: Fe Variation Discovered in Germplasm of 8 Staple Crops (ppm DW)
Wheat
Sweetpotato
Rice_unpolish
Rice_polish
Potato_Native
Potato_Adv
Maize
Cassava
6050403020100
Wheat
Sweetpotato
Rice_unpolish
Rice_polish
Potato_Native
Potato_Adv
Maize
Cassava
1501401301201101009080706050403020100
Beans
Pearl millet
Wheat
Sweetpotato
Rice_unpolish
Rice_polish
Potato_Native
Potato_Adv
Maize
Cassava
Beans
1101009080706050403020100
Pearl millet
Progress: Zn Variation Discovered in Germplasm of 8 Staple Crops (ppm DW)
BeansPearl MilletPolished_RicePotato_AdvPotato_NativeSweetpotatoUnpolished_RiceWheat
Fe vs Zn
Ord Crops N Correlation Coefficients
1 Pearl Millet 79 0.86
2 Sweetpotato 89 0.85
3 Unpolished_Rice 110 0.79
4 Wheat 176 0.64
5 Beans 215 0.63
6 Potato_Native 604 0.52
7 Polished_Rice 123 0.41
8 Potato_Adv 310 0.31
FEDW
ZnDW
160140120100806040200
120
100
80
60
40
20
0
Positive correlation between Fe & Zn allows simultaneous improvement for both
The amount of Fe or Zn required in a biofortified crop for significant impact on nutritional status
Breeding Target
• ‘Baseline’ = amount obtained from varieties consumed bytarget population
+• ‘Increment’ = amount to be added by
breeding
=
Consumption level (g/day)
Increment of nutrient required for health impact
Concentration of nutrient in the
crop as consumed (after storage, milling &
cooking )
Bioavailability of nutrient in
the diet
Target Nutrient
Content of Staple Foods
Influencial Factors
Primary Sources of Food for Populations at Risk of Malnutrition
Intak
e in g
rams
genYa
msPo
tato
Cassa
vaOFS
P
Cowpe
aLe
ntil
Bean
Maize
WheatRice
Pearl
Mil le
tBa
rley
Sorgh
um
500
400
300
200
100
0
Grains(100% DM)
Legumes(100% DM)
Roots (33% DM)
Tubers(25-33% DM)
Intak
e in g
rams
genYa
msPo
tato
Cassa
vaOFS
P
Cowpe
aLe
ntil
Bean
Maize
WheatRice
Pearl
Mil le
tBa
rley
Sorgh
um
500
400
300
200
100
0
Grains(100% DM)
Legumes(100% DM)
Roots (33% DM)
Tubers(25-33% DM)
Consumption Levels of 13 Staple Food Crops
(DW) (DW) (FW) (FW)
Targeting Food & Production Systems
High Zn Wheat Targets in India
ME1: Temperate Irrigated High Production
ME5: Irrigated High Temperate Stress
42
38
46
36
22
19
12
11
12
14
9
8
6
4
9
8
4
2
3
2
4
7
5
18
0 10 20 30 40 50 60 70 80 90 100
Women
Children
Women
Children
Ab
un
dan
ce
Sca
rcit
y
Cereals Potato Vegetables and fruitsPulses Noodles Food fron social programsBread and cookies Sugars Meat and chickenOther
Dietary Sources of Fe in Huancavelica, Peru
0
20
40
60
80
100
120
140
Pearl Millet Bean Bean Rice Rice Maiz Maiz Wheat Wheat Potato Sweetpotato
Fe Fe Zn Fe Zn Fe Zn Fe Zn Fe Fe
ppm
Baseline & Target Levels for 7 Crops
8
44
88
32
64
8
11
22 22
Non-BiofortifiedAvg. Baseline
BreedingTarget
Genetic Variation Discovered
30 TargetIncrement
Breeding Focus by Crop and Micronutrient
HarvestPlus investment level I. Zn Rice, Zn WheatII. Fe Pearl Millet, Fe BeanIII. Fe Potato, Fe Sorghum,
Fe Lentil. Zn Maize – initially
HarvestPlus, then AgroSalud
Fe & Zn Sweetpotato in SASHA
Fe (ppm)
P (ppm)
Rice polished
MaizeWheat
Bean
Cassava
Potato
Lentil
Pearl Millet
Yams
Phytate: Inhibitor of Fe Absorption
5%
SweetPotato10%
Iron Bioavailability in Landrace Potatoes
0
10
20
30
40
50
60
704393 703168 705543 702464 700234 700787 701997 703274 703488Caco
2 c
ells
ferr
itin
form
atio
n (n
g fe
rriti
n / m
g pr
otei
n)
Caco-2 Cell Ferritin Formation
USDA/SRS & CIP
0,0
5,0
10,0
15,0
20,0
25,0
30,0
15,5 23,3 31,1 38,8 46,6 54,4 62,1 69,9 77,7 85,4 93,2
mg Ac Ascorbico/ 100g DW
Porc
etaj
e de
pob
laci
ón
Base Population
k = 5%
Progeny of selected individuals
mg Vitamin C/ 100g
Perc
ent
Genetic Gains from SelectionGs = k * δp * H2
Selection Intensity
HeritabilityGenetic Variation
Non-negotiable Core Traits
Product Attributes - Breeding Objectives
Fe Zn
FV N=89
PBFN=64
FV N=89
PBFN=64
Genetic Gains for Fe and Zn in OFSPAfrican farmers’ varieties (FV) vs. Pre-breeding families (PBF
(ppm
in d
ry m
atte
r)
Cycle 1 Families: Source of superior clones
Selected genotypes with high micronutrient concentration
Fe (
mg/
kg)
32.0
31.0
30.0
29.0
28.0
27.0
26.0
25.0
24.0
23.0
22.0
21.0
20.0
19.0
18.0
17.0
16.5
16.0
15.0
14.0
12.5
12.0
11.09.0
8.0
7.0
6.0
5.0
4.0
3.0
2.0
1.0
45
40
35
30
25
20
15
10
5
Boxplot Ranges of Fe (mg/kg) in diploid potato families (NCD-II)
Base line(17.5 mg/kg
Biotechnologies
– Reduce time and cost to meet breeding goals
– Exceed levels feasible by conventional breeding
Identification of genes affecting variation in Fe & Zn in Bean by QTL analysis
• Overlapping Fe and Zn QTL suggest common transcriptional control of uptake
• Identification of allelic variation for FRO to facilitate transfer of high mineral traits among genepools and varieties
Blair et al., 2010
Promoter Genomic Wheat Ferritin clone
1DX5 Glutenin Nos
AB
C
• Introduce extra copies of the most active wheat allele of the TaFer1 gene into wheat.
• Biolistic transformation using glutenine1Dx5 promoter to drive endosperm specific expression.
Transgenic WT- Bob white
Prussian blue stain
Targeting Ferritin to the Wheat Endosperm
Exon Intron
(Aarhus University/Denmark)
Research Agreements & Contracts with 7 Private Companies - # will increase
• GxE Performance Testing
• Joint Development of Fe/Zn-denseHybrids (private NARS) & OPVs (public NARS) by Consortium PartnersPartners in Deployment
Variation for Fe in Inbred lines & Hybrids
Product Delivery: Case of Pearl Millet
Breeding cycles
Iron
(ppm
)
2005 2007 2009 2011
50
65
80
100
Lines in release process
Families in pipeline
2010
Baseline
Target
Incremental gains toward breeding goal for Fe in Bean
Wolfgang H PFEIFFER
Product Development & Release Schedule
What Do We Have in Hand to Succeed in Biofortification ?
Micronutrient-enrichment traits are available within the genomes of staple food crops.
Target levels have been defined. Breeding schemes established. First-ever genetic gains for mineral traits
realized Mainstreamed into adapted populations. Product pipelines defined. Partners engaged Early-stage efficacy trials: looking good!