1. 1
Heterosis

2. 2
Heterosis
“ In my opinion, hybrid corn is the most far reaching development in applied biology in this quarter century” Mangelsdorf, 1951
A plant breeding phenomena that we very successful exploit commercially, the biological basis of which remains poorly understood

3. Defining a locus in terms of scale3
Heterosis ‘d’ > ‘a’
Defining a locus in terms of scale
bb mp BB Bb -a +a d

4. 4
Heterosis
The converse or complement to inbreeding depression in which the value ‘d’ ≥ ‘a’
Inbreeding can result in loss of vigor, size, etc….
The restoration of phenotypic performance by crossing inbred lines to produce a hybrid is called heterosis.

5. 5
History
Fundamentally about the effects of inbreeding and outbreeding
When did man first observe and take advantage of this phenomena?
Is this only a modern “scientific” development?

6. Pre- History 6 Tantalizing anthropological evidence
Religious rituals associated with maintenance of maize lines
Helentjaris year old Anasazi cobs from SW USA observed molecular marker fragment patterns that more closely resembled F1 hybrid than an O.P. variety

7. Modern - History 7 Koelreuter (1766) Darwin (1876) Mendel (1865)
investigated hybrid vigor in Nicotiana, Dianthus, Datura, et. al.
Darwin (1876)
discussed hybrid vigor in his book “The effects of cross and self-fertilization in the vegetable kingdom” He demonstrated that cross fertilization frequently resulted in increased size, vigor and productiveness when compared with self-fertilization. He did not attribute the differences to the uniting of different gametes.
Mendel (1865)
Wrote “ in repeated experiments, stems of 1 foot and 6 feet in length yielded plants with varied in length from 6 to 7.5 ft.”

8. Modern -History 8 Beal - 1880 Shull - (1908-1914)
Described how he planted in alternate rows to stocks of the same variety, one row was detasseled and the hybrid seed was more productive than either parent.
Shull - ( )
Shifted emphasis from the negative effects of inbreeding to the positive effects of hybridization.
Coined the word “heterosis” to describe the increased vigor observed from heterozygosity.

9. Modern -History 9 East - (1908-1909)
Studied the effects of inbreeding and outbreeding
His work led to the formulation of the modern heterosis concept.

10. Yield and types of populations Forest Troyer - 199110
Yield and types of populations Forest Troyer

11. Mating system and heterosis11
Mating system and heterosis
Heterosis has been reported for a wide range of crops including both self and cross pollinated species
Commercial application is via F1 hybrids
Commercialization
Added value > cost of hybrid seed production

12. Estimated percentage of hybrids for selected vegetables12
Estimated percentage of hybrids for selected vegetables
Crop % hybrid Method
Tomato (fresh) Hand
(Processing) Hand
Sweet pepper Hand
Onion CMS
Broccoli S.I.
Snap beans
Lettuce

13. Attributes of F1 hybrids13
Attributes of F1 hybrids
Maximum performance under optimal conditions
Stability of performance under stress
Proprietary control of parents
Often, reduced time to cultivar development
Joint improvement of traits

14. Hybrid cultivars
Hybrid cultivars are first generation offspring after cross between different inbred parent lines
Major steps in breeding
develop inbred homozygous lines
find good F1 combination between inbreds
produce F1 seed in large scale for growers
Hybrids are uniform, reproducible and ”protected” if parents are homozygous.

15. Inbreeding and hybridisation to produce desirable hybrids
YIELD
Parent population
Inbreeding
F1 hybrid population
Inbred line
population
Each hybrid can
be produced large
scale from its two
parental inbreds
Genotypes
cannot be
reproduced
Rare desirable
genotypes

16. Major types of hybrid cultivars
Single cross hybrids (F1)
A x B = F1
Three way hybrids
(A x B) x C = Three Way Hybrid
Double cross (Four way hybrid)
(A x B) x (C x D) = Double Cross
Three way and double cross hybrids are used to
reduce seed costs when parentals are weak

17. Effects of inbreeding Selfing, full/half-sib pollination
Reduced height, seed set,
disease resistance, etc
Increased lodging,
Increased homozygosity

18. Hybrid vigour or heterosis
Heterosis: the increase in size, vigour or productivity of a hybrid plant over the average or mean of its parents.
Midparent heterosis
High parent heterosis
Standard heterosis

19. Measurement of Heterosis19
Measurement of Heterosis
Mid-parent heterosis
Hybrid performance is measured relative to mean of the parents (MP)
(F1 - MP) / MP * 100
High-parent heterosis
Comparison of hybrid to performance of best parent (HP)
(F1 - HP) / HP * 100

20. Real data from dry beans % heterosis above HP20
Real data from dry beans % heterosis above HP
9 x 9 Diallel of bean cultivars, evaluated in two locations
A132 A476 B1222 A359 X122 A457 A231 Toche A375
A476 5 *
B Yield of Toche = 2.38 T/Ha.
A Yield of A476 = T/Ha.
X F1 =
A ( )/ 2.46 *100
A !! Told me that favorable combinations do exist!!
Toche ? How to capture this genetic effect? A

21. Genetic basis of heterosis21
Genetic basis of heterosis
Three possible genetic causes:
Partial to complete dominance
Overdominance
Epistasis
The issue for plant breeders - What is the Ideal genotype?
Partial to complete dominance - Homozygote
Overdominance - Heterozygote

22. Dominance Hypothesis 22 Davenport (1908)
Hybrid vigor is due to action and interaction of favorable dominant alleles
Hypothesizes decreased homozygosity for unfavorable recessive alleles (covering up)
Conversely, inbreeding depression is due to exposure of these recessive alleles during inbreeding

23. Dominance Hypothesis Example23
Dominance Hypothesis Example
Model AA = Aa > aa - AA=10 Aa=10 and aa=0
Parent Parent 2
aaBBccDDee = 20 AAbbCCddEE = 30 F1
AaBbCcDdEe = 50
Also note that AABBCCDDEE = 50

24. Discussion of Dominance hypothesis24
Discussion of Dominance hypothesis
Theoretically, plants homozygous for all favorable alleles could be developed (AABBCCDDEE….)
Why then are there no inbred equal in performance to hybrids??
This was considered a until it was recognized that only 1 in 4n individuals in a population would be homozygous for all loci -
For 10 loci that would be 410 = one plant in a million.

25. Dominance hypothesis Linkage25
Dominance hypothesis Linkage
Recombination among loci could result in plants homozygous for all favorable alleles, but…
Repulsion phase linkages, either slow or preclude the development of such lines
Empirical evidence supports dominance hypothesis, as inbred line are improving in performance.
A b
a B

26. Repulsion phase linkage26
Repulsion phase linkage
In 70’s investigators were interested in the relative magnitude of s2A and s2D
In F2 crosses the ratio of s2D / s2A was >1 indicating large amounts of dominance variance, but once the populations were random mated for several generations the ratio of s2D / s2A was became <1, this was likely due to recombination among repulsion phase loci
A b
a B

27. 27
Overdominance
First proposed by Shull (1908) and late expanded by Hull (1945)
It states that the heterozygote (Aa) at one or more loci is superior to either homozygote (AA or aa)
Model would be Aa > aa or AA
They recognized importance of dominance, but it alone cannot account for observed heterosis.

28. 28
Overdominance
Superiority of heterozygotes may exist at the molecular level, if the products of two alleles have different properties, e.g. heat stability, or advantages at different environments or maturities - thus may result in stability.
But, “single locus heterosis” difficult to observe and detect if populations are not in linkage equilibrium.

29. Pseudo- Overdominance29
Pseudo- Overdominance
In which nearby loci which have alleles that are dominant or partially dominant are in repulsion phase
If the populations are not in linkage equilibrium, this could mimic the effects of overdominance
A b
a B

30. 30
Epistasis
Epistasis - interaction among loci, may also contribute to heterosis
Internode
Generation No. nodes length Height
Parent
Parent
Hybrid ( add)
Hybrid ( Dom)

31. 31
Epistasis
Estimates bases on mating designs to estimate the relative magnitude of add, dom and epistatic components of variance indicate that the magnitude of epistatic variance is small compared to additive and dominance components.
Yet, the magnitude of epistatic variance is difficult to estimate, and may play a very important role in heterosis.

32. Prediction of heterosis32
Prediction of heterosis
The ability to predict heterosis of “Specific combining ability” has been an elusive goal of plant breeders
Combining ability - Testing of hybrids
Diallel crosses n(n-1) / 2
General (GCA) - Average performance - additive effects
Specific (SCA) - ability of lines to combine in specific combinations
Due to dominance effects and heterosis.

33. Genetic distance and heterosis33
Genetic distance and heterosis
Moll (1965) showed a relationship between genetic distance and heterosis for yield in maize
Heterosis
Genetic distance

34. 34
Relationship between genetic distance and heterosis Smith et. Al. TAG 1990
Note, r2 of 0.76

35. Relationships between genetic distance and Heterosis35
Relationships between genetic distance and Heterosis
No relationship

36. Heterosis for yield in self -pollinated vegetables36
Heterosis for yield in self -pollinated vegetables
Crop Mean % Range
Tomato (fresh) to 168
(solids) to 53
Sweet pepper to 52
Eggplant to 242
Beans (dry) to 146
Peas to 218
Lettuce to 119

37. 37
Hybrid Rice in China
Hybrid rice yields about 20% more than the best commercial varieties
8.4 Million Ha. was hybrid in 1988
Based on CMS system
? If you believe the dominance hypothesis, is this the best investment of plant breeding effort?
? What is the ideal genotype in rice?