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Selection for a high mean. Success is a function ofthe population mean ?the deviation of the best segregants from ?ability to identify the best segregantsAdvanced Cycle Breeding = inbred recycling"cross best by best (often related)pedigree and backcross selectionemphasis on high mean at the
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2. Selection for a high mean Success is a function of
the population mean ?
the deviation of the best segregants from ?
ability to identify the best segregants
Advanced Cycle Breeding = inbred recycling
cross best by best (often related)
pedigree and backcross selection
emphasis on high mean at the expense of ?G2
need methods for predicting ?
3. Probability of fixing favorable alleles during inbreeding Three approaches to increase chances of fixing favorable alleles
selection before inbreeding
selection during inbreeding
one or more backcrosses to the better parent before inbreeding
4. Mean with selfing Inbreeding decreases the mean if there is dominance
At fixation (with no selection):
5. Mean of recombinant inbreds from a single-cross Mean of recombinant inbreds derived from F2 of a single-cross
6. Selfed families from a single-cross
7. Selfed families from a single-cross
8. Variance among and within selfed families
9. Genetic variance with selfing
10. Testcrosses The choice of tester will determine if an allele is favorable or not
11. Effect of alleles in testcrosses
12. Testcross mean of recombinant inbreds Testcross mean of recombinant inbreds derived from F2 of a single-cross
13. Testcross means Testcross mean of the heterozygote is half-way between the two homozygotes
Cross good by good
But, the correlation between the performance of inbred lines per se and their performance in testcrosses is very poor for yield and some other agronomic traits
14. Heterosis or Hybrid Vigor Quantitative genetics:
superiority over mean of parents
Applied definition
superiority over both parents
economic comparisons need to be made to nonhybrid cultivars
Various types
population cross
single-, three-way, and double-crosses
topcrosses
modified single-cross definition of a modified single-cross
advantages and disadvantages of double-crossesdefinition of a modified single-cross
advantages and disadvantages of double-crosses
15. Heterosis Amount of heterosis due to a single locus = d
50% is lost with random-mating
16. Theories for heterosis Dominance theory: many loci with d ? a
Should be possible to obtain inbred ? single-cross
Expect skewed distribution in F2 (may not be the case if many loci control the trait)
Overdominance theory: d > a
Pseudo-overdominance - decays over time
17. Heterosis some observations Epistasis can also contribute to heterosis
does not require d>0
Experimental evidence suggests that heterosis is largely due to partial or complete dominance
Yields of inbred lines per se are poor predictors of hybrid performance
due to dominance
due to heritability <1
18. Heterotic groups Parents of single-crosses generally come from different heterotic groups
Two complementary heterotic groups are often referred to as a heterotic pattern
19. Identifying heterotic patterns Diallel crosses among populations
Crosses to testers representing known heterotic groups
Use molecular markers to establish genetic relationships, and make diallel crosses among dissimilar groups
initial studies were disappointing
markers must be linked to important QTL
20. Exploiting heterosis Recycle inbreds within heterotic groups
Evaluate testcrosses between heterotic groups
elite inbreds often used as testers
BLUP can predict performance of new single-crosses using data from single-crosses that have already been tested
fairly good correlations between observed and predicted values
21. Predicting hybrid performance
