Title: Stratified sublining
1Stratified sublining
- Dag Lindgren,
- Swedish University of Agricultural Sciences, 901
83 UMEÅ, Sweden. - Seppo Ruotsalainen,
- The Finnish Forest Research Institute, 58450
Punkaharju, Finland. - Matti Haapanen,
- The Finnish Forest Research Institute, 01301
Vantaa, Finland.
Recipe for stratified sublining(Ruotsalainen and
Lindgren 2000)
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3- Rank tested founders for breeding value
- Mate adjacent founders (Single Pair Mating,
Positive Assortative Mating) - Test individual offspring for breeding value
- Select two best tested offspring in each family
- Rank these pairs
- Mate the adjacent offspring pairs (best with best
and second best with second best).
4- Rank tested founders for breeding value
- Mate adjacent founders (Single Pair Mating,
Positive Assortative Mating) - Test individual offspring for breeding value
- Select two best tested offspring in each family
- Rank these pairs
- Mate the adjacent offspring pairs (best with best
and second best with second best).
Now stratified sublines have been formed.
F2-individuals in different sublines are not
related, individuals within sublines are either
full sibs or double first cousins. The sublines
are genetically stratified, the best genotype in
the subline is expected to be better the higher
rank the subline has.
5Now stratified F2-sublines have been formed.
F2-individuals in different sublines are not
related, individuals within sublines are either
full sibs or double first cousins. The sublines
are genetically stratified, the best genotype in
the subline is expected to be better the higher
rank the subline has. Stratified sublining
structures the breeding material according to its
quality, other similar concepts are
- Nucleus breeding
- Elite breeding
- Positive Assortative Mating
- Structuring in tiers
6Why stratified sublining?
- Better seed orchards!!!! The very best clones
selected for seed orchards will be substantially
better!! - One generation ahead stratified lines are
identical to PAM, the added gain to seed orchards
(Rosvall 1999) is 15. - Two generations ahead, compared with assortment
to sublines by random, Ruotsalainen and Lindgren
(2000) found superiority gt15. - Guarantee that good unrelated selections can be
made from the recruitment population.
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8More advantages
- The superiority of the best families and family
forestry will boosted! - The advantage to allocate the families to the
best sites will increase! - The advantage of clonal forestry will be
amplified! - The advantage of the linear deployment technique
(where the better clones are used in higher
proportions) is considerable amplified!
9Advantage amplified if breeding effort dependent
on genetic value
- Such consideration could comprise size of
breeding population per parent. - Size of breeding population could be a matter of
optimisation, not a central parameter for
defining a breeding strategy! - Thus, in the good sublines more selections for
breeding could be done, resulting in more F2
families.
10Carry on more genmass from the best founders and
less from medium (Ruotsalainen and Lindgren 2001)
- It seems possible to improve implementation of
stratified lines. - One remedy may be to let the best gene mass be
present both in high and in low ranking lines,
the latter anyway are less likely to be used for
seed orchards in the near future. - Another remedy is to use more founders to build
the low ranking sublines.
11- Breeding population must be cycled by Single Pair
Mating, that may sometimes be an advantage as the
within family selection intensity is higher! - E.g. Swedish program
- DPM from two families size 10,
- the best is selected, i 1.54.
- SPM from one family size 20,
- the top two are selected, i 1.64.
12Potential advantage of inbreeding in breeding can
be well managed in stratified lines
- Fuller use of the genomes of the best founders
- Widens the variance among lines amplifies
stratification advantage - Inbreeding depression will decrease over the
generations - Selection within the best genomes with reduced
coancestry increase
13Gene mass in the low ranking lines will probably
have little impact on the seed orchards in the
near future
- That is right, it is an insurance to changing
demands and goals beyond the near future. For the
same reasons breeders carry on larger and more
diverse breeding populations than immediatly
needed. - Thus the advantage of stratified sublining is
more important in the upper strata. Maybe only
the top 60 of the effort should go to the
topranking gene mass organised in stratified
lines, how the gene mass is distributed in the
bottom is less of a stratified sublining problem.
14Later generations?
- Non inbred F2, but inbreeding can only be delyed,
not prevented. Inbreeding above gt 0.125 causes
problems even if the production population is
non-inbred. - Options (examples)
- Lassaiz faire
- Refresh
- Merge into fewer unrelated stratified lines
- Merge all lines
- Use inbreeding as a tool.
- There exists many variants of options and
suboptions, the long-term loss will be marginal
if any, but the benefits the first generations is
large!
15OP offspring, low rank line suggestion
- Select superior OP families (in office). Rank the
mothers for BV! - Select 6 phenotypically best trees from selected
families (in field) - Create 6 full sibs by crossing selected trees
from two families with adjacent ranks for BV! - Select 4 trees with assumed high BV for
progeny-test - Select best tree with the founder mother trees as
grandparents. That tree will be PAM mated and
join a stratified line. - Or select two cousins, and mate them to the most
adjacent pair of cousins from another similar
construct
16References
- Ruotsalainen S Lindgren D 2001 Number of
founders for a breeding population using variable
parental contribution. Forest Genetics 859-68. - Ruotsalainen S Lindgren D 2000 Stratified
sublining a new option for structuring breeding
populations Canadian Journal of Forest Research.
30 (4) 596-604