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Mating Systems

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Reduction in fitness in inbred individuals. Proper development. Disease resistance ... Non-Inbred vs. Inbred Crested Wood Partridges at the MN Zoo. 8% reduction ... – PowerPoint PPT presentation

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Title: Mating Systems


1
Lecture 24
Mating Systems
2
Inbreeding
3
Inbreeding
-- Increases homozygosity (uniformity gt like
gametes , like individuals)
4
Inbreeding
-- Disadvantages of Inbreeding --
5
Inbreeding
-- Disadvantages of Inbreeding -- 1) inbreeding
exposes deleterious genes
6
Inbreeding
-- Disadvantages of Inbreeding -- 1) inbreeding
exposes deleterious genes 2) inbreeding
depression --reduced performance due to
increased homozygosity, exposing genes
with negative effects
7
Inbreeding
-- Disadvantages of Inbreeding -- 1) inbreeding
exposes deleterious genes 2) inbreeding
depression --reduced performance due to
increased homozygosity, exposing genes
with negative effects --high risk (complete
lines can be lost)
8
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10
Inbreeding depression
  • Reduction in fitness in inbred individuals
  • Juvenile survival
  • Adult survival
  • Mate acquisition
  • Social dominance
  • Fertility and Fecundity
  • Growth

11
Inbreeding depression
  • Reduction in fitness in inbred individuals
  • Proper development
  • Disease resistance
  • Resistance to environmental stresses
  • Metabolic efficiency
  • Sensory acuity

12
Non-Inbred vs. Inbred Crested Wood Partridges at
the MN Zoo
  • 8 reduction in egg volume
  • 10 reduction in egg weight
  • 20 reduction in hatch rate
  • 51 reduction in 30 day survival
  • Non-inbred birds have 41 fewer medical notes
    than their inbred counterparts!

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15
Line breeding
16
Line breeding
-- mating system design to maintain a high degree
of relatedness of descendants to a particular
ancestor (mild form of inbreeding) --
17
Line breeding
Generation A super star ? 1 B 1/2
18
Line breeding
Generation A super star ? 1 B 1/2 ? 2
C 1/4
19
Line breeding
Generation A super star ? 1 B 1/2 ? 2
C 1/4 ? 3 D 1/8
20
Line breeding
Generation A super star ? 1 B 1/2 ? 2
C 1/4 ? 3 D 1/8
--Very quickly we lose the gene combinations that
defined the superstar.--
21
Line breeding
A 1 B C D 1/2
a F
22
Line breeding
A 1 B C D 1/2 2 E 1/2 1/8
a F
23
Line breeding
A 1 B C D 1/2 2 E 1/2
1/8 3 F 1/2 1/4
a F
24
Line breeding
A 1 B C D 1/2 2 E 1/2
1/8 3 F 1/2 1/4
a F
Note The relationship is high but F is
reasonably low.
25
Cross Breeding
26
Example of Crosses
PB2
PB1
F1



Backcross
Backcross
F2
27
Cross Breeding
-- crossing of animals from different breeds --
28
Cross Breeding
-- crossing of animals from different breeds
-- --Breed -- subpopulation of a species
inter se mated with the objective of
maintaining particular characteristics that
define the group.
29
Differentiation in Breeds
1) Different objectives using artificial
selection
30
Differentiation in Breeds
1) Different objectives using artificial
selection Example Holstein -- milk Hereford
-- beef Simmental -- dual purpose
31
Differentiation in Breeds
2) Originate in different environments and
are influenced differently by natural
selection
32
Differentiation in Breeds
2) Originate in different environments and
are influenced differently by natural
selection Example Brahman versus
Hereford
33
Differentiation in Breeds
2) Originate in different environments and
are influenced differently by natural
selection Example Brahman versus Hereford heat
dissipation, Brahman cattle have less hair,
sweat versus pant, have smaller metabolic
organs, lower birth weights and thicker hides
34
Differentiation in Breeds
Over time breeds come to represent different
reservoirs of genes
35
Differentiation in Breeds
Over time breeds come to represent different
reservoirs of genes 1) different alleles
36
Differentiation in Breeds
Over time breeds come to represent different
reservoirs of genes 1) different
alleles 2) different frequencies
37
Differentiation in Breeds Growth Hormone Alleles
Angus Brahman allele 1.0 .30 A
0 .17 B 0 .38 C 0 .20 D
38
Reasons for Crossbreeding

39
Reasons for Crossbreeding
1) Complementarity -- combine breeds to take
advantage of the best characteristics for both
breeds
40
Reasons for Crossbreeding
1) Complementarity -- combine breeds to take
advantage of the best characteristics for both
breeds 2) Method of migration of new genotypes
41
Reasons for Crossbreeding
1) Complementarity -- combine breeds to take
advantage of the best characteristics for both
breeds 2) Method of migration of new
genotypes 3) Creating synthetic breeds --
combining breeds then inter se mating to form a
new breed
42
Reasons for Crossbreeding
1) Complementarity -- combine breeds to take
advantage of the best characteristics for both
breeds 2) Method of migration of new
genotypes 3) Creating synthetic breeds --
combining breeds then inter se mating to form a
new breed 4) Rapid change in performance
43
Reasons for Crossbreeding
Example 1969 -- less than 15 Simmental
bulls imported in the US
44
Migrating New Genotypes
A B Generation
45
Migrating New Genotypes
A B Generation A 1/2A 1/2B 1
46
Migrating New Genotypes
A B Generation A 1/2A 1/2B 1 A
3/4A 1/4B 2
47
Migrating New Genotypes
A B Generation A 1/2A 1/2B 1 A
3/4A 1/4B 2 A 7/8A 1/8B 3
48
Migrating New Genotypes
A B Generation A 1/2A 1/2B 1 A
3/4A 1/4B 2 A 7/8A 1/8B 3 1 -
(1/2)tA (1/2)tB t
49
Creating Synthetics
Example Brangus (3/8 Brahman and 5/8
Angus)
50
Creating Synthetics
Example Brangus (3/8 Brahman and 5/8
Angus) Angus Brahman 1/2A 1/2B
51
Creating Synthetics
Example Brangus (3/8 Brahman and 5/8
Angus) Angus Brahman 1/2A
1/2B Brahman 1/4A 3/4B
52
Creating Synthetics
Example Brangus (3/8 Brahman and 5/8
Angus) Angus Brahman 1/2A
1/2B Brahman Angus 1/4A 3/4B 5/8A 3/8B ?
BRANGUS
53
Computing Fractions
GH x Lab
(1/2) GH (1/2) Lab
(1) GH x (1/2) GH (1/2) Lab
(3/4) GH (1/4) Lab
(3/4) GH (1/4) Lab x (1/2) GH (1/2)
Lab
54
Computing Fractions
(3/4) GH (1/4) Lab x (1/2) GH (1/2)
Lab What is the expected fraction of GH and Lab
genes in a progeny resulting from this mating?
55
Computing Fractions
(3/4) GH (1/4) Lab x (1/2) GH (1/2)
Lab GH (¾) x (1/2) (1/2) x (1/2) 5/8 Lab
(1/4) x (1/2) (1/2) x (1/2) 3/8
56
Rapid Change
Example Targhee and Finn
57
Reasons for Crossbreeding
Targhee -- 1.1 lambs/ ewe 1.5 lambs/
ewe
6 generations
58
Reasons for Crossbreeding
Targhee -- 1.1 lambs/ ewe 1.5 lambs/
ewe Finn -- 2.6 lambs/ ewe 2.1 lambs/
ewe
6 generations
1 generation (1/2F 1/2T)
59
Reasons for Crossbreeding
Targhee -- 1.1 lambs/ ewe 1.5 lambs/
ewe Finn -- 2.6 lambs/ ewe 2.1 lambs/
ewe
6 generations
selection
1 generation (1/2F 1/2T)
cross breeding
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