We have all heard the saying “You can’t judge a book by its
cover”, but it is true that the cover is what initially draws a person to pick
up the book in the first place. The same is true with selecting and breeding
cattle. What the animal looks like matters. However, what the saying really
means is it’s what is inside the book, or in this case underneath the animal’s
hide, that adds the most value.
The importance of phenotypic selection in cattle is non-negotiable.
But, once someone has made that initial gate cut, genomics can help in
marketing the value of sale bulls and heifers with increased confidence.
Cattlemen and women do their best to select elite bulls to
mate their cows to. Unfortunately, basic biology reminds us that variability
exists even within the best mating plans. But exactly how much variability? Well,
while discussed at length in the extension article The
Random Shuffle of Genes: Putting the E in EPD, basic math tells us that within
a single full sibling mating, there are over one quintillion possible
combinations of chromosomal inheritance (DNA passed from sire/dam to offspring).
Therefore, producers could be standing in a pen looking at two prospective full
sibling sale bulls that phenotypically look the same, but whose genetic merit could
be different. But differentiating those cattle on sale day goes one step beyond
just looks and Expected Progeny Differences (EPDs).
Table 1. Expected Progeny Differences for Calving
Ease Direct, Birthweight, and Ribeye Area for a sire and dam, along with 6 full
sibling progeny resulting from said mating1
|
Animal
|
CED
|
BW
|
REA
|
GE-EPDs
|
|
Sire
|
+2.3
|
+2.9
|
+0.67
|
Yes
|
|
Dam
|
-4.7
|
+5.5
|
+0.35
|
Yes
|
|
Heifer 1
|
-3.9
|
+5.8
|
+0.46
|
Yes
|
|
Heifer 2
|
-9.2
|
+8.1
|
+0.55
|
Yes
|
|
Heifer 3
|
-5.7
|
+7.4
|
+0.60
|
Yes
|
|
Bull 1
|
-1.3
|
+4.2
|
+0.51
|
No
|
|
Bull 2
|
-1.3
|
+4.2
|
+0.51
|
No
|
|
Bull 3
|
-1.3
|
+4.2
|
+0.51
|
No
|
|
1Data
reported are real EPDs and GE-EPDs pulled from a breed association.
|
Using Table 1 as an example, data has been captured on six embryo
transfer (ET) calves (3 bulls and 3 heifers) born from the same sire and dam
mating. Phenotype based EPDs are estimated using the pedigree, phenotype, and
progeny information on an animal. Yet when full siblings are born, they share
the same pedigree, and therefore the same phenotypic information stored within
the genetic evaluation. This means that until their own phenotype or progeny
information is reported, their EPDs for all traits are simply the average of
their parents. This is illustrated in Table 1 when looking at the bull progeny
who all appear to have the same genetic merit for calving ease direct (CED), birth
weight (BW), and rib eye area (REA). However,
unless identical twins, no two siblings look, act, or perform the same.
So how does one differentiate or capture the genetic
difference between those calves? Taking a DNA sample on an animal early in its
life and reporting that to the evaluation will immediately inform the
prediction which pieces of DNA each relative inherited from the members of
their pedigree (i.e. which 50% they received from their sire and dam,
respectively) and therefore differentiate cattle early in their lives. This
differentiation can be seen in the heifer progeny listed in Table 1 that have a
genomic profile on file.
The benefit of adding the genomic test on any
registered animal, related or not, is still the same. It gives the evaluation a
much better picture of the DNA inherited from an animal’s sire and dam, and
therefore increases the accuracy of the prediction. Most importantly, it better
defines the genetic potential of an animal and helps the producer or buyer
align that individual to their specific breeding objectives and goals.
Comments
Using Table 1 as an example, data has been captured on six embryo transfer (ET) calves (3 bulls and 3 heifers) born from the same sire and dam mating. Phenotype based EPDs are estimated using the pedigree, phenotype, and progeny information on an animal. Yet when full siblings are born, they share the same pedigree, and therefore the same phenotypic information stored within the genetic evaluation. This means that until their own phenotype or progeny information is reported, their EPDs for all traits are simply the average of their parents. This is illustrated in Table 1 when looking at the bull progeny who all appear to have the same genetic merit for calving ease direct (CED), birth weight (BW), and rib eye area (REA). However, unless identical twins, no two siblings look, act, or perform the same Using Table 1 as an example, data has been captured on six embryo transfer (ET) calves (3 bulls and 3 heifers) born from the same sire and dam mating. Phenotype based EPDs are estimated using the pedigree, phenotype, and progeny information on an animal. Yet when full siblings are born, they share the same pedigree, and therefore the same phenotypic information stored within the genetic evaluation. This means that until their own phenotype or progeny information is reported, their EPDs for all traits are simply the average of their parents. This is illustrated in Table 1 when looking at the bull progeny who all appear to have the same genetic merit for calving ease direct (CED), birth weight (BW), and rib eye area (REA). However, unless identical twins, no two siblings look, act, or perform the same.