18.5

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Transcript 18.5 

CHAPTER 18
Section 18.5
Dihybrid Crosses and Polygenic Traits
Dihybrid Cross
• A dihybrid cross is a genetic cross involving two genes,
each of which has more than one allele.
• Ex. A pure yellow, round seed is crossed with a pure
green, wrinkled seed.
yr
yr
YR
YR
YyRr
YyRr
YyRr
YyRr
100%
yellow,
round
seeds.
Independent Assortment
• After many observations, Mendel noticed that when he
crossed pea plants while looking at more than one trait,
many more possible combinations were produced than he
expected.
• This is because instead of the parents producing only two
possible gametes like in a monohybrid cross, they can
produce four, from all the different combinations of alleles.
• The reason for this is because the genes for the two
different traits are on different chromosomes.
• The chromosomes can separate however they like, they
do not have to separate as a pair with a certain allele for
the other gene.
• This is known as the idea of independent assortment.
• The alleles for the different genes are separating
individually.
Probability and Dihybrid Crosses
• Probability is more difficult to determine for dihybrid crosses,
because we must determine what the chances are of certain
traits occurring together.
• Example: What is the probability of a child having attached ear
lobes and a straight hairline (both recessive), if the parents are
both heterozygous for both traits.
• To have attached ear lobes and a straight hairline, the child
must have the genotype eeww. Since the two genes are on
separate chromosomes, the gene for ear shape and hairline
shape will assort independently. The outcome that the child will
receive two ‘e’ alleles is, therefore, independent of the outcome
that the child will receive two ‘w’ alleles.
• Solution: First determine the probability that the child will
receive attached ear lobes separately from a straight
hairline.
E
e
E
EE
Ee
W
WW
Ww
e
Ee
ee
w
Ww
ww
¼ or 25% chance
of being ‘ee.’
W
w
¼ or 25% chance
of being ‘ww.’
• Now to determine the probability that the child will have
both traits together you must multiply them together.
• ¼ x ¼ = 1/16
• 0.25 x 0.25 = 0.0625
• The child has a 6.25% chance of having both attached
ear lobes ‘ee’ and a straight hairline ‘ww.’
• There is another way that probability can be determined,
by using a bigger Punnett square.
EeWw x EeWw
EW
Ew
eW
ew
EEWW
EEWw
EeWW
EeWw
EEWw
EEww
EeWw
Eeww
EeWW
EeWw
eeWW
eeWw
EeWw
Eeww
eeWw
eeww
EW
Ew
eW
ew
There is a 1/16 chance that the child will
have the genotype ‘eeww’ and have both
attached ear lobes and a straight hairline.
Selective Breeding
• Selective breeding – is the crossing of plants or animals with
desired traits to produce offspring with desired characteristics.
• Many dogs and horses are breed by using a specific type of
selective breeding called inbreeding in order to keep the
original traits of the purebred dog.
• Another special type of selective breeding is hybridization,
where organisms are bred specifically to change the traits for
the better.
• Hybridization is usually a mixture of two different species to
create entirely new organisms.
Polygenic Traits
• In dihybrid crosses, two genes determine two separate traits.
• However, sometimes a single trait is determined by more
than one gene.
• These are known as polygenic traits – inherited
characteristics that are determined by more than one gene.
• In other words, two different genotypes interact to produce a
phenotype that neither genotype is capable of producing
itself.
• Examples are skin colour, hair colour and eye colour.
• This is why it is hard to track these inherited traits on a
pedigree chart because they are influenced by more than
one gene.
• Polygenic traits tend to have more variability than those
determined by a single gene.
• Each of the genes for polygenic traits are capable of
having multiple alleles, incomplete dominance or codominance and can be affected by the environment.
Epistatic Genes
• Epistatic genes – are polygenic trait genes that can
mask or interfere with the expression of the other gene.
• Ex. Coat colour of dogs:
• The coat colour of dogs is determined by two different
genes, the coat colour gene and another gene that affects
pigmentation of the hairs.
• Normally the ‘B’ allele produces a black coat, while a ‘b’
allele produces a brown coat.
• However, dog coat colour is a polygenic trait and is
affected by another gene for pigmentation.
• When the ‘W’ allele is present, it prevents pigmentation of
the coat, resulting in a white colour.
• When the ‘w’ allele is present, it does not have any affect
on the pigmentation of the coat and the dog will be black
or brown depending on the genotype of the coat gene.
* ‘B’ (black) is dominant over ‘b’ (brown).
* ‘W’ (prevention of pigmentation) is dominant over ‘w’ (no
affect).
• The punnett square to prove epistatic genes of dog coat
colour:
WwBb x wwBb
wB
wb
WB
WwBB
WwBb
Wb
WwBb
Wwbb
wB
wb
wwBB
wwBb
wwBb
wwbb
4/8 are white
because of the ‘W’
allele.
3/8 are black
because of the ‘w’
and ‘B’ alleles.
1/8 are brown
because of the ‘w’
and ‘b’ alleles.