Answer:
a. [tex](p + q)^7[/tex] = [tex]p^7q^0+7p^6q+21p^5q^2+35p^4q^3+35p^3q^4+21p^2q^5+7pq^6+p^0q^7[/tex]
b. i. 0.75
ii. 0.000061
iii. 0.012
iv. 0.17
c. 0.67
Explanation:
a. The expansion of the binomial (p + q)7 would be such that:
[tex](p + q)^7[/tex] = [tex]p^7q^0+7p^6q+21p^5q^2+35p^4q^3+35p^3q^4+21p^2q^5+7pq^6+p^0q^7[/tex]
b. Both couples are heterozygous:
Aa x Aa
AA Aa Aa aa
Since A is dominant over a,
probability of having mole (aa) = 1/4
probability of not having moles = 3/4
Therefore, the probability of the first child not having moles = 3/4 or 0.75
ii. Let the probability of not having mole = p and the probability of having mole = q. From the binomial expansion:
[tex](p + q)^7[/tex] = [tex]p^7q^0+7p^6q+21p^5q^2+35p^4q^3+35p^3q^4+21p^2q^5+7pq^6+p^0q^7[/tex]
Probability that all of the children will have moles = [tex]p^0q^7[/tex]
since p = 3/4 and q = 1/4
[tex]p^0q^7[/tex] = [tex](3/4)^0(1/4)^7[/tex] = 0.000061
iii. Probability that the first two children will have no moles and the last five will have moles = [tex]21p^2q5[/tex]
= [tex]21(3/4)^2(1/4)^5[/tex]
= 0.012
iv. Probability that 4 will have no moles and 3 will have moles out of the 7 children = [tex]35p^4q^3[/tex]
= [tex]35(3/4)^4(1/4)^3[/tex]
= 0.17
c. Probability that the child born without moles is a carrier of the a-allele = probability of heterozygous.
From the cross in (b), the genotypes of those born without moles are AA and 2Aa. Therefore, the probability of not having moles and be Aa is:
= 2/3 or 0.67
