Table of contents | |
Conditions of the Hardy-Weinberg population | |
The Equations | |
Inference | |
Applications | |
Sample Problem Involving Hardy-Weinberg Equilibrium |
Mathematically,
If there is a gene with two alleles, A and a.
p q = 1.... (Eq. 1)
p2 2pq q2 = 1.... (Eq. 2)
As shown by Hardy and Weinberg, alleles segregating in a population tend to establish equilibrium with reference to each other. Thus, if two alleles should occur in equal proportion in a large, isolated breeding population and neither had a selective or mutational advantage over the other, they would be expected to remain in equal proportion generation after generation.
The Hardy–Weinberg principle may be applied in two ways, either a population is assumed to be in Hardy–Weinberg proportions, in which the genotype frequencies can be calculated, or if the genotype frequencies of all three genotypes are known, they can be tested for deviations that are statistically significant.
Question: Sickle cell anemia, an autosomal recessive disease, occurs in 1 of every 400 African-American births. What is the frequency of carriers of the sickle cell gene in this population?
Ans:
Carriers (or heterozygotes) are represented by 2pq, so we need to solve for p and q.
We are told that q 2 is equal to 1/400 or 0.0025.
Thus, q = 0.05
We know that p q = 1, so p = 1 – q. In this case,
p = 1 – 0.05 = 0.95.
We then solve for 2pq, which is equal to 2(0.95) (0.05) or 0.095.
So 95 of every 1000 African-Americans carry the sickle cell gene.
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