In population genetics, the Wahlund effect is a reduction of heterozygosity (that is when an organism has two different alleles at a locus) in a population caused by subpopulation structure. Namely, if two or more subpopulations are in a Hardy–Weinberg equilibrium but have different allele frequencies, the overall heterozygosity is reduced compared to if the whole population was in equilibrium. The underlying causes of this population subdivision could be geographic barriers to gene flow followed by genetic drift in the subpopulations.
The Wahlund effect was first described by the Swedish geneticist Sten Wahlund in 1928.[1]
Suppose there is a population
P
p
q
p+q=1
P1
P2
P1
P2
To make a slight generalization of the above example, let
p1
p2
P1
P2
q1
q2
Let the allele frequency in each population be different, i.e.
p1\nep2
Suppose each population is in an internal Hardy–Weinberg equilibrium, so that the genotype frequencies AA, Aa and aa are p2, 2pq, and q2 respectively for each population.
Then the heterozygosity (
H
\begin{align} H&={2p1q1+2p2q2\over2}\\[5pt] &={p1q1+p2q2}\\[5pt] &={p1(1-p1)+p2(1-p2)} \end{align}
which is always smaller than
2p(1-p)
{}=2pq
p1=p2
The Wahlund effect may be generalized to different subpopulations of different sizes. The heterozygosity of the total population is then given by the mean of the heterozygosities of the subpopulations, weighted by the subpopulation size.
The reduction in heterozygosity can be measured using F-statistics.