In our articles on Genetics and Inheritance, we looked at the basic principles of how genes are passed on from generation to generation. Here, we’ll discuss what a gene pool is and explain how to calculate the frequency of an allele based on the Hardy Weinberg equation.
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Jetzt kostenlos anmeldenIn our articles on Genetics and Inheritance, we looked at the basic principles of how genes are passed on from generation to generation. Here, we’ll discuss what a gene pool is and explain how to calculate the frequency of an allele based on the Hardy Weinberg equation.
Allelic frequency: The number of times an allele appears in a population.
The Hardy-Weinberg principle, named after English mathematician G. H. Hardy and German doctor Wilhelm Weinburg, can calculate the frequency of an allele in a population at equilibrium. It is a null model in genetics. According to the Hardy-Weinberg principle, at equilibrium, the allele frequencies of a gene within a population will not differ from one generation to the next. Unless an allele leads to a phenotype with a significant advantage or disadvantage over other alleles, its frequency in a population is unlikely to change. A population in Hardy-Weinburg equilibrium is not evolving means it is described as ‘stable’.
The industrial revolution (transition to new manufacturing processes in Great Britain) created many changes to the environment, one of these was in moths. In the early years of the industrial revolution, the first black peppered moth appeared. Usually, peppered moths would be lightly coloured. As the industrial revolution progressed, dark moths became more and more prevalent. This phenomenon was due to directional selection. Dust, soot, and pollution filled the air in large cities, and hardly any lightly coloured moths were found. Lightly coloured moths on sooty, dirty buildings would be easily spotted and more susceptible to predation. At the level of each city, dark varieties of moths are selected - this is directional selection.
As we will see below, the Hardy-Weinberg principle provides us with a mathematical equation to calculate the expected frequency of an allele in a population.
P: dominant homozygous frequency (AA)
2 PQ: heterozygous frequency (Aa)
Q²: recessive homozygous frequency (aa)
1: 100% of the population
Imagine a population of diploid organisms that reproduce sexually. Let’s assume that there is no overlap between generations and that the frequencies of all alleles are equal in males and females.
There are five conditions for Hardy-Weinberg equilibrium. These are:
Unless the population exists in a lab, finding a population that fulfils all of these criteria is improbable.
These exact conditions are unlikely to be met in natural populations; however, the Hardy-Weinberg principle provides an essential and valuable null model which we can use to study gene frequencies. In biology, null models attempt to describe what would happen in a system not influenced by any biological processes of interest (such as the conditions above!).
If the predicted frequencies do not match the observed frequencies, we can conclude that at least one of the Hardy-Weinberg equilibrium conditions has not been met. For instance, that population might be undergoing directional selection, wherein an extreme phenotype is favoured over the mean or another phenotype.
The inheritance pattern for the gene in question might also be non-Mendelian, which affects its chances of being passed on to the next generation. (For more information, check out our articles on Selection and Inheritance!)
Let’s take, for example, a population of 10,000 humans.
b | b | |
b | bb | bb |
b | bb | bb |
B | b | |
B | BB | Bb |
b | Bb | bb |
Where p² = BB, 2pq = Bb, and b² = aa.
If you are told that the frequency of a dominant allele in a population is 70%, you have been given p directly, p = 0.7. Therefore q = 0.3, as p + q = 1.0
In the article on Inheritance, we learned that there are only four possible arrangements of these two alleles. It follows that all together, the probability of all four will equal 1.0.
Now that we have the Hardy-Weinberg equation, we can calculate the frequency of an allele in a population.
Suppose that blondeness is the result of recessive allele b, and only one in 10 people display this phenotype. What is the probability that an individual in this population is a heterozygote?
1. Since this trait is recessive, it will only appear in individuals with the genotype bb.
2. Only 1 in 10 individuals have this phenotype; the probability of bb is = 0.10.
3. q is the square root of 0.10. q = 0.3162.
4. p + q = 1.0. Therefore, p = 1.0 - q = 1.0 - 0.3162 = 0.6838.
5. The probability of heterozygotes is 2pq. 2pq = 0. 4324
The gene pool consists of all the alleles of all the genes of all the individuals in a population at a given time.
The number of times that an allele appears in a population is known as its allelic frequency.
The dominance of an allele has nothing to do with whether it is deleterious (harmful) or beneficial.
According to the Hardy-Weinberg principle, the allele frequencies of a gene within a population will not change from one generation to the next.
The Hardy-Weinberg equation is expressed as p2 + 2pq + q2 = 1.0. In biology, null models attempt to describe what would happen in a system that is not influenced by any biological processes of interest.
The Hardy-Weinberg principle predicts that at equilibrium, the allele frequencies of a gene within a population will not change from one generation to the next.
It can be used to calculate the frequency of an allele in a population at equilibrium. The Hardy-Weinberg principle is also used as a null model in genetics. If the predicted allelic frequencies do not match the observed frequencies, we can conclude that at least one of the Hardy-Weinberg equilibrium conditions has not been met.
There are 5 conditions for Hardy-Weinberg equilibrium. These are:
- Mating is random.
- The population size is infinitely large.
- There is no migration: the population is isolated.
- There is no selection: all alleles are equally likely to be passed on to the next generation.
- No mutations arise.
What is a gene pool?
The gene pool consists of all the alleles of all the genes of all the individuals in a population at a given time.
What is the number of times that an allele appears in a population known as?
Allelic frequency
According to the Hardy-Weinberg principle, at ______, the allele frequencies of a gene within a population will not change from one generation to the next.
Equilibrium
Which of the following is not a condition for a Hardy-Weinberg equilibrium?
- Mating is non-random
- The population size is infinitely large
- There is no migration: the population is isolated
- There is no selection: all alleles are equally likely to be passed on to the next generation
- No mutations arise
Mating is non-random
Which of the following is not an assumption of the Hardy-Weinberg principle?
The population is diploid
The population reproduces sexually
The frequency of males and females in the population is equal
None of the above
None of the above
The dominant allele X has a frequency p of 0.89. What is the frequency of heterozygotes in the population?
0.1958
Solution:
The heterozygote frequency is 2pq. We know that p = 0.89, so now we need to find the value of q.
p+q = 1.0. Therefore, q = 0.11.
2pq = 2(0.11)(0.89) = 0.1958.
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