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Example Questions
Example Question #1 : Understanding Hardy Weinberg Calculations
Consider a population in Hardy-Weinberg equilibrium. A gene in the population has two alleles. The gene pool shows a distribution of 80% of the dominant allele and 20% the recessive allele.
What percentage of the population is heterozygous for the trait?
Since the population is in Hardy-Weinberg equilibrium, we can use the following equation to determine the genotypic frequencies for the allele in question:
In this equation, represents the frequency of the dominant allele and represents the frequency of the recessive allele. The portion of the expression represents the frequency of heterozygotes in the population. Using the allelic frequencies given in the question, we can calculate the percentage of heterozygous individuals.
32% of the population is heterozygous for the trait.
Example Question #51 : Genetics Principles
In an isolated population of ants in the Amazon rainforest, color is determined by a single gene. Ants that are homozygous dominant (BB) and heterozygous (Bb) for this gene are black, but ants that are homozygous recessive (bb) for this gene are brown.
If the phenotype frequencies are 0.75 black and 0.25 brown, what are the allele frequencies within this population?
We can use the Hardy-Weinberg equations to solve this question:
We know that the black allele (B) is dominant and the brown allele (b) is recessive.
Using these two equations, we know that 0.25 are homozygous recessive (brown). This value will be equal to .
We can then solve as follows:
Therefore, we know that the frequency of each allele is equal to 0.5.
Example Question #1 : Understanding Hardy Weinberg Calculations
In a population of rabbits, the dominant B allele produces brown fur and the recessive b allele produces white fur. There are 544 brown rabbits and 306 white rabbits in the population.
How many of the brown rabbits would you expect to be homozygous dominant (BB)?
Cannot be determined from the information given
In the Hardy-Weinberg equation, the value of the term is the percentage of homozygous dominant (BB) individuals in a population. Thus, to answer this question we will need to solve for .
With the information we are given, we can calculate , which is the percentage of the population that is homozygous recessive (bb). We know the total number of homozygous recessive rabbits (306 white rabbits) and the total number of rabbits in the population (306 + 544 = 850). We can thus divide the number of white rabbits by the population total to find :
36% of the population is homozygous recessive. We then take the square root of to find :
This value tells us that 60% of all the alleles in the population are recessive (b).
The Hardy-Weinberg equation is based off the idea that the total number of alleles in a population is the sum of the dominant and recessive alleles, as shown by this equation:
We can use this equation to solve for using :
This value tells us that 40% of all the alleles in the population are dominant (B).
We can now square to obtain . Recall that this will be the frequency of homozygous dominant individuals in the population:
The result is 16%, meaning 16% of the rabbits in the population are homozygous dominant. We can then multiply 16% by the total population to find the number of rabbits who are homozygous dominant:
Thus, 136 homozygous dominant rabbits would be expected in this population.
Example Question #11 : Hardy Weinberg Equilibrium
A population of frogs, which is at equilibrium, carries a dominant allele for black spots (B) and a recessive allele for no spots (b). 76 frogs have no spots, and 399 frogs have black spots.
How many of the frogs are heterozygous (Bb) for the black spot trait?
In the Hardy-Weinberg equation, the value of the term is the percentage of heterozygous (Bb) individuals in a population. Thus, to answer this question we will need to solve for .
With the information we are given, we can calculate , which is the percentage of the population that is homozygous recessive (bb). We know the total number of homozygous recessive rabbits (76 without spots) and the total number of rabbits in the population (76+ 399= 475). We can thus divide the number of frogs without spots by the population total to find :
16% of the population is homozygous recessive. We then take the square root of to find :
This value tells us that 40% of all the alleles in the population are recessive (b).
The Hardy-Weinberg equation is based off the idea that the total number of alleles in a population is the sum of the dominant and recessive alleles, as shown by this equation:
We can use this equation to solve for using :
This value tells us that 60% of all the alleles in the population are dominant (B).
Now that we have and , we can calculate . Recall that this will be the frequency of heterozygous individuals in the population:
The result is 48%, meaning 48% of the frogs in the population are heterozygous. We can then multiply 48% by the total population to find the number of frogs who are heterozygous::
Thus, 228 heterozygous frogs would be expected in this population.
Example Question #2 : Understanding Hardy Weinberg Calculations
For a particular gene, the allele is dominant to the allele . If in a population the allele frequency for is 0.85, what is the frequency of individuals that are heterozygotes? Assume Hardy-Weinberg equilibrium conditions are met.
There are two equations for Hardy-Weinberg equilibrium:
Using the first equation, we can substitute in 0.85 for and solve to get .
We can then use the second equation to find the frequencies of each genotype.
= frequency of genotype
= frequency of genotype
(Why do we multiply by 2? Because we must count both and as heterozygotes.)
= frequency of genotype
Thus we get .
Example Question #51 : Genetics Principles
If p=0.9 and q=0.1 what will be the final genotypic frequencies of a population be under Hardy-Weinberg equilibrium?
Recall that under Hardy-Weinberg conditions, the allele frequencies remain constant. The formulas for Hardy-Weinberg equilibrium are:
and
Here, is the frequency of the homozygous dominant genotype, is the frequency of the heterozygous genotype, and is the frequency of the homozygous recessive genotype. Since we have all the variables we need, and we want to find the genotypic frequencies (not the phenotypic) we plug into the second equation.
Be sure to check to make sure these frequencies add up to 1.
Example Question #11 : Hardy Weinberg Equilibrium
If p=0.3 and q=0.7, what will be the final genotypic frequencies of a population be under Hardy-Weinberg equilibrium?
Recall that under Hardy-Weinberg conditions, the allele frequencies remain constant. The formulas for Hardy-Weinberg equilibrium are:
and
Here, is the frequency of the homozygous dominant genotype, is the frequency of the heterozygous genotype, and is the frequency of the homozygous recessive genotype. Since we have all the variables we need, and we want to find the genotypic frequencies (not the phenotypic) we plug into the second equation.
Be sure to check to make sure these frequencies add up to 1.
Example Question #52 : Genetics Principles
Tail length in a population of aardvarks is determined by one gene, where L=long tails and l=short tails. If the frequency of L in the population is 0.4, determine the expected frequencies of each possible genotype: homozygous dominant (LL), heterozygous (Ll), and homozygous recessive (ll).
LL = 0.16
Ll = 0.68
ll = 0.16
LL = 0.4
Ll = 0.0
ll = 0.6
LL= 0.24
Ll= 0.58
ll= 0.18
There is not enough information given to determine an answer.
LL = 0.16
Ll = 0.48
ll = 0.36
LL = 0.16
Ll = 0.48
ll = 0.36
To begin, we must know that we are working with the Hardy-Weinberg equations:
We can designate the dominant allele (L) as and the recessive allele (l) as .
Since the frequency of L was given (0.4) we know the the frequency of l must be:
Now we have both allele frequencies and can plug them into the equation:
So for , LL (homozygous dominant), is equal to 0.16
for , Ll (heterozygous), is equal to 0.48
for , ll (homozygous recessive), is equal to 0.36