In hardy-Weinberg equation, the frequency of heterozygous individual is represented by

Hardy-Weinberg equation is used to check

Genetic constitution of an individual is represented by :-

According to Hardy-Weinberg's principle, if allele one is denoted as 'A' and allele two as 'a' and their frequencies are denoted by p and q, and if random mating occurs. The frequency of heterozygous individual would be :

The frequency of two alleles in a gene pool is 0.19 ( A) and 0.81 ( a) . Assume that the population is in Hardy-Weinberg equilibrium and (a) Calculate the percentage of heterozygous individuals in the population. (b) Calculate the percentage of homozygous recessive in the population .

Percentage of heterozygous individuals obtained from selfing Rr individuals is:

In a population that is in Hardy weinberg equilibrium, the frequency of a recessive allele for a certain heareditary trait is 0.20. What percentage of the individual in the next generation would be expected to show the dominant trait :-

In a monohybrid cross between two heterozygous individuals, percentage of pure homozygous individuals obtained in F_(1) generation will be

According to the Hardy-Weinberg principle, the allele frequency of a population remains costant. How do you interpret the change of frequency of alleles in a population ?

The frequency of an autosomal recessive gene is 0.4. Then what will be the frequency of heterozygotes in progeny among 4000 individual ?

In a diploid population of Drosophila 9% of the population is black in colour. Black is recessive to grey. What is the frequency of heterozygous flies in that population, if it is in Hardy-Weinberg equilibrium?