346561 The tendency of population to remain in genetic equilibrium may be disturbed by :

346562 Match the following columns.
Column I
Column II
A
Stabilisation
P
Industrial melanism
B
Directional selection
Q
More individuals possess heterozygous character
C
Disruption selection
R
More individuals possess homozygous character

346563 Read the following statements and select the correct option.
I. Branching descent and natural selection are the two key concepts of Darwinian Theory of Evolution
II. When more individuals of a population acquire a mean character value, it is called disruption.
III. Hardy-Weinberg equilibrium says that allele frequencies in a population are stable and is constant from generation to generation.
IV. Genetic drift changes the existing gene or allelic frequency in future generations

346564 In a population of 1,000 individuals, 400 are homozygous \(\mathrm{Rh}+(\mathrm{DD}), 240\) are heterozygous \(\mathrm{Rh}+(\mathrm{Dd})\) and 360 are \(\mathrm{Rh}-(\mathrm{dd})\). The frequency of recessive allele (d) in that population is

346561 The tendency of population to remain in genetic equilibrium may be disturbed by :

346562 Match the following columns.
Column I
Column II
A
Stabilisation
P
Industrial melanism
B
Directional selection
Q
More individuals possess heterozygous character
C
Disruption selection
R
More individuals possess homozygous character

346563 Read the following statements and select the correct option.
I. Branching descent and natural selection are the two key concepts of Darwinian Theory of Evolution
II. When more individuals of a population acquire a mean character value, it is called disruption.
III. Hardy-Weinberg equilibrium says that allele frequencies in a population are stable and is constant from generation to generation.
IV. Genetic drift changes the existing gene or allelic frequency in future generations

346564 In a population of 1,000 individuals, 400 are homozygous \(\mathrm{Rh}+(\mathrm{DD}), 240\) are heterozygous \(\mathrm{Rh}+(\mathrm{Dd})\) and 360 are \(\mathrm{Rh}-(\mathrm{dd})\). The frequency of recessive allele (d) in that population is

346561 The tendency of population to remain in genetic equilibrium may be disturbed by :

346562 Match the following columns.
Column I
Column II
A
Stabilisation
P
Industrial melanism
B
Directional selection
Q
More individuals possess heterozygous character
C
Disruption selection
R
More individuals possess homozygous character

346563 Read the following statements and select the correct option.
I. Branching descent and natural selection are the two key concepts of Darwinian Theory of Evolution
II. When more individuals of a population acquire a mean character value, it is called disruption.
III. Hardy-Weinberg equilibrium says that allele frequencies in a population are stable and is constant from generation to generation.
IV. Genetic drift changes the existing gene or allelic frequency in future generations

346564 In a population of 1,000 individuals, 400 are homozygous \(\mathrm{Rh}+(\mathrm{DD}), 240\) are heterozygous \(\mathrm{Rh}+(\mathrm{Dd})\) and 360 are \(\mathrm{Rh}-(\mathrm{dd})\). The frequency of recessive allele (d) in that population is

346561 The tendency of population to remain in genetic equilibrium may be disturbed by :

346562 Match the following columns.
Column I
Column II
A
Stabilisation
P
Industrial melanism
B
Directional selection
Q
More individuals possess heterozygous character
C
Disruption selection
R
More individuals possess homozygous character

346563 Read the following statements and select the correct option.
I. Branching descent and natural selection are the two key concepts of Darwinian Theory of Evolution
II. When more individuals of a population acquire a mean character value, it is called disruption.
III. Hardy-Weinberg equilibrium says that allele frequencies in a population are stable and is constant from generation to generation.
IV. Genetic drift changes the existing gene or allelic frequency in future generations

346564 In a population of 1,000 individuals, 400 are homozygous \(\mathrm{Rh}+(\mathrm{DD}), 240\) are heterozygous \(\mathrm{Rh}+(\mathrm{Dd})\) and 360 are \(\mathrm{Rh}-(\mathrm{dd})\). The frequency of recessive allele (d) in that population is