The frequencies of the phenotypes of the MN blood group were measured in a European population - VCE - SSCE Biology - Question 14 - 2004 - Paper 1

To find the frequency of the L^N allele, we can use the formula: q = rac{2N_{NN} + N_{MN}}{2N} In this case:

• $N_{NN} = 40$ (blood type N)
• $N_{MN} = 20$ (blood type MN) Using the formula, we find: q = rac{2(40) + (20)}{2(100)} = rac{100}{200} = 0.5 Thus, the statement that the frequency of the L^N allele is 0.5 is correct.

To find the number of L^M alleles, we can calculate: $2N_{MM} + N_{MN}$ Substituting values:

• $N_{MM} = 40$
• $N_{MN} = 20$ Hence: $2(40) + 20 = 80 + 20 = 100$ This calculates the total alleles, not specifically the L^M alleles, leading us to conclude that the population has a total of 100 alleles, not specifically 60 L^M alleles.

In a diploid organism, each individual has two alleles per locus. Therefore, with 100 individuals, the total number of alleles is: $2 imes 100 = 200$ However, in terms of unique alleles (L^M and L^N), the total alleles present at this specific locus would indeed refer to the unique counts, so this statement can be considered misleading. The correct interpretation is that there is a total of 200 alleles overall.