1. Give the genotypes of the ABO blood groups for individuals 1 and 2. 1 Blood group A 2 Blood group AB 2. Explain one piece of evidence from Figure 3 that the allele for Rhesus positive is dominant. 3. Calculate the probability of individuals 1 and 2 producing a Rhesus positive son with blood group A (individual 3). You can assume that individual 1 is heterozygous for the Rhesus blood group. Show your working.

A-Level AQA Biology Mass Transport in Plants: 1. Give the genotypes of the ABO

1. Give the genotypes of the ABO blood groups for individuals 1 and 2 - AQA - A-Level Biology - Question 6 - 2022 - Paper 2

Question 6

1. Give the genotypes of the ABO blood groups for individuals 1 and 2. 1 Blood group A 2 Blood group AB 2. Explain one piece of evidence from Figure 3 that the... show full transcript

Worked Solution & Example Answer:1. Give the genotypes of the ABO blood groups for individuals 1 and 2 - AQA - A-Level Biology - Question 6 - 2022 - Paper 2

Step 1

Give the genotypes of the ABO blood groups for individuals 1 and 2.

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Answer

Individual 1 has blood group A, which can have the genotype either $I^A I^A$ (homozygous) or $I^A i$ (heterozygous).
Individual 2 has blood group AB, which has the genotype $I^A I^B$ .

Step 2

Explain one piece of evidence from Figure 3 that the allele for Rhesus positive is dominant.

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Answer

In Figure 3, individuals with a Rhesus positive phenotype (like individuals A and AB) can produce offspring with a Rhesus negative phenotype (like individual O). This indicates that the presence of the Rhesus positive allele can mask the expression of the Rhesus negative allele.

Step 3

Calculate the probability of individuals 1 and 2 producing a Rhesus positive son with blood group A (individual 3).

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Answer

To find the probability, we assume that individual 1 is heterozygous for the Rhesus blood group ( ${Rr}$ ) and individual 2 is also ${Rr}$ (since they can produce Rhesus negative offspring).

Possible Rhesus offspring:

${RR}$ (Rhesus positive)
${Rr}$ (Rhesus positive)
${rR}$ (Rhesus positive)
${rr}$ (Rhesus negative)

This results in a probability of producing a Rhesus positive child of $rac{3}{4}$ .

Next, consider the ABO blood groups. Individual 1 can pass on either $I^A$ or $i$ , while individual 2 can pass on $I^A$ or $I^B$ . The combinations yielding blood group A are:

$I^A I^A$ (from individual 1) and $i$ (from individual 2)
$I^A i$ (from individual 1) and $I^B$ (from individual 2)

Thus, the probability of individual 3 being blood group A is $rac{1}{4}$ (for homozygous) + $rac{1}{4}$ (for heterozygous from individual 1's contribution).

Combining these, the total probability of producing a Rhesus positive son with blood group A is:

$P(RR ext{ or } Rr) imes P(A) = rac{3}{4} imes rac{1}{2} = rac{3}{8}$ .

1. Give the genotypes of the ABO blood groups for individuals 1 and 2 - AQA - A-Level Biology - Question 6 - 2022 - Paper 2

Worked Solution & Example Answer:1. Give the genotypes of the ABO blood groups for individuals 1 and 2 - AQA - A-Level Biology - Question 6 - 2022 - Paper 2

Give the genotypes of the ABO blood groups for individuals 1 and 2.

Explain one piece of evidence from Figure 3 that the allele for Rhesus positive is dominant.

Calculate the probability of individuals 1 and 2 producing a Rhesus positive son with blood group A (individual 3).

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