2.1 The sequence of amino acids in a protein molecule is coded for by DNA and RNA - NSC Life Sciences - Question 2 - 2017 - Paper 2

The anticodon for glutamic acid (GAG) is CUC.

The last codon in the given mRNA sequence is ACC, so the corresponding DNA base triplet is TGG.

The first codon of the mRNA sequence is GAU, which codes for the amino acid aspartate.

The mutation resulted in the fourth codon changing from AGC to AGU. This can be defined as a substitution mutation where one base pair in the mRNA has been altered.

The mutation leads to the coding of the same amino acid, serine, for both AGC and AGU codons. Therefore, the mutation does not affect the protein structure, as the resulting protein would be identical.

The process is called transcription. During transcription, the DNA double helix unwinds, and one strand serves as a template for the synthesis of mRNA. RNA polymerase facilitates this process, and the complementary RNA nucleotides are added to form the mRNA strand.

A population is defined as a group of organisms of the same species that can interbreed and occupy a specific area at a given time.

Three causes of variation include:

1. Crossing over during meiosis
2. Random arrangement of chromosomes during metaphase
3. Random mating among individuals.

The squirrels with favourable characteristics due to the mutation survived and reproduced more effectively than those without it. This resulted in a greater population of mutant squirrels on that side, driven by natural selection.

The process of speciation has led to an increase in biodiversity since two separate species of squirrels now occupy the ecosystem, leading to increased variety in gene pools and ecological roles.

To confirm that the squirrels belong to two different biological species, researchers can conduct DNA tests of both species to compare genetic differences, ensuring they do not interbreed and can produce fertile offspring.

The phenotype of Senzo is colour-blind male.

The genotype of Thuli is X^F X^d.

Linda inherited colour-blindness as she received one X chromosome carrying the colour-blind allele (X^d) from her father and one X chromosome (either normal or colour-blind) from her mother, making her genotype either X^F X^d or X^d X^d.

Males typically have a single X chromosome, so if they inherit the X chromosome carrying the recessive allele (X^d), they will express colour-blindness. Females, however, have two X chromosomes and require two copies of the allele to be colour-blind, which is why males are generally affected more frequently.

In a genetic cross between a normal male (X^F Y) and Molly (X^d X^d):

The possible genotypes are X^F X^d (normal female), X^F X^d (normal female), X^d Y (colour-blind male), and X^d Y (colour-blind male). The phenotypes would thus show normal females and colour-blind males.