Essential Biology 4.3 Theoretical Genetics / Quiz Date:
Student Name:

Resources: Clegg pp 103-115, Rev Guide pp 26-29

  1. Define the following:

Genotype
Gene expression
Phenotype
Dominant allele
Recessive allele
Codominant alleles
Homozygous
Heterozygous
Carrier
Mixed phenotype
Autosome
Sex chromosome
Gene locus
Monohybrid cross
Test cross
  1. Outline the conventions for notation of genotypes, using one example of each:

Dominant/recessive alleles / Codominant alleles / Sex-linked traits
  1. The allele for tall plants is dominant over the allele for dwarf plants.
  1. State the possible genotypes of a tall plant.
  1. Explain how a test cross could be used to determine the genotype of a tall plant.
  1. Mendel is known as the father of genetics for his extensive experimental work with peas and different types of crosses.
  1. Complete the punnet grid below to show the outcome of the monohybrid cross that results in peas of different colours.

  1. Complete the punnet grid below to show the possible outcomes of a cross between two members of the F1 generation. Describe all genotypes produced.
  1. Human ABO blood types follow a codominant inheritance pattern.
  1. Describe what is meant by “some genes have multiple alleles.”
  1. Complete the table below to show how blood type is inherited.

alleles / i / IA / IB
i
IA
IB
  1. Highlight the genotype and phenotype which is an example of codominance.
  1. Complete this pedigree chart to show the inheritance of blood types in this family.

  1. Sickle cell is another example of codominance.
  1. State the genotypes and phenotypes of these individuals.

HbAHbA / HbAHbs / HbsHbs
genotype
phenotype
  1. Predict the phenotype ratios of offspring in the following crosses. Show all your working, and set it out as expected. Take care with notation.
  1. “Carrier”(heterozygous) mother with affected father
  1. Affected father with unaffected mother.
  1. “Carrier”(heterozygous) mother with carrier father.
  1. Explain how the prevalence of sickle cell in regions of Africa is an example of natural selection in action.
  1. The pedigree chart below shows a family affected by sickle cell:
  1. Deduce the genotype of each individual with a letter.

A / F
B / G
C / H
D / $
E / #
  1. Calculate the likelihood of any further children produced by E and her # having sickle cell anemia.
  1. Male $ is healthy but of unknown genotype. Calculate the likelihood of any children produced with female D having sickle cell anemia. Show all working.
  1. Some traits are autosomal whereas others are carried on sex chromosomes.
  1. Distinguish between autosomes and sex chromosomes.
  1. Annotate the diagram to distinguish between the X and Y chromosomes.
  1. Outline the role of the SRY gene on the Y chromosome.
  1. Outline how non-disjunction can lead to gender-related chromosome abnormalities.
  1. Some inherited disorders are associated with gender.
  1. Define sex-linkage.
  1. State two examples of sex-linked genetic disorders.
  1. Explain why sex-linked disorders are more common in males than females.
  1. Explain why human females can be homozygous or heterozygous for sex-linked genes, where males cannot.
  1. The allele for colour blindness (n) is recessive to the allele for normal vision (N). This gene is carried in a non-homologous region on the X chromosome. Complete the table below to show the genotypes and phenotypes of individuals with regard to colour blindness.

Female / Male
Normal / XN XN
Affected
Carrier / Not possible! Why?
  1. In the space below, complete a punnet grid to show a cross between a normal male and a carrier female. What is the expected ratio of phenotypes?
  1. Hemophilia is a blood-clotting disorder that is also recessive and sex-linked.
  1. State the normal function of the gene associated with hemophilia.
  1. Describe the effects and symptoms of hemophilia.
  1. Use the pedigree chart to deduce the possible genotype(s) of the named individuals.

/ Leopold
Helen
Alice
Mary
Rubert
Bob
Britney
  1. Outline one form of genetic engineering used to help patients with hemophilia.
  1. Suggest reasons why the frequency of some disease-related alleles might be increasing in the population.