Application of Reproduction and Genetics

Question 1

What is the Human Genome Project?

Answer 1

An international research project involving thousands of scientists which used Sanger sequencing to successfully map the entire human genome.

Question 2

What is DNA sequencing?

Answer 2

Identifying the base sequence of a DNA fragment.

Question 3

What is Sanger sequencing?

Answer 3

A method of DNA sequencing that only sequences relatively short sections of DNA at a time. It takes a long period of time.

Question 4

Outline the potential benefits of the Human Genome Project.

Answer 4

Allows for the development of targeted, personalised medical treatments and greater accuracy of diagnosis
Increased opportunities for screening genetic conditions and early detection of disease
Enables the study of incidences of mutation in different genes

Question 5

What is the 100K Genome Project?

Answer 5

A UK Government project that aims to study variation in the human genome amongst 100,000 UK citizens. It uses Next Generation Sequencers (NGS).

Question 6

Describe Next Generation Sequencing (NGS).

Answer 6

A faster, cheaper and more accessible method of sequencing that can sequence an entire genome in a few hours.

Question 7

Describe genetic counselling.

Answer 7

Service that provides information and advice to people affected by or at risk of genetic diseases
* Helps individuals and families to make informed decisions

Question 8

What is genetic screening?

Answer 8

• Testing individuals for certain faulty alleles
• Used to detect disorders such as cystic fibrosis, Huntington’s disease and thalassemia

Question 9

Outline the potential disadvantages of genetic screening.

Answer 9

Screening for conditions such as cancer and Alzheimer’s disease only indicates an increased risk - may cause unnecessary stress and anxiety.
What happens to the test result data? Discrimination from employers or insurance companies? Misuse of information?
Risk of false positives or false negatives
Who should be screened? Limited funds and time. Screening embryos could lead to ‘designer babies’

Question 10

Give some examples of organisms other than humans whose genomes have been sequenced.

Answer 10

• Chimpanzees and other primates
• Anopheles gambiae, the mosquito
• Plasmodium parasite

Question 11

How has sequencing the genome of the mosquito, Anopheles gambiae, been useful to humans?

Answer 11

Anopheles has developed insecticide resistance
* Sequencing has enabled the development of chemicals that make Anopheles susceptible to insecticides

Question 12

Outline the advantage of sequencing the genome of the Plasmodium sp. to humans.

Answer 12

• Plasmodium sp. has developed multi-drug resistance
• Enables the development of more effective
  drugs

Question 13

What is genetic fingerprinting? State some applications of genetic fingerprinting.

Answer 13

• A technique used to genetically identify an organism
• Applications in forensics, screening for hereditary diseases, paternity testing, selection for clinical trials

Question 14

What are exons?

Answer 14

Region of DNA that code for an amino acid sequence.

Question 15

What are introns?

Answer 15

Non-coding sequences of DNA.

Question 16

What techniques can be used to produce a genetic fingerprint?

Answer 16

PCR and gel electrophoresis

Question 17

What is PCR?

Answer 17

• Polymerase Chain Reaction
• An in vitro technique used to rapidly amplify fragments of DNA

Question 18

Describe the reaction mixture in the first stage of PCR.

Answer 18

Contains the DNA fragment to be amplified, primers that are complementary to the start of the fragment, free nucleotides to match up to exposed bases, and Taq DNA polymerase to
create the new DNA.

Question 19

What is Taq DNA polymerase?

Answer 19

A thermally stable enzyme that synthesises a double-stranded molecule of DNA from a single template strand using complementary nucleotides.

Question 20

Summarise the process of amplifying DNA fragments using PCR.

Answer 20

1. Heated (95°C) to break hydrogen bonds between DNA strands
2. Cooled (50-60°C) to allow primers to bind - annealing
3. Heated (70°C) to activate Taq DNA polymerase and allow free
   nucleotides to join
4. New DNA acts as a template for next cycle

Question 21

What is gel electrophoresis?

Answer 21

A technique that separates nucleic acid fragments or proteins by size using electric current.

Question 22

How does gel electrophoresis work?

Answer 22

DNA fragments of varying lengths are placed at one end of a slab of agarose gel. Electric current applied. DNA fragments move towards the
positive end of the gel. Shorter fragments travel further. The pattern of bands created is unique to every individual.

Question 23

What is genetic engineering?

Answer 23

The modification of the genome of an organism by the insertion of a desired gene from another organism. This enables the formation of organisms with beneficial characteristics.

Question 24

What is recombinant DNA?

Answer 24

A combination of DNA from two different organisms.

Question 25

Summarise the process of using restriction enzymes to produce DNA fragments.

Answer 25

Gene identified using gene probe. Restriction endonucleases cut DNA at specific palindromic sequences producing sticky ends .

Question 26

Summarise the process of using reverse transcriptase to produce DNA fragments.

Answer 26

mRNA complementary to the target gene used as a template
Reverse transcriptase synthesises cDNA (complementary)
Mixed with free nucleotides which match up to their base pairs. DNA polymerase joins nucleotides forming second strand.

Question 27

Outline the advantages of using reverse transcriptase to produce cDNA.

Answer 27

Don’t have to locate the gene
Gene not cut into non-functional fragments by restriction enzymes
Introns not present in cDNA
* Doesn’t require post-transcriptional processing to produce functional mRNA

Question 28

Summarise the process of inserting a DNA fragment into a vector.

Answer 28

• Plasmid (circular DNA from bacteria) used as the vector
• Plasmid cut using the same restriction enzymes as the DNA, so that the sticky ends are complementary. DNA ligase joins the fragment and plasmid together

Question 29

Describe how antibiotic-resistance genes are used in the identification of recombinant bacteria.

Answer 29

Antibiotic resistance genes can be inserted into plasmids at the same time as DNA fragments. The transformed cells are then placed on a plate with antibiotics. Only the cells that successfully took up the vector will grow.

Question 30

Give an application for genetic modification of bacterial cells.

Answer 30

Human gene for insulin production can be inserted into a vector, so that the bacterial cell will produce insulin. Useful in medicine e.g. treatment of diabetes.

Question 31

Outline the disadvantages of using recombinant DNA to make human products.

Answer 31

• Identifying the required gene may be difficult
  Some eukaryotic genes can’t be expressed in prokaryotes
  Antibiotic-resistance genes could be transferred to pathogenic bacteria
• Expensive

Question 32

What are GM organisms?

Answer 32

Organisms that have had their genome
altered.

Question 33

Outline the benefits of GM crop production.

Answer 33

• Improves nutritional value of foods
• Longer shelf-life of products
• Greater crop yields
• Reduces need for pesticides
• Reduces need for land clearing

Question 34

Outline the risks of GM crop production.

Answer 34

Reduction in biodiversity
Unknown effects on health
Cross-pollination could result in herbicide-resistant weeds
May increases costs for farmers

Question 35

What is gene therapy?

Answer 35

A therapeutic technique in which a faulty allele is replaced with a functional allele in order to treat or prevent disease.

Question 36

Name the two types of gene therapy.

Answer 36

Somatic cell therapy
Germ line therapy

Question 37

Differentiate between somatic cell therapy and germ line therapy.

Answer 37

Somatic - allele introduced to target cells only, short-term, must be repeated
Germ line - allele introduced to embryonic cells so it is present in all resultant cells, permanent, passed onto offspring

Question 38

What is a vector?

Answer 38

A carrier used to transfer a gene from one organism to another, e.g. plasmid or virus.

Question 39

What is Duchenne Muscular Dystrophy (DMD)?

Answer 39

• X-linked recessive condition
• Characterised by muscle degeneration and weakness

Question 40

What is the cause of DMD?

Answer 40

It is caused by one or more mutations in the dystrophin gene that prevent the production of dystrophin.

Question 41

Outline how DMD can be treated using gene
therapy.

Answer 41

1. Healthy gene inserted into vector (e.g. virus)
2. Vector inserted into muscle tissue
3. Virus delivers gene to muscle cells
4. New gene incorporated into DNA of cell
5. Transcription and translation of gene produces normal dystrophin protein
6. Symptoms of DMD alleviated

Question 42

What is drisapersen?

Answer 42

An experimental drug that aims to treat DMD by exon skipping.

Question 43

Explain how drisapersen works.

Answer 43

It introduces a ‘molecular patch’ over the mutated exon, enabling the gene to be read. A shorter, more functional type of dystrophin is synthesised.

Question 44

Discuss the ethical issues surrounding the use of gene therapy.

Answer 44

Health implications - may produce an immune response, activation of oncogenes etc.
Is it right to alter the genotype of an unborn child? What conditions should be treated using gene therapy? Could lead to healthcare inequalities. Expensive - money could be better spent elsewhere.

Question 45

What are stem cells?

Answer 45

Cells that are unspecialised and retain the ability to differentiate into a range of cell types.

Question 46

What is tissue engineering?

Answer 46

An extension of gene therapy that aims to replace, repair or improve biological function by replacing organs and tissues

Question 47

What is the main advantage of using stem cells?

Answer 47

Rapid production of genetically identical cells and organisms.

Question 48

Outline the disadvantages of using stem cells.

Answer 48

• Expensive and unreliable in mammals
  In plants, disease and pathogens can cause issues
• Inadvertent selection of disadvantageous alleles, unknown long-term effects

Question 49

What are the ethical issues related to the use of stem cells from embryos?

Answer 49

Embryos used to provide stem cells are destroyed which is seen as unethical and a waste of potential human life
Could lead to the ‘farming’ of embryos for stem cells
* May lead to the reproductive cloning of humans