Genetic Modification (Cambridge O Level Biology)

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Genetic Modification: Definition

  • Genetic modification is changing the genetic material of an organism by removing, changing or inserting individual genes from another organism
  • The organism receiving the genetic material is said to be ‘genetically modified’, or is described as a ‘transgenic organism’
  • The DNA of the organism that now contains DNA from another organism is known as ‘recombinant DNA’

Genetic Modification: Examples

  • There are many examples of genetically modified organisms, including:
    • Crop plants, such as wheat and maize, have been genetically modified to contain a gene from a bacterium that produces a poison that kills insects, making them resistant to insect pests such as caterpillars
    • Crop plants have also been genetically modified to make them resistant to certain herbicides (chemicals that kill plants), meaning that when the herbicide is sprayed on the crop it only kills weeds and does not affect the crop plant
    • Some crops have been genetically modified to produce additional vitamins, eg ‘golden rice’ contains genes from another plant and a bacterium which make the rice grains produce a chemical that is turned into vitamin A in the human body, which could help prevent deficiency diseases in certain areas of the world
    • The gene for human insulin has been inserted into bacteria which then produce human insulin which can be collected and purified for medical use for diabetics

Genetic modification using bacterial production of a human protein

  • The gene that is to be inserted is located in the original organism (for example, this could be the gene for human insulin)
  • Restriction enzymes are used to isolate the required gene, leaving it with ‘sticky ends’ (a short section of unpaired bases)
  • A bacterial plasmid is cut by the same restriction enzyme leaving it with corresponding sticky ends (plasmids are circles of DNA found inside bacterial cells)

Restriction Enzymes Cutting DNA

Restriction enzymes, IGCSE & GCSE Biology revision notesRestriction enzymes cut DNA strands at specific sequences to form ‘sticky ends’

  • The plasmid and the isolated gene are joined together by DNA ligase enzyme
  • If two pieces of DNA have matching sticky ends (because they have been cut by the same restriction enzyme), DNA ligase will link them to form a single, unbroken molecule of DNA

DNA Ligase and Plasmids

Recombinant plasmids, IGCSE & GCSE Biology revision notes

DNA ligase is used to join two separate pieces of DNA together

  • The genetically engineered plasmid is inserted into a bacterial cell
  • When the bacteria reproduce the plasmids are copied as well and so a recombinant plasmid can quickly be spread as the bacteria multiply and they will then all express the gene and make the human protein
  • The genetically engineered bacteria can be placed in a fermenter to reproduce quickly in controlled conditions and make large quantities of the human protein
  • Bacteria are extremely useful for genetic engineering purposes because:
    • They contain the same genetic code as the organisms we are taking the genes from, meaning they can easily ‘read’ it and produce the same proteins
    • There are no ethical concerns over their manipulation and growth (unlike if animals were used, as they can feel pain and distress)
    • The presence of plasmids in bacteria, separate from the main bacterial chromosome, makes them easy to remove and manipulate to insert genes into them and then place back inside the bacterial cells

Advantages & Risks of Genetic Modification

Advantages & Risks of Genetic Modification Table

 Advantages  Risks

Reduced use of chemicals such as herbicides and pesticides is: better for the environment, cheaper and less time-consuming for farmers.

Increased costs of seeds

Companies that make GM Seeds charge more for them to cover the cost of developing them. This can mean smaller, poorer farmers cannot compete with larger farms.

Increased yields from the crops as they are not competing with weeds for resources or suffering from pest damage. Increased dependency on certain chemicals, such as the herbicides that crops are resistant to. These are often made by the same companies that produce the seed and are more expensive to buy.
Bacteria have a rapid reproduction rate and so can produce large quantities of product in a short space of time. Risk of inserted genes being transferred to wild plants by pollination. This could reduce the usefulness of the GM Crop (e.g. if weeds also gain the gene that makes them resistant to herbicide).
There is a lack of ethical concerns over the manipulation and growth of bacteria.

Reduced biodiversity as there are fewer plant species when herbicides have been used. This can impact insects and insect-eating birds.

The genetic code in bacteria is shared with all other organisms. Some research has shown that plants that have had genes inserted into them do not grow as well as non-GM plants.
  Bacteria could pass human genes they carry to other bacteria, resulting in unknown consequences.

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Lára

Author: Lára

Expertise: Biology Lead

Lára graduated from Oxford University in Biological Sciences and has now been a science tutor working in the UK for several years. Lára has a particular interest in the area of infectious disease and epidemiology, and enjoys creating original educational materials that develop confidence and facilitate learning.