Insulin and Genetic Engineering

• Diabetes mellitus is the inability of beta cells of pancreas to produce insulin
• Restriction enzymes/endonuclease cut DNA at specific recognition sites
  • This produces either "sticky ends" or "blunt ends"
  • DNA ligase can be used to re-join the ends
• Recombinant DNA technology combines the DNA from two different organisms
• Reverse transcriptase catalyses the formation of DNA from mRNA
• Vector is a gene carrier. It will carry a human gene into the cell of a bacterium or yeast that will be used to make human protein. Produces no benefit for viruses / carrier
• Plasmid, circular strand of DNA, are useful vectors to make human protein from bacteria
• Transgenic organisms contain another species DNA

[EXAM] Remove a particular gene from the DNA of an animal cell

• Locate with the use of a gene probe
• Use restriction enzymes
• Use endonucleases to cut at specific base sequence by hydrolysing
• Breaking sugar-phosphate bonds

[EXAM] Insert this gene into the genetic material of a bacterium

• Same restriction enzymes
• Cut at same base sequence in bacterial DNA
• Leaving sticky ends/hydrogen bonds break
• Join/splice with ligase
• Use of plasmid

Task to find and insert the gene into bacterium for Insulin production

• Isolate human gene, e.g. insulin, by using cytoplasmic mRNA (no introns)
• Reverse transcriptase, taken from a retrovirus, makes DNA from mRNA
• DNA is given "sticky ends" by using the enzyme restriction endonuclease
• Insert into a plasmid from a bacterium
  • Dissolve cell walls using enzymes
  • Centrifuge to separate bacterial chromosome ring from plasmids
  • Cut open the plasmid
  • Add sticky ends
• Mix plasmid and DNA gene together and use DNA ligase to stick them together
• Mix with bacteria //only ≈1% will take up the engineered plasmids
• Identify by using antibiotic resistance. Add gene for antibiotic resistance next to insulin gene in the plasmid. Add antibiotic to the culture / only bacteria surviving have insulin gene
• Grow transformed cells using industrial fermenters
• Isolate and purify human protein made by these cells

Moral and ethical issues associated with recombinant DNA technology

• Transgenic bacteria or viruses may mutate and may become pathogenic
• Genetically modified crops could "escape"
• Forms a genetically modified population in the environment
• Genetic modification may involve the resistance to herbicides
• Escaped crops may become "superweeds" that are difficult to kill and control
• Transgenic organisms could upset the balance of nature
• Population of transgenic salmon have been produced in which individuals grow rapidly
• These transgenic fish could compete for food with other fish species