The Genetic Code (OCR AS Biology)

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Nature of the Genetic Code

  • A gene is a sequence of nucleotides that forms part of a DNA molecule (one DNA molecule contains many genes)
  • This sequence of nucleotides (the gene) codes for the production of a specific polypeptide (protein)
  • Protein molecules are made up of a series of amino acids bonded together
  • The shape and behaviour of a protein molecule depends on the exact sequence of these amino acids (the initial sequence of amino acids is known as the primary structure of the protein molecule)
  • The genes in DNA molecules, therefore, control protein structure (and as a result, protein function) as they determine the exact sequence in which the amino acids join together when proteins are synthesised in a cell

From gene to polypeptide, downloadable AS & A Level Biology revision notes

A gene is a sequence of nucleotides that codes for the production of a specific protein molecule (polypeptide)

The triplet code

  • The sequence of DNA nucleotide bases found within a gene is determined by a triplet (three-letter) code
  • Each sequence of three bases (i.e. each triplet of bases) in a gene codes for one amino acid
  • These triplets codes for different amino acids ā€“ there are 20 different amino acids that cells use to make up different proteins
  • For example:
    • CAG codes for the amino acid valine
    • TTC codes for the amino acid lysine
    • GAC codes for the amino acid leucine
    • CCG codes for the amino acid glycine

  • Some of these triplets of bases code for start (TAC ā€“ methionine) and stop signals
  • These start and stop signals tell the cell where individual genes start and stop
  • As a result, the cell reads the DNA correctly and produces the correct sequences of amino acids (and therefore the correct protein molecules) that it requires to function properly
  • The genetic code is non-overlapping
    • Each base is only read once in which codon it is part of

  • There are four bases, so there are 64 different codons (triplets) possible (43 = 64), yet there are only 20 amino acids that commonly occur in biological proteins
    • This is why the code is said to be degenerate: multiple codons can code for the same amino acids
    • The degenerate nature of the genetic code can limit the effect of mutations

  • The genetic code is also universal, meaning that almost every organism uses the same code (there are a few rare and minor exceptions)
  • The same triplet codes code for the same amino acids in all living things (meaning that genetic information is transferable between species)
    • The universal nature of the genetic code is why genetic engineering (the transfer of genes from one species to another) is possible

Codons and anticodons

  • Once mRNA has been formed and left the nucleus it moves to the ribosomes where it can as a template for protein synthesis
  • Each triplet within the mRNA code is described as a codon
  • The tRNA molecules that transfer amino acids possess anticodons which are complementary to the codons on mRNA

Ā 

A DNA molecule with the triplet code for the mRNA codons of the start amino acid (methionine) and valine

Examiner Tip

Remember ā€“ each chromosome in a human cell nucleus contains one very long DNA molecule. This DNA molecule is made up of thousands of specific nucleotide sequences called genes that code for specific proteins. Even though these genes are all found within the same DNA molecule and are therefore all linked up, the cell knows where individual genes start and stop. This ensures the cell reads the DNA correctly and can produce the correct protein molecules that it requires to function properly.

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Alistair

Author: Alistair

Expertise: Biology & Environmental Systems and Societies

Alistair graduated from Oxford University with a degree in Biological Sciences. He has taught GCSE/IGCSE Biology, as well as Biology and Environmental Systems & Societies for the International Baccalaureate Diploma Programme. While teaching in Oxford, Alistair completed his MA Education as Head of Department for Environmental Systems & Societies. Alistair has continued to pursue his interests in ecology and environmental science, recently gaining an MSc in Wildlife Biology & Conservation with Edinburgh Napier University.