Syllabus Edition

First teaching 2014

Last exams 2024

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Translation (DP IB Biology: HL)

Revision Note

Phil

Author

Phil

Expertise

Biology

Initiation of Translation

Initiation of translation involves assembly of the components that carry out the process.

  • During translation, the specific sequence of messenger RNA (mRNA) is translated to produce a polypeptide chain consisting of amino acids
    • mRNA is a single stranded, linear, RNA molecule that transfers the information in DNA from the nucleus into the cytoplasm
  • Translation is categorised into three stages: initiation, elongation and termination
  • Translation occurs in the cytoplasm at complex molecules made of protein and RNA called ribosomes
    • Ribosomes have a two-subunit (large and small) structure that helps bind mRNA
    • Ribosomes have three tRNA binding sites termed “E” (exit), “P” (peptidyl) and “A” (aminoacyl)
      • At the A site the mRNA codon joins with the tRNA anticodon
      • At the P site the amino acids attached to the tRNA are joined by peptide bonds
      • At the E site the tRNA exits the ribosome
  • Another key molecule in translation is transfer RNA (tRNA) that decodes mRNA
    • tRNA molecules are single stranded RNA molecules that fold to form a clover-shaped structure
      • The folded structure is held together by hydrogen bonds between bases at different points on the strand
      • tRNA molecules are the shortest of the RNA molecules, being only around 80 nucleotides in length
      • There are 20 different types of tRNA molecule, one for each of the amino acids involved in protein synthesis
    • tRNA molecules have a region that binds to a specific amino acid as well as a three-nucleotide region called an anticodon that is complementary to the codon on mRNA
    • The role of tRNA molecule is to carry a specific amino acid to the ribosome
tRNA structure
Structure of tRNA
  • In eukaryotic cells, the mRNA molecule leaves the nucleus through the nuclear pores
  • Translation is initiated by the following process
    • A small ribosomal subunit attaches to the 5’ end of mRNA
    • An initiator tRNA molecule carrying the amino acid methionine binds to the small ribosomal subunit
      • The initiator tRNA occupies the “P” site on the ribosome
    • The ribosome moves along the mRNA until it locates a start codon (AUG)
    • The large ribosomal subunit binds to the small subunit
      • Elongation of the polypeptide can begin

Elongation of the Polypeptide

  • The initiator tRNA currently occupies the “P” site, the next codon on the mRNA signals for the corresponding tRNA to bind at the “A” site
    • The two amino acids (attached to the tRNAs) are linked with a peptide bond, forming a dipeptide
  • Synthesis of the peptide chain now involves a repeated cycle of events
    • In the cytoplasm, free tRNA molecules bind to their corresponding amino acids and transport them to the ribosome
    • The ribosome shifts along the mRNA one codon (three bases) at a time
      • The initiator tRNA in the “P” site moves to the “E” site which releases it
      • The tRNA carrying the peptide chain moves from the “A” site to the “P” site
      • The next mRNA codon is exposed and a tRNA with the complementary anticodon binds to the unoccupied “A” site whilst its amino acid is linked to the polypeptide chain
  • The cyclical process is repeated as new amino acids are added to the growing chain

Termination of Translation

  • The process of elongation continues until one of three ‘stop’ codons (UAA, UAG and UGA) on the mRNA molecule is reached
    • Stop codons do not code for a tRNA molecule but act as a signal for translation to stop
  • The polypeptide chain and mRNA are released from the ribosome
  • The ribosome disassembles back into two separate subunits
    • And can await the arrival of the next mRNA molecule

elongation-of-polypeptide-ib-1

elongation-of-polypeptide-ib-2

elongation-of-polypeptide-ib-3

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elongation-of-polypeptide-ib-5

elongation-of-polypeptide-ib-6

Following the initiation of protein synthesis, translation involves a repeated cycle of events to build the polypeptide chain, tRNA molecules move into the A, P and E sites as the ribosome reads the mRNA

Exam Tip

You don't need to remember the precise base sequences of start and stop codons for your examination. 

tRNA-activating Enzymes

  • Amino acids are paired to specific tRNA molecules through the action of tRNA-activating enzymes
    • Each tRNA activating enzyme recognises a specific tRNA molecule
  • tRNA-activating enzymes, in common with most enzymes, are substrate-specific and recognise the correct tRNA molecules by their shape
    • Nucleotide sequence variability between tRNA molecules results in variation in their three-dimensional structure
    • Active sites of tRNA-activating enzymes are optimised to bind a specific tRNA
  • Initially, a tRNA-activating enzyme binds to ATP and a specific amino acid
  • The active site of the enzyme attracts a conformationally-specific tRNA molecule
  • The tRNA molecule is bound to the amino acid using ATP (phosphorylation) to create a high energy bond
    • The stored energy in this bond will be used later in peptide bond formation to link the amino acid to the growing polypeptide chain
    • This is an example of how an anabolic reaction like protein synthesis utilises the energy stored in ATP
  • A tRNA molecule with an amino acid attached is called a charged tRNA

specific-trna-activating

Specific tRNA-activating enzymes are involved in charging an amino acid to a specific tRNA molecule

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Phil

Author: Phil

Phil has a BSc in Biochemistry from the University of Birmingham, followed by an MBA from Manchester Business School. He has 15 years of teaching and tutoring experience, teaching Biology in schools before becoming director of a growing tuition agency. He has also examined Biology for one of the leading UK exam boards. Phil has a particular passion for empowering students to overcome their fear of numbers in a scientific context.