TRANSLATION The reading of the mRNA transcript and the creation of the polypeptide chain. The reading of the mRNA transcript and the creation of the polypeptide chain. Occurs on the Ribosomes: Occurs on the Ribosomes: Composed of a small subunit (40S) and a large subunit (60S) Composed of a small subunit (40S) and a large subunit (60S) Made up of ribosomal RNA and protein Made up of ribosomal RNA and protein The mRNA transcript is read by the ribosome in sets of 3 nucleotides to determine the amino acid sequence. The mRNA transcript is read by the ribosome in sets of 3 nucleotides to determine the amino acid sequence. tRNA deliver the appropriate amino acid to the ribosome where the polypeptide chain is built. tRNA deliver the appropriate amino acid to the ribosome where the polypeptide chain is built.

Genetic Code There are 20 amino acids found in proteins, but only 4 bases in the code (U C A G of mRNA) There are 20 amino acids found in proteins, but only 4 bases in the code (U C A G of mRNA) Codons: sequences of three nucleotide bases used to code for an amino acid. Ex. UAC codes for Tyrosine Codons: sequences of three nucleotide bases used to code for an amino acid. Ex. UAC codes for Tyrosine 4 3 =64 possible codons 4 3 =64 possible codons therefore some amino acids can have more than one codon therefore some amino acids can have more than one codon Ex. UUU UUC, UCU, UCC all code for phenylalanine Ex. UUU UUC, UCU, UCC all code for phenylalanine This redundancy helps to reduce errors This redundancy helps to reduce errors

The Genetic Code AUG: start codon used 99% of the time (codes for Methionine) AUG: start codon used 99% of the time (codes for Methionine) UAA, UAG, UGA: stop codons UAA, UAG, UGA: stop codons

tRNA tRNA delivers amino acids to the ribosome Looks like a cloverleaf Has an anticodon – sequence of three bases that recognize (are complementary to) the mRNA codon ex. The GCC codon specifies the a.a. alanine The anticodon on the tRNA carrying alanine would be CGG Opposite arm carries the amino acid binding site Amino acids are added by Aminoacyl t-RNA synthases to make aminoacyl- tRNA

1) Initiation The small subunit of the ribosome recognizes the 5' cap on the mRNA transcript and binds to the RNA. The small subunit of the ribosome recognizes the 5' cap on the mRNA transcript and binds to the RNA. The ribosome will position itself at AUG (the first codon read for every protein) The ribosome will position itself at AUG (the first codon read for every protein) Ensures the correct reading frame (phase in which the mRNA is read) is used by the ribosome Ensures the correct reading frame (phase in which the mRNA is read) is used by the ribosome The large subunit binds and the subunits act as a clamp (80S) around the mRNA. The large subunit binds and the subunits act as a clamp (80S) around the mRNA.

Sites on the Ribosome The large subunit of the ribosome has two sites that the mRNA moves through: The large subunit of the ribosome has two sites that the mRNA moves through: A (acceptor) site: where new amino acids enter the ribosome A (acceptor) site: where new amino acids enter the ribosome P (peptide) site: where the polypeptide chain grows as the amino acids are combined. P (peptide) site: where the polypeptide chain grows as the amino acids are combined. At a third site, the catalytic site, the peptide bonds are made between the amino acid in the A site and the P site. At a third site, the catalytic site, the peptide bonds are made between the amino acid in the A site and the P site.

2) Elongation of the Polypeptide Chain The AUG codon will be in the P site, tRNA carrying the corresponding amino acid (methionine) enters this site. The AUG codon will be in the P site, tRNA carrying the corresponding amino acid (methionine) enters this site. The next tRNA carrying the required a.a. enters the A site. The next tRNA carrying the required a.a. enters the A site. At the catalytic site (b/w A and P) a peptide bond forms between the two amino acids. At the catalytic site (b/w A and P) a peptide bond forms between the two amino acids.

The ribosome moves over one codon. The second tRNA moves to the P site, a new tRNA brings the next a.a. to the A site and the a.a. is added to the chain. The ribosome moves over one codon. The second tRNA moves to the P site, a new tRNA brings the next a.a. to the A site and the a.a. is added to the chain. The first tRNA is released to be recycled for use with another amino acid. The first tRNA is released to be recycled for use with another amino acid. The process repeats with the polypeptide chain trailing in the cytoplasm. The process repeats with the polypeptide chain trailing in the cytoplasm.

Translation

Translation

3) Termination Ribosome will reach a stop codon (UGA, UAG, UAA) Ribosome will reach a stop codon (UGA, UAG, UAA) No tRNA or a.a. exists for a stop codon No tRNA or a.a. exists for a stop codon A release-factor protein helps the two ribosome subunits to fall off the mRNA and the polypeptide chain is released. A release-factor protein helps the two ribosome subunits to fall off the mRNA and the polypeptide chain is released.

4) Post-Translational Modifications Polypeptide chains travel through the RER and are modified to become functional proteins. Polypeptide chains travel through the RER and are modified to become functional proteins. Some amino acids may be glycosylated (sugar added) or phosphorylated (phosphate added) or altered in another way. Some amino acids may be glycosylated (sugar added) or phosphorylated (phosphate added) or altered in another way. Enzymes may cleave (cut) the chain at specific places. Enzymes may cleave (cut) the chain at specific places.

Wobble Hypothesis In codons the third base may differ between 2 codons that code for the same amino acid (UAU and UAC both code for tyrosine). In codons the third base may differ between 2 codons that code for the same amino acid (UAU and UAC both code for tyrosine). If the tRNA's anticodon is AUA it can still bind to UAC. If the tRNA's anticodon is AUA it can still bind to UAC. This flexibility allows for the correct amino acid to be added to the polypeptide chain despite errors in the gene sequence. This flexibility allows for the correct amino acid to be added to the polypeptide chain despite errors in the gene sequence. The proposal that tRNA can recognize more than one codon by unusual base pairing is known as the “wobble hypothesis”. The proposal that tRNA can recognize more than one codon by unusual base pairing is known as the “wobble hypothesis”.