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Translation mRNA to Proteins

Translation mRNA to Proteins. Objectives . Identify that amino acids are coded by mRNA base sequences and are linked to become proteins Describe how mRNA codons are translated into amino acids Summarize the process of protein synthesis. Review . What was the purpose of transcription?

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Translation mRNA to Proteins

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  1. TranslationmRNA to Proteins

  2. Objectives Identify that amino acids are coded by mRNA base sequences and are linked to become proteins Describe how mRNA codons are translated into amino acids Summarize the process of protein synthesis

  3. Review What was the purpose of transcription? To transcribe (copy) DNA into a disposable copy called mRNA to leave the nucleus. What are the nitrogen bases of mRNA? A, U, G, C What is the sugar for mRNA? Ribose What are the 3 differences between DNA and RNA? Ribose sugar, single stranded, Uracil instead of Thymine What are the 3 different types of RNA? mRNA, rRNA, tRNA

  4. Translation TRANSLATION: process that converts, or translates, an mRNA message into a protein (amino acid chain). How is mRNA translated?? By reading the nitrogen base sequences in groups of 3. These groups of 3 are called Codons.

  5. codon for methionine (Met) codon for leucine (Leu) Codons • Codon- a group of three nucleotides on mRNA that code for a particular amino acid

  6. If you had the mRNA sequence: UCGCACGGU • The codons would be: UCG CAC GGU • What amino acids would be coded for? • Let’s find out!

  7. Finding Amino acids from Codon • Reading the mRNA codons left to right write the amino acid sequence of the protein translated from the mRNA.

  8. Codon to Amino Acid UCG = • Serine CAC = • Histidine GGU = • Glycine

  9. Amino Acids • There are 64 possible three-base codons that can be created using the four nitrogen bases (4 x 4 x 4 = 64) • There are 20 different amino acids • There are multiple codons that code for the same amino acids • AUG= start codon for protein synthesis or methionine. This means that translation always begins with methionine (AUG). • Three codonsdo not code for an amino acid so are considered stop codonsthat signals the end of an amino acid chain. - UAA, UAG, UGA

  10. How does a cell interpret DNA? • Write the following DNA sequence: • GAC AAG TCC ACA ATC • Write the mRNA sequence that would be transcribed from this gene: • CUG UUC AGG UGU UAG • Reading the mRNA codons, write the amino acid sequence of the polypeptide translated from the mRNA

  11. Codon to Amino Acid CUG= Leucine UUC= Phenylalanine AGG= Arginine UGU= Cysteine UAG= Stop

  12. Makin' Proteins • So proteins are determined by the chain of amino acids that make them up • But how do our protein makers know which amino acids to add?

  13. What’s Next… Translation! • After mRNA LEAVES the NUCLEUS, it takes DNA’s message to the RIBOSOME (rRNA) • Proteins are made on the rRNA using mRNA as a template. • So translation occurs in the rRNA, which is located in the cytoplasm of the cell. • Three steps to translation • Initiation • Elongation • Termination

  14. ) REMEMBER: mRNA is READ 3 letters at a time in order to determine what protein is to be made • These three letters are called a CODON • The CODON on the mRNA matches up with the ANTICODON on the tRNA molecule

  15. Initiation: The start of translation • The small ribosomal subunit attaches to the strand of mRNA at the 5` end. • A tRNA molecule with the start or initiator anticodon(UAC) attaches to the mRNA. • The large ribosomal subunit attaches, locking the initiator tRNA in the P (peptide) site.

  16. ElongationThe amino acid chain gets longer • The second tRNA molecule, with an anticodon that is complementary to the second codon on the mRNA, attaches in the A site of the large subunit. • A peptidebond is formed between the amino acid of the tRNA in the A site and that of the P site. • The tRNA molecule in the P site is kicked out and the one in the A site (with the growing polypeptide chain) shifts into the P site. • The process repeats many times until tRNA reaches a stop codon.

  17. TerminationThe final step • Toward the end of the coding sequence of the mRNA, a termination (stop) codon is encountered (UAG, UAA, or UGA). • There are no tRNA molecules that match the stop codons, but a special protein called a release factor does recognize the sequence, and attaches. • This special protein causes the newly created amino acid chain to be released. • The ribosomal subunits disassemble. • Translation is complete!!!!!!!!!!!!!!!!!

  18. Amino Acid Chain

  19. Review • 1. Initiation • 2. Elongation • 3. Termination

  20. Transcription -In NUCLEUS -DNA copied to mRNA -mRNA to Ribosome **Protein Synthesis in a Nutshell** Translation -In RIBOSOME -Codon/Anticodon pair -codon determines what AA comes in -AA combine-proteins

  21. Transcription Adenine (DNA and RNA) Cystosine (DNA and RNA) Guanine(DNA and RNA) Thymine (DNA only) Uracil (RNA only) RNApolymerase DNA RNA

  22. Translation Nucleus mRNA Lysine tRNA Phenylalanine Methionine Ribosome Start codon mRNA

  23. Translation Continued Growing polypeptide chain Ribosome tRNA Lysine tRNA mRNA Translation direction Ribosome

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