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Chapter 17~ From Gene to Protein.

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Presentation on theme: "Chapter 17~ From Gene to Protein."— Presentation transcript:

1 Chapter 17~ From Gene to Protein

2 Protein Synthesis: overview
One gene-one enzyme hypothesis (Beadle and Tatum) One gene-one polypeptide (protein) hypothesis pg 311 2

3 Protein Synthesis: overview
Genes provide the INSTRUCTIONS for making proteins RNA = bridge between DNA and Protein synthesis (ribonucleic acid - contains ribose) 2 major stages: Transcription: synthesis of messenger RNA (mRNA) under the direction of DNA (information is “copied” or “written” to RNA) Translation: actual synthesis of a polypeptide under the direction of mRNA

4 Protein Synthesis: overview
WHY use RNA as an intermediate? Protects DNA Allows for many copies of a protein to be made simultaneously Chain of command DNA - RNA - Protein 4

5 The Triplet Code The genetic instructions for a polypeptide chain are ‘written’ in the DNA as a series of nucleotide ‘words’ Codons written 5’-3’ direction ‘U’ (uracil) replaces ‘T’ in RNA

6 Transcription, I CLICK Picture for movie
RNA polymerase: pries DNA apart and hooks RNA nucleotides together from the DNA code Promoter region on DNA: where RNA polymerase attaches and where initiation of RNA begins Terminator region: sequence that signals the end of transcription Transcription unit: stretch of DNA transcribed into an RNA molecule CLICK Picture for movie

7 Transcription, II Initiation~ transcription factors mediate the binding of RNA polymerase to an initiation sequence (TATA box) Elongation~ RNA polymerase continues unwinding DNA and adding nucleotides to the 3’ end Termination~ RNA polymerase reaches terminator sequence

8 Transcription, II CLICK Picture for movie

9 mRNA modification 1) 5’ cap: modified guanine; protection; recognition site for ribosomes 2) 3’ tail: poly(A) tail (adenine); protection; recognition; transport 3) RNA splicing: exons (expressed sequences) kept,introns (intervening sequences) spliced out; spliceosome

10 mRNA modification - Splicing
Evolutionary ? Allows a single gene to code for more than one kind of polypeptide (alternative RNA splicing) Shifting of Introns can allow a new variety of protein 10

11 Translation, I mRNA from nucleus is ‘read’ along its codons by tRNA’s anticodons at the ribosome tRNA - (transfer RNA) anticodon (nucleotide triplet) amino acid

12 Translation, II rRNA (ribosomal RNA) site of mRNA codon & tRNA anticodon coupling P site holds the tRNA carrying the growing polypeptide chain A site holds the tRNA carrying the next amino acid to be added to the chain E site discharged tRNA’s Click for ANIMATION

13 Translation, III Initiation~ union of mRNA, tRNA, small ribosomal subunit; followed by large subunit Elongation~ •codon recognition •peptide bond formation •translocation Termination~ ‘stop’ codon reaches ‘A’ site Polyribosomes: translation of mRNA by many ribosomes (many copies of a polypeptide very quickly) String of ribosomes

14 Ribosomes: Free vs. Bound
Identical and switch their status Translation always begins w/ free When do they become bound? A signal peptide is formed causing translation to halt until ribosome connects to the ER Once connected, translation continues and protein enters the ER

15 Mutations: genetic material changes in a cell
Point mutations…. Changes in 1 or a few base pairs in a single gene Base-pair substitutions: silent mutations no effect on protein missense ∆ to a different amino acid (different protein) nonsense ∆ to a stop codon and a nonfunctional protein

16 Mutations: genetic material changes in a cell
Frameshift Mutation insertion or deletion of nucleotide pairs in a gene; alters the ‘reading frame’ of triplets Mutagens: physical and chemical agents that change DNA


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