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From Gene to Protein

From Gene to Protein. How Genes Work. The “Central Dogma”. Flow of genetic information in a cell How do we move information from DNA to proteins?. transcription. translation. RNA. DNA. protein. trait. replication. Transcription.

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From Gene to Protein

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  1. From Gene to Protein How Genes Work

  2. The “Central Dogma” • Flow of genetic information in a cell • How do we move information from DNA to proteins? transcription translation RNA DNA protein trait replication

  3. Transcription fromDNA nucleic acid languagetoRNA nucleic acid language

  4. RNA • ribose sugar • N-bases • uracil instead of thymine • U : A • C : G • single stranded • lots of RNAs • mRNA, tRNA, rRNA, siRNA… transcription DNA RNA

  5. Transcription • Making mRNA • transcribed DNA strand = template strand • untranscribed DNA strand = coding strand • same sequence as RNA • synthesis of complementary RNA strand • transcription bubble • enzyme • RNA polymerase coding strand 3 A G C A T C G T 5 A G A A A C G T T T T C A T C G A C T DNA 3 C T G A A 5 T G G C A U C G U T C unwinding 3 G T A G C A rewinding mRNA template strand RNA polymerase 5 build RNA 53

  6. RNA polymerases • 3 RNA polymerase enzymes • RNA polymerase 1 • only transcribes rRNA genes • makes ribosomes • RNA polymerase 2 • transcribes genes into mRNA • RNA polymerase 3 • only transcribes tRNA genes • each has a specific promoter sequence it recognizes

  7. Which gene is read? • Promoter region • binding site before beginning of gene • TATA box binding site • binding site for RNA polymerase & transcription factors • Enhancer region • binding site far upstream of gene • turns transcription on HIGH

  8. Transcription Factors • Initiation complex • transcription factors bind to promoter region • suite of proteins which bind to DNA • hormones? • turn on or off transcription • trigger the binding of RNA polymerase to DNA

  9. RNA polymerase Matching bases of DNA & RNA A • Match RNA bases to DNA bases on one of the DNA strands C U G A G G U C U U G C A C A U A G A C U A 5' 3' G C C A T G G T A C A G C T A G T C A T C G T A C C G T

  10. intron = noncoding (inbetween) sequence exon = coding (expressed) sequence Exons and Introns • Eukaryotic genes are not continuous • exons • expressed / coding DNA • introns • interupting sequence eukaryotic DNA

  11. intron = noncoding (inbetween) sequence exon = coding (expressed) sequence mRNA splicing • Post-transcriptional processing • eukaryotic mRNA needs work after transcription • primary transcript = pre-mRNA • mRNA splicing • edit out introns • make mature mRNA transcript ~10,000 bases eukaryotic DNA pre-mRNA primary mRNA transcript ~1,000 bases mature mRNA transcript spliced mRNA

  12. 1977 | 1993 Discovery of exons/introns Richard Roberts Philip Sharp adenovirus CSHL MIT common cold beta-thalassemia

  13. Splicing must be accurate • No room for mistakes! • a single base added or lost throws off the reading frame AUGCGGCTATGGGUCCGAUAAGGGCCAU AUGCGGUCCGAUAAGGGCCAU AUG|CGG|UCC|GAU|AAG|GGC|CAU Met|Arg|Ser|Asp|Lys|Gly|His AUGCGGCTATGGGUCCGAUAAGGGCCAU AUGCGGGUCCGAUAAGGGCCAU AUG|CGG|GUC|CGA|UAA|GGG|CCA|U Met|Arg|Val|Arg|STOP|

  14. snRNPs snRNA intron exon exon 5' 3' spliceosome 5' 3' lariat 5' 3' exon exon mature mRNA excised intron 5' 3' RNA splicing enzymes • snRNPs • small nuclear RNA • proteins • Spliceosome • several snRNPs • recognize splice site sequence • cut & paste gene

  15. Alternative splicing • Alternative mRNAs produced from same gene • when is an intron not an intron… • different segments treated as exons

  16. 3' poly-A tail 3' A A A A A mRNA 50-250 A’s 5' cap P P P 5' G More post-transcriptional processing • Need to protect mRNA on its trip from nucleus to cytoplasm • enzymes in cytoplasm attack mRNA • protect the ends of the molecule • add 5 GTP cap • add poly-A tail • longer tail, mRNA lasts longer: produces more protein

  17. Translation fromnucleic acid languagetoamino acid language

  18. TACGCACATTTACGTACGCGG DNA AUGCGUGUAAAUGCAUGCGCC mRNA MetArgValAsnAlaCysAla protein ? How does mRNA code for proteins? How can you code for 20 amino acids with only 4 nucleotide bases (A,U,G,C)? 4 ATCG 4 AUCG 20

  19. TACGCACATTTACGTACGCGG DNA AUGCGUGUAAAUGCAUGCGCC mRNA AUGCGUGUAAAUGCAUGCGCC mRNA codon MetArgValAsnAlaCysAla protein ? mRNA codes for proteins in triplets

  20. The code • Code for ALL life! • strongest support for a common origin for all life • Code is redundant • several codons for each amino acid • 3rd base “wobble” • Start codon • AUG • methionine • Stop codons • UGA, UAA, UAG

  21. GCA UAC CAU Met Arg Val How are the codons matched to amino acids? 3 5 TACGCACATTTACGTACGCGG DNA 5 3 AUGCGUGUAAAUGCAUGCGCC mRNA codon 3 5 tRNA anti-codon aminoacid

  22. Transfer RNA structure • “Clover leaf” structure • anticodon on “clover leaf” end • amino acid attached on 3 end

  23. Loading tRNA • Aminoacyl tRNA synthetase • enzyme which bonds amino acid to tRNA • bond requires energy • ATP  AMP • bond is unstable • so it can release amino acid at ribosome easily Trp C=O Trp Trp C=O H2O OH O OH C=O O activating enzyme tRNATrp A C C mRNA U G G anticodon tryptophan attached to tRNATrp tRNATrp binds to UGG condon of mRNA

  24. Ribosomes • Facilitate coupling of tRNA anticodon to mRNA codon • organelle or enzyme? • Structure • ribosomal RNA (rRNA) & proteins • 2 subunits • large • small E P A

  25. Ribosomes • A site (aminoacyl-tRNA site) • holds tRNA carrying next amino acid to be added to chain • P site (peptidyl-tRNA site) • holds tRNA carrying growing polypeptide chain • E site (exit site) • empty tRNA leaves ribosome from exit site Met C A U 5' G U A 3' E P A

  26. 3 2 1 Building a polypeptide • Initiation • brings together mRNA, ribosome subunits, initiator tRNA • Elongation • adding amino acids based on codon sequence • Termination • end codon release factor Leu Val Ser Met Met Ala Leu Met Met Leu Leu Trp tRNA C A G C G A C C C A A G A G C U A C C A U A U U A U G A A 5' 5' A A 5' C U U 5' A A G G A G U U G U C U U U G C A C U 3' G G U A A U A A C C mRNA 3' 3' 3' U G G U A A 3' E P A

  27. Destinations: • secretion • nucleus • mitochondria • chloroplasts • cell membrane • cytoplasm • etc… Protein targeting • Signal peptide • address label start of a secretory pathway

  28. RNA polymerase DNA Can you tell the story? aminoacids exon intron tRNA pre-mRNA 5' GTP cap mature mRNA aminoacyl tRNAsynthetase poly-A tail 3' large ribosomal subunit polypeptide 5' tRNA small ribosomal subunit E P A ribosome

  29. enhancer translation start translation stop exons 1000+b 20-30b RNA polymerase DNA UTR UTR introns promoter transcription start transcription stop pre-mRNA 5' 3' 5' 3' mature mRNA The Transcriptional unit (gene?) transcriptional unit (gene) 3' 5' TAC ACT TATA DNA GTP AAAAAAAA

  30. Bacterial chromosome Protein Synthesis in Prokaryotes Transcription mRNA Cell membrane Cell wall

  31. Prokaryotes DNA in cytoplasm circular chromosome naked DNA no introns Eukaryotes DNA in nucleus linear chromosomes DNA wound on histone proteins introns vs. exons intron = noncoding (inbetween) sequence exon = coding (expressed) sequence Prokaryote vs. Eukaryote genes eukaryotic DNA

  32. Translation in Prokaryotes • Transcription & translation are simultaneous in bacteria • DNA is in cytoplasm • no mRNA editing • ribosomesread mRNA as it is being transcribed

  33. Translation: prokaryotes vs. eukaryotes • Differences between prokaryotes & eukaryotes • time & physical separation between processes • takes eukaryote ~1 hour from DNA to protein • no RNA processing

  34. Substitute Slides for Student Print version

  35. Can you tell the story?

  36. enhancer 1000+b 20-30b RNA polymerase 5' 3' 5' 3' The Transcriptional unit exons transcriptional unit 3' 5' TAC ACT TATA DNA introns

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