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Codon Optimization

Codon Optimization. Codon Optimization. Codon Usage Bias: Variable frequency of synonomous codons . Codon preferences reflect natural selection in organisms for translational optimization. Optimal codons allow faster translation rates, thus highly expressed genes are coded by these.

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Codon Optimization

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  1. Codon Optimization

  2. Codon Optimization • Codon Usage Bias: Variable frequency of synonomouscodons. • Codon preferences reflect natural selection in organisms for translational optimization. • Optimal codons allow faster translation rates, thus highly expressed genes are coded by these. • Codon optimization can be used to produce a synthetic version of a foreign gene for more efficient expression.

  3. Codon Usage of HIV vs. Human

  4. Expression Profile of Synthetic vs. Wildtype gp120

  5. HIV Codons Decrease Efficiency of Thy-1 Expression -Thy-1 is a highly expressed cell-surface protein. -Replacing codons of Thy-1 with HIV envelope codons significantly decreases expression.

  6. Codon Optimization of GFP • A: Control: Empty vector. • B: Native GFP from Aequoreavictoria. • C: Mammalian codon optimized GFP. • D: Mammalian codon optimized GFP + S65T replacement.

  7. E. Coli vs. Human Codon Usage

  8. Codon Optimization: Human to Bacteria

  9. Codon Optimization: Human to Bacteria

  10. Codon Optimization: Human to Bacteria

  11. Codon Optimization: Human to Bacteria

  12. Codon Optimization: Human to Bacteria

  13. Polymerase Chain Reaction • Molecular biology technique used to amplify specific nucleotide sequences. • Developed by Kary Mullis in 1983. • Takes advantage of Taq polymerase from thermophileThermusaquaticus. • Taq is a heat-resistant enzyme that can function in temperatures above 70°C.

  14. Polymerase Chain Reaction

  15. Polymerase Chain Reaction

  16. Components of PCR • Water • Taq Buffer containing divalent and monovalentcations – Provides suitable chemical environment for optimal activity of DNA polymerase (pH, [salt], co-factors,etc.) • DNA template containing target region to be amplified. • Sense and anti-sense primers. • Deoxynucleotidetriphosphates (dNTPs), the building-blocks for synthesis of new DNA. • Taq polymerase – has optimal activity around 70°C.

  17. Homework Assignment • NCBI • Search through GENE databases. • Enter the name of the gene of interest. • Search for Homo sapien or E. coli and select the gene. • Scroll down to mRNA and proteins and select. • Copy the “translation” • Encorbio • Select the organism that the gene will be codon optimized to. • Paste the amino acid sequence into the top box. • Generate the coding sequence.

  18. Example: Insulin-like Growth Factor 1 Receptor (IGF1R) • Amino Acid Sequence • MKSGSGGGSPTSLWGLLFLSAALSLWPTSGEICGPGIDIRNDYQQLKRLENCTVIEGYLHILLISKAEDYRSYRFPKLTVITEYLLLFRVAGLESLGDLFPNLTVIRGWKLFYNYALVIFEMTNLKDIGLYNLRNITRGAIRIEKNADLCYLSTVDWSLILDAVSNNYIVGNKPPKECGDLCPGTMEEKPMCEKTTINNEYNYRCWTTNRCQKMCPSTCGKRACTENNECCHPECLGSCSAPDNDTACVACRHYYYAGVCVPACPPNTYRFEGWRCVDRDFCANILSAESSDSEGFVIHDGECMQECPSGFIRNGSQSMYCIPCEGPCPKVCEEEKKTKTIDSVTSAQMLQGCTIFKGNLLINIRRGNNIASELENFMGLIEVVTGYVKIRHSHALVSLSFLKNLRLILGEEQLEGNYSFYVLDNQNLQQLWDWDHRNLTIKAGKMYFAFNPKLCVSEIYRMEEVTGTKGRQSKGDINTRNNGERASCESDVLHFTSTTTSKNRIIITWHRYRPPDYRDLISFTVYYKEAPFKNVTEYDGQDACGSNSWNMVDVDLPPNKDVEPGILLHGLKPWTQYAVYVKAVTLTMVENDHIRGAKSEILYIRTNASVPSIPLDVLSASNSSSQLIVKWNPPSLPNGNLSYYIVRWQRQPQDGYLYRHNYCSKDKIPIRKYADGTIDIEEVTENPKTEVCGGEKGPCCACPKTEAEKQAEKEEAEYRKVFENFLHNSIFVPRPERKRRDVMQVANTTMSSRSRNTTAADTYNITDPEELETEYPFFESRVDNKERTVISNLRPFTLYRIDIHSCNHEAEKLGCSASNFVFARTMPAEGADDIPGPVTWEPRPENSIFLKWPEPENPNGLILMYEIKYGSQVEDQRECVSRQEYRKYGGAKLNRLNPGNYTARIQATSLSGNGSWTDPVFFYVQAKTGYENFIHLIIALPVAVLLIVGGLVIMLYVFHRKRNNSRLGNGVLYASVNPEYFSAADVYVPDEWEVAREKITMSRELGQGSFGMVYEGVAKGVVKDEPETRVAIKTVNEAASMRERIEFLNEASVMKEFNCHHVVRLLGVVSQGQPTLVIMELMTRGDLKSYLRSLRPEMENNPVLAPPSLSKMIQMAGEIADGMAYLNANKFVHRDLAARNCMVAEDFTVKIGDFGMTRDIYETDYYRKGGKGLLPVRWMSPESLKDGVFTTYSDVWSFGVVLWEIATLAEQPYQGLSNEQVLRFVMEGGLLDKPDNCPDMLFELMRMCWQYNPKMRPSFLEIISSIKEEMEPGFREVSFYYSEENKLPEPEELDLEPENMESVPLDPSASSSSLPLPDRHSGHKAENGPGPGVLVLRASFDERQPYAHMNGGRKNERALPLPQSSTC • Codon Optimized Sequence • ATGAAAAGCGGCAGCGGCGGCGGCAGCCCGACCAGCCTGTGGGGCCTGCTGTTTCTGAGCGCGGCGCTGAGCCTGTGGCCGACCAGCGGCGAAATTTGCGGCCCGGGCATTGATATTCGCAACGATTATCAGCAGCTGAAACGCCTGGAAAACTGCACCGTGATTGAAGGCTATCTGCATATTCTGCTGATTAGCAAAGCGGAAGATTATCGCAGCTATCGCTTTCCGAAACTGACCGTGATTACCGAATATCTGCTGCTGTTTCGCGTGGCGGGCCTGGAAAGCCTGGGCGATCTGTTTCCGAACCTGACCGTGATTCGCGGCTGGAAACTGTTTTATAACTATGCGCTGGTGATTTTTGAAATGACCAACCTGAAAGATATTGGCCTGTATAACCTGCGCAACATTACCCGCGGCGCGATTCGCATTGAAAAAAACGCGGATCTGTGCTATCTGAGCACCGTGGATTGGAGCCTGATTCTGGATGCGGTGAGCAACAACTATATTGTGGGCAACAAACCGCCGAAAGAATGCGGCGATCTGTGCCCGGGCACCATGGAAGAAAAACCGATGTGCGAAAAAACCACCATTAACAACGAATATAACTATCGCTGCTGGACCACCAACCGCTGCCAGAAAATGTGCCCGAGCACCTGCGGCAAACGCGCGTGCACCGAAAACAACGAATGCTGCCATCCGGAATGCCTGGGCAGCTGCAGCGCGCCGGATAACGATACCGCGTGCGTGGCGTGCCGCCATTATTATTATGCGGGCGTGTGCGTGCCGGCGTGCCCGCCGAACACCTATCGCTTTGAAGGCTGGCGCTGCGTGGATCGCGATTTTTGCGCGAACATTCTGAGCGCGGAAAGCAGCGATAGCGAAGGCTTTGTGATTCATGATGGCGAATGCATGCAGGAATGCCCGAGCGGCTTTATTCGCAACGGCAGCCAGAGCATGTATTGCATTCCGTGCGAAGGCCCGTGCCCGAAAGTGTGCGAAGAAGAAAAAAAAACCAAAACCATTGATAGCGTGACCAGCGCGCAGATGCTGCAGGGCTGCACCATTTTTAAAGGCAACCTGCTGATTAACATTCGCCGCGGCAACAACATTGCGAGCGAACTGGAAAACTTTATGGGCCTGATTGAAGTGGTGACCGGCTATGTGAAAATTCGCCATAGCCATGCGCTGGTGAGCCTGAGCTTTCTGAAAAACCTGCGCCTGATTCTGGGCGAAGAACAGCTGGAAGGCAACTATAGCTTTTATGTGCTGGATAACCAGAACCTGCAGCAGCTGTGGGATTGGGATCATCGCAACCTGACCATTAAAGCGGGCAAAATGTATTTTGCGTTTAACCCGAAACTGTGCGTGAGCGAAATTTATCGCATGGAAGAAGTGACCGGCACCAAAGGCCGCCAGAGCAAAGGCGATATTAACACCCGCAACAACGGCGAACGCGCGAGCTGCGAAAGCGATGTGCTGCATTTTACCAGCACCACCACCAGCAAAAACCGCATTATTATTACCTGGCATCGCTATCGCCCGCCGGATTATCGCGATCTGATTAGCTTTACCGTGTATTATAAAGAAGCGCCGTTTAAAAACGTGACCGAATATGATGGCCAGGATGCGTGCGGCAGCAACAGCTGGAACATGGTGGATGTGGATCTGCCGCCGAACAAAGATGTGGAACCGGGCATTCTGCTGCATGGCCTGAAACCGTGGACCCAGTATGCGGTGTATGTGAAAGCGGTGACCCTGACCATGGTGGAAAACGATCATATTCGCGGCGCGAAAAGCGAAATTCTGTATATTCGCACCAACGCGAGCGTGCCGAGCATTCCGCTGGATGTGCTGAGCGCGAGCAACAGCAGCAGCCAGCTGATTGTGAAATGGAACCCGCCGAGCCTGCCGAACGGCAACCTGAGCTATTATATTGTGCGCTGGCAGCGCCAGCCGCAGGATGGCTATCTGTATCGCCATAACTATTGCAGCAAAGATAAAATTCCGATTCGCAAATATGCGGATGGCACCATTGATATTGAAGAAGTGACCGAAAACCCGAAAACCGAAGTGTGCGGCGGCGAAAAAGGCCCGTGCTGCGCGTGCCCGAAAACCGAAGCGGAAAAACAGGCGGAAAAAGAAGAAGCGGAATATCGCAAAGTGTTTGAAAACTTTCTGCATAACAGCATTTTTGTGCCGCGCCCGGAACGCAAACGCCGCGATGTGATGCAGGTGGCGAACACCACCATGAGCAGCCGCAGCCGCAACACCACCGCGGCGGATACCTATAACATTACCGATCCGGAAGAACTGGAAACCGAATATCCGTTTTTTGAAAGCCGCGTGGATAACAAAGAACGCACCGTGATTAGCAACCTGCGCCCGTTTACCCTGTATCGCATTGATATTCATAGCTGCAACCATGAAGCGGAAAAACTGGGCTGCAGCGCGAGCAACTTTGTGTTTGCGCGCACCATGCCGGCGGAAGGCGCGGATGATATTCCGGGCCCGGTGACCTGGGAACCGCGCCCGGAAAACAGCATTTTTCTGAAATGGCCGGAACCGGAAAACCCGAACGGCCTGATTCTGATGTATGAAATTAAATATGGCAGCCAGGTGGAAGATCAGCGCGAATGCGTGAGCCGCCAGGAATATCGCAAATATGGCGGCGCGAAACTGAACCGCCTGAACCCGGGCAACTATACCGCGCGCATTCAGGCGACCAGCCTGAGCGGCAACGGCAGCTGGACCGATCCGGTGTTTTTTTATGTGCAGGCGAAAACCGGCTATGAAAACTTTATTCATCTGATTATTGCGCTGCCGGTGGCGGTGCTGCTGATTGTGGGCGGCCTGGTGATTATGCTGTATGTGTTTCATCGCAAACGCAACAACAGCCGCCTGGGCAACGGCGTGCTGTATGCGAGCGTGAACCCGGAATATTTTAGCGCGGCGGATGTGTATGTGCCGGATGAATGGGAAGTGGCGCGCGAAAAAATTACCATGAGCCGCGAACTGGGCCAGGGCAGCTTTGGCATGGTGTATGAAGGCGTGGCGAAAGGCGTGGTGAAAGATGAACCGGAAACCCGCGTGGCGATTAAAACCGTGAACGAAGCGGCGAGCATGCGCGAACGCATTGAATTTCTGAACGAAGCGAGCGTGATGAAAGAATTTAACTGCCATCATGTGGTGCGCCTGCTGGGCGTGGTGAGCCAGGGCCAGCCGACCCTGGTGATTATGGAACTGATGACCCGCGGCGATCTGAAAAGCTATCTGCGCAGCCTGCGCCCGGAAATGGAAAACAACCCGGTGCTGGCGCCGCCGAGCCTGAGCAAAATGATTCAGATGGCGGGCGAAATTGCGGATGGCATGGCGTATCTGAACGCGAACAAATTTGTGCATCGCGATCTGGCGGCGCGCAACTGCATGGTGGCGGAAGATTTTACCGTGAAAATTGGCGATTTTGGCATGACCCGCGATATTTATGAAACCGATTATTATCGCAAAGGCGGCAAAGGCCTGCTGCCGGTGCGCTGGATGAGCCCGGAAAGCCTGAAAGATGGCGTGTTTACCACCTATAGCGATGTGTGGAGCTTTGGCGTGGTGCTGTGGGAAATTGCGACCCTGGCGGAACAGCCGTATCAGGGCCTGAGCAACGAACAGGTGCTGCGCTTTGTGATGGAAGGCGGCCTGCTGGATAAACCGGATAACTGCCCGGATATGCTGTTTGAACTGATGCGCATGTGCTGGCAGTATAACCCGAAAATGCGCCCGAGCTTTCTGGAAATTATTAGCAGCATTAAAGAAGAAATGGAACCGGGCTTTCGCGAAGTGAGCTTTTATTATAGCGAAGAAAACAAACTGCCGGAACCGGAAGAACTGGATCTGGAACCGGAAAACATGGAAAGCGTGCCGCTGGATCCGAGCGCGAGCAGCAGCAGCCTGCCGCTGCCGGATCGCCATAGCGGCCATAAAGCGGAAAACGGCCCGGGCCCGGGCGTGCTGGTGCTGCGCGCGAGCTTTGATGAACGCCAGCCGTATGCGCATATGAACGGCGGCCGCAAAAACGAACGCGCGCTGCCGCTGCCGCAGAGCAGCACCTGC

  19. Example: Insulin-like Growth Factor 1 Receptor (IGF1R) • Add EcoRI (GAATTC) at 5’ end and BamHI (GGATCC) at 3’ end. • GAATTCATGAAAAGCGGCAGCGGCGGCGGCAGCCCGACCAGCCTGTGGGGCCTGCTGTTTCTGAGCGCGGCGCTGAGCCTGTGGCCGACCAGCGGCGAAATTTGCGGCCCGGGCATTGATATTCGCAACGATTATCAGCAGCTGAAACGCCTGGAAAACTGCACCGTGATTGAAGGCTATCTGCATATTCTGCTGATTAGCAAAGCGGAAGATTATCGCAGCTATCGCTTTCCGAAACTGACCGTGATTACCGAATATCTGCTGCTGTTTCGCGTGGCGGGCCTGGAAAGCCTGGGCGATCTGTTTCCGAACCTGACCGTGATTCGCGGCTGGAAACTGTTTTATAACTATGCGCTGGTGATTTTTGAAATGACCAACCTGAAAGATATTGGCCTGTATAACCTGCGCAACATTACCCGCGGCGCGATTCGCATTGAAAAAAACGCGGATCTGTGCTATCTGAGCACCGTGGATTGGAGCCTGATTCTGGATGCGGTGAGCAACAACTATATTGTGGGCAACAAACCGCCGAAAGAATGCGGCGATCTGTGCCCGGGCACCATGGAAGAAAAACCGATGTGCGAAAAAACCACCATTAACAACGAATATAACTATCGCTGCTGGACCACCAACCGCTGCCAGAAAATGTGCCCGAGCACCTGCGGCAAACGCGCGTGCACCGAAAACAACGAATGCTGCCATCCGGAATGCCTGGGCAGCTGCAGCGCGCCGGATAACGATACCGCGTGCGTGGCGTGCCGCCATTATTATTATGCGGGCGTGTGCGTGCCGGCGTGCCCGCCGAACACCTATCGCTTTGAAGGCTGGCGCTGCGTGGATCGCGATTTTTGCGCGAACATTCTGAGCGCGGAAAGCAGCGATAGCGAAGGCTTTGTGATTCATGATGGCGAATGCATGCAGGAATGCCCGAGCGGCTTTATTCGCAACGGCAGCCAGAGCATGTATTGCATTCCGTGCGAAGGCCCGTGCCCGAAAGTGTGCGAAGAAGAAAAAAAAACCAAAACCATTGATAGCGTGACCAGCGCGCAGATGCTGCAGGGCTGCACCATTTTTAAAGGCAACCTGCTGATTAACATTCGCCGCGGCAACAACATTGCGAGCGAACTGGAAAACTTTATGGGCCTGATTGAAGTGGTGACCGGCTATGTGAAAATTCGCCATAGCCATGCGCTGGTGAGCCTGAGCTTTCTGAAAAACCTGCGCCTGATTCTGGGCGAAGAACAGCTGGAAGGCAACTATAGCTTTTATGTGCTGGATAACCAGAACCTGCAGCAGCTGTGGGATTGGGATCATCGCAACCTGACCATTAAAGCGGGCAAAATGTATTTTGCGTTTAACCCGAAACTGTGCGTGAGCGAAATTTATCGCATGGAAGAAGTGACCGGCACCAAAGGCCGCCAGAGCAAAGGCGATATTAACACCCGCAACAACGGCGAACGCGCGAGCTGCGAAAGCGATGTGCTGCATTTTACCAGCACCACCACCAGCAAAAACCGCATTATTATTACCTGGCATCGCTATCGCCCGCCGGATTATCGCGATCTGATTAGCTTTACCGTGTATTATAAAGAAGCGCCGTTTAAAAACGTGACCGAATATGATGGCCAGGATGCGTGCGGCAGCAACAGCTGGAACATGGTGGATGTGGATCTGCCGCCGAACAAAGATGTGGAACCGGGCATTCTGCTGCATGGCCTGAAACCGTGGACCCAGTATGCGGTGTATGTGAAAGCGGTGACCCTGACCATGGTGGAAAACGATCATATTCGCGGCGCGAAAAGCGAAATTCTGTATATTCGCACCAACGCGAGCGTGCCGAGCATTCCGCTGGATGTGCTGAGCGCGAGCAACAGCAGCAGCCAGCTGATTGTGAAATGGAACCCGCCGAGCCTGCCGAACGGCAACCTGAGCTATTATATTGTGCGCTGGCAGCGCCAGCCGCAGGATGGCTATCTGTATCGCCATAACTATTGCAGCAAAGATAAAATTCCGATTCGCAAATATGCGGATGGCACCATTGATATTGAAGAAGTGACCGAAAACCCGAAAACCGAAGTGTGCGGCGGCGAAAAAGGCCCGTGCTGCGCGTGCCCGAAAACCGAAGCGGAAAAACAGGCGGAAAAAGAAGAAGCGGAATATCGCAAAGTGTTTGAAAACTTTCTGCATAACAGCATTTTTGTGCCGCGCCCGGAACGCAAACGCCGCGATGTGATGCAGGTGGCGAACACCACCATGAGCAGCCGCAGCCGCAACACCACCGCGGCGGATACCTATAACATTACCGATCCGGAAGAACTGGAAACCGAATATCCGTTTTTTGAAAGCCGCGTGGATAACAAAGAACGCACCGTGATTAGCAACCTGCGCCCGTTTACCCTGTATCGCATTGATATTCATAGCTGCAACCATGAAGCGGAAAAACTGGGCTGCAGCGCGAGCAACTTTGTGTTTGCGCGCACCATGCCGGCGGAAGGCGCGGATGATATTCCGGGCCCGGTGACCTGGGAACCGCGCCCGGAAAACAGCATTTTTCTGAAATGGCCGGAACCGGAAAACCCGAACGGCCTGATTCTGATGTATGAAATTAAATATGGCAGCCAGGTGGAAGATCAGCGCGAATGCGTGAGCCGCCAGGAATATCGCAAATATGGCGGCGCGAAACTGAACCGCCTGAACCCGGGCAACTATACCGCGCGCATTCAGGCGACCAGCCTGAGCGGCAACGGCAGCTGGACCGATCCGGTGTTTTTTTATGTGCAGGCGAAAACCGGCTATGAAAACTTTATTCATCTGATTATTGCGCTGCCGGTGGCGGTGCTGCTGATTGTGGGCGGCCTGGTGATTATGCTGTATGTGTTTCATCGCAAACGCAACAACAGCCGCCTGGGCAACGGCGTGCTGTATGCGAGCGTGAACCCGGAATATTTTAGCGCGGCGGATGTGTATGTGCCGGATGAATGGGAAGTGGCGCGCGAAAAAATTACCATGAGCCGCGAACTGGGCCAGGGCAGCTTTGGCATGGTGTATGAAGGCGTGGCGAAAGGCGTGGTGAAAGATGAACCGGAAACCCGCGTGGCGATTAAAACCGTGAACGAAGCGGCGAGCATGCGCGAACGCATTGAATTTCTGAACGAAGCGAGCGTGATGAAAGAATTTAACTGCCATCATGTGGTGCGCCTGCTGGGCGTGGTGAGCCAGGGCCAGCCGACCCTGGTGATTATGGAACTGATGACCCGCGGCGATCTGAAAAGCTATCTGCGCAGCCTGCGCCCGGAAATGGAAAACAACCCGGTGCTGGCGCCGCCGAGCCTGAGCAAAATGATTCAGATGGCGGGCGAAATTGCGGATGGCATGGCGTATCTGAACGCGAACAAATTTGTGCATCGCGATCTGGCGGCGCGCAACTGCATGGTGGCGGAAGATTTTACCGTGAAAATTGGCGATTTTGGCATGACCCGCGATATTTATGAAACCGATTATTATCGCAAAGGCGGCAAAGGCCTGCTGCCGGTGCGCTGGATGAGCCCGGAAAGCCTGAAAGATGGCGTGTTTACCACCTATAGCGATGTGTGGAGCTTTGGCGTGGTGCTGTGGGAAATTGCGACCCTGGCGGAACAGCCGTATCAGGGCCTGAGCAACGAACAGGTGCTGCGCTTTGTGATGGAAGGCGGCCTGCTGGATAAACCGGATAACTGCCCGGATATGCTGTTTGAACTGATGCGCATGTGCTGGCAGTATAACCCGAAAATGCGCCCGAGCTTTCTGGAAATTATTAGCAGCATTAAAGAAGAAATGGAACCGGGCTTTCGCGAAGTGAGCTTTTATTATAGCGAAGAAAACAAACTGCCGGAACCGGAAGAACTGGATCTGGAACCGGAAAACATGGAAAGCGTGCCGCTGGATCCGAGCGCGAGCAGCAGCAGCCTGCCGCTGCCGGATCGCCATAGCGGCCATAAAGCGGAAAACGGCCCGGGCCCGGGCGTGCTGGTGCTGCGCGCGAGCTTTGATGAACGCCAGCCGTATGCGCATATGAACGGCGGCCGCAAAAACGAACGCGCGCTGCCGCTGCCGCAGAGCAGCACCTGCGGATCC

  20. Example: Insulin-like Growth Factor 1 Receptor (IGF1R) • Add EcoRI (GAATTC) at 5’ end and BamHI (GGATCC) at 3’ end. • GAATTCATGAAAAGCGGCAGCGGCGGCGGCAGCCCGACCAGCCTGTGGGGCCTGCTGTTTCTGAGCGCGGCGCTGAGCCTGTGGCCGACCAGCGGCGAAATTTGCGGCCCGGGCATTGATATTCGCAACGATTATCAGCAGCTGAAACGCCTGGAAAACTGCACCGTGATTGAAGGCTATCTGCATATTCTGCTGATTAGCAAAGCGGAAGATTATCGCAGCTATCGCTTTCCGAAACTGACCGTGATTACCGAATATCTGCTGCTGTTTCGCGTGGCGGGCCTGGAAAGCCTGGGCGATCTGTTTCCGAACCTGACCGTGATTCGCGGCTGGAAACTGTTTTATAACTATGCGCTGGTGATTTTTGAAATGACCAACCTGAAAGATATTGGCCTGTATAACCTGCGCAACATTACCCGCGGCGCGATTCGCATTGAAAAAAACGCGGATCTGTGCTATCTGAGCACCGTGGATTGGAGCCTGATTCTGGATGCGGTGAGCAACAACTATATTGTGGGCAACAAACCGCCGAAAGAATGCGGCGATCTGTGCCCGGGCACCATGGAAGAAAAACCGATGTGCGAAAAAACCACCATTAACAACGAATATAACTATCGCTGCTGGACCACCAACCGCTGCCAGAAAATGTGCCCGAGCACCTGCGGCAAACGCGCGTGCACCGAAAACAACGAATGCTGCCATCCGGAATGCCTGGGCAGCTGCAGCGCGCCGGATAACGATACCGCGTGCGTGGCGTGCCGCCATTATTATTATGCGGGCGTGTGCGTGCCGGCGTGCCCGCCGAACACCTATCGCTTTGAAGGCTGGCGCTGCGTGGATCGCGATTTTTGCGCGAACATTCTGAGCGCGGAAAGCAGCGATAGCGAAGGCTTTGTGATTCATGATGGCGAATGCATGCAGGAATGCCCGAGCGGCTTTATTCGCAACGGCAGCCAGAGCATGTATTGCATTCCGTGCGAAGGCCCGTGCCCGAAAGTGTGCGAAGAAGAAAAAAAAACCAAAACCATTGATAGCGTGACCAGCGCGCAGATGCTGCAGGGCTGCACCATTTTTAAAGGCAACCTGCTGATTAACATTCGCCGCGGCAACAACATTGCGAGCGAACTGGAAAACTTTATGGGCCTGATTGAAGTGGTGACCGGCTATGTGAAAATTCGCCATAGCCATGCGCTGGTGAGCCTGAGCTTTCTGAAAAACCTGCGCCTGATTCTGGGCGAAGAACAGCTGGAAGGCAACTATAGCTTTTATGTGCTGGATAACCAGAACCTGCAGCAGCTGTGGGATTGGGATCATCGCAACCTGACCATTAAAGCGGGCAAAATGTATTTTGCGTTTAACCCGAAACTGTGCGTGAGCGAAATTTATCGCATGGAAGAAGTGACCGGCACCAAAGGCCGCCAGAGCAAAGGCGATATTAACACCCGCAACAACGGCGAACGCGCGAGCTGCGAAAGCGATGTGCTGCATTTTACCAGCACCACCACCAGCAAAAACCGCATTATTATTACCTGGCATCGCTATCGCCCGCCGGATTATCGCGATCTGATTAGCTTTACCGTGTATTATAAAGAAGCGCCGTTTAAAAACGTGACCGAATATGATGGCCAGGATGCGTGCGGCAGCAACAGCTGGAACATGGTGGATGTGGATCTGCCGCCGAACAAAGATGTGGAACCGGGCATTCTGCTGCATGGCCTGAAACCGTGGACCCAGTATGCGGTGTATGTGAAAGCGGTGACCCTGACCATGGTGGAAAACGATCATATTCGCGGCGCGAAAAGCGAAATTCTGTATATTCGCACCAACGCGAGCGTGCCGAGCATTCCGCTGGATGTGCTGAGCGCGAGCAACAGCAGCAGCCAGCTGATTGTGAAATGGAACCCGCCGAGCCTGCCGAACGGCAACCTGAGCTATTATATTGTGCGCTGGCAGCGCCAGCCGCAGGATGGCTATCTGTATCGCCATAACTATTGCAGCAAAGATAAAATTCCGATTCGCAAATATGCGGATGGCACCATTGATATTGAAGAAGTGACCGAAAACCCGAAAACCGAAGTGTGCGGCGGCGAAAAAGGCCCGTGCTGCGCGTGCCCGAAAACCGAAGCGGAAAAACAGGCGGAAAAAGAAGAAGCGGAATATCGCAAAGTGTTTGAAAACTTTCTGCATAACAGCATTTTTGTGCCGCGCCCGGAACGCAAACGCCGCGATGTGATGCAGGTGGCGAACACCACCATGAGCAGCCGCAGCCGCAACACCACCGCGGCGGATACCTATAACATTACCGATCCGGAAGAACTGGAAACCGAATATCCGTTTTTTGAAAGCCGCGTGGATAACAAAGAACGCACCGTGATTAGCAACCTGCGCCCGTTTACCCTGTATCGCATTGATATTCATAGCTGCAACCATGAAGCGGAAAAACTGGGCTGCAGCGCGAGCAACTTTGTGTTTGCGCGCACCATGCCGGCGGAAGGCGCGGATGATATTCCGGGCCCGGTGACCTGGGAACCGCGCCCGGAAAACAGCATTTTTCTGAAATGGCCGGAACCGGAAAACCCGAACGGCCTGATTCTGATGTATGAAATTAAATATGGCAGCCAGGTGGAAGATCAGCGCGAATGCGTGAGCCGCCAGGAATATCGCAAATATGGCGGCGCGAAACTGAACCGCCTGAACCCGGGCAACTATACCGCGCGCATTCAGGCGACCAGCCTGAGCGGCAACGGCAGCTGGACCGATCCGGTGTTTTTTTATGTGCAGGCGAAAACCGGCTATGAAAACTTTATTCATCTGATTATTGCGCTGCCGGTGGCGGTGCTGCTGATTGTGGGCGGCCTGGTGATTATGCTGTATGTGTTTCATCGCAAACGCAACAACAGCCGCCTGGGCAACGGCGTGCTGTATGCGAGCGTGAACCCGGAATATTTTAGCGCGGCGGATGTGTATGTGCCGGATGAATGGGAAGTGGCGCGCGAAAAAATTACCATGAGCCGCGAACTGGGCCAGGGCAGCTTTGGCATGGTGTATGAAGGCGTGGCGAAAGGCGTGGTGAAAGATGAACCGGAAACCCGCGTGGCGATTAAAACCGTGAACGAAGCGGCGAGCATGCGCGAACGCATTGAATTTCTGAACGAAGCGAGCGTGATGAAAGAATTTAACTGCCATCATGTGGTGCGCCTGCTGGGCGTGGTGAGCCAGGGCCAGCCGACCCTGGTGATTATGGAACTGATGACCCGCGGCGATCTGAAAAGCTATCTGCGCAGCCTGCGCCCGGAAATGGAAAACAACCCGGTGCTGGCGCCGCCGAGCCTGAGCAAAATGATTCAGATGGCGGGCGAAATTGCGGATGGCATGGCGTATCTGAACGCGAACAAATTTGTGCATCGCGATCTGGCGGCGCGCAACTGCATGGTGGCGGAAGATTTTACCGTGAAAATTGGCGATTTTGGCATGACCCGCGATATTTATGAAACCGATTATTATCGCAAAGGCGGCAAAGGCCTGCTGCCGGTGCGCTGGATGAGCCCGGAAAGCCTGAAAGATGGCGTGTTTACCACCTATAGCGATGTGTGGAGCTTTGGCGTGGTGCTGTGGGAAATTGCGACCCTGGCGGAACAGCCGTATCAGGGCCTGAGCAACGAACAGGTGCTGCGCTTTGTGATGGAAGGCGGCCTGCTGGATAAACCGGATAACTGCCCGGATATGCTGTTTGAACTGATGCGCATGTGCTGGCAGTATAACCCGAAAATGCGCCCGAGCTTTCTGGAAATTATTAGCAGCATTAAAGAAGAAATGGAACCGGGCTTTCGCGAAGTGAGCTTTTATTATAGCGAAGAAAACAAACTGCCGGAACCGGAAGAACTGGATCTGGAACCGGAAAACATGGAAAGCGTGCCGCTGGATCCGAGCGCGAGCAGCAGCAGCCTGCCGCTGCCGGATCGCCATAGCGGCCATAAAGCGGAAAACGGCCCGGGCCCGGGCGTGCTGGTGCTGCGCGCGAGCTTTGATGAACGCCAGCCGTATGCGCATATGAACGGCGGCCGCAAAAACGAACGCGCGCTGCCGCTGCCGCAGAGCAGCACCTGCGGATCC

  21. Designing Amplification Oligos ~5’ End 5’GAATTCATGAAAAGCGGCAGCGGCGGCGGC3’ 3’CTTAAGTACTTTTCGCCGTCGCCGCCGCCG5’ ~*You need an available 3’OH, so for this end you make a primer against the antisense strand. 5’GAATTCATGAAAAGCGGCAGCGGCGGCGGC3’ 5’GAATTCATGAAAAGCGGCAGCGGC3’OH 3’CTTAAGTACTTTTCGCCGTCGCCGCCGCCG5’

  22. Designing Amplification Oligos ~3’ End 5’TGCCGCTGCCGCAGAGCAGCACCTGCGGATCC3’ 3’ACGGCGACGGCGTCTCGTCGTGGACGCCTAGG5’ ~Again, you need a 3’OH so this time make a primer against the sense strand. 5’TGCCGCTGCCGCAGAGCAGCACCTGCGGATCC3’ HO3’GGCGTCTCGTCGTGGACGCCTAGG5’ 3’ACGGCGACGGCGTCTCGTCGTGGACGCCTAGG5’

  23. Designing Amplification Oligos • Primers need to be anywhere from 18-25 nucleotides. • Don’t include the restriction site or Kozak sequence as part of your 18-25 nucleotides for the primer. • Should contain at least 50% GC composition. • Must flank the entire CODING sequence.

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