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Transcript
Exam 2 T 10/30 at 7:30-9pm Review Th 10/25 at 5-7pm in WRW 102 and/or in class Bonus #1 due 10/25 in class Genetic Engineering: Direct manipulation of DNA Bacteria can be modified or serve as intermediates a typical bacteria Bacterial DNA plasmid DNA A typical bacterial plasmid used for genetic engineering Moving a gene into bacteria via a plasmid What problems exist for expressing eukaryotic gene in bacteria? Bacterial DNA plasmid DNA Reverse transcriptase can be used to obtain coding regions without introns. After RT, PCR will amplify the gene or DNA Fig 20.14 Moving a gene into bacteria via a plasmid RT and PCR Restriction Enzymes cut DNA at specific sequences Restriction enzymes cut DNA at a specific sequence Cutting the plasmid and insert with the same restriction enzyme makes matching sticky ends Fig 20.2 A typical bacterial plasmid used for genetic engineering Using sticky ends to add DNA to a bacterial plasmid Fig 20.2 If the same restriction enzyme is used for both sides, the plasmid is likely to religate to itself. Fig 20.2 The plasmid is treated with phosphatase to remove the 5’-P, preventing selfligation Fig 20.2 Transformation of bacteria can happen via several different methods. Fig 20.8 Bacteria can take up DNA from the environment Fig 7.2 Transformation of bacteria can happen via several different methods all involving perturbing the bacterial membrane: •Electroporation •Heat shock •Osmotic Stress Fig 20.8 How can you know which bacteria have been transformed, and whether they have the insert? Fig 20.5 Resistance genes allow Figurebacteria 20-5 with the plasmid to be selected. Bacteria with the resistance gene will survive when grown in the presence of antibiotic Fig 20.5 Is the insert present? FigurePlasmids 20-5 with the MCS in the lacZ gene can be used for blue/white screening… A typical bacterial plasmid used for genetic engineering Fig 20.5 Intact lacZ makes a Figureblue 20-5 color when expressed and provided X-galactose Fig 20.5 When the lacZ gene is Figuredisrupted, 20-5 the bacteria appear white Blue/white screening: Transformed bacteria plated on antibiotic and Xgal plates. Each colony represents millions of clones of one transformed cell. Successful transformation will grow a colony of genetically modified bacteria Fig 20.4 RT and/or PCR Inserting a gene into a bacterial plasmid Millions of Hectares Bacteria can be used to transform plants Global area planted with GM crops http://www.gmo-compass.org/eng/agri_biotechnology/gmo_planting/257.global_gm_planting_2006.html Texas = 70 ha Agrobacterium infect plants, inserting their plasmid DNA into the plants genome. Agrobacterium infect plants, inserting their plasmid DNA into the plants genome. Fig 20.24 By replacing the gall forming genes with other DNA when the Agrobacterium infect a plant, it will insert that DNA into the plant. Fig 20.25 The generation of a transgenic plant Grown on herbicide Fig 20.26 How do you know whether the gene you want to express has the correct sequence? How do you know whether the gene you want to express has the correct sequence? DNA sequencing • The structure of 2’,3’-dideoxynucleotides Fig 20.15 The dideoxy sequencing method Fig 20.16 The dideoxy sequencing method Fig 20.16 Gel produced by the dideoxy sequencing method Fig 20.16 Computerized sequencers use a similar method Fig 20.17 • Creation of Caenorhabditis elegans transgenes Figure 20-28 Creation of Drosophila melanogaster transgenes using a transposon Fig 20.29 • Creation of Mus musculus transgenes Figure 20-30 Fig 20.30 …now enjoy making Frakencritters. Exam 2 T 10/30 at 7:30-9pm Review Th 10/25 at 5-7pm in WRW 102 and/or in class Bonus #1 due 10/25 in class
