1 / 33

Problem

Problem. 1. You screen two libraries- cDNA; genomic 2. Clones are isolated having homology to PSY- 10 clones from each library 3. These are subcloned into pBluescript. 4. Protein expression is induced with IPTG and proteins separated by SDS-PAGE. Results: Genomic clones: 0/10 gave expression

morwen
Download Presentation

Problem

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Problem 1. You screen two libraries- cDNA; genomic 2. Clones are isolated having homology to PSY- 10 clones from each library 3. These are subcloned into pBluescript. 4. Protein expression is induced with IPTG and proteins separated by SDS-PAGE. Results: Genomic clones: 0/10 gave expression cDNA clones: 2/10 gave expression Question: Why zero genomic clones Why only 2 cDNA clones

  2. Lecture 6 Transgenic Organisms Reading: Chapter 9 Molecular Biology syllabus web site

  3. Genetic Markers RFLP/ RAPDS and other newer PCR-based methods -to create maps -to study evolutionary relationships Mapping markers -in situ hybridization, fluorescent tags -Southern analysis (linked markers co-segregate) -chromosome walking to generate physical maps -comparison of physical and genetic maps

  4. DNA polymorphisms can be used to map human mutations Analysis of restriction fragment length polymorhpisms (RFLPs)

  5. Isolation of a contiguous stretch of DNA and construction of a physical map in that region Chromosome walking

  6. Physical maps of entire chromosomes can be constructed by screening YAC clones for sequence-tagged sites Ordering of contiguous overlapping YAC clones

  7. Gene replacement and transgenic organisms • Some genes are identified through means other than mutant analysis • To determine the function of these genes, it is possible to replace an organism’s wild type gene with an inactive gene to create a “gene knockout” • It is also possible to introduce additional genes (transgenes) to create a transgenic organism

  8. In vitro mutagenesis of a cloned gene Gene knockout and transgenic techniques usually involve mutagenesis of cloned genes prior to transfer into the organism

  9. Transgenic Approaches • Methods spheroplasts-yeast, plants chemical methods; microinjection- animal cells electroporation particle gun bombardment bacterial-plants • Stable or transient selection with markers • Knockouts (homologous recombination) “gene replacement” • Transgenic Organisms

  10. Purposes of transgenic research • Basic- understanding gene function • Applied- gene therapy to introduce functional genes improvement (foods; create novel sources of drugs; increasing plant production to provide more food)

  11. Creation of mice ES cells carrying a knockout mutation

  12. Production of transgenic Drosophila Eye color, a screenable phenotype encoded by w+ gene. Drosophila, red-eyed wild type (left) & white-eyed mutant (right).

  13. Transgenic Plants • Plants cells are totipotent and can regenerate from undifferentiated tissue to produce viable, seed-bearing plants. • Methods: electroporation, microinjection, bombardment, use of Agrobacterium tumefaciens

  14. Production of transgenic plants with Ti plasmids

  15. Reporter Genes as Transgenes • GUS- b-glucuronidase • GFP- green fluorescent protein • LACZ- b-galactosidase • LUC- luciferase Examples Advantage: Easy to assay compared to native gene

  16. Gene X is an enzyme,GGPPS • How do we determine where in the plant this gene is expressed? • Fuse the promoter of Gene X to the coding region encoding GUS (a bacterial enzyme, betaglucuronidase). • Assay enzyme activity of GUS using a chromogenic substrate. Active enzyme catalyzes formation of a blue product.

  17. Reporter Genes as TransgenesExample: assaying the promoter of Gene X Gene X Promoter Coding Region ORF Promoter REPORTER ORF

  18. Reporter Genes as Transgenes GUS b–glucuronidase is a bacterial enzyme that acts on a chromogenic substrate to produce a blue product. Arabidopsis promoter-GUS fusions expressed in Arabidopsis. (Okada et al., 2000, Plant Physiology 122:1045-56.)

  19. Promoter Coding Region ORF Artificial Promoters To alter natural expression with respect to time, place, or level of expression Promoter Coding Region ORF

  20. 35 S Promoter 35 S Promoter REPORTER (GFP) REPORTER (GFP) ORF ORF Combining artificial promoters and reporter genes • Promoter for constitutive expression (35S) • GFP coding region +

  21. Constitutive expression of GFP GFP, Green Fluorescent Protein- is a bacterial protein that will normally localize to the cytoplasm. Transient expression of GFP in tobacco (Zhu, Li, Wurtzel, unpub.)

  22. Gene X is a chloroplast protein • How do we determine which part of the protein is needed to direct it to a chloroplast • Fuse DNA encoding the putative transit sequence to the coding sequence of GFP (jellyfish green fluorescent protein) which is driven by a constitutive promoter (35S). • Use a fluorescence microscope to detect the fluorescence of GFP.

  23. Combining reporters & constitutive promoters to assay gene elementsExample: assaying transit sequence of Gene X Gene X Promoter Coding Region ORF 35 S Promoter REPORTER (GFP) ORF

  24. Untransformed PSY-GFP Green Red Merged Fusion of maize PSY transit sequence to GFP directs GFP to tobacco chloroplasts. Zhu, Li, & Wurtzel unpublished

  25. Reporter Genes as Transgenes • GUS- b-glucuronidase • GFP- green fluorescent protein • LACZ- b-galactosidase • LUC- luciferase Arabidopsis promoter-GUS fusions expressed in Arabidopsis. (Okada et al., 2000, Plant Physiology 122:1045-56.) Transient expression of GFP in tobacco (Zhu, Li, Wurtzel, unpub.)

  26. Promoter Promoter Coding Region Coding Region ORF ORF Turning off genes • Antisense

  27. Turning off genes • RNAi

More Related