1 / 16

Genetic Engineering of Plants: Methods and Applications

Explore the methodology of plant transformation using the Ti plasmid system and other genetic engineering tools for improving crops' value, bioreactor purposes, energy sources, and genetic studies.

poore
Download Presentation

Genetic Engineering of Plants: Methods and Applications

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. Chapter 18-Genetic Engineering of Plants: Methodology Plant transformation with the Ti plasmid of Agrobacterium tumefaciens Ti plasmid derived vector systems Physical methods of transferring genes to plants Microprojectile bombardment Use of reporter genes in transformed plant cells Manipulation of gene expression in plants Production of marker-free transgenic plants

  2. Why genetically engineer plants? • To improve the agricultural, horticultural or ornamental value of a crop plant • To serve as a living bioreactor for the production of economically important proteins or metabolites • To provide a renewable source of energy • To provide a powerful means for studying the action of genes (and gene products) during development and other biological processes

  3. Plant transformation with the Ti plasmid of Agrobacterium tumefaciens • A. tumefaciens is a gram-negative soil bacterium which naturally transforms plant cells, resulting in crown gall (cancer) tumors • Tumor formation is the result of the transfer, integration and expression of genes on a specific segment of A. tumefaciens plasmid DNA called the T-DNA (transferred DNA) • The T-DNA resides on a large plasmid called the Ti (tumor inducing) plasmid found in A. tumefaciens

  4. The Ti plasmid of Agrobacterium tumafaciens and the transfer of its T-DNA to the plant nuclear genome

  5. Fig. 18.3 The Ti plasmid of Agrobacterium tumafaciens and its T-DNA region containing eukaryotic genes for auxin, cytokinin, and opine production.

  6. Fig. 28-27 Crown Gall on Tobacco Fig. 18.1 Infection of a plant with A. tumefaciens and formation of crown galls

  7. Fig. 17.3 Ti plasmid: structure & function • The infection process: • Wounded plant cell releases phenolics and nutrients. • Phenolics and nutrients cause chemotaxic response of A. tumefaciens • Attachment of the bacteria to the plant cell. • Certain phenolics (e.g., acetosyringone, hydroxyacetosyringone) induce vir gene transcription and allow for T-DNA transfer and integration into plant chromosomal DNA. • Transcription and translation of the T-DNA in the plant cell to produce opines (food) and tumors (housing) for the bacteria. • The opine permease/catabolism genes on the Ti plasmid allow A. tumefaciens to use opines as a C, H, O, and N source.

  8. Fig. 18.4 The right and left borders of the T-DNA of the Ti plasmid are 25 bp direct “repeats” important for mobilization of the T-DNA by vir gene products Right 5’-TGNCAGGATATATNNNNNNGTNANN-3’ Left 5’-TGGCAGGATATATNNNNNTGTAAAN-3’

  9. Fig. 18.7 The binary Ti plasmid system involves using a small T-DNA plasmid (shown below) and a disarmed (i.e., no T-DNA) Ti plasmid in A. tumefaciens

  10. (disarmed) Plant genetic engineering with the binary Ti plasmid system Clone YFG (your favorite gene) or the target gene in the small T-DNA plasmid in E. coli, isolate the plasmid and use it to transform the disarmed A. tumefaciens as shown. Transgenic plant

  11. Table 18.1 Plant cell DNA-delivery methods * Most commonly used methods

  12. Fig. 18.10 Microprojectile bombardment or biolistic-mediated DNA transfection equipment(a) lab version(b) portable version * When the helium pressure builds to a certain point, the plastic rupture disk bursts, and the released gas accelerates the flying disk* with the DNA-coated gold particles on its lower side. The gold particles pass the stopping screen, which holds back the flying disk, and penetrate the cells of the plant.

  13. Table 18.5 Some plant cell reporter and selectable marker gene systems

  14. Reporter Genes • For how reporter genes work, see: http://bcs.whfreeman.com/lodish5e/pages/bcs-main.asp?v=category&s=00010&n=15000&i=15010.01&o=|00510|00610|00520|00530|00540|00560|00570|00590|00600|00700|00710|00010|00020|00030|00040|00050|01000|02000|03000|04000|05000|06000|07000|08000|09000|10000|11000|12000|13000|14000|15000|16000|17000|18000|19000|20000|21000|22000|23000|99000|&ns=1322 • GFP Researchers Win Nobel Prize (October 8, 2008) Osamu Shimomura, Martin Chalfie, and Roger Tsien won the Nobel Prize in chemistry for their work on green flourescent protein, a tool that has become ubiquitous in modern biology as a tag and molecular highlighter, vastly improving our ability to understand what goes on inside cells. • Perhaps you may even want to see a 10 minute YouTube video on GFP; if so please see http://www.youtube.com/watch?v=Sl2PRHGpYuU

  15. Manipulation of gene expression in plants • Strong, constitutive promoters (35S Cauliflower mosaic virus promoter or 35S CaMV or 35S) • Organ and tissue specific promoter (e.g., the leaf-specific promoter for the small subunit of the photosynthetic enzyme ribulosebisphosphate carboxylase or rbc) • Promoterless reporter gene constructs to find new organ- and tissue-specific promoter (see Fig. 18.15) • Inducible promoters • Secretion of transgene products by inclusion of a signal peptide sequence between a root promoter and YFG and growing the transgenic plant hydroponically (YFG product will be secreted)

  16. Fig. 18.26 Marker genes may be a safety issue, so it is best to remove them—here is one strategy Recombinase gene Selectable marker LB RB Target gene Recombinase recognition sequence

More Related