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Lecture 8 Genes and traits of interest

Lecture 8 Genes and traits of interest. Neal Stewart. Happy Valentine’s Day!. Objectives and discussion questions. What is genomics (and “omics” in general)? What are the tools for finding genes that might be useful in biotechnology.

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Lecture 8 Genes and traits of interest

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  1. Lecture 8 Genes and traits of interest Neal Stewart

  2. Happy Valentine’s Day!

  3. Objectives and discussion questions • What is genomics (and “omics” in general)? What are the tools for finding genes that might be useful in biotechnology. • Know the principles of two key methods: cDNA (complementary DNA) library production and PCR (polymerase chain reaction). 3. What are the differences between “input” and “output” traits? Considering the environmental and biological factors that limit production in a farmer’s field, what are some new input traits that might be good candidates for improvement using biotechnology? 4. Consider the possibility that you are employed by an agricultural biotechnology company, and they ask you to find a bacterial gene for resistance to a specific herbicide. The herbicide has been manufactured by the company for many years. Using a strategy similar to that used to find glyphosate resistance, where might you start to look for a bacterium resistant to that herbicide?

  4. More objectives 5. Golden Rice producing provitamin A has the potential to help many impoverished people who might benefit from eating it. Although application of this technology is supported by many people and organizations, there are also some who oppose the technology. Considering their possible motivations and potential biases, discuss some of the reasons that groups have come out in favor or in opposition to Golden Rice. 6. What are the potential benefits of producing pharmaceutical proteins in plants? What are some of the disadvantages or potential dangers? 7. Animal genes can be inserted into plants and expressed. Would you be opposed to eating foods from plants expressing proteins encoded by animal genes? By human genes? Discuss the reasons for your answers.

  5. Finding genes to modify: many strategies • Biochemistry—understanding pathways • Functional screens • Hunting for specific genes– cDNAs • Searching databases for similar genes • Omics

  6. How plant genome sizes compare with other organisms http://fig.cox.miami.edu/~cmallery/150/gene/genome2.jpg

  7. Omics—what’s the point? • Genomics • Transcriptomics • Proteomics • Metabolomics • Phenomics

  8. Omics—what’s the point? • Genomics • Transcriptomics • Proteomics • Metabolomics • Phenomics • ID genes • Transcript abundance • Protein abundance • ID metabolites • To understand how perturbing the system results in a new phenotype—whole plant phenotyping

  9. Omics—main approaches • Genomics • Transcriptomics • Proteomics • Metabolomics • Phenomics • Genome sequencing • RNA-seq • Mass spec techniques • Mass spec techniques • Suite of technologies that can be automated and used in the field

  10. Creating cDNAscomplementary DNA from mRNA

  11. Introducing PCR

  12. Figure 7.10 http://youtube.com/watch?v=_YgXcJ4n-kQ

  13. Sample preparation Test material Reference material Source: Murali Rao Total RNA isolation mRNA purification

  14. Image Collection Sample Array Data

  15. Progression of GM plants • 1st Generation: Input traits (herbicide tolerance, insect resistance, etc.) • 2nd Generation: Output traits: (enhanced nutrition, etc.)—also known as quality traits • 3rd Generation: Non-traditional– (pharmaceuticals, phytoremediation, phytosensors, next-generation biofuels)

  16. First generation Input traits

  17. Herbicide-resistant crops

  18. Figure 8.1

  19. Finding a glyphosate resistance gene • Discovery of glyphosate—kills most plants • Knowledge of shikimate pathway • Targeting enyzme (gene) for resistance • Functional screen for resistance • Clone resistance gene • Overexpress gene in plants

  20. Discussion question Consider the possibility that you are employed by an agricultural biotechnology company, and they ask you to find a bacterial gene for resistance to a specific herbicide. The herbicide has been manufactured by the company for many years. Using a strategy similar to that used to find glyphosate resistance, where might you start to look for a bacterium resistant to that herbicide?

  21. Transgenic disease resistance • Viruses (yes) • Bacteria (no) • Fungi (no) • Nematodes (no)

  22. Photo by Dennis Gonsalves. Stewart, 2004. Genetically Modified Planet 2004

  23. Figure 8.5

  24. Biotechnologist of the dayDennis Gonsalves • From Hawaii • At USDA-ARS in Hilo, Hawaii • Humboldt Prize winner 2002 • Virus resistant papaya credited for saving papaya industry in Hawaii

  25. Figure 8.4

  26. Insect resistance

  27. Controlling Colorado potato beetle is not easy

  28. Bt corn

  29. Bt cotton

  30. Bacillus thuringiensis Stewart, 2004. Genetically Modified Planet 2004

  31. Bt Cry structure III I II Stewart, 2004. Genetically Modified Planet 2004

  32. Figure 8.3

  33. Bt toxin Insect midgut cells that have bound Bt toxin. Same gut cells a few hours later– note the damage and leakage. Stewart, 2004. Genetically Modified Planet 2004

  34. Bt Insect midgut cells that have bound Bt toxin. Mutated receptors cannot bind Bt toxin. Receptors are not present– cells cannot bind Bt Stewart, 2004. Genetically Modified Planet 2004

  35. Different Bt Crys • Cry 1s—kills caterpillars (lepidoptera) • Cry 2s—kills caterpillars (lepidoptera) • Cry 3s—kills beetles (coleoptera) Canola plant expresses a Bt cry1Ac gene

  36. Discussion question Other than the products discussed in this chapter, what other sorts of genes or strategies might be useful in engineering transgenic plants resistant to insects or pathogens?

  37. Second generation Output traits=quality traits

  38. Improved nutrition, better foods • Golden rice • Modified oils from oilseeds • Vitamin E enhancements • Arctic apple—non-browning • Innate potato—non-browning and reduced acrylamide upon browning

  39. Golden rice: producing provitamin A www.goldenrice.org

  40. Biotechnologist of the day:Ingo Potrykus

  41. Figure 8.6

  42. Third generation Non-traditional products

  43. Examples • Pharmaceuticals • Oral vaccines • Phytoremediation • Phytosensors • Biofuels

  44. Plant-made pharmaceuticalsakaMolecular pharming Duckweed Grow in lab Or field Protein Purification Genetic Engineering Oral vaccine– eat the fruit, or purify the vaccine pill or injection Corn

  45. Fraunhofer USA: one plant-based platform to produce pharmaceutical proteins: vaccines http://www.youtube.com/watch?v=oCGFW1WOFTY

  46. What are the potential benefits of producing pharmaceutical proteins in plants? What are some of the disadvantages or potential dangers?

  47. Phytorediation exampleHow to remediate mercury in soil www.uga.genetics.edu/rmblab

  48. So, transgenic plants could be used in a lot of applications… Are there any we should avoid?

  49. PCR videos! How PCR works: http://youtube.com/watch?v=_YgXcJ4n-kQ PCR song! http://youtube.com/watch?v=x5yPkxCLads&feature=related

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