Tuesday May 3 Get out your journal open to next open page and have writing utensil Big idea!!: DNA to mRNA to Protein to Trait Question: If we make a change to the DNA in an organism, what will happen? By the end of class today, I should be able to: 1. Understand some basics of genetically modifying an organism (GMO!) 2. Summarize & Flow Chart the steps in a genetic modification process
Central Dogma of Molecular Biology If we put in new DNA into an organism– what will happen to the organism? DNA RNA ProteinTraitBackground:
This Little Light of Mine: Aequorea victoria: Source of “glowing gene” for this experiment Transform bacteria with a jellyfish gene to make them glow AP Lab 8 Bacterial Transformation
Jellyfish Gene put into Other Critters
Agenda Prep pFLO lab Begin Genetic Engineering Lab
Gene Plasmid Transformation-process of giving another organism a new gene. Plasmids can “carry” multiple genes.
Genes-R-Us Produce genes and their protein products This project produces proteins that produce a color and fluoresce (glow). Insert the pFLO plasmid into a harmless strain of the E. coli bacteria The E. coli will be our “factory” that produces the color protein. It also includes an ampicillin resistant gene.
How do antibiotics work and what is antibiotic resistance? Fungus and bacteria compete for same resources Fungus make ampicillin to kill bacteria (and we use it for medicine) Ampicillin binds to enzyme that builds bacterial cell walls – kills bacteria Ampicillin resistant bacteria have an enzyme that destroys ampicillin Battle is ON!!!
Genes-R-Us New Lab Notebook Heading: Genes-R-Us Your objective (s) 1. Learn how to genetically modify the genes in (GMO) a bacteria so that it has a new trait. 2. Suggest possible improvements to the bacterial transformation process
Genes-R-Us Hypothesis: If we insert a gene for a glowing colored protein, then…. E.coli without pFLO (control) E.coli with pFLO LB LB/Amp E. coli colonies are usually white. E. coli with pFLO will be colored and fluoresce under UV light.
Genes-R-Us Procedures 1. Remove excess bacteria from table top by cleaning with disinfectant (ETOH) wash hands!
Genes-R-Us 2. Get 2 mictrotubes with 250 μ l cold CaCl Label with group # and one with “C” for Control and the other with “pFLO.” Put on ice. CpFLO CaCl 2 solution Why CaCl2? Would a (-) charged molecule like DNA be able to get through the cell membrane? Ca++ neutralizes DNA
Genes-R-Us 4. Use a sterile toothpick to gently scrape up a large colony of bacteria from the stock plate. Add to C tube. SPIN and MIX! Repeat with new sterile toothpick into pFLO tube. Return to ice. CpFLO
Genes-R-Us 4. Use a sterile micropipette tip to transfer 10 μ l of pFLO plasmid (stock tube at front) to pFLO tube. 5. Add 10 μ l sterile water to tube C. 6. Mix by gently tapping tube. Let rest on ice for 15 minutes! Read next steps carefully. Timing is essential! CpFLO 15 minutes
Genes-R-Us 5. Label your four plates as indicated. Also include group #/name & class period Read next steps carefully. Timing is essential! c c
Genes-R-Us 6. Take ice container with tubes to the 42° C water bath. Place tubes in water bath for exactly 90 seconds. Immediately return to ice for at least 2 minutes. 90 seconds
Genes-R-Us 7. After 2 minutes on ice, add 250 μ l Luria broth (LB) to each tube, using sterile micropipette tip for each one. C pFLO
Genes-R-Us 8. Incubate tubes in incubator for minutes.
Genes-R-Us 9. Set micropipette to 100 μ l. Use a sterile tip & spreader to plate each tube! Pipette 100 μ l from tube C onto the Control LB plate. Evenly spread cells over surface of plate using sterile cell spreader. Cover. Repeat process for other C and both pFLO plates. c c
Genes-R-Us 10. Allow 5 minutes for plates surfaces to absorb cells. Place your four plates upside-down, tape to secure and label with group period (don’t mummify!) and put into the 37° incubator.
Genes-R-Us Data: E.coli without pFLO (control) E.coli with pFLO LB LB/Amp
Results!