CHAPTER 1: Some Tools of the Trade Lab 1.2

1. CHAPTER 1: Some Tools of the Trade Lab 1.2 2014

2. Purpose of Lab 1.2 • Become familiar with gel electrophoresis • Practice using the micropipette to load wells in practice plates • Practice running an electrophoresis gel using three dyes: xylene cyanole, bromophenol blue, and orange G

3. SB buffer solution • 1X SB buffer used in agarose gel solution • 1X SB buffer used in electrophoresis box • Materials include 20x SB buffer solution • Dilute 20x SB buffer solution with dH20 to make the 1x SB buffer solution

4. SB buffer solution procedure • Determine V1, amount of 1x SB buffer needed, by multiplying number of gels by 40 mL • Determine V2, amount of 20x SB buffer used in the dilution, by using the formula (1x)V1 – (20x)V2

5. Agarose solution • An 0.8% agarose solution is used to make the electrophoresis gel • Materials include agarose • The 0.8% agarose solution must be heated in a double boiler or in a microwave in order for the agarose to dissolve

6. Agarose solution procedure • Determine amount of agarose solution needed by multiplying number of gels by 30mL • Calculate amount of agarose needed by multiplying number of gels by 0.24g • Carefully heat in double boiler or microwave until all “flecks” are dissolved

7. Magnified agarose matrix

8. Pouring the gels • Cool agarose to 60⁰ C and pour into tray until each comb is covered by 2 mm • Once the gels solidify pull each comb straight out of the gel without wiggling • Transfer gels from trays to zip-lock bags • Add small amount 1x SB buffer to gel and store in refrigerator until ready to use

9. Pouring the gels (cont.)

10. Setting up the gel box • Play the gel in the gel box so that the wells are at the negative (-) end • Add buffer to the gel box to just cover the gel–no dimples showing • Make sure the gel is in position before loading the wells

11. Loading gels • Insert pipette tip • Under buffer level • Above gel well

12. Improper loading technique • Tip is in the well • Tip punched through the gel • Dye spreading under the well

13. Proper loading technique • Tip is above the well and in the buffer • Sample in well Courtesy of K. Schramm

14. Lab 1.2 results A C B

15. Analysis of sample composition • Sample A has blue and purple dye • Sample B has blue, purple, and yellow dye • Sample C has blue dye A C B

16. Predicted dye molecular weights • Heaviest is blue dye (xylene cyanole) • Middle is purple dye (bromophenol blue) • Lightest is yellow dye (orange G) A C B

17. Actual dye molecular weights • Heaviest is purple dye (bromophenol blue) – 670.0 amu • Middle is blue dye (xylene cyanole) – 538.6 amu • Lightest is yellow dye (orange G) – 452.4 amu

18. Dye molecular weight discrepancy • Purple dye (bromophenol blue) has more negative charge per unit of mass than blue dye (xylene cyanole) due to bromine ions • The heavier purple dye molecule travels farther through the gel than the lighter blue dye molecule

19. DNA molecular weight discrepancy • All DNA molecules have same ratio of charge to mass • The movement of DNA is determined solely by mass and shape • There are 3 plasmid configurations and their shapes affect how far they travel through the gel