Wet Lab Radiation-Induced Chromosome Damage and Rejoining

1. Wet Lab Radiation-Induced Chromosome Damage and Rejoining • Background • Equipment • Supplies • Procedures • Troubleshooting and tips • Lab Demonstrations

2. Background • Types of chromosome aberrations • Radiation dose response curves

3. G1 G2M Rx Rx Background

4. THE CELL CYCLE M A T P Mitosis G2 Single chromatid G1 S phase DNA replication Background

5. Type of cytogenetic damage observed dependents upon where in the cell cycle irradiation occurs Chromosome Aberrations G1 irradiation Both sister chromatids involved Chromatid Aberrations S or G2 irradiation Usually only 1 chromatid involved Background

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12. Multiple mis-rejoining events occurring in CHO chromosomes after G1 irradiation tricentric dicentrics Background

13. Mis-rejoining of 2 breaks on one chromatid after G1 irradiation Centric ring + fragment Acentric ring or interstitial deletion Background

14. Acentric ring or interstitial deletion Ring chromosome Background

15. Chromatid deletions in CHO chromosomes after irradiation in S or G2 Iso-chromatid deletion Chromatid deletion Background

16. Chromatid exchanges in CHO chromosomes after irradiation in S or G2 complex exchange asymmetrical quadra-radial Background

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18. Chromosomal rearrangement is the best biomarker for radiation exposure Sensitive Reliable Large data base Application of new techniques Fluorescence InSitu Hybridization (FISH) Background

19. Multi-color FISH in human lymphocyte chromosomes Non-irradiated Irradiated From: Dr. J.D. Tucker Background

20. Aneupolid cell following FISH with probes for human chromosome 2 and human centromeres From: Dr. J.L. Schwartz Background

21. Fate of rearranged chromosomes 1. Deletions Lost at mitosis - micronuclei 2. Exchange-type rearrangements Symmetrical (balanced) gene rearrangement Asymmetrical (not balanced) fragment usually lost Polycentric chromosomes bridge-breakage-fusion fail mitosis cell death aneuploidy Background

22. Yield of radiation-induced chromosome damage Deletion: Terminal deletion = 1 hit Chromatid deletion = 1 hit Interstitial deletion = 2 hit Yield (Y) ~ linear Y = k + aD k = background a = proportionality Fate: Deletions lost at mitosis 200 Chromatid breaks 100 Aberrations per 100 cells 1 2 Dose (Gy) Background

23. 2. Exchange-type rearrangements > 2 hits required; dependent upon: Space = proximity Time = interaction P (2 hits) = D x D = D2 Y(yield) = k + bD2 3. Total yield Y = k + aD + bD2 Background

24. Low dose dominated by linear component assume k (background) constant Y = k + aD + bD2 Y(0.1 Gy) = 0.1 + (0.1)2 = 0.11 Y(0.2 Gy) = 0.2 + (0.2)2 = 0.24 Y(1.0 Gy) = 1.0 + (1.0)2 = 2.0 Y(2.0 Gy) = 2.0 + (2.0)2 = 6.0 Y(3.0 Gy) = 3.0 + (3.0)2 = 12.0 Y(6.0 Gy) = 6.0 + (6.0)2 = 42.0 Background

25. Dose Rate Effects One hit aberrations - no dose rate effect Two hit aberrations - dose and fractionation effect 2.0 As dose rate aberrations Why? Repair Breaks rejoined, thus unavailable for further interaction 4Gy/hr 1.0 Dicentrics/Cell 0.1 Gy/hr 0 2 4 Dose (Gy) Background

26. SUMMARY • Chromosomal rearrangements observed at first metaphase after irradiation, or after PCC • Chromosome aberrations- G1 damage • Chromatid aberrations - S or G2 damage • Deletion type aberrations - lost at mitosis • Y = k + aD • Exchange-type aberrations • Dose rate and LET dependent • Symmetric - gene rearrangement • complexity revealed by FISH • role in carcinogenesis? • Asymmetric - generally lethal • mitotic failure, aneuploidy • bridge - breakage - fusion cycles • Y = k + aD + bD2

27. Equipment • Sterile tissue culture hood • Incubator (CO2, 37oC, humidified) • Centrifuge • Microscopes( upright, inverted) • Slide warmer (hot plate) • Radiation source

28. Supplies • Tissue culture flasks (dishes) • Tissue culture medium • Glass slides • Colchicine • Methanol (ethanol), acetic acid • KCl, sodium citrate

29. Procedures • Cell culture • Cell growth and division leading to a good mitotic index • Harvesting • Metaphase by colchicine • Hypotonic treatments to swell and weaken the cell membrane • Fixation: (3:1 methanol:acetic acid) to make cell membrane very fragile.

30. Procedures • Chromosome spreading • Drops of cell suspension are placed on a slide, and allowed to dry in a controlled fashion, leading to chromosome spreading • Aging • dry heat and/or ethanol to denature the proteins, remove water/fixative , and enhance the adherence of the chromosomes to the glass slide

31. Procedure Tissue culture and harvesting • Peripheral blood (whole blood) • 1640 RPMI with 10% FCS, PHA stimulation for 72 hrs • Colchicine for 40 min • Re-suspending in 0.075 M KCl hypotonic buffer for 15 min at 37o C • Add fixatives to the cell suspension and wash 3x with fixatives • Cell pellets were stored at -20oC in fixative

32. Procedure Hypotonic treatment • Lymphocytes: 0.075 M KCl, 37oC, 12-20 min • Fibroblasts: 1:1 0.4% KCl:0.8% sodium citrate, 37oC, 12-20 min • Longer time or more hypotonic • Longer, thicker, sticker, less refractive chromosome • Shorter time or less hypotonic • Cell membranes and cell/nuclear debris around the chromosomes

33. Procedure Dropping/drying process • Cells touch the glass surface and become immobile. • Fixative starts drying. • Cells with metaphase chromosomes start flattening and spread their content (chromosome spreading). • As the fixative continues to dry, the nucleated cells continue to flatten slowly.

34. Procedure Dropping/drying process • Dropping cells from different height helps distributing the cells more evenly on the slide, but does not influence chromosome spreading. • Most of chromosome spreading takes place at the time when the fixative evaporates from the spherical surfaces of cells.

35. Troubleshooting and tips • Fixatives • 1:1, 3:1, 6:1, methanol:acetic acid • 3:1 ethanol:acetic acid • Hypotonic buffers • Drying temperatures • Humidity conditions

36. Tips Metaphases spreading • Breaking too easily: • Fragile cell pellets • Lowering the drying temperature • Do not spread well: • Extension of the drying period • Increasing the humidity

37. Tips High speed centrifugation • Higher recovery • Better cell pellet for dropping • 6,000-7,000 rpm in 2 ml microfuge vials with round bottom for 2-5 min • After addition of fixative

38. Tips Glass preparation • Commercially available pre-cleaned glass • Successive washed in aceton, HCl/ethanol and triple distilled water • Dust or cardboard/paper residue

39. Tips Pre-dropping conditions • Dry slides at room temperature. • Cold slides (0oC) when humidity is low. • Slightly warm slides (37oC) when humidity is high. • Pre-soaking the slides with fixative when humidity is very high. • Adding few drops of acetic acid on the slides to improve chromosome spreading in high humidity conditions (increase membrane fragility).

40. Tips Post-dropping: Drying • Room temperature • Heat plate: rainy days or high humidity • Hot water vapor (75-80oC): dry atmospheric conditions

41. Lab Demonstrationsroom B-6624, B-6625 • Chromosome spreading • Counting aberrations-microscope • Counting aberrations-video image