1 / 37

Practical Issues

Practical Issues. Joop van Helvoort March, 9 th , 2004. Topics. Water and chemicals RNA isolation cRNA versus cDNA Quantification Hybridisation Available slides Future developments. Water and chemicals RNA isolation cRNA versus cDNA Quantification Hybridisation

ulla
Download Presentation

Practical Issues

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. Practical Issues Joop van Helvoort March, 9th, 2004

  2. Topics Water and chemicals RNA isolation cRNA versus cDNA Quantification Hybridisation Available slides Future developments

  3. Water and chemicals RNA isolation cRNA versus cDNA Quantification Hybridisation Available slides Future developments

  4. Stick to chemicals used in our protocols and stated in our list of chemicals: write down lot numbers (helpful in troubleshooting) • Water quality is crucial: • - RNA-isolation • labeling • hybridization use MilliQ, regularly change the cartridge never use DEPC treated water, because DEPC removal is not 100%: DEPC: - modifies RNA - interferes with quantification - causes artifacts during hybridization

  5. Water and chemicals RNA isolation cRNA versus cDNA Quantification Hybridisation Available slides Future developments

  6. trizol method for cDNA labeling • Dnase treatment + removal of Dnase: • - beads (Ambion) • phenol/ChCl3 extraction + LiCl precipitation • LiCl precipitation Amount of material after purification from 400µg total RNA 500 400 300 After purification 200 100 0.0 Beads Phenol-LiCl LiCl

  7. What the mock tells you: Beads Phenol-LiCl

  8. Beads Phenol-LiCl LiCl Hybs according to latest protocol with borohydride 300 ng of labeled cell line material on human v2.0

  9. Beads Phenol-LiCl LiCl Normalized on genes 5676 red; 7156 green 14691 red; 15483 green 13433 red; 17507 green 7882 red; 12939 green 14800 red; 20079 green 12633 red; 18189 green spots > 2*sd(bg)

  10. Signal intensity of Genes-Background

  11. RNA isolation from tissues for RNA amplification • Why is hybridisation of amplified RNA less vulnerable to contamination? • several cleaning steps before labeling • start with 1 ug and use only ~10% of final product • cDNA labeling: start with 30-60 ug, use almost everything methods involve cryosection instead of tissue disruption

  12. - Trizol/RNeasy/Dnase+beads method: proven method in large scale study Tumor sample pool raw normalized on genes

  13. alternative: RNeasy+Dnase on column (Dermatology) • tissuetek not compatible with trizol (phenol) • only recently introduced Skin biopsy 1 2 raw normalized on genes

  14. Methods of choice cDNA labeling of cell line RNA: Trizol + Dnase + Phenol/LiCl cRNA labeling of tissue RNA cryosection of material Trizol + Rneasy + Dnase + beads

  15. Spectrophotometric analysis of RNA • - OD 260 for quantification • Ratio OD260/280 in buffer = 1.8 – 2.0 • Ratio OD260/280 in water ~ 1.6 • spectrum will reveal • phenol contamination: peak shift to 270 nm • - high salt concentration: ‘valley’ between shorter wavelengths and • 260 nm disappears

  16. Bioanalyzer Quantification unreliable: amount and 28S/18S ratio: 28S/18S = 1.52 28S/18S = 1.75

  17. RNA contamination Tumor material contaminated with mycoplasma in vivo Don’t use

  18. RNA degradation Don’t use RNA from apoptotic cells? • When do you stop using degraded RNA? • depends on origin material: • - cell line should give good quality RNA • tissue or primary cells: quality is variable

  19. Water and chemicals RNA isolation cRNA versus cDNA Quantification Hybridisation Available slides Future developments

  20. Amplified RNA on the Bioanalyzer proper size distribution ribosomal peaks shining through degraded RNA

  21. Use RNA amplification • more robust, less vulnerable for contamination • To avoid bias: • start with identical amount of total RNA: 1 µg • in vitro transcription: 4 hours, not longer (our experience and in lit.)

  22. Water and chemicals RNA isolation cRNA versus cDNA Quantification Hybridisation Available slides Future developments

  23. Spectrophotometric analysis of RNA Spectrophotometric analysis of cDNA and mock synthesis RNA hydrolysis failed Repeat hydrolysis

  24. hybridisation can be hampered by size of the dyes amino allyl UTP Cy5 - quenching: Spectrophotometric analysis of labeled material Higher labeling percentage  more signal • a-specific adherence of Cy dyes to one another

  25. Cy3 Cy5 average signal intensity 4.9 % 7.3 % 2.0 % 4.5 % • Optimal labeling percentage • Cy3: 3 – 5% • Cy5: 2 – 4%

  26. Correct amount of cDNA but labeling failed Repeat labeling: because hydroxylamine only hydrolyses the Cy dyes and doesn’t affect the amino group of the (d)UTP

  27. Water and chemicals RNA isolation cRNA versus cDNA Quantification Hybridization Available slides Future developments

  28. Removal of excess oligos Standard pre-hybridisation UMC. Rigid wash of slides in 50-ml Falcon tube filled with 2xSSC and 0.05% SDS followed by standard pre-hybridisation.

  29. Borohydride treatment (as published by Corning): temporary solution Mock hybridisation (no labeled material) Borohydride treatment • Cy3 artifact: autofluorescence of oligospots in the Cy3 channel: • impurities in oligos • glass surface • - oligos themselves

  30. Hybridization of labeled yeast cDNA old protocol borohydride • Storage of borohydride: • hygroscopic • in aliquots • in dessicator

  31. Lifterslips - highly variable within and among batches: clean good lifterslips carefully - use soft soap from hand pump, not from dispenser above sink - wash extensively - after drying the lifterslips check for presence of haze over surface of lifterslip

  32. Wash slides • Reducing background fluorescence • Shake slides in 0.1x SSC as last step • Don’t use ethanol as the last step: • signal reduction

  33. Water and chemicals RNA isolation cRNA versus cDNA Quantification Hybridization Available arrays Future developments

  34. spots genes + splice variants Dog (cDNA) 23000 20000 Human 1.1 20000 17000 Human 2.0 24500 21500 Yeast 16000 6300 (in duplo) Rat 12000 4500 (in duplo) coming soon: Mouse 35000 32000 All arrays contain 3000 control spots Jan Mol/Rene van den Ham

  35. Water and chemicals RNA isolation cRNA versus cDNA Quantification Hybridization Available arrays Future developments

  36. Spotting: • high density spotting <80000 features per slide • larger oligo collections • - duplo spots • - loose Cy3 artifact • Ozone: • >5 ppb ozone causes bleaching (in combination with humidity + X) • july / august / september • ozone monitoring • ozone free environment • Hyb station: • alternative for lifterslips • more reproducible but lower signals

More Related