Fundamentals of experimental design for cDNA microarrays

1. Fundamentals of experimental design for cDNA microarrays Gary A. Churchill http://www.jax.org/research/churchill 2004. 3. 20 김하성

2. SUBJECT • Fundamental issues of how to design an experiment to ensure that the resulting data are amenable to statistical analysis

3. mRNA cDNA DNA microarray OUTLINE 1. Source of variation in microarray experiments 2. Experimental units and treatments 3. Pairing samples for hybridizations 4. Printing the slides 5. Randomization 6. Analysis 7. Examples

4. 1. SOURCES OF VARIATION IN MICROARRAY EXPERIMENTS

5. 2. EXPERIMENTAL UNITS AND TREATMENTS #1 • The correlation observation • A single microarray slide observe two times : 95% • Same sample divided and hybridized two different microarray : 60%~80% • Different lab : lower  various source of variations  Avoid biological replication.

6. 2. EXPERIMENTAL UNITS AND TREATMENTS #2 • Identifying the independent units in an experiment • Interest : Characterize that sample accurately -> one sample, multiple slide -> independent replication • Interest : a biological comparison at the whole organism -> one sample, multiple slide -> no longer independent replication.

7. 2. EXPERIMENTAL UNITS AND TREATMENTS #3 A B 2 Treatments, 24 Observations, 8 experimental unit A B 2 Treatments, 24 Observations, 2 experimental unit

8. 2. EXPERIMENTAL UNITS AND TREATMENTS #4 • Degrees of freedom(df) • A simple way to assess the adequacy of a design • df = number of independent unit – number of distinct treatments • No df = no information of variance • 5 df or more = good shape. • Pooling

9. 3. PAIRING SAMPLES FOR HYBRIDIZATIONS#1Direct Comparison of Two Treatments • A dye swap • A repeated dye swap • A replicated dye swap • Simple loop design

10. 3. PAIRING SAMPLES FOR HYBRIDIZATIONS#2 Direct Comparison of Multiple Samples

11. 3. PAIRING SAMPLES FOR HYBRIDIZATIONS #3 Indirect Comparisons via a Reference Sample a. The standard reference design use a single array to compare each test sample to the reference RNA b. A variation use a dye swap for each comparison.

12. spot Slide pingroup subarray gene 4. PRINTING THE SLIDES • The arrangement of spots Raises design issues that can impact on normalization and analysis of microarray data • Repeated spotting of the same clone increase precision of the measurements if the spot intensities are averaged and minimize problems ( scratches, dust, contaminate the surface of microarray slide) • Repeated spot should be dispersed over the microarray surface to minimize correlations .

13. 5. RANMOMIZAION #1 • 1) Randomization of treatment assignments and random sampling of populations form the physical basis for the validity of statistical test. • It is most crucial to apply randomization or random sampling at the stage of assigning treatments to the experimental unit for the validity of statistical test. • Ex) injection of a drug(bias), • the sex and strain of a mouse(already attatched) • 2) Randomization can be used at other statges in the microarray experiment to help avoid or minimize hidden biases; • Ex) dye assignmet • first sample – Cy5, second sampe – Cy3  bias.

14. 5. RANMOMIZAION #2 • Randomizing the arrangement of spots on an array. • Fisher – regular arrangements cause potential biases. • Each slide in an experiment might have clones printed in a different arrangement. but impractical (printing device or logistics of tracking spot identities) • The possibility of position effects within the array is not farfetched, but it may be a reality that we simply have to accept with awareness.

15. 6. ANALYSIS • Not touched on issues of analysis ( review by D.K. Slonim, p 502~508) • 2) A well designed experiment will often suggest a suitable method of analysis.(kerr, churchil Analysis of variance for gene expression microarray data ) • 3) Recommend that analysis should be carried out in collaboration with a statistician until standards of microarray design and analysis evolve further

16. 7. EXAMPLES #1Mouse Mammary Tumor Survey #1 • A survey of mouse mammary tumor samples(G.A. Churchill) • Treatment factor is strain. • Four levels strain and each strain represented by three independent tumor • 8 df = 12(exp unit) – 4(treatment)

17. HeJ HeJ HeJ HeN BALB HeN REF BALB Hen BALB YBr YBr YBr 7. EXAMPLES #2 Mouse Mammary Tumor Survey #2 • RNA from each tumor was compared directly to a reference sample using two arrays in a dye-swap arrangement

18. Northern Southern Grandis 1 2 3 4 5 1 1 2 2 3 3 4 4 5 5 7. EXAMPLES #3Variation in Fundulus Species • A study of variation in natual population of teleost fish. • Treatment factor is population • Three populations and five fish were sampled from each. • 12 df = 15(exp unit) – 3(treatment)

19. 7. EXAMPLES #4 Geographic Variation in Fundulus • The direct comparisons were arranged as loops • Each sample was measured using four technical replicate. • Dye assignments were balanced

20. 7. EXAMPLES #5 A Two Factor Design Sex x Diet with 2x replication • Gene expression in liver tissues of mice from Pera and DBA/I on low-fat and high-fat diets. • Two independent pools and three mice providing 6df ( 12 pools – 6groups )

21. 8. CONCLUSIONS • Designing a microarray experiment • replication of biological samples • technical replicates • duplication of spotted clones • Some important points to keep in mind • Use adequate biological replicaton • Make direct comparisons between samples • Use dye swapping or looping to balance dyes and samples • Always keep the goals of the experiment in mind