Gene-Environment Case-Control Studies

1. Gene-Environment Case-Control Studies Raymond J. Carroll Department of Statistics Center for Statistical Bioinformatics Institute for Applied Mathematics and Computational Science Texas A&M University http://stat.tamu.edu/~carroll TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: AAAAAAAAAA

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6. Outline • Problem: Case-Control Studies with Gene-Environment relationships • Theme I: Logistic regression is lousy for understanding interactions. We make assumptions that can double or triple the effective sample size

7. Outline • Problem: Case-Control Studies with Gene-Environment relationships • Theme II: There is a lousy estimator, and a good one that makes more assumptions. How do you protect yourself if the assumptions fail, and you want to analyze 500,00 SNP?

8. Outline • Problem: Case-Control Studies with Gene-Environment relationships • Theme III: How does all this work with actual data, as opposed to simulated data?

9. Software • SAS and Matlab Programs Available at my web site under the software button • R programs available from the NCI • New Statistical Science paper 2009, volume 24, 489-502 http://stat.tamu.edu/~carroll

10. Basic Problem Formalized • GeneandEnvironment • Question: For women who carry the BRCA1/2 mutation, does oral contraceptive use provide any protection against ovarian cancer?

11. Basic Problem Formalized • GeneandEnvironment • Question: For people carrying a particular haplotype in the VDR pathway, does higher levels of serum Vitamin D protect against prostate cancer?

12. Basic Problem Formalized • GeneandEnvironment • Question: If you are a current smoker, are you protected against colorectal adenoma if you carry a particular haplotype in the NAT2 smoking metabolism region?

13. Retrospective Studies • D = disease status (binary) • X = environmental variables • Smoking status • Vitamin D • Oral contraceptive use • G = gene status • Mutation or not • Multiple or single SNP • Haplotypes

14. Prospective and Retrospective Studies • Retrospective Studies: Usually called case-control studies • Find a population of cases, i.e., people with a disease, and sample from it. • Find a population of controls, i.e., people without the disease, and sample from it.

15. Prospective and Retrospective Studies • Retrospective Studies: Because the gene G and the environment X are sample after disease status is ascertained

16. Basic Problem Formalized • Case control sample: D = disease • Gene expression: G • Environment, can include strata: X • We are interested in main effects for G and X along with their interaction as they affect development of disease

17. Logistic Regression • Logistic Function: • The approximation works for rare diseases

18. Prospective Models • Simplest logistic model without an interaction • The effect of having a mutation (G=1) versus not (G=0) is

19. Prospective Models • Simplest logistic model with an interaction • The effect of having a mutation (G=1) versus not (G=0) is

20. Empirical Observations • Statistical Theory: There is a lovely statistical theory available • It says: ignore the fact that you have a case-control sample, and pretend you have a prospective study

21. When G is observed • Logistic regression is robust to any modeling assumptions about the covariates in the population • Unfortunately it is not very efficient for understanding interactions • Much larger sample sizes are required for interactions that for just gene effects

22. Gene-Environment Independence • In many situations, it may be reasonable to assume G and X are independently distributed in the underlying population, possibly after conditioning on strata • This assumption is often used in gene-environment interaction studies

23. G-E Independence • Does not always hold! • Example: polymorphisms in the smoking metabolism pathway may affect the degree of addiction

24. Gene-Environment Independence • If you are willing to make assumptions about the distributions of the covariates in the population, more efficiency can be obtained. • This is NOT TRUE for prospective studies, only true for retrospective studies.

25. Gene-Environment Independence • The reason is that you are putting a constraint on the retrospective likelihood

26. Gene-Environment Independence • Our Methodology: Is far more general than assuming that genetic status and environment are independent • We have developed capacity for modeling the distribution of genetic status given strata and environmental factors • I will skip this and just pretend G-E independence here

27. More Efficiency, G Observed • Our model: G-E independence and a genetic model, e.g., Hardy-Weinberg Equilibrium

28. The Formulation • Any logistic model works • Question: What methods do we have to construct estimators?

29. Methodology • I won’t give you the full methodology, but it works as follows. • Case-control studies are very close to a prospective (random sampling) study, with the exception that sometimes you do not observe people

30. Methodology N Total Population Np1 Np0 Controls in the Population Cases in the Population Cases in the Sample n1 n0 Controls in the Sample Missing Cases Np1-n1 Np0-n0 Missing Controls % of Controls observed % of Cases observed

31. Pretend Missing Data Formulation • This means that there is a missing data problem. • The selection into the case control study is biased: cases are vastly over-represented • Ordinary logistic regression computes the probability of disease given the environment, given the gene, and given that the person was selected into the case control study

32. Pretend Missing Data Formulation • This means that there is a missing data problem. • Our method computes the probability of disease and the probability of gene given the environment and given that the person was selected into the case control study • The selection into the case control study is biased: cases are vastly over-represented

33. Methodology • Our method has an explicit form, i.e., no integrals or anything nasty • It is easy to program the method to estimate the logistic model • It is likelihood based. Technically, a semiparametric profile likelihood

34. Methodology • We can handle missing gene data • We can handle error in genotyping • We can handle measurement errors in environmental variables, e.g., diet

35. Methodology • Our method results in much more efficient statistical inference

36. More Data • What does More efficient statistical inference mean? • It means, effectively, that you have more data • In cases that G is a simple mutation, our method is typically equivalent to having 3 times more data

37. How much more data: Typical Simulation Example • The increase in effective sample size when using our methodology

38. Real Data Complexities • The Israeli Ovarian Cancer Study • G = BRCA1/2 mutation (very deadly) • X includes • age, • ethnic status (below), • parity, • oral contraceptive use • Family history • Smoking • Etc.

39. Real Data Complexities • In the Israeli Study, G is missing in 50% of the controls, and 10% of the cases • Also, among Jewish citizens, Israel has two dominant ethnic types • Ashkenazi (European) • Shephardic (North African)

40. Real Data Complexities • The gene mutation BRCA1/2 if frequent among the Ashkenazi, but rare among the Shephardic • Thus, if one component of X is ethnic status, then pr(G=1 | X) depends on X • Gene-Environment independence fails here • What can be done? Model pr(G=1 | X) as binary with different probabilities!

41. Israeli Ovarian Cancer Study • Question: Can carriers of the BRCA1/2 mutation be protected via OC-use?

42. Typical Empirical Example

43. Israeli Ovarian Cancer Study • Main Effect of BRCA1/2:

44. Israeli Ovarian Cancer Study

45. Haplotypes • Haplotypes consist of what we get from our mother and father at more than one site • Mother gives us the haplotype hm = (Am,Bm) • Father gives us the haplotype hf = (af,bf) • Our diplotype is Hdip = {(Am,Bm), (af,bf)}

46. Haplotypes • Unfortunately, we cannot presently observe the two haplotypes • We can only observe genotypes • Thus, if we were really Hdip = {(Am,Bm), (af,bf)}, then the data we would see would simply be the unordered set (A,a,B,b)

47. Missing Haplotypes • Thus, if we were really Hdip = {(Am,Bm), (af,bf)}, then the data we would see would simply be the unordered set (A,a,B,b) • However, this is also consistent with a different diplotype, namely Hdip = {(am,Bm), (Af,bf)} • Note that the number of copies of the (a,b) haplotype differs in these two cases • The true diploid = haplotype pair is missing

48. Missing Haplotypes • Our methods handle unphased diplotyes (missing haplotypes) with no problem. • Standard EM-algorithm calculations can be used • We assume that the haplotypes are in HWE, and have extended to cases of non-HWE

49. Robustness • Robustness: We are making assumptions to gain efficiency = “get more data” • What happens if the assumptions are wrong? • Biases, incorrect conclusions, etc. • How can we gain efficiency when it is warranted, and yet have valid inferences?

50. Two Likelihoods • The two likelihoods lead to two estimators • The former is robust but not efficient • The latter is efficient but not robust • What to do?