| name | bio-causal-genomics-mediation-analysis |
| description | Decompose genetic effects into direct and indirect paths through mediating variables using the mediation R package. Tests whether gene expression, methylation, or other molecular phenotypes mediate the effect of genetic variants on disease. Use when testing whether a molecular phenotype mediates the genotype-to-phenotype relationship. |
| tool_type | r |
| primary_tool | mediation |
Version Compatibility
Reference examples tested with: R stats (base), ggplot2 3.5+
Before using code patterns, verify installed versions match. If versions differ:
- R:
packageVersion('<pkg>') then ?function_name to verify parameters
If code throws ImportError, AttributeError, or TypeError, introspect the installed
package and adapt the example to match the actual API rather than retrying.
Mediation Analysis
"Test whether gene expression mediates the effect of this variant on disease" → Decompose the total genetic effect into direct and indirect (mediated) paths through a molecular phenotype, estimating ACME, ADE, and proportion mediated with bootstrap confidence intervals.
- R:
mediation::mediate() for causal mediation analysis
Framework
Causal mediation decomposes the total effect of a treatment (genotype) on an outcome
(phenotype) into:
- ACME (Average Causal Mediation Effect) - Indirect effect through the mediator
- ADE (Average Direct Effect) - Direct effect not through the mediator
- Total effect = ACME + ADE
- Proportion mediated = ACME / Total effect
Typical genomic applications:
- SNP -> gene expression (mediator) -> disease
- SNP -> DNA methylation (mediator) -> gene expression
- SNP -> protein levels (mediator) -> clinical outcome
Basic Mediation with the mediation Package
Goal: Decompose a genetic effect into direct and indirect (mediated) paths through a molecular phenotype.
Approach: Fit separate models for mediator and outcome, then run mediate() with bootstrap to estimate ACME (indirect), ADE (direct), and proportion mediated.
library(mediation)
mediator_model <- lm(expression ~ genotype + age + sex + pc1 + pc2, data = dat)
outcome_model <- glm(
disease ~ genotype + expression + age + sex + pc1 + pc2,
data = dat, family = binomial
)
med_result <- mediate(
mediator_model, outcome_model,
treat = 'genotype', mediator = 'expression',
boot = TRUE, sims = 1000
)
summary(med_result)
Interpreting Results
acme <- med_result$d0
acme_ci <- med_result$d0.ci
ade <- med_result$z0
total <- med_result$tau.coef
prop_med <- med_result$n0
cat('ACME (indirect):', round(acme, 4), '\n')
cat('ACME 95% CI:', round(acme_ci[1], 4), 'to', round(acme_ci[2], 4), '\n')
cat('ADE (direct):', round(ade, 4), '\n')
cat('Total effect:', round(total, 4), '\n')
cat('Proportion mediated:', round(prop_med, 3), '\n')
eQTL Mediation
Goal: Test whether gene expression mediates the effect of an eQTL on a disease outcome across multiple genes.
Approach: Wrap the mediation workflow in a function, loop over candidate genes, and adjust p-values for multiple testing.
library(mediation)
run_eqtl_mediation <- function(dat, snp_col, expr_col, outcome_col, covariates) {
covar_formula <- paste(covariates, collapse = ' + ')
med_formula <- as.formula(paste(expr_col, '~', snp_col, '+', covar_formula))
out_formula <- as.formula(paste(outcome_col, '~', snp_col, '+', expr_col, '+', covar_formula))
med_model <- lm(med_formula, data = dat)
if (length(unique(dat[[outcome_col]])) == 2) {
out_model <- glm(out_formula, data = dat, family = binomial)
} else {
out_model <- lm(out_formula, data = dat)
}
result <- mediate(
med_model, out_model,
treat = snp_col, mediator = expr_col,
boot = TRUE, sims = 1000
)
data.frame(
snp = snp_col, gene = expr_col,
acme = result$d0, acme_p = result$d0.p,
ade = result$z0, ade_p = result$z0.p,
total = result$tau.coef, total_p = result$tau.p,
prop_mediated = result$n0
)
}
genes <- c('GENE_A', 'GENE_B', 'GENE_C')
covars <- c('age', 'sex', 'pc1', 'pc2', 'pc3')
mediation_results <- do.call(rbind, lapply(genes, function(g) {
run_eqtl_mediation(dat, 'rs12345', g, 'disease_status', covars)
}))
mediation_results$acme_fdr <- p.adjust(mediation_results$acme_p, method = 'BH')
Multi-Omics Mediation
Goal: Test cascading mediation chains across multiple molecular layers (e.g., SNP -> methylation -> expression -> disease).
Approach: Fit sequential models for each link in the chain and run separate mediation analyses for each mediator-outcome pair.
library(mediation)
mod_meth <- lm(methylation ~ genotype + age + sex, data = dat)
mod_expr <- lm(expression ~ methylation + genotype + age + sex, data = dat)
mod_disease <- glm(
disease ~ expression + methylation + genotype + age + sex,
data = dat, family = binomial
)
med_meth_expr <- mediate(mod_meth, mod_expr, treat = 'genotype', mediator = 'methylation',
boot = TRUE, sims = 1000)
med_expr_disease <- mediate(mod_expr, mod_disease, treat = 'methylation', mediator = 'expression',
boot = TRUE, sims = 1000)
High-Dimensional Mediation (HDMA)
Goal: Test thousands of potential mediators simultaneously (e.g., all CpG sites) to identify which mediate a genetic effect.
Approach: Use HIMA's penalized regression to jointly select significant mediators from a high-dimensional mediator matrix and estimate their indirect effects.
library(HIMA)
result <- hima(
X = dat$genotype,
Y = dat$disease,
M = as.matrix(dat[, mediator_cols]),
COV.XM = as.matrix(dat[, covariate_cols]),
Y.family = 'binomial',
M.family = 'gaussian',
penalty = 'MCP'
)
significant_mediators <- result[result$BH.FDR < 0.05, ]
Assumptions and Diagnostics
sens <- medsens(med_result, rho.by = 0.1, effect.type = 'indirect', sims = 1000)
summary(sens)
plot(sens)
Visualization
library(ggplot2)
plot_mediation_diagram <- function(acme, ade, total, prop_med) {
cat('Mediation Path Diagram:\n\n')
cat(' Genotype ---[a]---> Mediator ---[b]---> Outcome\n')
cat(' | ^\n')
cat(' +----------[c\' (ADE)]----------------+\n')
cat('\n')
cat(' Indirect (a*b = ACME):', round(acme, 4), '\n')
cat(' Direct (c\' = ADE):', round(ade, 4), '\n')
cat(' Total (c):', round(total, 4), '\n')
cat(' Proportion mediated:', round(prop_med, 3), '\n')
}
plot_mediation_results <- function(results_df) {
results_df$gene <- factor(results_df$gene, levels = results_df$gene[order(results_df$prop_mediated)])
ggplot(results_df, aes(x = gene, y = prop_mediated)) +
geom_col(fill = 'steelblue', alpha = 0.7) +
geom_hline(yintercept = 0.2, linetype = 'dashed', color = 'red', alpha = 0.5) +
coord_flip() +
labs(x = NULL, y = 'Proportion Mediated', title = 'Mediation by Gene Expression') +
theme_minimal()
}
Related Skills
- mendelian-randomization - Causal inference using genetic instruments
- colocalization-analysis - Test if signals share a causal variant
- population-genetics/association-testing - GWAS for treatment-outcome associations
- multi-omics-integration/mofa-integration - Multi-omics data for mediation chains
