RNA Dwell Time Analysis
This example demonstrates how to analyze RNA dwell time data to understand transcriptional dynamics.
Setup
First, let's set up our project directory and load the package:
using StochasticGene
# Create project directory
rna_setup("dwell_time_example")
cd("dwell_time_example")Data Preparation
Place your dwell time data in the data/ directory. The data should be organized as follows:
data/
├── gene_name/
│ ├── condition1/
│ │ ├── dwell_times.csv
│ │ └── metadata.csv
│ └── condition2/
│ ├── dwell_times.csv
│ └── metadata.csvEach dwell time CSV file should contain:
- Time intervals
- State labels (ON/OFF)
- Optional metadata
Model Definition
We'll fit a model with:
- 2 gene states (G=2) - ON and OFF
- No pre-RNA steps (R=0)
- Simple transitions between states
# Define model parameters
G = 2 # Number of gene states (ON and OFF)
R = 0 # Number of pre-RNA steps
# Define state transitions
# Format: (from_states, to_states)
transitions = (
[1, 2], # From states
[2, 1] # To states
)
# Define transcription rates for each state
transcription_rates = [0.0, 1.0] # No transcription in OFF stateFitting the Model
Now we can fit the model to our dwell time data:
# Fit the model
fits, stats, measures, data, model, options = fit(
G = G,
R = R,
transitions = transitions,
transcription_rates = transcription_rates,
datatype = "dwell_time",
datapath = "data/",
gene = "MYC",
datacond = "CONTROL"
)Analyzing Results
Basic Analysis
# Print basic statistics
println(stats)
# Plot the results
using Plots
plot(fits)
# Save results
save_results(fits, "results/")Dwell Time Analysis
# Analyze dwell time distributions
dwell_times = analyze_dwell_times(fits)
plot_dwell_times(dwell_times, "results/dwell_times/")
# Calculate state residence times
residence_times = analyze_residence_times(fits)
plot_residence_times(residence_times, "results/residence_times/")Burst Analysis
# Analyze transcriptional bursts
burst_stats = analyze_bursts(fits)
println(burst_stats)
# Plot burst statistics
plot_bursts(fits, "results/bursts/")Advanced Analysis
State Transition Analysis
# Analyze state transitions
transitions = analyze_transitions(fits)
# Plot transition probabilities
plot_transitions(transitions, "results/transitions/")
# Calculate transition rates
rates = calculate_transition_rates(fits)
println(rates)Model Comparison
# Compare different model configurations
configurations = [
(G=2, rates=[0.0, 1.0]), # Basic ON-OFF
(G=3, rates=[0.0, 0.5, 1.0]), # Three-state
(G=4, rates=[0.0, 0.3, 0.7, 1.0]) # Four-state
]
config_fits = []
for (G, rates) in configurations
fits, stats, measures, data, model, options = fit(
G = G,
R = R,
transitions = ([1:G...], [2:G..., 1]),
transcription_rates = rates,
datatype = "dwell_time",
datapath = "data/",
gene = "MYC",
datacond = "CONTROL"
)
push!(config_fits, (fits, stats))
end
# Compare configurations
compare_configurations(config_fits, configurations, "results/config_comparison/")Best Practices
Model Selection
- Start with basic ON-OFF model
- Use model selection criteria
- Validate state assumptions
Parameter Estimation
- Check parameter identifiability
- Verify convergence
- Consider parameter correlations
Interpretation
- Relate states to biological mechanisms
- Consider experimental validation
- Document assumptions
Common Issues and Solutions
Parameter Identifiability
# Check parameter identifiability
identifiability = check_identifiability(fits)
plot_identifiability(identifiability, "results/identifiability/")State Validation
# Validate state assignments
validation = validate_states(fits)
plot_validation(validation, "results/validation/")Next Steps
- Try different state configurations
- Experiment with transition patterns
- Compare results across different genes
For more advanced examples, see: