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Measuring Microbial Mutation Rates with the Fluctuation Assay
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Fluctuation structure predicts genome-wide perturbation outcomes.

Yogesh Goyal1,2,3,4, Benjamin Kuznets-Speck1,2,3,4,5, Leon Schwartz1,2,3,4

  • 1Department of Cell and Developmental Biology, Feinberg School of Medicine, Northwestern University, Chicago IL, USA.

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PubMed
Summary
This summary is machine-generated.

We developed CIPHER, a new framework for analyzing gene expression data from single-cell perturbation screens. CIPHER uses gene co-fluctuations to predict how cells respond to perturbations, improving biological insights.

Keywords:
Bayesian statisticsfluctuationsgenome-wide responseslinear response theorysingle-cell perturbations

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Area of Science:

  • Functional genomics
  • Systems biology
  • Statistical physics

Background:

  • Interpreting pooled single-cell perturbation screens is challenging.
  • Current methods are either opaque deep learning models or oversimplified frameworks.
  • Gene co-fluctuations in unperturbed cells can inform perturbation response modeling.

Purpose of the Study:

  • To present CIPHER (Covariance Inference for Perturbation and High-dimensional Expression Response), a novel framework for predicting transcriptome-wide perturbation outcomes.
  • To leverage linear response theory and gene co-fluctuations for enhanced biological interpretation of perturbation screens.

Main Methods:

  • Developed CIPHER, a framework using linear response theory and gene co-fluctuations.
  • Validated on synthetic networks and 11 large-scale single-cell perturbation datasets (4,234 perturbations, >1.36M cells).
  • Employed Bayesian inference for uncertainty-aware effect size estimation.

Main Results:

  • CIPHER accurately recapitulated genome-wide responses to single and double perturbations by utilizing baseline gene covariance.
  • Removing gene-gene covariances reduced model performance 11-fold, highlighting the importance of fluctuation structures.
  • Gene-gene correlations were transferable across independent studies, indicating conserved fluctuation patterns.
  • CIPHER outperformed differential expression metrics in identifying perturbations and provided uncertainty-aware estimates.
  • Genome-wide responses propagated through the covariance matrix along ~3 global gene modules.

Conclusions:

  • CIPHER demonstrates the power of theoretically-grounded models in understanding complex biological responses.
  • Cellular fluctuation patterns encode fundamental design principles crucial for predicting perturbation outcomes.
  • Harnessing gene co-fluctuations offers a more robust approach to functional genomics analysis.