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Related Concept Videos

Mutation, Gene Flow, and Genetic Drift01:09

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In a population that is not at Hardy-Weinberg equilibrium, the frequency of alleles changes over time. Therefore, any deviations from the five conditions of Hardy-Weinberg equilibrium can alter the genetic variation of a given population. Conditions that change the genetic variability of a population include mutations, natural selection, non-random mating, gene flow, and genetic drift (small population size).
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The genomes of eukaryotes are punctuated by long stretches of sequence which do not code for proteins or RNAs. Although some of these regions do contain crucial regulatory sequences, the vast majority of this DNA serves no known function. Typically, these regions of the genome are the ones in which the fastest change, in evolutionary terms, is observed, because there is typically little to no selection pressure acting on these regions to preserve their sequences.
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Organisms are capable of detecting and fixing nucleotide mismatches that occur during DNA replication. This sophisticated process requires identifying the new strand and replacing the erroneous bases with correct nucleotides. Mismatch repair is coordinated by many proteins in both prokaryotes and eukaryotes.
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Point mutations are genetic alterations involving the change of a single nucleotide base pair in DNA. Depending on how the alteration affects protein synthesis, they can lead to various consequences.Point mutations fall into the following types:Silent mutations occur when a nucleotide change does not alter the amino acid sequence due to the redundancy of the genetic code. For instance, changing ACC to ACA still encodes threonine, leaving the protein function unaffected. This occurs because...
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Updated: Sep 16, 2025

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

Benjamin Kuznets-Speck1,2,3,4, Leon Schwartz1,2,3,4,5, Hanxiao Sun1,2,3,4

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

Biorxiv : the Preprint Server for Biology
|July 9, 2025
PubMed
Summary
This summary is machine-generated.

We developed CIPHER, a new method using gene co-fluctuations to predict cellular responses to genetic perturbations. This approach leverages baseline gene covariance for robust functional genomics 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 offer a promising avenue for modeling perturbation responses.

Purpose of the Study:

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

Main Methods:

  • Developed CIPHER, a conceptual framework using linear response theory.
  • Applied CIPHER to synthetic networks and 11 large-scale single-cell perturbation datasets (4,234 perturbations, >1.36M cells).
  • Validated model performance by comparing gene covariance-based predictions with and without baseline gene covariances.

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 proved transferable across independent experiments of the same cell type.
  • CIPHER outperformed differential expression metrics and provided uncertainty-aware effect size estimates via Bayesian inference.
  • Genome-wide responses propagated through the covariance matrix along approximately three independent gene modules.

Conclusions:

  • CIPHER demonstrates the power of theoretically-grounded models in capturing complex biological responses.
  • Baseline gene fluctuation patterns encode fundamental design principles crucial for understanding cellular responses.
  • Harnessing gene co-fluctuations provides a robust and interpretable approach to functional genomics.