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Gene Evolution - Fast or Slow?02:05

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Updated: Oct 18, 2025

JUMPn: A Streamlined Application for Protein Co-Expression Clustering and Network Analysis in Proteomics
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A data-driven method to learn a jump diffusion process from aggregate biological gene expression data.

Jia-Xing Gao1, Zhen-Yi Wang2, Michael Q Zhang3

  • 1LMAM, School of Mathematical Sciences, Peking University, Beijing 100871, China.

Journal of Theoretical Biology
|October 4, 2021
PubMed
Summary
This summary is machine-generated.

This study introduces a new dynamic model for gene expression using a jump diffusion process. This method accurately predicts cell development and heterogeneity, offering a novel way to calculate RNA velocity.

Keywords:
Aggregate dataGene dynamicsStochastic modelingWasserstein distance

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Area of Science:

  • Computational Biology
  • Systems Biology
  • Genetics

Background:

  • Dynamic models of gene expression are crucial for understanding cellular processes.
  • Current models often struggle to capture the inherent stochasticity and complexity of gene expression.
  • A need exists for methods that can model the time evolution of gene expression from aggregate data.

Purpose of the Study:

  • To develop a novel dynamic model for gene expression using a jump diffusion process.
  • To enable prediction of population distributions and individual cell trajectories.
  • To provide a new computational approach for determining RNA velocity.

Main Methods:

  • Learning a jump diffusion process directly from aggregate gene expression data.
  • Utilizing Wasserstein distance to minimize the difference between empirical and predicted distributions.
  • Treating gene expression data at a time point as an empirical marginal distribution.

Main Results:

  • The learned jump diffusion process accurately predicts population distributions and long-time cell trajectories.
  • The model offers a novel method for computing RNA velocity based on instantaneous rates of state change.
  • Demonstrated superior performance in recovering nonlinear dynamics compared to existing parametric and Brownian motion diffusion models on synthetic and real datasets.

Conclusions:

  • The jump diffusion process provides a powerful stochastic dynamic perspective for studying biological systems.
  • The method effectively models cell development, heterogeneity, and RNA velocity.
  • The approach is robust to data perturbations due to its reliance on population expectations.