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Literature DB >> 21513377

The stochastic quasi-steady-state assumption: reducing the model but not the noise.

Rishi Srivastava¹, Eric L Haseltine, Ethan Mastny, James B Rawlings.

Abstract

Highly reactive species at small copy numbers play an important role in many biological reaction networks. We have described previously how these species can be removed from reaction networks using stochastic quasi-steady-state singular perturbation analysis (sQSPA). In this paper we apply sQSPA to three published biological models: the pap operon regulation, a biochemical oscillator, and an intracellular viral infection. These examples demonstrate three different potential benefits of sQSPA. First, rare state probabilities can be accurately estimated from simulation. Second, the method typically results in fewer and better scaled parameters that can be more readily estimated from experiments. Finally, the simulation time can be significantly reduced without sacrificing the accuracy of the solution.

Entities: Disease

Mesh：

Year: 2011 PMID： 21513377 PMCID： PMC3094464 DOI： 10.1063/1.3580292

Source DB: PubMed Journal: J Chem Phys ISSN： 0021-9606 Impact factor: 3.488

21 in total

The stochastic quasi-steady-state assumption: reducing the model but not the noise.

1. Regulation of noise in the expression of a single gene.

2. Stochastic gene expression in a single cell.

3. Control of stochasticity in eukaryotic gene expression.

4. State-dependent biasing method for importance sampling in the weighted stochastic simulation algorithm.

5. Ultrasensitivity and noise propagation in a synthetic transcriptional cascade.

6. Nested stochastic simulation algorithm for chemical kinetic systems with disparate rates.

7. Two classes of quasi-steady-state model reductions for stochastic kinetics.

8. The finite state projection algorithm for the solution of the chemical master equation.

9. An efficient and exact stochastic simulation method to analyze rare events in biochemical systems.

10. Universally sloppy parameter sensitivities in systems biology models.

1. Multiscale stochastic modelling of gene expression.

2. Comparison of finite difference based methods to obtain sensitivities of stochastic chemical kinetic models.

3. Asynchronous τ-leaping.

4. Analytical Expressions and Physics for Single-Cell mRNA Distributions of the lac Operon of E. coli.

5. A multi-time-scale analysis of chemical reaction networks: II. Stochastic systems.

6. Comparison of Parameter Estimation Methods in Stochastic Chemical Kinetic Models: Examples in Systems Biology.

7. Stochastic modelling of biochemical systems of multi-step reactions using a simplified two-variable model.

8. Stochastic modeling of biochemical systems with multistep reactions using state-dependent time delay.

9. Mixture distributions in a stochastic gene expression model with delayed feedback: a WKB approximation approach.