Frequency domain analysis of noise in autoregulated gene circuits
AUTOR(ES)
Simpson, Michael L.
FONTE
National Academy of Sciences
RESUMO
We describe a frequency domain technique for the analysis of intrinsic noise within negatively autoregulated gene circuits. This approach is based on the transfer function around the feedback loop (loop transmission) and the equivalent noise bandwidth of the system. The loop transmission, T, is shown to be a determining factor of the dynamics and the noise behavior of autoregulated gene circuits, and this T-based technique provides a simple and flexible method for the analysis of noise arising from any source within the gene circuit. We show that negative feedback not only reduces the variance of the noise in the protein concentration, but also shifts this noise to higher frequencies where it may have a negligible effect on the noise behavior of following gene circuits within a cascade. This predicted effect is demonstrated through the exact stochastic simulation of a two-gene cascade. The analysis elucidates important aspects of gene circuit structure that control functionality, and may provide some insights into selective pressures leading to this structure. The resulting analytical relationships have a simple form, making them especially useful as synthetic gene circuit design equations. With the exception of the linearization of Hill kinetics, this technique is general and may be applied to the analysis or design of networks of higher complexity. This utility is demonstrated through the exact stochastic simulation of an autoregulated two-gene cascade operating near instability.
ACESSO AO ARTIGO
http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=404696Documentos Relacionados
- Nonlinear analysis of cat retinal ganglion cells in the frequency domain.
- Spectral domain analysis of double screen frequency selective surfaces
- Frequency domain analysis of core inflation measures for Brazil
- THE REDUCTION OF SWITCHING NOISE IN MIXED ANALOG-DIGITAL VLSI CIRCUITS USING CURRENT STEERING LOGIC
- Quantitative noise analysis for gene expression microarray experiments