Abstract
BackgroundAs a highly efficient and specific gene regulation technology, RNAi has broad application fields and good prospects. The effect of RNAi enhances as the dosage of siRNA increases, while an exorbitant siRNA dosage will inhibit the RNAi effect. So it is crucial to formulate a dose-effect model to describe the degradation effects of the target mRNA at different siRNA dosages.ResultsIn this work, a simple RNA interference model with hill kinetic function (Giulia Cuccato et al. (2011)) is extended. Firstly, by introducing both the degradation time delay τ1 of mRNA caused by siRNA and the transportation time delay τ2 of mRNA from the nucleus to the cytoplasm during protein translation, one acquires a novel delay differential equations (DDEs) model with physiology lags. Secondly, qualitative analyses are executed to identify regions of stability of the positive equilibrium and to determine the corresponding parameter scales. Next, the approximate period of the limit cycle at Hopf bifurcation points is computed. Furthermore we analyze the parameter sensitivity of the limit cycle. Finally, we propose an optimal strategy to select siRNA dosage which arouses significant silencing efficiency.ConclusionsOur researches indicate that when the dosage of siRNA is large, oscillating periods are identical for disparate number of siRNA target sites even if it greatly impacts the critical siRNA dosage which is the switch of oscillating behavior. Furthermore, parametric sensitivity analyses of limit cycle disclose that both of degradation lag and maximum degradation rate of mRNA due to RNAi are principal elements on determining periodic oscillation. Our explorations will provide evidence for gene regulation and RNAi.
Highlights
As a highly efficient and specific gene regulation technology, RNA interference (RNAi) has broad application fields and good prospects
Our result show that the stability of the only positive equilibrium has changed: it is stable while the original model without time delays, as the time delay increases, it will turn into damped oscillation and lose its stability via a Hopf Bifurcation
It indicates that when the dosage of Small interfering RNA (siRNA) is large, oscillating periods are identical for disparate number of siRNA target sites even though it greatly impacts the critical siRNA dosage Sn which is the switch of oscillating behavior
Summary
As a highly efficient and specific gene regulation technology, RNAi has broad application fields and good prospects. It identifies and unites target mRNAs via the principle of complementary base pairing
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