![[feed]](/style/images/feed-icon-14x14.png){kind=icon}
Small RNA driven feed-forward loop: critical role of sRNA in noise filtering.
Swathi, Tej and Gaurav, Kumar and Sutapa, Mukherji (2019) Small RNA driven feed-forward loop: critical role of sRNA in noise filtering. Physical Biology, 64 (4). pp. 1-17.
![[img]](http://ir.cftri.res.in/style/images/fileicons/other.png) |
PDF
Phys. Biol 2019.pdf - Published Version Restricted to Registered users only Download (1MB) | Request a copy |
Abstract
Gene regulatory networks are often partitioned into di�erent types of recurring network motifs. A feed-forward loop (FFL) is a common motif in which an upstream regulator is a protein, typically a transcription factor, that regulates the expression of the target protein in two ways - �rst, directly by regulating the mRNA levels of the target protein and second, indirectly via an intermediate molecule that in turn regulates the target protein level. Investigations on two variants of FFL - purely transcriptional FFL (tFFL) and sRNA-mediated FFL (smFFL) reveal several advantages of using such motifs. Here, we study a distinct sRNA-driven FFL (sFFL) that was discovered recently in Salmonella enterica: The distinction being the upstream regulator here is not a protein but an sRNA that translationally activates the target protein expression directly; and also indirectly via regulation of the transcriptional activator of the target protein. This variant, i.e. sFFL has not been subjected to rigorous analysis. We therefore set out to understand two aspects. First is a quantitative comparison of the regulatory response of sFFL with tFFL and smFFL using a di�erential equation framework. Since, the process of gene expression is inherently stochastic, the second objective is to �nd how noise in gene expression a�ects the functionality of the sFFL. We �nd that unlike for tFFL and smFFL, the response of sFFL is stronger and faster: the change in target protein concentration is rapid and depends critically on the initial concentration of sRNA. Further, our analysis based on generating function approach and stochastic simulations leads to a non-trivial prediction that an optimal noise �ltration can be attained depending on the synthesis rate of the upstream sRNA and the degradation rate of the intermediate transcriptional activator. A comparison with a simpler process involving only translational activation by sRNA indicates that the design of sFFL is crucial for optimal noise �ltration. These observations prompt us to conclude that sFFL has distinct advantages where the master regulator, sRNA, plays a critical role not only in driving a rapid and strong response, but also a reliable response that depends critically on its concentration.
| Item Type: | Article |
|---|---|
| Uncontrolled Keywords: | sRNA-driven FFL, Salmonella enterica, feed-forward loop |
| Subjects: | 500 Natural Sciences and Mathematics > 07 Life Sciences > 03 Biochemistry & Molecular Biology |
| Divisions: | Protein Chemistry and Technology |
| Depositing User: | Food Sci. & Technol. Information Services |
| Date Deposited: | 22 Jul 2019 04:21 |
| Last Modified: | 22 Jul 2019 04:21 |
| URI: | http://ir.cftri.res.in/id/eprint/14201 |
Actions (login required)
 |
View Item |