Abstract
BackgroundReverse-engineering regulatory networks is one of the central challenges for computational biology. Many techniques have been developed to accomplish this by utilizing transcription factor binding data in conjunction with expression data. Of these approaches, several have focused on the reconstruction of the cell cycle regulatory network of Saccharomyces cerevisiae. The emphasis of these studies has been to model the relationships between transcription factors and their target genes. In contrast, here we focus on reverse-engineering the network of relationships among transcription factors that regulate the cell cycle in S. cerevisiae.ResultsWe have developed a technique to reverse-engineer networks of the time-dependent activities of transcription factors that regulate the cell cycle in S. cerevisiae. The model utilizes linear regression to first estimate the activities of transcription factors from expression time series and genome-wide transcription factor binding data. We then use least squares to construct a model of the time evolution of the activities. We validate our approach in two ways: by demonstrating that it accurately models expression data and by demonstrating that our reconstructed model is similar to previously-published models of transcriptional regulation of the cell cycle.ConclusionOur regression-based approach allows us to build a general model of transcriptional regulation of the yeast cell cycle that includes additional factors and couplings not reported in previously-published models. Our model could serve as a starting point for targeted experiments that test the predicted interactions. In the future, we plan to apply our technique to reverse-engineer other systems where both genome-wide time series expression data and transcription factor binding data are available.
Highlights
Reverse-engineering regulatory networks is one of the central challenges for computational biology
Here we focus on the regulatory network of interactions among transcription factors themselves – such interactions play a central role in regulating cellular programs
We focus on the cell cycle of S. cerevisiae due to the availability of genome-wide time series expression data
Summary
Reverse-engineering regulatory networks is one of the central challenges for computational biology. Many techniques have been developed to accomplish this by utilizing transcription factor binding data in conjunction with expression data. Of these approaches, several have focused on the reconstruction of the cell cycle regulatory network of Saccharomyces cerevisiae. Several have focused on the reconstruction of the cell cycle regulatory network of Saccharomyces cerevisiae The emphasis of these studies has been to model the relationships between transcription factors and their target genes. Here we focus on reverse-engineering the network of relationships among transcription factors that regulate the cell cycle in S. cerevisiae. Using chromatin immunoprecipitation in conjunction with microarrays, it is possible to measure the binding of many transcription factors to the promoters of most (page number not for citation purposes). Does the binding of a specific transcription factor to the promoter of a gene regulate its expression? Does the transcription factor act alone or in cooperation with other factors? Under which conditions is a particular transcription factor active? In general, how does the connectivity of the network change in different conditions (e.g., during the cell cycle)?
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
