Abstract
A major goal of bioinformatics is the characterization of transcription factors and the transcriptional programs they regulate.
Given the speed of genome sequencing, we would like to quickly annotate regulatory sequences in newly-sequenced
genomes. In such cases, it would be helpful to predict sequence motifs by using experimental data from closely related
model organism. Here we present a general algorithm that allow to identify transcription factor binding sites in one newly
sequenced species by performing Bayesian regression on the annotated species. First we set the rationale of our method by
applying it within the same species, then we extend it to use data available in closely related species. Finally, we generalise
the method to handle the case when a certain number of experiments, from several species close to the species on which to
make inference, are available. In order to show the performance of the method, we analyse three functionally related
networks in the Ascomycota. Two gene network case studies are related to the G2/M phase of the Ascomycota cell cycle; the
third is related to morphogenesis. We also compared the method with MatrixReduce and discuss other types of validation
and tests. The first network is well known and provides a biological validation test of the method. The two cell cycle case
studies, where the gene network size is conserved, demonstrate an effective utility in annotating new species sequences
using all the available replicas from model species. The third case, where the gene network size varies among species, shows
that the combination of information is less powerful but is still informative. Our methodology is quite general and could be
extended to integrate other high-throughput data from model organisms.
Anno
2012
Autori IAC
Tipo pubblicazione
Altri Autori
Pietro Li, Claudia Angelini, Italia De Feis, VietAnh Nguyen
Editore
Public Library of Science
Rivista
PloS one