TY - CHAP
T1 - MicroRNA as an Integral Part of Cell Communication
T2 - Regularized Target Prediction and Network Prediction
AU - Backofen, Rolf
AU - Costa, Fabrizio
AU - Theis, Fabian
AU - Marr, Carsten
AU - Preusse, Martin
AU - Becker, Claude
AU - Saunders, Sita
AU - Palme, Klaus
AU - Dovzhenko, Oleksandr
N1 - Publisher Copyright:
© 2018, Springer International Publishing AG.
PY - 2018
Y1 - 2018
N2 - MicroRNAs, gene encoded small RNA molecules, play an integral part in gene regulation by binding to target mRNAs and preventing their translation. The prediction of microRNA–mRNA-binding sites and the resulting interaction network are essential to understand, and thus influence, regulation of a genetic information flow inside the living organism. Numerous algorithms have been proposed based on various heuristics; however the predictions often vary considerably. In this proposal we will extend a physical model for the binding of microRNAs to the corresponding target and establish an extended set of features influencing binding probabilities. We will be faced with the challenge of (i) too many features and (ii) few known interactions on which to train any prediction algorithm. This problem will be solved using (i) information-theoretical criteria for feature reduction, (ii) regularization, (iii) application of the Infomax approach to guarantee minimal loss of information after dimension reduction, and (iv) experimental validation of theoretical predictions using a novel test system. This strategy will allow (i) statistical analysis of the predicted microRNA–mRNA hypergraph, (ii) characterization of network motives and hierarchies, (iii) identification of missing links, and (iv) removal of false interactions.
AB - MicroRNAs, gene encoded small RNA molecules, play an integral part in gene regulation by binding to target mRNAs and preventing their translation. The prediction of microRNA–mRNA-binding sites and the resulting interaction network are essential to understand, and thus influence, regulation of a genetic information flow inside the living organism. Numerous algorithms have been proposed based on various heuristics; however the predictions often vary considerably. In this proposal we will extend a physical model for the binding of microRNAs to the corresponding target and establish an extended set of features influencing binding probabilities. We will be faced with the challenge of (i) too many features and (ii) few known interactions on which to train any prediction algorithm. This problem will be solved using (i) information-theoretical criteria for feature reduction, (ii) regularization, (iii) application of the Infomax approach to guarantee minimal loss of information after dimension reduction, and (iv) experimental validation of theoretical predictions using a novel test system. This strategy will allow (i) statistical analysis of the predicted microRNA–mRNA hypergraph, (ii) characterization of network motives and hierarchies, (iii) identification of missing links, and (iv) removal of false interactions.
UR - http://www.scopus.com/inward/record.url?scp=85062913582&partnerID=8YFLogxK
U2 - 10.1007/978-3-319-54729-9_2
DO - 10.1007/978-3-319-54729-9_2
M3 - Chapter
AN - SCOPUS:85062913582
T3 - Lecture Notes in Bioengineering
SP - 85
EP - 100
BT - Lecture Notes in Bioengineering
PB - Springer
ER -