Integrated SiRNA Design Based on Surveying of Features Associated with High RNAi Effectiveness

Overview

Journal BMC Bioinformatics

Publisher Biomed Central

Specialty Biology

Date 2006 Nov 30

PMID 17129386

Citations 20

Authors

Wuming Gong

Yongliang Ren

Qiqi Xu

Yejun Wang

Dong Lin

Haiyan Zhou

Tongbin Li

Affiliations

Soon will be listed here.

Abstract

Background: Short interfering RNAs have allowed the development of clean and easily regulated methods for disruption of gene expression. However, while these methods continue to grow in popularity, designing effective siRNA experiments can be challenging. The various existing siRNA design guidelines suffer from two problems: they differ considerably from each other, and they produce high levels of false-positive predictions when tested on data of independent origins.

Results: Using a distinctly large set of siRNA efficacy data assembled from a vast diversity of origins (the siRecords data, containing records of 3,277 siRNA experiments targeting 1,518 genes, derived from 1,417 independent studies), we conducted extensive analyses of all known features that have been implicated in increasing RNAi effectiveness. A number of features having positive impacts on siRNA efficacy were identified. By performing quantitative analyses on cooperative effects among these features, then applying a disjunctive rule merging (DRM) algorithm, we developed a bundle of siRNA design rule sets with the false positive problem well curbed. A comparison with 15 online siRNA design tools indicated that some of the rule sets we developed surpassed all of these design tools commonly used in siRNA design practice in positive predictive values (PPVs).

Conclusion: The availability of the large and diverse siRNA dataset from siRecords and the approach we describe in this report have allowed the development of highly effective and generally applicable siRNA design rule sets. Together with ever improving RNAi lab techniques, these design rule sets are expected to make siRNAs a more useful tool for molecular genetics, functional genomics, and drug discovery studies.

Citing Articles

siRNA Design and GalNAc-Empowered Hepatic Targeted Delivery.

Lu M, Zhang M, Hu B, Huang Y Methods Mol Biol. 2021; 2282:77-100.

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A database of breast oncogenic specific siRNAs.

Tyagi A, Semwal M, Sharma A Sci Rep. 2017; 7(1):8706.

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A semi-supervised tensor regression model for siRNA efficacy prediction.

Thang B, Ho T, Kanda T BMC Bioinformatics. 2015; 16:80.

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Computational design of artificial RNA molecules for gene regulation.

Lagana A, Veneziano D, Russo F, Pulvirenti A, Giugno R, Croce C Methods Mol Biol. 2015; 1269:393-412.

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Target gene abundance contributes to the efficiency of siRNA-mediated gene silencing.

Hong S, Jiang Y, Kim S, Li C, Lee D Nucleic Acid Ther. 2014; 24(3):192-8.

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