Here we use a human esiRNA library in a high-throughput screen for genes involved in cell division. We demonstrate how to set up and conduct an esiRNA screens, as well as how to analyze and validate the results.
RNA interference (RNAi) is a basic cellular mechanism for the control of gene expression. RNAi is induced by short double-stranded RNAs also known as small interfering RNAs (siRNAs). The short double-stranded RNAs originate from longer double stranded precursors by the activity of Dicer, a protein of the RNase III family of endonucleases. The resulting fragments are components of the RNA-induced silencing complex (RISC), directing it to the cognate target mRNA. RISC cleaves the target mRNA thereby reducing the expression of the encoded protein1,2,3. RNAi has become a powerful and widely used experimental method for loss of gene function studies in mammalian cells utilizing small interfering RNAs.
Currently two main methods are available for the production of small interfering RNAs. One method involves chemical synthesis, whereas an alternative method employs endonucleolytic cleavage of target specific long double-stranded RNAs by RNase III in vitro. Thereby, a diverse pool of siRNA-like oligonucleotides is produced which is also known as endoribonuclease-prepared siRNA or esiRNA. A comparison of efficacy of chemically derived siRNAs and esiRNAs shows that both triggers are potent in target-gene silencing. Differences can, however, be seen when comparing specificity. Many single chemically synthesized siRNAs produce prominent off-target effects, whereas the complex mixture inherent in esiRNAs leads to a more specific knockdown10.
In this study, we present the design of genome-scale MISSION esiRNA libraries and its utilization for RNAi screening exemplified by a DNA-content screen for the identification of genes involved in cell cycle progression. We show how to optimize the transfection protocol and the assay for screening in high throughput. We also demonstrate how large data-sets can be evaluated statistically and present methods to validate primary hits. Finally, we give potential starting points for further functional characterizations of validated hits.
1. High-quality MISSION esiRNA libraries
2. Choosing a cell line and optimizing transfection for screening
3. Setting Up the Primary screen5,6
4. Primary screen
5. Secondary screen and hit validation
RNA interference has become a standard technique to study loss-of-function phenotypes. Large-scale collections of RNAi-mediators are available from different suppliers and provide an easy, cost-effective and rapid method for gene-silencing. This opened the gate for systematic screening for key-players in many biological processes allowing a genome-scale perspective on a wide range of different species and cell types.
High false positive and false negative rates are a common challenge in RNAi screens. To address this problem, considerable efforts have been invested to improve the efficacy and in particular the specificity of the silencing triggers. An important discovery was that a pool of different siRNAs targeting the same transcript greatly enhances target specificity. Because a very complex pool of different siRNAs is produced by the endoribonuclease, esiRNAs are high target specificity triggers, reducing the false positive rate in RNAi screens. esiRNAs have also demonstrated to achieve efficient knockdowns, reducing also the false negative rate.
Because RNAi screens are technically demanding, they will likely remain challenging to perform on a routine basis for some time. However, as reagents and instruments get better and more laboratories share their expertise, the use of RNAi screens in modern biology are deemed to increase in the future.
The authors have nothing to disclose.
We would like to acknowledge members of the Buchholz laboratory and the Sigma-Aldrich RNAi-team for discussion. We would like to thank the Max Planck Society and the Bundesministerium für Bildung und Forschung grands Go-Bio [0315105] for support.
MISSION ® is a registered trademark of Sigma-Aldrich Biotechnology L.P.
Material Name | Tipo | Company | Catalogue Number | Comments |
MISSION esiRNA | Sigma-Aldrich | For additional information contact: rnai@sial.com | ||
Wellmate | ThermoScientific | |||
Breathable sealing tape | Corning | Breathable Sealing Tape, Sterile (Product #3345) | ||
OptiMEM | Invitrogen | |||
Ethanol | Sigma-Aldrich | E7023 | 200 proof (absolute), for molecular biology | |
Phosphate buffered saline | Sigma-Aldrich | P5493 | BioReagent, 10x concentrate, suitable for cell culture, for molecular biology | |
4′,6-Diamidino-2-phenylindole dihydrochloride | Sigma-Aldrich | D8417 | Poweder, BioReagent, suitable for cell culture, >98% (HPLC and TLC) | |
Ribonuclease A from bovine pancreas | Sigma-Aldrich | R6513 | For molecular biology, ≥70 Kunitz units/mg protein, lyophilized powder | |
Tris-EDTA buffer solution | Sigma-Aldrich | T9285 | 100 x, for molecular biology |