Abstract
BackgroundThe design of multi-stable RNA molecules has important applications in biology, medicine, and biotechnology. Synthetic design approaches profit strongly from effective in-silico methods, which substantially reduce the need for costly wet-lab experiments.ResultsWe devise a novel approach to a central ingredient of most in-silico design methods: the generation of sequences that fold well into multiple target structures. Based on constraint networks, our approach supports generic Boltzmann-weighted sampling, which enables the positive design of RNA sequences with specific free energies (for each of multiple, possibly pseudoknotted, target structures) and GC-content. Moreover, we study general properties of our approach empirically and generate biologically relevant multi-target Boltzmann-weighted designs for an established design benchmark. Our results demonstrate the efficacy and feasibility of the method in practice as well as the benefits of Boltzmann sampling over the previously best multi-target sampling strategy—even for the case of negative design of multi-stable RNAs. Besides empirically studies, we finally justify the algorithmic details due to a fundamental theoretic result about multi-stable RNA design, namely the #P-hardness of the counting of designs.Conclusion introduces a novel, flexible, and effective approach to multi-target RNA design, which promises broad applicability and extensibility.Our free software is available at: https://github.com/yannponty/RNARedPrintSupplementary data are available online.
Highlights
The design of multi-stable RNA molecules has important applications in biology, medicine, and biotechnology
Synthetic biology strives for the engineering of artificial biological systems, promising broad applications in biology, biotechnology and medicine
For the sake of clarity, we introduce this method specialized to the sampling of RNA sequences that have specific energies for multiple structures and specific GC%
Summary
The design of multi-stable RNA molecules has important applications in biology, medicine, and biotechnology. Synthetic biology strives for the engineering of artificial biological systems, promising broad applications in biology, biotechnology and medicine. This requires the design of biological macromolecules with highly specific properties and programmable functions. Simultaneous compatibility to multiple structures is a Hammer et al BMC Bioinformatics (2019) 20:209 relevant design objective for engineering kinetically controlled RNAs, targeting prescribed folding pathways. Advanced applications of RNA design often target multiple structures, aiming at other features, such as specific GC-content (GC%) [9] or the presence/absence of functionally relevant motifs, either anywhere or at specific positions [10]; these objectives motivate flexible computational design methods
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