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RaptRanker: in silico RNA aptamer selection from HT-SELEX experiment based on local sequence and structure information

Ryoga Ishida, Tatsuo Adachi, Aya Yokota, Hidehito Yoshihara, Kazuteru Aoki, Yoshikazu Nakamura, Michiaki Hamada

2020Nucleic Acids Research73 citationsDOIOpen Access PDF

Abstract

Aptamers are short single-stranded RNA/DNA molecules that bind to specific target molecules. Aptamers with high binding-affinity and target specificity are identified using an in vitro procedure called high throughput systematic evolution of ligands by exponential enrichment (HT-SELEX). However, the development of aptamer affinity reagents takes a considerable amount of time and is costly because HT-SELEX produces a large dataset of candidate sequences, some of which have insufficient binding-affinity. Here, we present RNA aptamer Ranker (RaptRanker), a novel in silico method for identifying high binding-affinity aptamers from HT-SELEX data by scoring and ranking. RaptRanker analyzes HT-SELEX data by evaluating the nucleotide sequence and secondary structure simultaneously, and by ranking according to scores reflecting local structure and sequence frequencies. To evaluate the performance of RaptRanker, we performed two new HT-SELEX experiments, and evaluated binding affinities of a part of sequences that include aptamers with low binding-affinity. In both datasets, the performance of RaptRanker was superior to Frequency, Enrichment and MPBind. We also confirmed that the consideration of secondary structures is effective in HT-SELEX data analysis, and that RaptRanker successfully predicted the essential subsequence motifs in each identified sequence.

Topics & Concepts

BiologySystematic evolution of ligands by exponential enrichmentIn silicoAptamerSelection (genetic algorithm)Computational biologySequence (biology)RNABase sequenceSELEX Aptamer TechniqueGeneticsDNAGeneArtificial intelligenceComputer scienceAdvanced biosensing and bioanalysis techniquesBacteriophages and microbial interactionsRNA and protein synthesis mechanisms