Abstract
The development of biochemistry and molecular biology has revealed an increasingly important role of compounds in several biological processes. Like the aptamer-protein interaction, aptamer-compound interaction attracts increasing attention. However, it is time-consuming to select proper aptamers against compounds using traditional methods, such as exponential enrichment. Thus, there is an urgent need to design effective computational methods for searching effective aptamers against compounds. This study attempted to extract important features for aptamer-compound interactions using feature selection methods, such as Maximum Relevance Minimum Redundancy, as well as incremental feature selection. Each aptamer-compound pair was represented by properties derived from the aptamer and compound, including frequencies of single nucleotides and dinucleotides for the aptamer, as well as the constitutional, electrostatic, quantum-chemical, and space conformational descriptors of the compounds. As a result, some important features were obtained. To confirm the importance of the obtained features, we further discussed the associations between them and aptamer-compound interactions. Simultaneously, an optimal prediction model based on the nearest neighbor algorithm was built to identify aptamer-compound interactions, which has the potential to be a useful tool for the identification of novel aptamer-compound interactions. The program is available upon the request.
Highlights
Aptamers are defined as single-stranded nucleic acids or peptides that act like antibodies [1, 2]
For the MaxRel features list, we investigated the top 10% of features, which were important for the determination of aptamercompound interactions
An optimal prediction model based on a certain basic prediction engine can be built according to the Maximum Relevance Minimum Redundancy (mRMR) features list and the Incremental Feature Selection (IFS) method
Summary
Aptamers are defined as single-stranded nucleic acids or peptides that act like antibodies [1, 2]. These specific selective molecules can recognize and identify certain targets in the proper environment. Aptamers are widely artificially selected from a large random sequence pool; at the same time, natural aptamers always exist in the riboswitches [3]. Compared to antibodies, these artificial molecules have several advantages. Polymerase chain reaction makes it amazingly easy to attain quantities of target aptamers without a complex
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