Genome-wide analysis of microRNA targeting impacted by SNPs in cucumber genome

Abstract

Background: microRNAs (miRNAs) are endogenous small RNAs that play important regulatory functions in plant development. Genetic variations in miRNAs sequences or their target-binding sites (microRNA-target interaction sites) can alter miRNA targets in animal and human. Whether these single nucleotide polymorphisms (SNPs) in plant are functional have not yet been determined. Results: In this study, we constructed leaf, root, and stem-derived small libraries of cucumber (Cucumis sativus) line 9930 (cultivated China-group cucumber) and C. sativus var. hardwickii (wild India group cucumber). A total of 22 conserved miRNA families, nine less-conserved miRNA families, and 49 cucumber-specific miRNAs were identified in both line 9930 and hardwickii. We employed cucumber resequencing data to perform a genome-wide scan for SNPs in cucumber miRNA-target interaction sites, including miRNA mature sequences and miRNA-target binding sites. As a result, we identified a total of 19 SNPs in mature miRNA sequences and 113 SNPs in miRNA-target binding sites with the potential to affect miRNA-target interactions. Furthermore, we experimentally confirmed that these SNPs produced 14 9930-unique targets mRNAs and 15 hardwickii-unique targets mRNA for cucumber miRNAs. This is the first experimental validation of SNPs in miRNA-target interaction sites affecting miRNA-target binding in plants. Conclusions: Our results indicate that SNPs can alter miRNA function and produce unique miRNA targets in cultivated and wild cucumbers. Therefore, miRNA-related SNPs may have played important in events that led to the agronomic differences between domestic and wild cucumber.