A shorter inverted repeat length in a hairpin RNA results in a stronger silencing efficacy

Abstract

RNA interference (RNAi), particularly hairpin RNA (hpRNA) constructs, is a potent genetic manipulation tool, influencing traits that are crucial for crop improvement. Typical hpRNA constructs consist of inverted repeat sequences derived from the mRNA of the target gene, separated by a non-complementary spacer. This configuration initiates the formation of a double-stranded RNA structure due to the complementary nature of sense and antisense sequences in the transcribed RNA. In this research, two hpRNA constructs, namely hp-TFL1-S and hp-TFL1-L, with distinct lengths of inverted repeats, were designed to target TFL1, a pivotal regulator of both flowering timing and inflorescence structure. hp-TFL1-L construct encompasses all the 150 nucleotide sequences of the hp-TFL1-S construct and an extra 135 nucleotides. These constructs included a chalcone synthase intron as a spacer, resulting in hairpin double-stranded RNA molecules of 150 and 285 base pair after transcription. The PCR and qRT-PCR analysis results confirmed the accurate design of both constructs and their successful suppression of TFL1 mRNA expression in transgenic Arabidopsis. Interestingly, Arabidopsis lines carrying hp-TFL1-S and hp-TFL1-L exhibited distinct phenotypic features. hp-TFL1-S induced more pronounced phenotypic changes, resulting in earlier flowering compared to the hp-TFL1-L and control group. Moreover, hp-TFL1-S had a significant impact on inflorescence architecture, distinguishing it from both hp-TFL1-L and control plants. This study provides an example where inverted repeat length alters the efficacy of silencing, and in this case, surprisingly the shorter construct appears to have a stronger silencing efficacy. This argues multiple sized hpRNAs should be tested in RNAi-based gene silencing experiments.