Soybean (Glycine max), a significant oilseed and protein source for humans and livestock feed, needs short day photoperiod for floral induction. Further, soybean has a paleopolyploid genome with multiple copies of flowering genes adding to the complexity of genetic regulation of flowering, and seed set, especially in investigating the role of the noncoding genome. microRNAs, a class of noncoding RNA, play a regulatory role in plant development. miR156 and miR172 are major components of the essential regulatory hub controlling juvenile and vegetative developments and initiation of reproductive phase change leading to flowering. These microRNAs have been originally isolated and studied from model plant, Arabidopsis. However, a study on soybean microRNAs is lacking. We investigated the temporal expression patterns of gma-miR156a and gma-miR172a and found inversely related - gma-miR156a expression was higher in the vegetative stage, and gma-miR172a expression was elevated under inductive flowering conditions. The functions of gma-miR156a and gma-miR172a were evaluated via heterologous expressions in transgenic tobacco plants (Nicotiana tabacum L.). The analysis of overexpression transgenic lines highlighted that gma-miR156a plays a role in juvenile development via repression of the SPL transcription factor family. In contrast, gma-miR172a plays a pivotal role in the reproductive development phase by down-regulating its target genes, AP2. In addition, ectopic expression of gma-miR156a and gma-miR172a affected plant morphology and physiology during plant growth. Collectively, our results suggest that gma-miR156a and gma-miR172a regulate multiple morpho-physiological traits that could be used to enhance crop yield under changing climate conditions.
Keywords: Floral transition; Legume; Soybean; microRNAs.
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