Functional diversification of miR172 isoforms in tomato under abiotic stress

Abstract

Plant gene families have expanded many folds as opposed to animals to compensate for being sessile as well as having unique features like ability to photosynthesise. While different protein families are well characterised in plants, similar knowledge on miRNA families is still in its infancy. The MIR172 family plays important role in various plant development processes including vegetative to reproductive phase change, floral patterning, nodulation, and fruit ripening as well as also in response to different environmental cues. However, in-depth analysis of this family in tomato (Solanum lycopersicum) is limited. In this study, we identified four new MIR172 loci (Sly-MIR172a1/a2/e/f) and two new isoforms, other than those reported at the miRBase repository. The MIR172 family has expanded by segmental duplication events and is conserved between the wild (S. pennellii and S. pimpinellifolium) and the cultivated tomato varieties. However, phylogenetic analysis showed that S. pennellii formed the most divergent member within each clade and S. pimpinellifolium is closer to the cultivated varieties. Additionally, investigations in 42 plant species highlighted that miR172a/b is the most abundant form in the plant kingdom. In addition to the classical target Apetala2 (AP2), degradome analysis identified SEC14p-like phosphatidylinositol transfer family protein (SEC14p) as a novel target of Sly-miR172 that was validated using precursor:effector and target:reporter transient assays. Further, we report dual mode of Sly-miR172-mediated silencing of targets Sly-AP2 and Sly-SEC14p by post-transcriptional transcript cleavage as well as translational repression. Different members of Sly-MIR172s:Sly-AP2s and Sly-MIR172s:Sly-SEC14p exhibit inverse expression correlation in response to different abiotic stresses, suggesting their role in stress response. Functional investigation of MIR172 showed that tomato plants performed better in different abiotic stresses (heat, drought, and salt) upon MIR172 overexpression or target knock-down by virus-induced-gene-silencing. Conversely, when miRNA is chelated using short-tandem-target-mimic, the plants exhibit sensitivity to these stresses. Thus, SlymiR172 acts as a positive regulator while its targets Sly-AP2a and Sly-SEC14p as negative regulators of different abiotic stresses.