Profiling of the Salt Stress Responsive MicroRNA Landscape of C4 Genetic Model Species Setaria viridis (L.) Beauv

Joseph L Pegler,Andrew L Eamens,Duc Quan Nguyen,Christopher P.L Grof

doi:10.3390/agronomy10060837

Joseph L Pegler, Andrew L Eamens + Show 2 more

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https://doi.org/10.3390/agronomy10060837

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Journal: Agronomy	Publication Date: Jun 12, 2020
Citations: 12	License type: CC BY 4.0

Affiliation: University of Newcastle Australia

Abstract

Setaria viridis has recently emerged as an ideal model species to genetically characterize the C4 monocotyledonous grasses via a molecular modification approach. Soil salinization has become a compelling agricultural problem globally with salinity adversely impacting the yield potential of many of the major cereals. Small regulatory molecules of RNA, termed microRNAs (miRNAs), were originally demonstrated crucial for developmental gene expression regulation in plants, however, miRNAs have since been shown to additionally command a central regulatory role in abiotic stress adaptation. Therefore, a small RNA sequencing approach was employed to profile the salt stress responsive miRNA landscapes of the shoot and root tissues of two Setaria viridis accessions (A10 and ME034V) amenable to molecular modification. Small RNA sequencing-identified abundance alterations for miRNAs, miR169, miR395, miR396, miR397, miR398 and miR408, were experimentally validated via RT-qPCR. RT-qPCR was further applied to profile the molecular response of the miR160 and miR167 regulatory modules to salt stress. This analysis revealed accession- and tissue-specific responses for the miR160 and miR167 regulatory modules in A10 and ME034V shoot and root tissues exposed to salt stress. The findings reported here form the first crucial step in the identification of the miRNA regulatory modules to target for molecular manipulation to determine if such modification provides S. viridis with an improved tolerance to salt stress.

Highlights

The global population continues to increase, and with this has come intensive urbanization and the greatly accelerated consumption of fossil fuels
Setaria viridis (L.) Beauv. accessions, A10 and ME034V, were used for all experimental work performed in this study due to both of these S. viridis accessions having been previously demonstrated to be amenable to Agrobacterium-mediated transformation [42,43,44,45,70]
While ME034V seedlings formed an equivalent number of lateral roots off the primary root as observed for the A10 accession, the lateral roots that formed proximal to the germinated seed of ME034V seedlings appeared to be more elongated (Figure 1E) than the lateral roots that emerged from the corresponding section of the primary root of control grown 10-day-old A10 seedlings (Figure 1B)

Summary

Introduction

The global population continues to increase, and with this has come intensive urbanization and the greatly accelerated consumption of fossil fuels. The environmental issues associated with anthropogenically driven climate change, including altered precipitation patterns leading to drought and flood events, as well as soil salinity and nutrient imbalances and heat and cold stresses, have all increased in frequency, duration and severity of impact. Together, these changes have adversely affected the global crop yield [1,5,6].

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