Arabidopsis Type III Gγ Protein AGG3 Is a Positive Regulator of Yield and Stress Responses in the Model Monocot Setaria viridis

Jagdeep Kaur,Swarup Roy Choudhury,Sona Pandey,Laryssa Hovis,Anitha Vijayakumar,Dylan Blumenthal,Zach Rhodes,Rob Polzin

doi:10.3389/fpls.2018.00109

Jagdeep Kaur, Swarup Roy Choudhury + Show 6 more

Open Access

https://doi.org/10.3389/fpls.2018.00109

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Abstract

Heterotrimeric G-proteins are key regulators of a multitude of growth and development pathways in eukaryotes. Along with the conserved G-protein components found in all organisms, plants have certain novel variants with unique architecture, which may be involved in the regulation of plant-specific traits. The higher plant-specific type III (or Class C) Gγ protein, which possesses a large C terminal extension, represented by AGG3 in Arabidopsis, is one such variant of canonical Gγ proteins. The type III Gγ proteins are involved in regulation of many agronomically important traits in plants, including seed yield, organ size regulation, abscisic acid (ABA)-dependent signaling and stress responses, and nitrogen use efficiency. However, the extant data, especially in the monocots, present a relatively complex and sometimes contradictory picture of the regulatory role of these proteins. It remains unclear if the positive traits observed in certain naturally occurring populations are due to the presence of specific allelic variants of the proteins or due to the altered expression of the gene itself. To address these possibilities, we have overexpressed the Arabidopsis AGG3 gene in the model monocot Setaria viridis and systematically evaluated its role in conferring agriculturally relevant phenotypes. Our data show that AtAGG3 is indeed functional in Setaria and suggest that a subset of the traits affected by the type III Gγ proteins are indeed positively correlated with the gene expression level, while others might have more complex, allele specific regulation.

Highlights

Food security has become an imminent challenge especially with the ever increasing human population on the planet and is thought to be worse than it was 20 years ago (Alexandratos, 1999)
The homologs of type III Gγ genes are present in all higher plants
Using Arabidopsis AGG3 and rice DEP1 and GS3 as query sequences we identified three type III Gγ genes Sevir.6G177400.1, Sevir.2G229300.1 and Sevir.9G375000.1 referred as SvGG3a, SvGG3b and SvGG3c, respectively, in the Setaria viridis genome (Supplementary Table S1)

Summary

Introduction

Food security has become an imminent challenge especially with the ever increasing human population on the planet and is thought to be worse than it was 20 years ago (Alexandratos, 1999). The population of the planet is projected to increase by almost 50% within the 35 years. With the drastic increase in population, food production must increase. Without appropriate solutions the need for increased land for crops could irreversibly change terrestrial and aquatic environments (Tilman et al, 2002). Identification of specific genes/targets that confer increased yield potential in non-optimal environment and elucidation of their mode of action is, AGG3 Regulated Responses in Setaria central to our future needs. The type III Gγ proteins of the heterotrimeric G-protein complex are fast emerging as one such agronomically important target (Botella, 2012)

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