The Role of Triacylglycerol in Plant Stress Response.

Junhao Lu,Guanqun Chen,Stacy D Singer,Juli Wang,Yang Xu

doi:10.3390/plants9040472

Abstract

Vegetable oil is mainly composed of triacylglycerol (TAG), a storage lipid that serves as a major commodity for food and industrial purposes, as well as an alternative biofuel source. While TAG is typically not produced at significant levels in vegetative tissues, emerging evidence suggests that its accumulation in such tissues may provide one mechanism by which plants cope with abiotic stress. Different types of abiotic stress induce lipid remodeling through the action of specific lipases, which results in various alterations in membrane lipid composition. This response induces the formation of toxic lipid intermediates that cause membrane damage or cell death. However, increased levels of TAG under stress conditions are believed to function, at least in part, as a means of sequestering these toxic lipid intermediates. Moreover, the lipid droplets (LDs) in which TAG is enclosed also function as a subcellular factory to provide binding sites and substrates for the biosynthesis of bioactive compounds that protect against insects and fungi. Though our knowledge concerning the role of TAG in stress tolerance is expanding, many gaps in our understanding of the mechanisms driving these processes are still evident. In this review, we highlight progress that has been made to decipher the role of TAG in plant stress response, and we discuss possible ways in which this information could be utilized to improve crops in the future.

Highlights

The growth of the global population, along with escalating per capita calorific consumption and need for plant-derived renewable resources, is leading to increased demand for crop products [1].crop yields are negatively impacted by abiotic stresses such as heat, cold, drought, and salinity—the severity and frequency of which are increasing due to climate change [2,3].The growing prevalence of abiotic challenges increases the susceptibility of plants to biotic stresses such as pathogens and insects [4], which can further exacerbate crop yield losses
Plants have evolved various molecular, metabolic, and physiological adaptations that aid in their ability to cope with a wide range of stresses [5], and while our knowledge surrounding these processes is expanding at a rapid pace, large gaps remain in our understanding
We examine our current understanding of TAG metabolism in vegetative tissues, as well as recent progress that has been made towards elucidating the role of vegetative TAG

Summary

Introduction

The growth of the global population, along with escalating per capita calorific consumption and need for plant-derived renewable resources, is leading to increased demand for crop products [1]. Due to the substantial negative effect abiotic and biotic stresses can have on yield, it is essential that stress response mechanisms are further elucidated. Such knowledge will almost certainly be requisite for the enhancement of stress tolerance, and, the maintenance or increase of crop yield, under a future of climate change. TAG is mainly stored as a high-energy storage compound within lipid droplets (LDs) in seeds or fruits [6]. Vegetative tissues such as leaves and Plants 2020, 9, 472; doi:10.3390/plants9040472 www.mdpi.com/journal/plants. We discuss the potential of modulating TAG metabolism as a means of increasing the resiliency of crop species to environmental challenges

Triacylglycerol Biosynthesis

Triacylglycerol Storage

Induction of TAG Accumulation under Stress Conditions

Role of TAG in Stress Response by Sequestering Toxic Lipid Intermediates

Role of Cytosolic Lipid Droplets in Stress Response

Closing Comments