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Temperature Stress and Redox Homeostasis: The Synergistic Network of Redox and Chaperone System in Response to Stress in Plants

  • Hui-Chen WuEmail author
  • Florence Vignols
  • Tsung-Luo JinnEmail author
Chapter
Part of the Heat Shock Proteins book series (HESP, volume 17)

Abstract

A remarkable number of strategies has been developed by living organisms to mitigate conflict with environmental changes. The global environment rising with ambient temperature has a wide range of effects on plant growth, and therefore activation of various molecular defenses before the appearance of heat damage. Evidence revealed key components of stress that trigger enhanced tolerance, and some determinants for plant tolerance have been identified. The interplay between heat shock proteins (HSP) and redox proteins is supposed to be vital for the survival under extreme stress conditions. Any circumstance in which cellular redox homeostasis is disrupted can lead to the generation of reactive oxygen species (ROS) that are continuously generated in cells as an unavoidable consequence of aerobic life. Integrative network analysis of synthetic genetic interactions, protein-protein interactions, and functional annotations revealed many new functional processes linked to heat stress (HS) and oxidative stress (OS) tolerance, implicated upstream regulators activated by the either HS or OS, and revealed new connections between them. We present different models of acquired stress resistance to interpret the condition-specific involvement of genes. Considering the basic concepts and the recent advances, the following subsections provide an overview of calcium ion (Ca2+) and ROS interplay in abiotic signaling pathways; further we introduce several examples of chaperone and redox proteins that respond the change of cellular redox status under environmental circumstances. Thus, the involvement or contribution of redox proteins through the functional switching in conjunction with the HSP that prevent heat- and oxidative-induced protein aggregation in plants.

Keywords

Calcium ion Chaperone Heat shock proteins Heat stress Oxidative stress Reactive oxygen species Redox proteins 

Abbreviations

ABA

abscisic acid

AOX

alternative oxidase

AsA

ascorbic acid

APX

ascorbate peroxidase

Ca2+

calcium ion

CaM

calmodulin

CML

CaM-like protein

CAT

catalase

Cys

cysteine

GRX

glutaredoxin

GR

glutathione reductase

GSH

glutathione

GST1

glutathione-S-transferase 1

GPX

glutathione peroxidase

HIP

Hsp70-interacting protein

HS

heat stress

HSE

heat shock element

HSG

heat shock granule

HSP

heat shock protein

HSF

heat shock transcription factor

HSR

heat shock response

H2O2

hydrogen peroxide

OH.

hydroxyl radical

HMW

high molecular weight

LMW

low molecular weight

NTR

NADPH-dependent TrxR

NO

nitric oxide

OS

oxidative stress

PDI

protein disulfide isomerase

PRX

peroxiredoxin

RBOH

respiratory burst oxidase homolog

ROS

reactive oxygen species

1O2

singlet oxygen

O2·-

superoxide anion

SOD

superoxide dismutase

TRX

thioredoxin

TrxR

thioredoxin reductases

TPR

tetratricopeptide repeat

RNR

ribonucleotide reductase

Notes

Acknowledgements

We thank Lynne Stracovsky for English editing. This work was supported by the National Taiwan University (grant nos. 101R892003-105R892003 and 106R891506) and by the Ministry of Science and Technology, Taiwan (grant nos. 105-2311-B-002-033-MY3 and 107-2923-B-002-003-MY3) to T.L.J. and (grant no. 105-2311-B-024-001) to H.C.W.

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© Springer Nature Switzerland AG 2019

Authors and Affiliations

  1. 1.Department of Biological Sciences and TechnologyNational University of TainanTainanTaiwan
  2. 2.BPMP, CNRS, INRA, Montpellier SupAgroUniv MontpellierMontpellierFrance
  3. 3.Department of Life Science and Institute of Plant BiologyNational Taiwan UniversityTaipeiTaiwan

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