Metabolic and physiological responses to progressive drought stress in bread wheat.
Abscisic Acid
/ metabolism
Acclimatization
/ physiology
Adaptation, Physiological
/ physiology
Biomarkers
/ metabolism
Bread
Droughts
Metabolome
/ physiology
Nitrogen
/ metabolism
Plant Breeding
/ methods
Reactive Oxygen Species
/ metabolism
Soil
Stress, Physiological
/ physiology
Triticum
/ metabolism
Water
/ metabolism
Journal
Scientific reports
ISSN: 2045-2322
Titre abrégé: Sci Rep
Pays: England
ID NLM: 101563288
Informations de publication
Date de publication:
14 10 2020
14 10 2020
Historique:
received:
11
12
2019
accepted:
22
09
2020
entrez:
15
10
2020
pubmed:
16
10
2020
medline:
15
1
2021
Statut:
epublish
Résumé
Wheat (Tritium aestivum) is vulnerable to future climate change because it is predominantly grown under rain-fed conditions in drought-prone areas. Thus, in-depth understanding of drought effect on wheat metabolism is essential for developing drought-tolerant wheat varieties. Here, we exposed wheat 'Norin 61' plants to progressive drought stress [0 (before drought), 2, 4, 6, 8, and 10 days after withholding water] during the flowering stage to investigate physiological and metabolomic responses. Transcriptional analyses of key abscisic acid-responsive genes indicated that abscisic acid signalling played a major role in the adaptation of wheat to water deficit. Carbon isotope composition had a higher value than the control while canopy temperature (CT) increased under drought stress. The CT depression was tightly correlated with soil water potential (SWP). Additionally, SWP at - 517 kPa was identified as the critical point for increasing CT and inducing reactive oxygen species. Metabolome analysis identified four potential drought-responsive biomarkers, the enhancement of nitrogen recycling through purine and pyrimidine metabolism, drought-induced senescence based on 1-aminocyclopropane-1-carboxylic acid and Asn accumulation, and an anti-senescence response through serotonin accumulation under severe drought stress. Our findings provide in-depth insight into molecular, physiological and metabolite changes involved in drought response which are useful for wheat breeding programs to develop drought-tolerant wheat varieties.
Identifiants
pubmed: 33057205
doi: 10.1038/s41598-020-74303-6
pii: 10.1038/s41598-020-74303-6
pmc: PMC7560863
doi:
Substances chimiques
Biomarkers
0
Reactive Oxygen Species
0
Soil
0
Water
059QF0KO0R
Abscisic Acid
72S9A8J5GW
Nitrogen
N762921K75
Types de publication
Journal Article
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Pagination
17189Références
J Plant Physiol. 2006 Oct;163(10):1061-70
pubmed: 16368161
Mol Plant. 2012 Mar;5(2):418-29
pubmed: 22207720
Proc Natl Acad Sci U S A. 2017 Aug 29;114(35):9326-9331
pubmed: 28811375
J Exp Bot. 2020 Jan 7;71(2):543-554
pubmed: 31232445
Plant Physiol. 1985 Sep;79(1):24-7
pubmed: 16664378
Trends Plant Sci. 2010 Feb;15(2):89-97
pubmed: 20036181
Nat Plants. 2019 Feb;5(2):153-159
pubmed: 30737511
Science. 2010 Feb 12;327(5967):812-8
pubmed: 20110467
Trends Plant Sci. 2004 Mar;9(3):110-5
pubmed: 15003233
J Exp Bot. 2007;58(12):3309-21
pubmed: 17804429
Plant Physiol. 2000 Mar;122(3):907-14
pubmed: 10712555
Int J Mol Sci. 2013 Mar 01;14(3):4885-911
pubmed: 23455464
Planta. 2017 Oct;246(4):737-747
pubmed: 28668976
J Agric Food Chem. 2015 Sep 23;63(37):8125-33
pubmed: 26330002
J Exp Bot. 2017 Mar 1;68(7):1697-1713
pubmed: 28338908
Plant Physiol. 2004 Feb;134(2):838-48
pubmed: 14764908
Plant J. 2002 Jun;30(5):601-9
pubmed: 12047634
J Exp Bot. 2019 Sep 24;70(18):4931-4948
pubmed: 31189018
Annu Rev Plant Biol. 2010;61:651-79
pubmed: 20192755
Plant Physiol. 2017 Jul;174(3):1747-1763
pubmed: 28500268
J Exp Bot. 2016 Apr;67(8):2519-2532
pubmed: 26931169
Plant Biotechnol J. 2012 Sep;10(7):826-39
pubmed: 22594629
Plant Biotechnol J. 2008 Apr;6(3):281-94
pubmed: 18086232
Amino Acids. 2008 Nov;35(4):753-9
pubmed: 18379856
J Sci Food Agric. 2010 Jul;90(9):1410-6
pubmed: 20549790
J Chem Inf Model. 2013 Jul 22;53(7):1689-99
pubmed: 23800267
Plants (Basel). 2017 May 25;6(2):
pubmed: 28587097
Cell Mol Life Sci. 2012 Oct;69(19):3225-43
pubmed: 22885821
PLoS One. 2019 Mar 11;14(3):e0213502
pubmed: 30856235
Theor Appl Genet. 2018 Aug;131(8):1615-1626
pubmed: 29705916
Front Plant Sci. 2014 Nov 11;5:640
pubmed: 25426135
Plant Cell Environ. 2015 Oct;38(10):2171-92
pubmed: 25828772
J Exp Bot. 2012 Aug;63(13):4671-712
pubmed: 22922637
Science. 2008 Apr 11;320(5873):171-3
pubmed: 18403686
Plant J. 2009 Mar;57(6):1065-78
pubmed: 19036030
Proc Natl Acad Sci U S A. 2017 Feb 7;114(6):E913-E921
pubmed: 28096351
Sci Rep. 2017 Jan 11;7:40641
pubmed: 28074873
Sci Rep. 2018 Apr 9;8(1):5710
pubmed: 29632386
J Exp Bot. 2013 Nov;64(14):4491-502
pubmed: 24078671
Plant Physiol. 2018 Sep;178(1):441-450
pubmed: 30037808
Genetics. 2005 May;170(1):61-70
pubmed: 15744050
Plant J. 1997 Sep;12(3):557-69
pubmed: 9351242
Science. 1982 Oct 29;218(4571):443-8
pubmed: 17808529
Mol Plant. 2010 Jan;3(1):2-20
pubmed: 20035037
J Exp Bot. 2018 Feb 12;69(4):845-853
pubmed: 28992323
Plant Cell Environ. 2012 Jan;35(1):136-49
pubmed: 21902697
Plant Cell Environ. 2016 Apr;39(4):787-803
pubmed: 26436679
Plant Cell Environ. 2014 Apr;37(4):1022-36
pubmed: 24182190