Publication Date:
2022-01-31
Description:
We are currently experiencing a climate crisis that is associated with extreme weather events worldwide. Some of its most noticeable effects are increases in temperatures, droughts, and desertification. These effects are already making whole regions unsuitable for agriculture. Therefore, we urgently need global measures to mitigate the effects of climate breakdown as well as crop alternatives that are more stress-resilient. These crop alternatives can come from breeding new varieties of well-established crops, such as wheat and barley. They can also come from promoting underutilized crop species that are naturally tolerant to some stresses, such as quinoa. Either way, we need to gather more knowledge on how plants respond to stresses related to climate breakdown, such as heat, water-deficit, flooding high salinity, nitrogen, and heavy metal stress. This Special Issue provides a timely collection of recent advances in the understanding of plant responses to these stresses. This information will definitely be useful to the design of new strategies to prevent the loss of more cultivable land and to reclaim the land that has already been declared unsuitable.
Keywords:
SB1-1110
;
QH301-705.5
;
Q1-390
;
ZIP
;
landraces
;
orphan crop
;
morphological characteristics
;
De novo transcriptome
;
lateral root
;
abiotic stress
;
heat stress
;
transcriptome sequencing
;
photosynthesis
;
hyperaccumulation
;
HSP70
;
photoprotection
;
IREG
;
photosystem I
;
quinoa
;
plant cell cultures
;
water stress
;
high temperatures
;
tobacco BY-2
;
serpentine
;
heat
;
chaperons
;
waterlogging
;
water deficit
;
photoinhibition
;
selenium
;
wheat
;
Vigna vexillata
;
mechanism
;
grain protein content
;
salinity
;
nickel
;
poaceae
;
genome-wide association mapping
;
nickel hyper-accumulation
;
cell death
;
mediterranean area
;
ferroportin
;
high salinity stress
;
low nitrogen stress
;
legume
;
drought
;
RNA-Seq
;
histidine
Language:
English
Format:
application/octet-stream
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