LEADER 03922nam  2200925z- 450 
001 9910557296703321
005 20231214132949.0
035   $a(CKB)5400000000041072
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/69276
035   $a(EXLCZ)995400000000041072
100   $a20202105d2020      |y             0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aSeed Dormancy$eMolecular Control of Its Induction and Alleviation
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2020
215   $a1 electronic resource (124 p.)
311   $a3-03943-653-8 
311   $a3-03943-654-6 
330   $aThe appearance of the new generation in higher plants is ensured by the presence of viable seeds in the mother plant. A good number of signaling networks is necessary to provoke germination. Phytohormones play a key role in all stages of seed development, maturation, and dormancy acquisition. The dormancy of some seeds can be relieved through a tightly regulated process called after-ripening (AR) that occurs in viable seeds stored in a dry environment. Although ABA is directly involved in dormancy, recent data suggest that auxin also plays a preponderant role. On the other hand, the participation of reactive oxygen species (ROS) in the life of the seed is becoming increasingly confirmed. ROS accumulate at different stages of the seed?s life and are correlated with a low degree of dormancy. Thus, ROS increase upon AR and dormancy release. In the last decade, the advances in the knowledge of seed life have been noteworthy. In this Special Issue, those processes regulated by DOG1, auxin, and nucleic acid modifications are updated. Likewise, new data on the effect of alternating temperatures (AT) on dormancy release are here present. On the one hand, the transcriptome patterns stimulated at AT that encompasses ethylene and ROS signaling and metabolism together with ABA degradation were also discussed. Finally, it was also suggested that changes in endogenous ?-aminobutyric acid (GABA) may prevent seed germination.
517   $aSeed Dormancy 
606   $aResearch & information: general$2bicssc
606   $aBiology, life sciences$2bicssc
610   $achestnut
610   $aGABA
610   $aseed germination
610   $acarbon metabolism
610   $anitrogen metabolism
610   $aDOG1
610   $aseed dormancy
610   $aABA
610   $aethylene
610   $aclade-A PP2C phosphatase (AHG1
610   $aAHG3)
610   $aafter-ripening
610   $aasDOG1
610   $aheme-group
610   $aassociation mapping
610   $aclimate adaptation
610   $agermination
610   $agenomics
610   $alegumes
610   $aMedicago
610   $aplasticity
610   $aphysical dormancy
610   $aDNA methylation
610   $aoxidation
610   $aRNA stability
610   $aseed vigour
610   $aROS
610   $aprimary dormancy
610   $aABI3
610   $aauxin
610   $aYUC
610   $aPIN
610   $aARF
610   $aendosperm
610   $ainteguments
610   $aAGL62
610   $aPRC2
610   $aRNA-Seq
610   $adormancy termination
610   $agene expression
610   $aantioxidants
610   $aethylene signaling
610   $aenvironmental signals
610   $along-lived mRNA
610   $amonosomes
610   $aauxin and ABA
610   $aalternating temperatures
615  7$aResearch & information: general
615  7$aBiology, life sciences
700   $aMatilla$b Angel J$4edt$01329328
702   $aMatilla$b Angel J$4oth
906   $aBOOK
912   $a9910557296703321
996   $aSeed Dormancy$93039434
997   $aUNINA