Stratification overcomes ABA-mediated seed dormancy by uncoupling RGL2/ABI5 inhibition from α-amylase expression

Yuan Tian; Qin-Lai Liu; Mo-Xian Chen; Ying-Gao Liu

doi:10.1007/s44154-026-00312-6

Stress Biology ›› 2026, Vol. 6 ›› Issue (1) :43 DOI: 10.1007/s44154-026-00312-6

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Stratification overcomes ABA-mediated seed dormancy by uncoupling RGL2/ABI5 inhibition from α-amylase expression

Yuan Tian ¹
, Qin-Lai Liu ⁴
, Mo-Xian Chen ¹^,³^,^a
, Ying-Gao Liu ¹^,²^,^b

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Abstract

Cold-pretreatment (stratification) is widely employed to overcome seed dormancy and enhance germination, however, its underlying molecular mechanisms remain elusive. We tested the hypothesis that stratification alleviates the repression of α-amylase expression, a critical step for endosperm starch mobilization during germination. Stratification at 4 °C effectively overcame dormancy in wild-type Arabidopsis thaliana, the ABA-catabolism mutant cyp707a2, the GA-insensitive mutant sleepy1, and the cyp707a2 sleepy1 double mutant, but failed to rescue the dormancy phenotype of the GA-biosynthesis mutant ga3ox1. Moreover, stratification markedly promoted starch hydrolysis by increasing both the transcript abundance and the enzymatic activity of α-amylase in freshly harvested seeds of wild-type and in those mutants exhibiting elevated endogenous ABA or treated with exogenous ABA. Concomitantly, stratification substantially suppressed the expression of RGL2, a DELLA protein that represses GA signaling, and ABI5, a key ABA-responsive transcription factor. Collectively, our data indicates that stratification initiates GA biosynthesis, thereby relieving RGL2-mediated repression of α-amylase expression. Secondly, stratification mitigates ABA-imposed inhibition of germination without alleviating the suppressive effect of ABA on post-germinative seedling development.

Keywords

Stratification / Abscisic Acid (ABA) / Gibberellins (GA) / Seed dormancy / RGL2 / SLEEPY1 / CYP707A2 / α-amylase

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Yuan Tian, Qin-Lai Liu, Mo-Xian Chen, Ying-Gao Liu. Stratification overcomes ABA-mediated seed dormancy by uncoupling RGL2/ABI5 inhibition from α-amylase expression. Stress Biology, 2026, 6 (1) : 43 DOI:10.1007/s44154-026-00312-6

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