Low temperature-mediated repression and far-red light-mediated induction determine morning FLOWERING LOCUS T expression levels

Arabidopsis RGLG1/2 regulate flowering time under different soil moisture conditions by affecting the protein stability of TOE1/2

Drought constitutes a significant environmental factor influencing the growth and development of plants. Consequently, terrestrial plants have evolved a range of strategies to mitigate the adverse effects of soil water deficit. One such strategy, known as drought escape, involves the acceleration of flowering under drought, thereby enabling plants to complete their life cycle rapidly. However, the molecular mechanisms underlying this adaptive response remain largely unclear. Using genetic, molecular, and biochemical techniques, we demonstrated that the AP2 family proteins TARGET OF EAT 1/2 (TOE1/2) are essential for the drought escape response in Arabidopsis, with a significant reduction in their protein stability observed during this process. Our findings indicate that the RING-type E3 ubiquitin ligases RING DOMAIN LIGASE 1/2 (RGLG1/2) interact with TOE1/2 and facilitate their degradation within the nucleus. Under water deficit conditions, there is increased expression of RGLG1/2, and their protein products translocate to the nucleus to ubiquitinate and degrade TOE1/2, thereby enhancing the drought escape response. Furthermore, the loss of TOE1/2 in drought conditions directly results in a reduction of drought resistance in plants, suggesting that drought escape is a high-risk behaviour for plants and that the RGLG1/2-TOE1/2 signalling cascade may serve as a central regulatory mechanism governing the trade-off between drought escape and drought tolerance in plants.

OfWRKY17-OfC3H49 module responding to high ambient temperature delays flowering via inhibiting OfSOC1B expression in Osmanthus fragrans

Ambient temperature is a pivotal factor in the regulation of the flowering process in plants. In this study, we found that high ambient temperature exerts an inhibitory effect on the flowering of Osmanthus fragrans "Sjigui". However, the underlying molecular mechanisms remain not fully understood. Through transcriptome analysis, a differently expressed C3H gene OfC3H49 was identified, which is induced by high ambient temperature. OfC3H49 was demonstrated to delay the flowering process of Arabidopsis and downregulate the expression of flowering-related genes in O. fragrans calli. Further investigation indicates that OfC3H49 as a transcriptional repressor directly suppresses the expression of the OfSOC1B thereby causing a delay in flowering time. Furthermore, a WRKY transcription factor, OfWRKY17, was identified to be responsive to high ambient temperature, directly binding to the OfC3H49 promoter and enhance OfC3H49 expression. Overexpression of OfWRKY17 in Arabidopsis resulted in a significant delay in flowering and induced the expression of OfC3H49 in O. fragrans calli. Collectively, our findings delineate a regulatory module, OfWRKY17-OfC3H49, which is activated by high ambient temperature and functions as a negative regulator of flowering by suppressing the expression of OfSOC1B in O. fragrans. This study provides novel insights into the molecular mechanisms involved in ambient temperature-mediated flowering control and contributes to the development of molecular breeding strategies for O. fragrans.

Disrupting FKF1 homodimerization increases FT transcript levels in the evening by enhancing CO stabilization

KEY MESSAGE

FKF1 dimerization is crucial for proper FT levels to fine-tune flowering time. Attenuating FKF1 homodimerization increased CO abundance by enhancing its COP1 binding, thereby accelerating flowering under long days. In Arabidopsis (Arabidopsis thaliana), the blue-light photoreceptor FKF1 (FLAVIN-BINDING, KELCH REPEAT, F-BOX 1) plays a key role in inducing the expression of FLOWERING LOCUS T (FT), encoding the main florigenic signal in plants, in the late afternoon under long-day conditions (LDs) by forming dimers with FT regulators. Although structural studies have unveiled a variant of FKF1 (FKF1 I160R) that disrupts homodimer formation in vitro, the mechanism by which disrupted FKF1 homodimer formation regulates flowering time remains elusive. In this study, we determined that the attenuation of FKF1 homodimer formation enhances FT expression in the evening by promoting the increased stability of CONSTANS (CO), a primary activator of FT, in the afternoon, thereby contributing to early flowering. In contrast to wild-type FKF1, introducing the FKF1 I160R variant into the fkf1 mutant led to increased FT expression under LDs. In addition, the FKF1 I160R variant exhibited diminished dimerization with FKF1, while its interaction with GIGANTEA (GI), a modulator of FKF1 function, was enhanced under LDs. Furthermore, the FKF1 I160R variant increased the level of CO in the afternoon under LDs by enhancing its binding to COP1, an E3 ubiquitin ligase responsible for CO degradation. These findings suggest that the regulation of FKF1 homodimerization and heterodimerization allows plants to finely adjust FT expression levels around dusk by modulating its interactions with GI and COP1.