ABSCISIC ACID-DEFICIENT4 Has an Essential Function in Both cis-Violaxanthin and cis-Neoxanthin Synthesis

International audienceAbscisic acid (ABA), a plant hormone synthesized from carotenoids, functions in seed germination and abiotic stress responses. ABA is derived from the cleavage of 9-cis-isomers of violaxanthin and neoxanthin, which are oxygenated carotenoids, also called xanthophylls. Although genes encoding enzymes responsible for most steps of the ABA biosynthesis pathway have been identified, enzymatic reactions leading to the production of these cis-isomers from trans-violaxanthin remain poorly understood. Two mutants that lack trans- and cis-neoxanthin, tomato (Solanum lycopersicum) neoxanthin-deficient1 (nxd1) and Arabidopsis (Arabidopsis thaliana) ABA-deficient4 (aba4), were identified previously, but only aba4 exhibited ABA-deficient phenotypes. No enzymatic activity was detected for ABA4 and NXD1 proteins, and their exact function remained unknown. To further investigate ABA4 and NXD1 function in Arabidopsis, we compared phenotypes of single and double mutants, and analyzed the effect of ABA4 overexpression on ABA and carotenoid accumulation in wild-type and mutant backgrounds. We provide convergent evidence that ABA4 is not only required for the formation of trans- and 9 '-cis-neoxanthin from trans-violaxanthin, but also controls 9-cis-violaxanthin accumulation. While nxd1 produces high amounts of 9-cis-violaxanthin and ABA, aba4 nxd1 exhibits reduced levels in both leaves and seeds. Furthermore, ABA4 constitutive expression in nxd1 increases both 9-cis-violaxanthin and ABA accumulation. Subcellular localization of NXD1 protein in transient expression assays suggests that production of the NXD1-derived factor required for neoxanthin synthesis takes place in the cytosol. Finally, we postulate that ABA4, with additional unknown cofactor(s), is required for, or contributes to, trans-to-cis violaxanthin isomerase activity, producing both cis-xanthophyll precursors of ABA

Deciphering the molecular mechanisms underpinning the transcriptional control of gene expression by L-AFL proteins in Arabidopsis seed.

International audienceIn Arabidopsis (Arabidopsis thaliana), transcriptional control of seed maturation involves three related regulators with a B3domain, namely LEAFY COTYLEDON2 (LEC2), ABSCISIC ACID INSENSITIVE3 (ABI3), and FUSCA3 (ABI3/FUS3/LEC2[AFLs]). Although genetic analyses have demonstrated partially overlapping functions of these regulators, the underlyingmolecular mechanisms remained elusive. The results presented here confirmed that the three proteins bind RY DNA elements(with a 59-CATG-39 core sequence) but with different specificities for flanking nucleotides. In planta as in the moss Physcomitrellapatens protoplasts, the presence of RY-like (RYL) elements is necessary but not sufficient for the regulation of the OLEOSIN1 (OLE1)promoter by the B3AFLs. G box-like domains, located in the vicinity of the RYL elements, also are required for proper activation ofthe promoter, suggesting that several proteins are involved. Consistentwith this idea, LEC2 andABI3 showed synergistic effects onthe activation of the OLE1 promoter. What is more, LEC1 (a homolog of the NF-YB subunit of the CCAAT-binding complex)further enhanced the activation of this target promoter in the presence of LEC2 and ABI3. Finally, recombinant LEC1 and LEC2proteins produced in Arabidopsis protoplasts could form a ternary complex with NF-YC2 in vitro, providing a molecular explanationfor their functional interactions. Taken together, these results allow us to propose a molecularmodel for the transcriptional regulationof seed genes by the L-AFL proteins, based on the formation of regulatory multiprotein complexes between NF-YBs, which carry aspecific aspartate-55 residue, and B3 transcription factors