During plant development, because no cell movement takes place, control of the timing and extent of cell division and coordination of the direction and extent of cell expansion are particularly important for growth and development. The plant hormone gibberellins (GAs) play key roles in the control of these developmental processes. However, little is known about the molecular components that integrate the generic GA signaling into a specific cell/tissue to coordinate cell division and cell expansion. Here we report that SCARECROW-LIKE 3 (SCL3), a GRAS protein, acts as a positive regulator to integrate and maintain a functional GA pathway by attenuating the DELLA repressors in the root endodermis. The tissue-specific maintenance of GA signaling in the root endodermis plays distinct roles along the longitudinal root axis. While in the elongation/differentiation zone (EDZ), the endodermis-confined GA pathway by SCL3 controls primarily coordination of root cell elongation; in the meristem zone (MZ) SCL3 in conjunction with the SHORT-ROOT/SCARECROW (SHR/SCR) pathway controls GA-modulated ground tissue maturation. Our findings highlight the regulatory network of the GRAS transcription regulators (SCL3, DELLAs, and SHR/SCR) in the root endodermis, shedding light on how GA homeostasis is achieved and how the maintenance of GA signaling controls developmental processes in roots.
Glycosyltransferases (GTs) play an important role in modulating solubility, stability, bioavailability, and bioactivity of secondary metabolites, such as flavonoids. In Arabidopsis thaliana, at least 120 family 1 uridine diphosphate (UDP)-glycosyltransferases (UGTs) have been predicted. However, little is known about their substrates or their physiological roles in planta. To define the role of UGT73B2 in planta, we first characterized its expression pattern using transgenic Arabidopsis plants carrying the ciselements of UGT73B2 fused to the GUS reporter. During vegetative phase, its expression was high in embryonic and postembryonic roots, where it may play a physiological role in the glycosylation of flavonoids. Loss of function of UGT73B2 alone or in conjunction with its closest homologs, UGT73B1 and UGT73B3, confers greater tolerance to oxidative stress, whereas overexpression of UGT73B2 increases sensitivity to oxidative stress. In addition, growth phenotypes of mutant and transgenic seedlings correlate well with ROS levels in planta. Our results suggest that the glycosylation of flavonoids by UGT73B2-and/or its closest homologs-modulate the response of plants to oxidative stress.
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