Plants have developed intricate mechanisms to adapt to fluctuating nitrogen availability in the soil, including modulation of anthocyanin biosynthesis. However, the regulation mechanism of lateral organ boundary domain (LBD) transcription factors on anthocyanin biosynthesis under low nitrogen conditions remains poorly understood. Here, we functionally characterized PsLBD42 from Populus simonii, a class II LBD transcription factor, which was upregulated under low nitrogen conditions. PsLBD42-overexpression transgenic poplar exhibited enhanced resistance to the low nitrogen stress with increased photosynthetic rates and decreased photooxidation, but unchanged nitrogen content and uptake capability. Meanwhile, the accumulation of anthocyanin related with photooxidation was significantly increased in the leaves of PsLBD42-overexpression transgenic poplar. The contrary results were showed in the lines of PsLBD42-suppression transgenic poplar. It was confirmed that PsLBD42 could directly binds to the promoters of PsUGT78D2 and PsUGT79B3 in the genes of anthocyanin pathway by yeast one-hybrid, dual luciferase, and ChIP-qPCR assays. Under low nitrogen conditions, the overexpressing PsUGT78D2 and PsUGT79B3 in the poplar leaves accumulated more anthocyanins while the suppression of PsUGT78D2 and PsUGT79B3 reduced anthocyanins content. Furthermore, overexpression of PsUGT78D2 and PsUGT79B3 restored anthocyanin levels in PsLBD42-RNAi lines under low nitrogen conditions. Collectively, our results indicate that the PsLBD42-PsUGT78D2/PsUGT79B3 module regulates anthocyanin accumulation in poplar leaves as a novel mechanism to enhance poplar tolerance to low nitrogen stress.
Feng et al. (Wed,) studied this question.