directly bind to the PER57 promoter, as a representative instance, suggesting that PER genes are downstream target of MYB70 (Figures 7D, 7E and S10). Moreover, the transcriptional activity analysis revealed that MYB70 acts as a transcriptional repressor (Figure 7G), downregulating the expression of PER57 (Figure 7F). This outcome together with that described above for the transcriptional activity assay on the GH3.3 gene indicate that MYB70 has dual transcriptional activities, and can act as each activator and repressor to regulate the expression of its downstream genes. Even so, when the activation function and when the TRPML manufacturer repression function act, this necessary further investigations. The dual functions of TFs in activation or repression of unique target genes by way of direct physical interaction is an intriguing phenomenon that has been reported previously, like for ABI4. ABI4 modulates seed dormancy by directly repressing the PIM2 site transcription of ARR6, ARR7, and ARR15 (Huang et al., 2017), and decreasing ABA degradation via direct repression with the expression of CYP707A1 and CYP707A2, while promoting GA degradation via direct activation of GA2ox7 expression (Shu et al., 2016a, 2016b). Furthermore, ABI4 also modulates flowering by directly activating Flowering Locus C (FLC) expression (Shu et al., 2016b), though it modulates ROS levels by directly repressing Vitamin C Defective two (VTC2) expression in Arabidopsis (Yu et al., 2019). Results of this study, a minimum of, suggest that both the activation and repression functions of MYB70 have been activated in parallel for regulation of PR development of Arabidopsis seedlings by way of the auxin and ROS signaling pathways (Figures six and 7). Also, taking into consideration that MYB70 can be a transcriptional repressor having a repression activity of EAR motif (Figure 7G), a co-activator may be necessary in addition to MYB70 to activate the expression of GH3 genes. This co-activator really should also be capable of overcome the repression activity of MYB70. It can then be intriguing to discover detailed molecular mechanisms for the dual activities of MYB70 in regulation of plant development and development in a spatiotemporal manner. PERs regulate ROS status in two opposite approaches, namely reduction of H2O2 by transferring electrons to donor molecules and formation of O2,by catalyzing the hydroxylic cycle (Passardi et al., 2005; Pitzschke et al., 2006; Tsukagoshi et al., 2010). In OX70 plants, repression of PER gene expression led to decreased O2,and enhanced H2O2 accumulation in the roots, specially inside the EZ (Figures 7A, 7B and S9). Although the phenotype from the PRs of OX70 was equivalent to that of 35S:UPB1 (UPB1OX), our benefits revealed that the repression of PER gene expression by MYB70 occurred independently of UPB1 (Figure S11). These findings showed that several pathways are involved within the regulation of H2O2/O2,ratio to retain apical meristem activity within the root ideas, and MYB70 pathway regulates ROS status no less than independently on the UPB1 pathway.iScience 24, 103228, November 19,iScienceArticleIn addition to modulating cell proliferation and differentiation, PER-mediated ROS status also plays a part within the modification of cell wall structure and initiation of cell expansion, thereby regulating root development (Passardi et al., 2005; Tsukagoshi et al., 2010). Our transcriptome analysis revealed that as well as PER genes, MYB70 also repressed the transcription of lots of other genes participated in modifying cell wall structure, su