Role of the tomato MARS1/ROUGH gene encoding a LYSINE-SPECIFIC HISTONE DEMETHYLASE 1 in adventitious root and fruit skin formation

In contrast to animals, plants have a high regenerative capacity, and they can form new organs and even complete individuals from a few cells present in adult tissues, either in response to injury or to the alteration of their environment. In this study, we describe the isolation and characterization of the more adventitious roots1-1 ( mars1-1 ) mutant, which exhibits enhanced regenerative potential upon wounding in tomato hypocotyl explants. Additionally, the mars1-1 fruits exhibited a rough surface due to the ectopic proliferation of subepidermal cells, which formed callus-like structures on the cuticle. The MARS1/ROUGH gene encodes a conserved lysine-specific histone demethylase, SlLSD1, which regulates a variety of processes in metazoans, including cell proliferation, stem cell pluripotency, and embryogenesis. Two CRISPR/Cas9 null alleles, mars1-2 and mars1-3 , were generated and their pleiotropic phenotype was characterized. We found elevated levels of H3K4me1 in mars1/rough seedlings, which suggests that SlLSD1 is required for the demethylation of this histone mark. To ascertain the impact of altered epigenetic marks in the mars1/rough mutants on gene expression regulation, we conducted a transcriptome analysis using a variety of RNA-Seq studies on tomato hypocotyls. By employing specific bioinformatic workflows and leveraging on the resolution of directional RNA-Seq data, we have identified over several dozen distinct genomic regions that exhibit de novo expression in the mars1/rough mutants. One such region includes a novel B-type cyclin gene, which is upregulated in the mars1/rough mutants and may account for the observed phenotypes. Our findings indicate that SlLSD1 plays a role in the establishment and maintenance of silencing in specific genomic regions that are essential for tissue-specific reprogramming.