Cytosine methylation is an epigenetic mark that promotes gene silencing and plays important roles in development and genome defense against transposons. Methylation patterns are established and maintained by DNA methyltransferases that catalyze transfer of a methyl group from S-adenosyl-L-methionine to cytosine bases in DNA. Erasure of cytosine methylation occurs during development, but the enzymatic basis of active demethylation remains controversial. In Arabidopsis thaliana, DEMETER (DME) activates the maternal expression of two imprinted genes silenced by methylation, and REPRESSOR OF SILENCING 1 (ROS1) is required for release of transcriptional silencing of a hypermethylated transgene. DME and ROS1 encode two closely related DNA glycosylase domain proteins, but it is unknown whether they participate directly in a DNA demethylation process or counteract silencing through an indirect effect on chromatin structure. Here we show that DME and ROS1 catalyze the release of 5-methylcytosine (5-meC) from DNA by a glycosylase͞lyase mechanism. Both enzymes also remove thymine, but not uracil, mismatched to guanine. DME and ROS1 show a preference for 5-meC over thymine in the symmetric dinucleotide CpG context, where most plant DNA methylation occurs. Nevertheless, they also have significant activity on both substrates at CpApG and asymmetric sequences, which are additional methylation targets in plant genomes. These findings suggest that a function of ROS1 and DME is to initiate erasure of 5-meC through a base excision repair process and provide strong biochemical evidence for the existence of an active DNA demethylation pathway in plants.Arabidopsis ͉ demethylation ͉ gene silencing ͉ methylation M ethylation of cytosine at carbon 5 of the pyrimidine ring [5-methylcytosine (5-meC)] is an epigenetic modification that guides formation of transcriptionally silent chromatin and allows transmission of specific patterns of gene activity across cellular divisions (1, 2). In eukaryotes, DNA methylation is detected in protists, fungi, plants, and animals (3) and plays important roles in the establishment of developmental programs (4, 5) and in genome defense against parasitic mobile elements (6). Most of mammalian and plant DNA methylation is restricted to symmetrical CpG sequences, but plants also have significant levels of cytosine methylation in the symmetric context CpNpG (where N is any nucleotide) and even in asymmetric contexts (2, 7). Similarly to other biochemical modifications such as protein phosphorylation and acetylation, DNA methylation is also reversible. Demethylation may take place as a passive process because of lack of maintenance methylation during several cycles of DNA replication or as an active mechanism in the absence of replication (8). In mammalian preimplantation embryos the maternal genome is demethylated by a passive process along cleavage stages, whereas the paternal genome is demethylated by an active mechanism immediately after fertilization (9). In addition to global demethylation, site-specific...
SUMMARY DNA methylation is an important epigenetic mark established by the combined actions of methylation and demethylation reactions. Plants use a base excision repair pathway for active DNA demethylation. After 5-methylcytosine removal, the Arabidopsis DNA glycosylase/lyase ROS1 incises the DNA backbone and part of the product has a single-nucleotide gap flanked by 3′- and 5′-phosphate termini. Here we show that the DNA phosphatase ZDP removes the blocking 3′-phosphate, allowing subsequent DNA polymerization and ligation steps needed to complete the repair reactions. ZDP and ROS1 interact in vitro and co-localize in vivo in nucleoplasmic foci. Extracts from zdp mutant plants are unable to complete DNA demethylation in vitro, and the mutations cause DNA hypermethylation and transcriptional silencing of a reporter gene. Genome-wide methylation analysis in zdp mutant plants identified hundreds of hypermethylated endogenous loci. Our results show that ZDP functions downstream of ROS1 in one branch of the active DNA demethylation pathway.
DNA cytosine methylation is an epigenetic mark that promotes gene silencing and performs critical roles during reproduction and development in both plants and animals. The genomic distribution of DNA methylation is the dynamic outcome of opposing methylation and demethylation processes. In plants, active demethylation occurs through a base excision repair pathway initiated by 5-methycytosine (5-meC) DNA glycosylases of the REPRESSOR OF SILENCING 1 (ROS1)/ DEMETER (DME) family. To gain insight into the mechanism by which Arabidopsis ROS1 recognizes and excises 5-meC, we have identified those protein regions that are required for efficient DNA binding and catalysis. We have found that a short N-terminal lysine-rich domain conserved in members of the ROS1/DME family mediates strong methylation-independent binding of ROS1 to DNA and is required for efficient activity on 5-meC⅐G, but not for T⅐G processing. Removal of this domain does not significantly affect 5-meC excision from short molecules, but strongly decreases ROS1 activity on long DNA substrates. This region is not required for product binding and is not involved in the distributive behavior of the enzyme on substrates containing multiple 5-meC residues. Altogether, our results suggest that methylation-independent DNA binding allows ROS1 to perform a highly redundant search for efficient excision of a nondamaged, correctly paired base such as 5-meC in long stretches of DNA. These findings may have implications for understanding the evolution of structure and target specificity in DNA glycosylases.
There are two major and alternative pathways to repair DNA double-strand breaks: non-homologous end-joining and homologous recombination. Here we identify and characterize novel factors involved in choosing between these pathways; in this study we took advantage of the SeeSaw Reporter, in which the repair of double-strand breaks by homology-independent or -dependent mechanisms is distinguished by the accumulation of green or red fluorescence, respectively. Using a genome-wide human esiRNA (endoribonuclease-prepared siRNA) library, we isolate genes that control the recombination/end-joining ratio. Here we report that two distinct sets of genes are involved in the control of the balance between NHEJ and HR: those that are required to facilitate recombination and those that favour NHEJ. This last category includes CCAR2/DBC1, which we show inhibits recombination by limiting the initiation and the extent of DNA end resection, thereby acting as an antagonist of CtIP.
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