Abstract
The restriction-modification systems use epigenetic modification to distinguish between self and nonself DNA. A modification enzyme transfers a methyl group to a base in a specific DNA sequence while its cognate restriction enzyme introduces breaks in DNA lacking this methyl group. So far, all the restriction enzymes hydrolyze phosphodiester bonds linking the monomer units of DNA. We recently reported that a restriction enzyme (R.PabI) of the PabI superfamily with half-pipe fold has DNA glycosylase activity that excises an adenine base in the recognition sequence (5′-GTAC). We now found a second activity in this enzyme: at the resulting apurinic/apyrimidinic (AP) (abasic) site (5′-GT#C, # = AP), its AP lyase activity generates an atypical strand break. Although the lyase activity is weak and lacks sequence specificity, its covalent DNA–R.PabI reaction intermediates can be trapped by NaBH4 reduction. The base excision is not coupled with the strand breakage and yet causes restriction because the restriction enzyme action can impair transformation ability of unmethylated DNA even in the absence of strand breaks in vitro. The base excision of R.PabI is inhibited by methylation of the target adenine base. These findings expand our understanding of genetic and epigenetic processes linking those in prokaryotes and eukaryotes.
Highlights
Restriction-modification (RM) systems recognize and attack nonself DNA based on DNA chemical modifications (Figure 1A)
Our results demonstrated that R.PabI restricted the biological activity of DNA in the absence of strand breaks through glycosylase activity
Because this restriction was inhibited by methylation of a specific base in the enzyme’s recognition sequence, this represents a novel mode in restriction modification processes
Summary
Restriction-modification (RM) systems recognize and attack nonself DNA based on DNA chemical modifications (Figure 1A). Among the various types of chemical modification, epigenetic methylation of bases is well studied. Methylation occurs at specific bases, generating m5C (5methylcytosine, 5mC), m4C (N4-methylcytosine) or m6A (N6-methyladenine, mA) at specific sequences [1]. RM systems are frequently encountered in the prokaryotic world and, less often, in the eukaryotic world (REBASE, http: //rebase.neb.com) [2,3]. These systems show mobility and variability in sequence recognition [4] and interact in cooperative or conflicting ways [5]. Bacterial strains can have very different RM systems and methylomes, even genomic information indicates that they are closely related [7]
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