Abstract
BackgroundGmrSD is a modification-dependent restriction endonuclease that specifically targets and cleaves glucosylated hydroxymethylcytosine (glc-HMC) modified DNA. It is encoded either as two separate single-domain GmrS and GmrD proteins or as a single protein carrying both domains. Previous studies suggested that GmrS acts as endonuclease and NTPase whereas GmrD binds DNA.MethodsIn this work we applied homology detection, sequence conservation analysis, fold recognition and homology modeling methods to study sequence-structure-function relationships in the GmrSD restriction endonucleases family. We also analyzed the phylogeny and genomic context of the family members.ResultsResults of our comparative genomics study show that GmrS exhibits similarity to proteins from the ParB/Srx fold which can have both NTPase and nuclease activity. In contrast to the previous studies though, we attribute the nuclease activity also to GmrD as we found it to contain the HNH endonuclease motif. We revealed residues potentially important for structure and function in both domains. Moreover, we found that GmrSD systems exist predominantly as a fused, double-domain form rather than as a heterodimer and that their homologs are often encoded in regions enriched in defense and gene mobility-related elements. Finally, phylogenetic reconstructions of GmrS and GmrD domains revealed that they coevolved and only few GmrSD systems appear to be assembled from distantly related GmrS and GmrD components.ConclusionsOur study provides insight into sequence-structure-function relationships in the yet poorly characterized family of Type IV restriction enzymes. Comparative genomics allowed to propose possible role of GmrD domain in the function of the GmrSD enzyme and possible active sites of both GmrS and GmrD domains. Presented results can guide further experimental characterization of these enzymes.Electronic supplementary materialThe online version of this article (doi:10.1186/s12859-015-0773-z) contains supplementary material, which is available to authorized users.
Highlights
GmrSD is a modification-dependent restriction endonuclease that targets and cleaves glucosylated hydroxymethylcytosine modified DNA
Restriction enzymes are classified into four Types, with Types I, II and III encompassing all Restriction-Modification systems (RMs) and a few Modification-Dependent systems (MDs), and Type IV encompassing the majority of MDs [4]
DUF4268 is most often associated with DUF262 (GmrS) and DUF1524 (GmrD), while DUF4357 was found in proteins containing the GIY-YIG nuclease superfamily domain [46] and Bacteriophage T5 Orf172 DNAbinding domain
Summary
GmrSD is a modification-dependent restriction endonuclease that targets and cleaves glucosylated hydroxymethylcytosine (glc-HMC) modified DNA. It is encoded either as two separate single-domain GmrS and GmrD proteins or as a single protein carrying both domains. Restriction systems are protein complexes able to recognize and destroy foreign DNA based on sequence and modification patterns. They are found in Archaea, Bacteria, Eukaryota, bacteriophages, and some viruses infecting algae [1,2,3]. Restriction systems can be divided into two main groups: Restriction-Modification systems (RMs) and Modification-Dependent systems (MDs), depending on their enzymatic activity and the way they recognize foreign DNA. Restriction enzymes are classified into four Types, with Types I, II and III encompassing all RMs and a few MDs (those that exhibit sequence specificity are grouped in Subtype IIM), and Type IV encompassing the majority of MDs [4]
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