Biophysical study of the DNA charge mimicry displayed by the T7 Ocr protein

The homodimeric Ocr protein of bacteriophage T7 is a molecular mimic of a bent double-stranded DNA molecule ~24 bp in length. As such, Ocr is a highly effective competitive inhibitor of the bacterial Type I restriction modification (R/M) system. Thus, Ocr facilitates phage infection of the bacterial cell to proceed unhindered by the action of the R/M defense system. The main aim of this work was to understand the basis of the DNA mimicry displayed by Ocr. The surface of the protein is replete with acidic residues, most or all of which mimic the phosphate backbone of DNA. Aspartate and glutamate residues on the surface of Ocr were either mutated or chemically modified in order to investigate their contribution to the tight binding between Ocr and the EcoKI Type I R/M enzyme. Single or double mutations of Ocr had no discernable effect on binding to EcoKI or its methyltransferase component (M.EcoKI). Chemical modification was then used to specifically modify the carboxyl moieties of Ocr, thereby neutralizing the negative charges on the protein surface. Ocr samples modified to varying degrees were analysed to establish the extent of derivatisation prior to extensive biophysical characterisation to assess the impact of these changes in terms of binding to the EcoKI R/M system. The results of this analysis revealed that the electrostatic mimicry of Ocr increases the binding affinity for its target enzyme by at least ~800-fold. In addition, based on the known 3-D structure of the protein, a set of multiple mutations were introduced into Ocr aimed at eliminating patches of negative charge from the protein surface. Specifically, between 5 and 17 acidic residues were targeted for mutation (Asp and Glu to Asn and Gln, respectively). Analysis of the in vivo activity of the mutant Ocr along with biophysical characterisation of the purified proteins was then performed. Results from these studies identified regions of the Ocr protein that were critical in forming a tight association with the EcoKI R/M system. Furthermore by comparing the relative contribution of different groups of acidic residues to the free energy of binding, the actual mechanism by which Ocr mimics the charge distribution of DNA has been delineated

The evolutionary pathway from a biologically inactive polypeptide sequence to a folded, active structural mimic of DNA

The protein Ocr (overcome classical restriction) from bacteriophage T7 acts as a mimic of DNA and inhibits all Type I restriction/modification (RM) enzymes. Ocr is a homodimer of 116 amino acids and adopts an elongated structure that resembles the shape of a bent 24 bp DNA molecule. Each monomer includes 34 acidic residues and only six basic residues. We have delineated the mimicry of Ocr by focusing on the electrostatic contribution of its negatively charged amino acids using directed evolution of a synthetic form of Ocr, termed pocr, in which all of the 34 acidic residues were substituted for a neutral amino acid. In vivo analyses confirmed that pocr did not display any antirestriction activity. Here, we have subjected the gene encoding pocr to several rounds of directed evolution in which codons for the corresponding acidic residues found in Ocr were specifically re-introduced. An in vivo selection assay was used to detect antirestriction activity after each round of mutation. Our results demonstrate the variation in importance of the acidic residues in regions of Ocr corresponding to different parts of the DNA target which it is mimicking and for the avoidance of deleterious effects on the growth of the host

Impact of target site distribution for Type I restriction enzymes on the evolution of methicillin-resistant Staphylococcus aureus (MRSA) populations.

A limited number of Methicillin-resistant Staphylococcus aureus (MRSA) clones are responsible for MRSA infections worldwide, and those of different lineages carry unique Type I restriction-modification (RM) variants. We have identified the specific DNA sequence targets for the dominant MRSA lineages CC1, CC5, CC8 and ST239. We experimentally demonstrate that this RM system is sufficient to block horizontal gene transfer between clinically important MRSA, confirming the bioinformatic evidence that each lineage is evolving independently. Target sites are distributed randomly in S. aureus genomes, except in a set of large conjugative plasmids encoding resistance genes that show evidence of spreading between two successful MRSA lineages. This analysis of the identification and distribution of target sites explains evolutionary patterns in a pathogenic bacterium. We show that a lack of specific target sites enables plasmids to evade the Type I RM system thereby contributing to the evolution of increasingly resistant community and hospital MRSA

Fusion of GFP to the M.EcoKI DNA methyltransferase produces a new probe of Type I DNA restriction and modification enzymes

► Successful fusion of GFP to M.EcoKI DNA methyltransferase. ► GFP located at C-terminal of sequence specificity subunit does not later enzyme activity. ► FRET confirms structural model of M.EcoKI bound to DNA

Dissection of the DNA Mimicry of the Bacteriophage T7 Ocr Protein using Chemical Modification

The homodimeric Ocr (overcome classical restriction) protein of bacteriophage T7 is a molecular mimic of double-stranded DNA and a highly effective competitive inhibitor of the bacterial type I restriction/modification system. The surface of Ocr is replete with acidic residues that mimic the phosphate backbone of DNA. In addition, Ocr also mimics the overall dimensions of a bent 24-bp DNA molecule. In this study, we attempted to delineate these two mechanisms of DNA mimicry by chemically modifying the negative charges on the Ocr surface. Our analysis reveals that removal of about 46% of the carboxylate groups per Ocr monomer results in an ∼ 50-fold reduction in binding affinity for a methyltransferase from a model type I restriction/modification system. The reduced affinity between Ocr with this degree of modification and the methyltransferase is comparable with the affinity of DNA for the methyltransferase. Additional modification to remove ∼ 86% of the carboxylate groups further reduces its binding affinity, although the modified Ocr still binds to the methyltransferase via a mechanism attributable to the shape mimicry of a bent DNA molecule. Our results show that the electrostatic mimicry of Ocr increases the binding affinity for its target enzyme by up to ∼ 800-fold