The type I restriction-modification system EcoR124I recognizes and binds to the split DNA recognition sequence 5'-GAAN(6)RTCG-3'. The methyltransferase, consisting of HsdM and HsdS subunits with the composition M2S, can interact with one or more subunits of the HsdR subunit to form the endonuclease. The interaction of the methyltransferase with HsdR has been investigated by surface plasmon resonance, showing that there are two non-equivalent binding sites for HsdR which differ in binding affinity by at least two orders of magnitude. DNA footprinting experiments using Exonuclease III suggest that the addition of HsdR to the methyltransferase (at a stoichiometry of either 1:1 or 2:1) increases the stability of the resulting DNA-protein complex but does not increase the size of the footprint. More extensive in situ footprinting experiments using copper-phenanthroline on the DNA-protein complexes formed by M2S, R1M2S and R2M2S also show no difference in the detailed cleavage pattern, with approximately 18 nucleotides protected on both strands in each complex. Thus the HsdR subunit(s) of the endonuclease stabilise the interaction of the M2S complex with DNA, but do not directly contribute to DNA binding. In addition, the thymidine nucleotide in the tetranucleotide recognition sequence GTCG is hyper-reactive to cleavage in each case, suggesting that the DNA structure in this region is altered in these complexes.
The conjugation of thermoresponsive polymers to multisubunit, multifunctional hybrid type 1 DNA restriction-modification (R-M) enzymes enables temperature-controlled "switching" of DNA methylation by the conjugate. Polymers attached to the enzyme at a subunit distal to the methylation subunit allow retention of DNA recognition and ATPase activity while controlling methylation of plasmid DNA. This regulation of enzyme activity arises from the coil-globule phase transitions of the polymer as shown in light scattering and gel retardation assays.
The type I DNA methyltransferase M.EcoR124I is a multi-subunit enzyme that binds to the sequence GAAN6RTCG, transferring a methyl group from S-adenosyl methionine to a specific adenine on each DNA strand. We have investigated the protein-DNA interactions in the complex by DNase I and hydroxyl radical footprinting. The DNase I footprint is unusually large: the protein protects the DNA on both strands for at least two complete turns of the helix, indicating that the enzyme completely encloses the DNA in the complex. The higher resolution hydroxyl radical probe shows a smaller, but still extensive, 18 bp footprint encompassing the recognition site. Within this region, however, there is a remarkably hyper-reactive site on each strand. The two sites of enhanced cleavage are co-incident with the two adenines that are the target bases for methylation, showing that the DNA is both accessible and highly distorted at these sites. The hydroxyl radical footprint is unaffected by the presence of the cofactor S-adenosyl methionine, showing that the distorted DNA structure induced by M.EcoR124I is formed during the initial DNA binding reaction and not as a transient intermediate in the reaction pathway.
The type I DNA methyltransferase M.EcoR124I consists of two methylation subunits (HsdM) and one DNA recognition subunit (HsdS). When expressed independently, HsdS is insoluble, but this subunit can be obtained in soluble form as a GST fusion protein. We show that the HsdS subunit, even as a fusion protein, is unable to form a discrete complex with its DNA recognition sequence. When HsdM is added to the HsdS fusion protein, discrete complexes are formed but these are unable to methylate DNA. The two complexes formed correspond to species with one or two copies of the HsdM subunit, indicating that blocking the N-terminus of HsdS affects one of the HsdM binding sites. However, removal of the GST moiety from such complexes results in tight and specific DNA binding and restores full methylation activity. The results clearly demonstrate the importance of the HsdM subunit for DNA binding, in addition to its catalytic role in the methyltransferase reaction.
We have analysed the DNA-protein contacts made between the type I DNA methyltransferase M.EcoR124I and its recognition sequence. The effects of base modifications have been probed by measuring the affinity of M.EcoR124I for the modified sequences relative to that for the wild-type sequence by using gel-retardation competition assays. These results, along with those from methylation interference footprinting and photo-affinity cross-linking have identified the location of potential DNA contacts within the DNA recognition site. Substitution of 6-thioguanosine for each of the three specific guanines in the recognition sequence leads to a large (10-20-fold) decrease in the strength of DNA binding, indicating the importance of hydrogen-bonding interactions in the major groove of DNA. In contrast, replacement of either (or both) of the adenines at the target site for methylation by the enzyme, to produce either a base pair mismatch or loss of the base, leads to a marked increase in DNA-binding affinity. The results strongly support the proposal that type I methyltransferases employ a base-flipping mechanism to methylate their target base.
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