A novel mutant of the type I restriction-modification enzyme EcoR124I is altered at a key stage of the subunit assembly pathway

The HsdS subunit of a type I restriction-modification (R-M) system plays an essential role in the activity of both the modification methylase and the restriction endonuclease. This subunit is responsible for DNA binding, but also contains conserved amino acid sequences responsible for protein-protein interactions. The most important protein-protein interactions are those between the HsdS subunit and the HsdM (methylation) subunit that result in assembly of an independent methylase (MTase) of stoichiometry M(2)S(1). Here, we analysed the impact on the restriction and modification activities of the change Trp(212)-->Arg in the distal border of the central conserved region of the EcoR124I HsdS subunit. We demonstrate that this point mutation significantly influences the ability of the mutant HsdS subunit to assemble with the HsdM subunit to produce a functional MTase. As a consequence of this, the mutant MTase has drastically reduced DNA binding, which is restored only when the HsdR (restriction) subunit binds with the MTase. Therefore, HsdR acts as a chaperon allowing not only binding of the enzyme to DNA, but also restoring the methylation activity and, at sufficiently high concentrations in vitro of HsdR, restoring restriction activity.     

DNA binding and subunit interactions in the type I methyltransferase M.EcoR124I.

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.     

The HsdR subunit of R.EcoR124II: cloning and over-expression of the gene and unexpected properties of the subunit.

Type I restriction endonucleases are composed of three subunits, HsdR, HsdM and HsdS. The HsdR subunit is absolutely required for restriction activity; while an independent methylase is composed of HsdM and HsdS subunits. DNA cleavage is associated with a powerful ATPase activity during which DNA is translocated by the enzyme prior to cleavage. The presence of a Walker type I ATP-binding site within the HsdR subunit suggested that the subunit may be capable of independent enzymatic activity. Therefore, we have, for the first time, cloned and over-expressed the hsdRgene of the type IC restriction endonuclease EcoR124II. The purified HsdR subunit was found to be a soluble monomeric protein capable of DNA- and Mg2+-dependent ATP hydrolysis. The subunit was found to have a weak nuclease activity both in vivo and in vitro, and to bind plasmid DNA; although was not capable of binding a DNA oligoduplex. We were also able to reconstitute the fully active endonuclease from purified M. EcoR124I and HsdR. This is the first clear demonstration that the HsdR subunit of a type I restriction endonuclease is capable of independent enzyme activity, and suggests a mechanism for the evolution of the endonuclease from the independent methylase.     

Characterization of an<Emphasis Type="Italic">Eco</Emphasis>R 124I restriction-modification enzyme produced from a deleted form of the DNA-binding subunit,which results in a novel DNA specificity

We purified and characterized both the methyltransferase and the endonuclease containing the HsdS delta 50 subunit (type I restriction endonucleases are composed of three subunits--HsdR required for restriction, HsdM required for methylation and HsdS responsible for DNA recognition) produced from the deletion mutation hsdS delta 50 of the type IC R-M system EcoR 124I; this mutant subunit lacks the C-terminal 163 residues of HsdS and produces a novel DNA specificity. Analysis of the purified HsDs delta 50 subunit indicated that during purification it is subject to partial proteolysis resulting in removal of approximately 1 kDa of the polypeptide at the C-terminus. This proteolysis prevented the purification of further deletion mutants, which were determined as having a novel DNA specificity in vivo. After biochemical characterization of the mutant DNA methyltransferase (MTase) and restriction endonuclease we found only one difference comparing with the wild-type enzyme--a significantly higher binding affinity of the MTase for the two substrates of hemimethylated and fully methylated DNA. This indicates that MTase delta 50 is less able to discriminate the methylation status of the DNA during its binding. However, the mutant MTase still preferred hemimethylated DNA as the substrate for methylation. We fused the hsdM and hsdS delta 50 genes and showed that the HsdM-HsdS delta 50 fusion protein is capable of dimerization confirming the model for assembly of this deletion mutant.     

High-level expression of the cloned genes encoding the subunits of and intact DNA methyltransferase, M.EcoR124.

We have cloned the genes coding for the two subunits (HsdM and HsdS) of the type-I DNA methyltransferase (MTase), M.EcoR124, into the specially constructed expression vector, pJ119. These subunits have been synthesized together as an intact MTase. We have also cloned the individual subunit-encoding genes under the control of the T7 gene 10 promoter or the lacUV5 promoter. High levels of expression have been obtained in all cases. While HsdM was found to be soluble, HsdS was insoluble. However, in the presence of the co-produced HsdM subunit, HsdS was found in the soluble fraction as part of an active MTase. We have partially purified the cloned multi-subunit enzyme and shown that it is capable of DNA methylation both in vivo and in vitro.     

The HsdS polypeptide of the Type IC restriction enzyme Eco R124 is a sequence-specific DNA-binding protein

The HsdS and HsdM polypeptides of the type IC restriction enzyme EcoR124 have been purified independently and used in a set of gel retardation experiments to determine the minimum requirements for sequence-specific recognition of DNA by this enzyme. The HsdS polypeptide alone is able to bind to DNA in a sequence-specific manner. In addition, whilst the presence of the HsdM polypeptide gives rise to a stimulation of DNA binding by the HsdS subunit it is not clear whether, under the conditions of the experiments reported here, the HsdS subunit maintains the same interactions with the HsdM subunits observed in the absence of DNA.     

Cloning, production and characterisation of wild type and mutant forms of the R.EcoK endonucleases.

The hsdR, hsdM and hsdS genes coding for R.EcoK restriction endonuclease, both with and without a temperature sensitive mutation (ts-1) in the hsdS gene, were cloned in pBR322 plasmid and introduced into E.coli C3-6. The presence of the hsdSts-1 mutation has no effect on the R-M phenotype of this construct in bacteria grown at 42 degrees C. However, DNA sequencing indicates that the mutation is still present on the pBR322-hsdts-1 operon. The putative temperature-sensitive endonuclease was purified from bacteria carrying this plasmid and the ability to cleave and methylate plasmid DNA was investigated. The mutant endonuclease was found to show temperature-sensitivity for restriction. Modification was dramatically reduced at both the permissive and non-permissive temperatures. The wild type enzyme was found to cleave circular DNA in a manner which strongly suggests that only one endonuclease molecule is required per cleavage event. Circular and linear DNA appear to be cleaved using different mechanisms, and cleavage of linear DNA may require a second endonuclease molecule. The subunit composition of the purified endonucleases was investigated and compared to the level of subunit production in minicells. There is no evidence that HsdR is prevented from assembling with HsdM and HsdSts-1 to produce the mutant endonuclease. The data also suggests that the level of HsdR subunit may be limiting within the cell. We suggest that an excess of HsdM and HsdS may produce the methylase in vivo and that assembly of the endonuclease may be dependent upon the prior production of this methylase.     

Localization of the type I restriction-modification enzyme EcoKI in the bacterial cell

To localise the type I restriction-modification (R-M) enzyme EcoKI within the bacterial cell, the Hsd subunits present in subcellular fractions were analysed using immunoblotting techniques. The endonuclease (ENase) as well as the methylase (MTase) were found to be associated with the cytoplasmic membrane. HsdR and HsdM subunits produced individually were soluble, cytoplasmic polypeptides and only became membrane-associated when coproduced with the insoluble HsdS subunit. The release of enzyme from the membrane fraction following benzonase treatment indicated a role for DNA in this interaction. Trypsinization of spheroplasts revealed that the HsdR subunit in the assembled ENase was accessible to protease, while HsdM and HsdS, in both ENase and MTase complexes, were fully protected against digestion. We postulate that the R-M enzyme EcoKI is associated with the cytoplasmic membrane in a manner that allows access of HsdR to the periplasmic space, while the MTase components are localised on the inner side of the plasma membrane.     

Domain structure and subunit interactions in the type I DNA methyltransferase M.EcoR124I.

The type IC DNA methyltransferase M.EcoR124I is a trimeric enzyme of 162 kDa consisting of two modification subunits, HsdM, and a single specificity subunit, HsdS. Studies have been largely restricted to the HsdM subunit or to the intact methyltransferase since the HsdS subunit is insoluble when over-expressed independently of HsdM. Two soluble fragments of the HsdS subunit have been cloned, expressed and purified; a 25 kDa N-terminal fragment (S3) comprising the N-terminal target recognition domain together with the central conserved domain, and a 8.6 kDa fragment (S11) comprising the central conserved domain alone. Analytical ultracentrifugation shows that the S3 subunit exists principally as a dimer of 50 kDa. Gel retardation and competition assays show that both S3 and S11 are able to bind to HsdM, each with a subunit stoichiometry of 1:1. The tetrameric complex (S3/HsdM)(2) is required for effective DNA binding. Cooperative binding is observed and at low enzyme concentration, the multisubunit complex dissociates, leading to a loss of DNA binding activity. The (S3/HsdM)(2) complex is able to bind to both the EcoR124I DNA recognition sequence GAAN(6)RTCG and a symmetrical DNA sequence GAAN(7)TTC, but has a 30-fold higher affinity binding for the latter DNA sequence. Exonuclease III footprinting of the (S3/HsdM)(2) -DNA complex indicates that 29 nucleotides are protected on each strand, corresponding to a region 8 bp on both the 3' and 5' sides of the recognition sequence bound by the (S3/HsdM)(2) complex.     

The location of a temperature-sensitive trans-dominant mutation and its effect on restriction and modification in Escherichia coli K12

An Escherichia coli K12 chromosomal EcoRI-BamHI fragment containing a mutant hsdS locus was cloned into plasmid pBR322. The mcrB gene, closely linked to hsdS, was used for selection of clones with the inserted fragment using T4 alpha gt57 beta gt14 and lambda vir. PvuII phages; the phage DNAs contain methylated cytosines and hence can be used to demonstrate McrB restriction. For the efficient expression of the hsdS gene, a BglII fragment of phage lambda carrying the pR promoter was inserted into the BamHI site of the hybrid plasmid. Under these conditions a trans-dominant effect of the hsdXts+d mutation on restriction and modification was detected. Inactivation of the hsdS gene by the insertion of the lambda phage BglII fragment into the BglII site within this gene resulted in the disappearance of the trans-dominant effect. When the cloned BamHI-EcoRI fragment was shortened by HpaI and EcoRI restriction enzymes, the trans-dominant effect was fully expressed. The results indicate that the Xts+d mutation is located in the hsdS gene. The effect of gene dosage of the HsdS subunit on the expression of Xts+d mutation was studied. The results of complementation experiments, using F'-merodiploids or plasmid pBR322 with an inserted Xts+d mutation, support the idea that the HsdSts+d product competes with the wild-type HsdS product, and has a quantitatively different effect on restriction and modification.     

Analysis of the subunit assembly of the typeIC restriction-modification enzyme EcoR124I.

Type I restriction-modification (R-M) enzymes are composed of three different subunits, of which HsdS determines DNA specificity, HsdM is responsible for DNA methylation and HsdR is required for restriction. The HsdM and HsdS subunits can also form an independent DNA methyltransferase with a subunit stoichiometry of M2S1. We found that the purified Eco R124I R-M enzyme was a mixture of two species as detected by the presence of two differently migrating specific DNA-protein complexes in a gel retardation assay. An analysis of protein subunits isolated from the complexes indicated that the larger species had a stoichiometry of R2M2S1and the smaller species had a stoichiometry of R1M2S1. In vitro analysis of subunit assembly revealed that while binding of the first HsdR subunit to the M2S1complex was very tight, the second HsdR subunit was bound weakly and it dissociated from the R1M2S1complex with an apparent K d of approximately 2.4 x 10(-7) M. Functional assays have shown that only the R2M2S1complex is capable of DNA cleavage, however, the R1M2S1complex retains ATPase activity. The relevance of this situation is discussed in terms of the regulation of restriction activity in vivo upon conjugative transfer of a plasmid-born R-M system into an unmodified host cell.     

Two temperature-sensitive mutations in the DNA binding subunit of EcoKI with differing properties

Two temperature-sensitive mutations in the hsdS gene, which encodes the DNA specificity subunit of the type IA restriction-modification system EcoKI, designated Sts1 (Ser(340)Phe) and Sts2 (Ala(204)Thr) had a different impact on restriction-modification functions in vitro and in vivo. The enzyme activities of the Sts1 mutant were temperature-sensitive in vitro and were reduced even at 30 degrees C (permissive temperature). Gel retardation assays revealed that the Sts1 mutant had significantly decreased DNA binding, which was temperature-sensitive. In contrast the Sts2 mutant did not show differences from the wild-type enzyme even at 42 degrees C. Unlike the HsdSts1 subunit, the HsdSts2 subunit was not able to compete with the wild-type subunit in assembly of the restriction enzyme in vivo, suggesting that the Sts2 mutation affects subunit assembly. Thus, it appears that these two mutations map two important regions in HsdS subunit responsible for DNA-protein and protein-protein interactions, respectively.     

A deletion mutant of the type IC restriction endonuclease EcoR1241 expressing a novel DNA specificity.

We have developed a complementation assay which allows us to distinguish between mutations affecting subunit assembly and mutations affecting DNA binding in the DNA recognition subunit (HsdS) of the multimeric restriction endonuclease EcoR1241. A number of random point mutations were constructed to test the validity of this assay. Two of the mutants produced were found to be truncated polypeptides that were still capable of complementation with the EcoR1241 Hsd subunits to give an active restriction enzyme of novel DNA specificity. The N-terminal variable domain (responsible for recognition of GAA from the EcoR1241 recognition sequence GAAnnnnnnRTCG) and the spacer region (central conserved region) is intact in both of these mutants. One of these mutant genes (hsdS(delta 50) has been cloned as an active Mtase. Purification of the Mtase proved to be difficult because the complex is weak. However, Mtase activity was obtained from a soluble cell extract, and this allowed us to determine the DNA recognition sequence of the Mtase to be GAAnnnnnnnTTC. This recognition sequence is an inverted repeat of 5'-end of the EcoR1241 recognition sequence. This suggests that the mutant Mtase is assembled from two inverted HsdS(D50) subunits, possibly held together by the HsdM subunits.     

HsdR subunit of the type I restriction-modification enzyme EcoR124I: biophysical characterisation and structural modelling

Type I restriction-modification (RM) systems are large, multifunctional enzymes composed of three different subunits. HsdS and HsdM form a complex in which HsdS recognizes the target DNA sequence, and HsdM carries out methylation of adenosine residues. The HsdR subunit, when associated with the HsdS-HsdM complex, translocates DNA in an ATP-dependent process and cleaves unmethylated DNA at a distance of several thousand base-pairs from the recognition site. The molecular mechanism by which these enzymes translocate the DNA is not fully understood, in part because of the absence of crystal structures. To date, crystal structures have been determined for the individual HsdS and HsdM subunits and models have been built for the HsdM-HsdS complex with the DNA. However, no structure is available for the HsdR subunit. In this work, the gene coding for the HsdR subunit of EcoR124I was re-sequenced, which showed that there was an error in the published sequence. This changed the position of the stop codon and altered the last 17 amino acid residues of the protein sequence. An improved purification procedure was developed to enable HsdR to be purified efficiently for biophysical and structural analysis. Analytical ultracentrifugation shows that HsdR is monomeric in solution, and the frictional ratio of 1.21 indicates that the subunit is globular and fairly compact. Small angle neutron-scattering of the HsdR subunit indicates a radius of gyration of 3.4 nm and a maximum dimension of 10 nm. We constructed a model of the HsdR using protein fold-recognition and homology modelling to model individual domains, and small-angle neutron scattering data as restraints to combine them into a single molecule. The model reveals an ellipsoidal shape of the enzymatic core comprising the N-terminal and central domains, and suggests conformational heterogeneity of the C-terminal region implicated in binding of HsdR to the HsdS-HsdM complex.     

Deletion of one nucleotide within the homonucleotide tract present in the hsdS gene alters the DNA sequence specificity of type I restriction-modification system NgoAV

As a result of a frameshift mutation, the hsdS locus of the NgoAV type IC restriction and modification (RM) system comprises two genes, hsdS(NgoAV1) and hsdS(NgoAV2). The specificity subunit, HsdS(NgoAV), the product of the hsdS(NgoAV1) gene, is a naturally truncated form of an archetypal specificity subunit (208 N-terminal amino acids instead of 410). The presence of a homonucleotide tract of seven guanines (poly[G]) at the 3' end of the hsdS(NgoAV1) gene makes the NgoAV system a strong candidate for phase variation, i.e., stochastic addition or reduction in the guanine number. We have constructed mutants with 6 guanines instead of 7 and demonstrated that the deletion of a single nucleotide within the 3' end of the hsdS(NgoAV1) gene restored the fusion between the hsdS(NgoAV1) and hsdS(NgoAV2) genes. We have demonstrated that such a contraction of the homonucleotide tract may occur in vivo: in a Neisseria gonorrhoeae population, a minor subpopulation of cells appeared to have only 6 guanines at the 3' end of the hsdS(NgoAV1) gene. Escherichia coli cells carrying the fused gene and expressing the NgoAVΔ RM system were able to restrict λ phage at a level comparable to that for the wild-type NgoAV system. NgoAV recognizes the quasipalindromic interrupted sequence 5'-GCA(N(8))TGC-3' and methylates both strands. NgoAVΔ recognizes DNA sequences 5'-GCA(N(7))GTCA-3' and 5'-GCA(N(7))CTCA-3', although the latter sequence is methylated only on the complementary strand within the 5'-CTCA-3' region of the second recognition target sequence.     

The effect ofrecA mutation on the expression ofEcoKI andEcoR124Ihsd genes cloned in a multicopy plasmid

Type I restriction-modification (R-M) endonucleases are composed of three subunits—HsdR, required for restriction, and HsdM and HsdS which can produce a separate DNA methyltransferase. The HsdS subunit is required for DNA recognition. In this paper we describe the effect of clonedEcoKI andEcoR124Ihsd genes on the resulting R-M phenotype. The variability in the expression of the wild type (wt) restriction phenotype after cloning of the wthsd genes in a multicopy plasmid inEscherichia coli recA ⁺ background suggests that the increased production of the restriction endonuclease from pBR322 is detrimental to the cell and this leads to the deletion of the clonedhsd genes from the hybrid plasmid and/or inactivation of the enzyme. The effect of a mutation inE. coli recA gene on the expression of R-M phenotype is described and discussed in relation to the role of the cell surface and the localization of the restriction endonuclease in the cell.     

Combinational variation of restriction modification specificities in Lactococcus lactis

Three genes coding for a type I R-M system related to the class C enzymes have been identified on the chromosome of Lactococcus lactis strain IL1403. In addition, plasmids were found that encode only the HsdS subunit that directs R-M specificity. The presence of these plasmids in IL1403 conferred a new R-M phenotype on the host, indicating that the plasmid-encoded HsdS is able to interact with the chromosomally encoded HsdR and HsdM subunits. Such combinational variation of type I R-M systems may facilitate the evolution of their specificity and thus reinforce bacterial resistance against invasive foreign unmethylated DNA.     

Structural model for the multisubunit Type IC restriction-modification DNA methyltransferase M.EcoR124I in complex with DNA

Recent publication of crystal structures for the putative DNA-binding subunits (HsdS) of the functionally uncharacterized Type I restriction–modification (R-M) enzymes MjaXIP and MgeORF438 have provided a convenient structural template for analysis of the more extensively characterized members of this interesting family of multisubunit molecular motors. Here, we present a structural model of the Type IC M.EcoR124I DNA methyltransferase (MTase), comprising the HsdS subunit, two HsdM subunits, the cofactor AdoMet and the substrate DNA molecule. The structure was obtained by docking models of individual subunits generated by fold-recognition and comparative modelling, followed by optimization of inter-subunit contacts by energy minimization. The model of M.EcoR124I has allowed identification of a number of functionally important residues that appear to be involved in DNA-binding. In addition, we have mapped onto the model the location of several new mutations of the hsdS gene of M.EcoR124I that were produced by misincorporation mutagenesis within the central conserved region of hsdS, we have mapped all previously identified DNA-binding mutants of TRD2 and produced a detailed analysis of the location of surface-modifiable lysines. The model structure, together with location of the mutant residues, provides a better background on which to study protein–protein and protein–DNA interactions in Type I R-M systems.     

Escherichia coli rpoA mutation which impairs transcription of positively regulated systems

The rpoA341 (phs) mutation of Escherichia coli results in decreased expression of several positively regulated operons and has been mapped to within or very near the rpoA gene encoding the alpha subunit of RNA polymerase. We have shown that plasmid-directed synthesis of the wild-type alpha subunit can complement the defective phenotypes associated with this mutation consistent with its proposed location within rpoA. This mutation was mapped by marker rescue to within a 182bp region near the 3' end of rpoA and was subsequently transferred to a plasmid by recombination in vivo. DNA sequence analysis revealed that the RpoA341 phenotype was the result of the substitution of lysine 271 by glutamate within the alpha polypeptide. We discuss this result in relation to our current understanding of the functional organization of the alpha subunit.