Nucleoside triphosphate-dependent restriction enzymes

The known nucleoside triphosphate-dependent restriction enzymes are hetero-oligomeric proteins that behave as molecular machines in response to their target sequences. They translocate DNA in a process dependent on the hydrolysis of a nucleoside triphosphate. For the ATP-dependent type I and type III restriction and modification systems, the collision of translocating complexes triggers hydrolysis of phosphodiester bonds in unmodified DNA to generate double-strand breaks. Type I endonucleases break the DNA at unspecified sequences remote from the target sequence, type III endonucleases at a fixed position close to the target sequence. Type I and type III restriction and modification (R-M) systems are notable for effective post-translational control of their endonuclease activity. For some type I enzymes, this control is mediated by proteolytic degradation of that subunit of the complex which is essential for DNA translocation and breakage. This control, lacking in the well-studied type II R-M systems, provides extraordinarily effective protection of resident DNA should it acquire unmodified target sequences. The only well-documented GTP-dependent restriction enzyme, McrBC, requires methylated target sequences for the initiation of phosphodiester bond cleavage.     

Plasmid-encoded antirestriction protein ArdA can discriminate between type I methyltransferase and complete restriction-modification system

Many promiscuous plasmids encode the antirestriction proteins ArdA (alleviation of restriction of DNA) that specifically affect the restriction activity of heterooligomeric type I restriction-modification (R-M) systems in Escherichia coli cells. In addition, a lot of the putative ardA genes encoded by plasmids and bacterial chromosomes are found as a result of sequencing of complete genomic sequences, suggesting that ArdA proteins and type I R-M systems that seem to be widespread among bacteria may be involved in the regulation of gene transfer among bacterial genomes. Here, the mechanism of antirestriction action of ArdA encoded by IncI plasmid ColIb-P9 has been investigated in comparison with that of well-studied T7 phage-encoded antirestriction protein Ocr using the mutational analysis, retardation assay and His-tag affinity chromatography. Like Ocr, ArdA protein was shown to be able to efficiently interact with EcoKI R-M complex and affect its in vivo and in vitro restriction activity by preventing its interaction with specific DNA. However, unlike Ocr, ArdA protein has a low binding affinity to EcoKI Mtase and the additional C-terminal tail region (VF-motif) is needed for ArdA to efficiently interact with the type I R-M enzymes. It seems likely that this ArdA feature is a basis for its ability to discriminate between activities of EcoKI Mtase (modification) and complete R-M system (restriction) which may interact with unmodified DNA in the cells independently. These findings suggest that ArdA may provide a very effective and delicate control for the restriction and modification activities of type I systems and its ability to discriminate against DNA restriction in favour of the specific modification of DNA may give some advantage for efficient transmission of the ardA-encoding promiscuous plasmids among different bacterial populations.     

New restriction enzymes discovered from Escherichia coli clinical strains using a plasmid transformation method

The presence of restriction enzymes in bacterial cells has been predicted by either classical phage restriction-modification (R-M) tests, direct in vitro enzyme assays or more recently from bacterial genome sequence analysis. We have applied phage R-M test principles to the transformation of plasmid DNA and established a plasmid R-M test. To validate this test, six plasmids that contain BamHI fragments of phage lambda DNA were constructed and transformed into Escherichia coli strains containing known R-M systems including: type I (EcoBI, EcoAI, Eco124I), type II (HindIII) and type III (EcoP1I). Plasmid DNA with a single recognition site showed a reduction of relative efficiency of transformation (EOT = 10(-1)-10(-2)). When multiple recognition sites were present, greater reductions in EOT values were observed. Once established in the cell, the plasmids were subjected to modification (EOT = 1.0). We applied this test to screen E.coli clinical strains and detected the presence of restriction enzymes in 93% (14/15) of cells. Using additional subclones and the computer program, RM Search, we identified four new restriction enzymes, Eco377I, Eco585I, Eco646I and Eco777I, along with their recognition sequences, GGA(8N)ATGC, GCC(6N)TGCG, CCA(7N)CTTC, and GGA(6N)TATC, respectively. Eco1158I, an isoschizomer of EcoBI, was also found in this study.     

A residue of motif III positions the helicase domains of motor subunit HsdR in restriction-modification enzyme EcoR124I

Type I restriction-modification enzymes differ significantly from the type II enzymes commonly used as molecular biology reagents. On hemi-methylated DNAs type I enzymes like the EcoR124I restriction-modification complex act as conventional adenine methylases at their specific target sequences, but unmethylated targets induce them to translocate thousands of base pairs through the stationary enzyme before cleaving distant sites nonspecifically. EcoR124I is a superfamily 2 DEAD-box helicase like eukaryotic double-strand DNA translocase Rad54, with two RecA-like helicase domains and seven characteristic sequence motifs that are implicated in translocation. In Rad54 a so-called extended region adjacent to motif III is involved in ATPase activity. Although the EcoR124I extended region bears sequence and structural similarities with Rad54, it does not influence ATPase or restriction activity as shown in this work, but mutagenesis of the conserved glycine residue of its motif III does alter ATPase and DNA cleavage activity. Through the lens of molecular dynamics, a full model of HsdR of EcoR124I based on available crystal structures allowed interpretation of functional effects of mutants in motif III and its extended region. The results indicate that the conserved glycine residue of motif III has a role in positioning the two helicase domains.     

Temporal dynamics of methyltransferase and restriction endonuclease accumulation in individual cells after introducing a restriction-modification system

Type II restriction-modification (R-M) systems encode a restriction endonuclease that cleaves DNA at specific sites, and a methyltransferase that modifies same sites protecting them from restriction endonuclease cleavage. Type II R-M systems benefit bacteria by protecting them from bacteriophages. Many type II R-M systems are plasmid-based and thus capable of horizontal transfer. Upon the entry of such plasmids into a naïve host with unmodified genomic recognition sites, methyltransferase should be synthesized first and given sufficient time to methylate recognition sites in the bacterial genome before the toxic restriction endonuclease activity appears. Here, we directly demonstrate a delay in restriction endonuclease synthesis after transformation of Escherichia coli cells with a plasmid carrying the Esp1396I type II R-M system, using single-cell microscopy. We further demonstrate that before the appearance of the Esp1396I restriction endonuclease the intracellular concentration of Esp1396I methyltransferase undergoes a sharp peak, which should allow rapid methylation of host genome recognition sites. A mathematical model that satisfactorily describes the observed dynamics of both Esp1396I enzymes is presented. The results reported here were obtained using a functional Esp1396I type II R-M system encoding both enzymes fused to fluorescent proteins. Similar approaches should be applicable to the studies of other R-M systems at single-cell level.     

Quick identification of Type I restriction enzyme isoschizomers using newly developed pTypeI and reference plasmids

Although DNA-recognition sequences are among the most important characteristics of restriction enzymes and their corresponding methylases, determination of the recognition sequence of a Type-I restriction enzyme is a complicated procedure. To facilitate this process we have previously developed plasmid R-M tests and the computer program RM search. To specifically identify Type-I isoschizomers, we engineered a pUC19 derivative plasmid, pTypeI, which contains all of the 27 Type-I recognition sequences in a 248-bp DNA fragment. Furthermore, a series of 27 plasmids (designated 'reference plasmids'), each containing a unique Type-I recognition sequence, were also constructed using pMECA, a derivative of pUC vectors. In this study, we tried those vectors on 108 clinical E. coli strains and found that 48 strains produced isoschizomers of Type I enzymes. A detailed study of 26 strains using these 'reference plasmids' revealed that they produce seven different isoschizomers of the prototypes: EcoAI, EcoBI, EcoKI, Eco377I, Eco646I, Eco777I and Eco826I. One strain EC1344 produces two Type I enzymes (EcoKI and Eco377I).     

The specificity of sty SKI, a type I restriction enzyme, implies a structure with rotational symmetry.

The type I restriction and modification (R-M) enzyme from Salmonella enterica serovar kaduna ( Sty SKI) recognises the DNA sequence 5'-CGAT(N)7GTTA, an unusual target for a type I R-M system in that it comprises two tetranucleotide components. The amino target recognition domain (TRD) of Sty SKI recognises 5'-CGAT and shows 36% amino acid identity with the carboxy TRD of Eco R124I which recognises the complementary, but degenerate, sequence 5'-RTCG. Current models predict that the amino and carboxy TRDs of the specificity subunit are in inverted orientations within a structure with 2-fold rotational symmetry. The complementary target sequences recognised by the amino TRD of Sty SKI and the carboxy TRD of Eco R124I are consistent with the predicted inverted positions of the TRDs. Amino TRDs of similar amino acid sequence have been shown to recognise the same nucleotide sequence. The similarity reported here, the first example of one between amino and carboxy TRDs, while consistent with a conserved mechanism of target recognition, offers additional flexibility in the evolution of sequence specificity by increasing the potential diversity of DNA targets for a given number of TRDs. Sty SKI identifies the first member of the IB family in Salmonella species.     

Type I restriction endonucleases are true catalytic enzymes

Type I restriction endonucleases are intriguing, multifunctional complexes that restrict DNA randomly, at sites distant from the target sequence. Restriction at distant sites is facilitated by ATP hydrolysis-dependent, translocation of double-stranded DNA towards the stationary enzyme bound at the recognition sequence. Following restriction, the enzymes are thought to remain associated with the DNA at the target site, hydrolyzing copious amounts of ATP. As a result, for the past 35 years type I restriction endonucleases could only be loosely classified as enzymes since they functioned stoichiometrically relative to DNA. To further understand enzyme mechanism, a detailed analysis of DNA cleavage by the EcoR124I holoenzyme was done. We demonstrate for the first time that type I restriction endonucleases are not stoichiometric but are instead catalytic with respect to DNA. Further, the mechanism involves formation of a dimer of holoenzymes, with each monomer bound to a target sequence and, following cleavage, each dissociates in an intact form to bind and restrict subsequent DNA molecules. Therefore, type I restriction endonucleases, like their type II counterparts, are true enzymes. The conclusion that type I restriction enzymes are catalytic relative to DNA has important implications for the in vivo function of these previously enigmatic enzymes.     

Characterization of AloI, a restriction-modification system of a new type.

We report the properties of the new AloI restriction and modification enzyme from Acinetobacter lwoffi Ks 4-8 that recognizes the DNA target 5' GGA(N)6GTTC3' (complementary strand 5' GAAC(N)6TCC3'), and the nucleotide sequence of the gene encoding this enzyme. AloI is a bifunctional large polypeptide (deduced M(r) 143 kDa) revealing both DNA endonuclease and methyltransferase activities. Depending on reaction cofactors, AloI cleaves double-stranded DNA on both strands, seven bases on the 5' side, and 12-13 bases on the 3' side of its recognition sequence, and modifies adenine residues in both DNA strands in the target sequence yielding N6-methyladenine. For cleavage activity AloI maintains an absolute requirement for Mg(2+) and does not depend on or is stimulated by either ATP or S-adenosyl-L-methionine. Modification function requires the presence of S-adenosyl-L-methionine and is stimulated by metal ions (Ca(2+)). The C-terminal and central parts of the protein were found to be homologous to certain specificity (HsdS) and modification (HsdM) subunits of type I R-M systems, respectively. The N-terminal part of the protein possesses the putative endonucleolytic motif DXnEXK of restriction endonucleases. The deduced amino acid sequence of AloI shares significant homology with polypeptides encoding HaeIV and CjeI restriction-modification proteins at the N-terminal and central, but not at the C-terminal domains. The organization of AloI implies that its evolution involved fusion of an endonuclease and the two subunits, HsdM and HsdS, of type I restriction enzymes. According to the structure and function properties AloI may be regarded as one more representative of a newly emerging group of HaeIV-like restriction endonucleases. Discovery of these enzymes opens new opportunities for constructing restriction endonucleases with a new specificity.     

MmeI: a minimal Type II restriction-modification system that only modifies one DNA strand for host protection

MmeI is an unusual Type II restriction enzyme that is useful for generating long sequence tags. We have cloned the MmeI restriction-modification (R-M) system and found it to consist of a single protein having both endonuclease and DNA methyltransferase activities. The protein comprises an amino-terminal endonuclease domain, a central DNA methyltransferase domain and C-terminal DNA recognition domain. The endonuclease cuts the two DNA strands at one site simultaneously, with enzyme bound at two sites interacting to accomplish scission. Cleavage occurs more rapidly than methyl transfer on unmodified DNA. MmeI modifies only the adenine in the top strand, 5′-TCCRAC-3′. MmeI endonuclease activity is blocked by this top strand adenine methylation and is unaffected by methylation of the adenine in the complementary strand, 5′-GTYGGA-3′. There is no additional DNA modification associated with the MmeI R-M system, as is required for previously characterized Type IIG R-M systems. The MmeI R-M system thus uses modification on only one of the two DNA strands for host protection. The MmeI architecture represents a minimal approach to assembling a restriction-modification system wherein a single DNA recognition domain targets both the endonuclease and DNA methyltransferase activities.     

Regulation of a restriction and modification system via DNA inversion in Mycoplasma pulmonis

An invertible DNA element of 6.8 kb, designated the hsd1 locus, was identified in the chromosome of Mycoplasma pulmonis. Infection of host cells with mycoplasma virus P1 revealed that the organism's restriction and modification (R-M) properties are controlled by inversion of hsd1. The nucleotide sequence of hsd1 revealed several genes, the predicted amino acids of which bear striking similarity to the subunits of the type I R-M enzymes previously found only in enteric bacteria.     

Single amino acid substitutions in the HsdR subunit of the type IB restriction enzyme EcoAI uncouple the DNA translocation and DNA cleavage activities of the enzyme.

Type I restriction enzymes bind to specific DNA sequences but subsequently translocate non-specific DNA past the complex in a reaction coupled to ATP hydrolysis and cleave DNA at any barrier that can halt the translocation process. The restriction subunit of these enzymes, HsdR, contains a cluster of seven amino acid sequence motifs typical of helicase superfamily II, that are believed to be relevant to the ATP-dependent DNA translocation. Alignment of all available HsdR sequences reveals an additional conserved region at the protein N-terminus with a consensus sequence reminiscent of the P-D.(D/E)-X-K catalytic motif of many type II restriction enzymes. To investigate the role of these conserved residues, we have produced mutants of the type IB restriction enzyme Eco AI. We have found that single alanine substitutions at Asp-61, Glu-76 and Lys-78 residues of the HsdR subunit abolished the enzyme's restriction activity but had no effect on its ATPase and DNA translocation activities, suggesting that these residues are part of the active site for DNA cleavage.     

A prediction of the amino acids and structures involved in DNA recognition by type I DNA restriction and modification enzymes.

The S subunits of type I DNA restriction/modification enzymes are responsible for recognising the DNA target sequence for the enzyme. They contain two domains of approximately 150 amino acids, each of which is responsible for recognising one half of the bipartite asymmetric target. In the absence of any known tertiary structure for type I enzymes or recognisable DNA recognition motifs in the highly variable amino acid sequences of the S subunits, it has previously not been possible to predict which amino acids are responsible for sequence recognition. Using a combination of sequence alignment and secondary structure prediction methods to analyse the sequences of S subunits, we predict that all of the 51 known target recognition domains (TRDs) have the same tertiary structure. Furthermore, this structure is similar to the structure of the TRD of the C5-cytosine methyltransferase, Hha I, which recognises its DNA target via interactions with two short polypeptide loops and a beta strand. Our results predict the location of these sequence recognition structures within the TRDs of all type I S subunits.     

Restriction by EcoKI is enhanced by co-operative interactions between target sequences and is dependent on DEAD box motifs.

One subunit of both type I and type III restriction and modification enzymes contains motifs characteristic of DEAD box proteins, which implies that these enzymes may be DNA helicases. This subunit is essential for restriction, but not modification. The current model for restriction by both types of enzyme postulates that DNA cutting is stimulated when two enzyme complexes bound to neighbouring target sequences meet as the consequence of ATP-dependent DNA translocation. For type I enzymes, this model is supported by in vitro experiments, but the predicted co-operative interactions between targets have not been detected by assays that monitor restriction in vivo. The experiments reported here clearly establish the required synergistic effect but, in contrast to earlier experiments, they use Escherichia coli K-12 strains deficient in the restriction alleviation function associated with the Rac prophage. In bacteria with elevated levels of EcoKI the co-operative interactions are obscured, consistent with co-operation between free enzyme and that bound at target sites. We have made changes in three of the motifs characteristic of DEAD box proteins, including motif III, which in RecG is implicated in the migration of Holliday junctions. Conservative changes in each of the three motifs impair restriction.     

Different restriction and modification phenotypes in ruminal lactate-utilizing bacteria

Analysis of restriction and modification activities in lactate-utilizing bacteria belonging to the Megasphaera elsdenii and Mitsuokella multiacida species revealed the presence of GATC-specific, MboI isospecific, restriction-modification (R-M) systems in all strains tested. While restriction endonucleases isolated from M. elsdenii strains were found to be sensitive to Dam methylation, enzymes from M. multiacida cleaved DNA irrespective of Dam methylation. The comparison of type II R-M systems specificities in three closely related lactate-utilizing ruminal bacterial species indicated complete lack of restriction and/or modification enzymes previously characterized from Selenomonas ruminantium in tested M. elsdenii and M. multiacida strains. R-M systems are believed to represent the main defense tool against phage infection. Based on the results of our experiments it could be assumed that M. elsdenii and M. multiacida use the different strategy for bacteriophage protection compared to S. ruminantium.     

Initiation of translocation by Type I restriction-modification enzymes is associated with a short DNA extrusion

Recognition of ‘foreign’ DNA by Type I restriction–modification (R-M) enzymes elicits an ATP-dependent switch from methylase to endonuclease activity, which involves DNA translocation by the restriction subunit HsdR. Type I R-M enzymes are composed of three (Hsd) subunits with a stoichiometry of HsdR₂:HsdM₂:HsdS₁ (R₂-complex). However, the EcoR124I R-M enzyme can also exist as a cleavage deficient, sub-assembly of HsdR₁:HsdM₂:HsdS₁ (R₁-complex). ATPγS was used to trap initial translocation complexes, which were visualized by Atomic Force Microscopy (AFM). In the R₁-complex, a small bulge, associated with a shortening in the contour-length of the DNA of 8 nm, was observed. This bulge was found to be sensitive to single-strand DNA nucleases, indicative of non-duplexed DNA. R₂-complexes appeared larger in the AFM images and the DNA contour length showed a shortening of ~11 nm, suggesting that two bulges were formed. Disclosure of the structure of the first stage after the recognition-translocation switch of Type I restriction enzymes forms an important first step in resolving a detailed mechanistic picture of DNA translocation by SF-II DNA translocation motors.     

On the structure and operation of type I DNA restriction enzymes.

Type I DNA restriction enzymes are large, molecular machines possessing DNA methyltransferase, ATPase, DNA translocase and endonuclease activities. The ATPase, DNA translocase and endonuclease activities are specified by the restriction (R) subunit of the enzyme. We demonstrate that the R subunit of the Eco KI type I restriction enzyme comprises several different functional domains. An N-terminal domain contains an amino acid motif identical with that forming the catalytic site in simple restriction endonucleases, and changes within this motif lead to a loss of nuclease activity and abolish the restriction reaction. The central part of the R subunit contains amino acid sequences characteristic of DNA helicases. We demonstrate, using limited proteolysis of this subunit, that the helicase motifs are contained in two domains. Secondary structure prediction of these domains suggests a structure that is the same as the catalytic domains of DNA helicases of known structure. The C-terminal region of the R subunit can be removed by elastase treatment leaving a large fragment, stable in the presence of ATP, which can no longer bind to the other subunits of Eco KI suggesting that this domain is required for protein assembly. Considering these results and previous models of the methyltransferase part of these enzymes, a structural and operational model of a type I DNA restriction enzyme is presented.     

Mutations that confer de novo activity upon a maintenance methyltransferase.

DNA methyltransferases are not only sequence specific in their action, but they also differentiate between the alternative methylation states of a target site. Some methyltransferases are equally active on either unmethylated or hemimethylated DNA and consequently function as de novo methyltransferases. Others are specific for hemimethylated target sequences, consistent with the postulated role of a maintenance methyltransferase in perpetuating a pattern of DNA modification. The molecular basis for the difference between de novo and maintenance methyltransferase activity is unknown, yet fundamental to cellular activities that are affected by different methylation states of the genome. The methyltransferase activity of the type I restriction and modification system, EcoK, is the only known prokaryotic methyltransferase shown to be specific for hemimethylated target sequences. We have isolated mutants of Escherichia coli K-12 which are able to modify unmethylated target sequences efficiently in a manner indicative of de novo methyltransferase activity. Consistent with this change in specificity, some mutations shift the balance between DNA restriction and modification as if both activities now compete at unmethylated targets. Two genes encode the methyltransferase and all the mutations are loosely clustered within one of them.