Subunit assembly and mode of DNA cleavage of the type III restriction endonucleases EcoP1I and EcoP15I

DNA cleavage by type III restriction endonucleases requires two inversely oriented asymmetric recognition sequences and results from ATP-dependent DNA translocation and collision of two enzyme molecules. Here, we characterized the structure and mode of action of the related EcoP1I and EcoP15I enzymes. Analytical ultracentrifugation and gel quantification revealed a common Res(2)Mod(2) subunit stoichiometry. Single alanine substitutions in the putative nuclease active site of ResP1 and ResP15 abolished DNA but not ATP hydrolysis, whilst a substitution in helicase motif VI abolished both activities. Positively supercoiled DNA substrates containing a pair of inversely oriented recognition sites were cleaved inefficiently, whereas the corresponding relaxed and negatively supercoiled substrates were cleaved efficiently, suggesting that DNA overtwisting impedes the convergence of the translocating enzymes. EcoP1I and EcoP15I could co-operate in DNA cleavage on circular substrate containing several EcoP1I sites inversely oriented to a single EcoP15I site; cleavage occurred predominantly at the EcoP15I site. EcoP15I alone showed nicking activity on these molecules, cutting exclusively the top DNA strand at its recognition site. This activity was dependent on enzyme concentration and local DNA sequence. The EcoP1I nuclease mutant greatly stimulated the EcoP15I nicking activity, while the EcoP1I motif VI mutant did not. Moreover, combining an EcoP15I nuclease mutant with wild-type EcoP1I resulted in cutting the bottom DNA strand at the EcoP15I site. These data suggest that double-strand breaks result from top strand cleavage by a Res subunit proximal to the site of cleavage, whilst bottom strand cleavage is catalysed by a Res subunit supplied in trans by the distal endonuclease in the collision complex.     

Type III DNA restriction and modification systems EcoP1 and EcoP15. Nucleotide sequence of the EcoP1 operon, the EcoP15 mod gene and some EcoP1 mod mutants

This paper presents the nucleotide sequence of the mod-res operon of phage P1, which encodes the two structural genes for the EcoP1 type III restriction and modification system. We have also sequenced the mod gene of the allelic EcoP15 system. The mod gene product is responsible for binding the system-specific DNA recognition sequences in both restriction and modification; it also catalyses the modification reaction. A comparison of the two mod gene product sequences shows that they have conserved amino and carboxyl ends but have completely different sequences in the middle of the molecules. Two alleles of the EcoP1 mod gene that are defective in modification but not in restriction were also sequenced. The mutations in both alleles lie within the non-conserved regions.     

Type III restriction endonucleases translocate DNA in a reaction driven by recognition site-specific ATP hydrolysis.

Type III restriction/modification systems recognize short non-palindromic sequences, only one strand of which can be methylated. Replication of type III-modified DNA produces completely unmethylated recognition sites which, according to classical mechanisms of restriction, should be signals for restriction. We have shown previously that suicidal restriction by the type III enzyme EcoP15I is prevented if all the unmodified sites are in the same orientation: restriction by EcoP15I requires a pair of unmethylated, inversely oriented recognition sites. We have now addressed the molecular mechanism of site orientation-specific DNA restriction. EcoP15I is demonstrated to possess an intrinsic ATPase activity, the potential driving force of DNA translocation. The ATPase activity is uniquely recognition site-specific, but EcoP15I-modified sites also support the reaction. EcoP15I DNA restriction patterns are shown to be predetermined by the enzyme-to-site ratio, in that site-saturating enzyme levels elicit cleavage exclusively between the closest pair of head-to-head oriented sites. DNA restriction is blocked by Lac repressor bound in the intervening sequence between the two EcoP15I sites. These results rule out DNA looping and strongly suggest that cleavage is triggered by the close proximity of two convergently tracking EcoP15I-DNA complexes.     

DNA cleavage by type III restriction-modification enzyme EcoP15I is independent of spacer distance between two head to head oriented recognition sites

The type III restriction-modification enzyme EcoP15I requires the interaction of two unmethylated, inversely oriented recognition sites 5'-CAGCAG in head to head configuration to allow an efficient DNA cleavage. It has been hypothesized that two convergent DNA-translocating enzyme-substrate complexes interact to form the active cleavage complex and that translocation is driven by ATP hydrolysis. Using a half-automated, fluorescence-based detection method, we investigated how the distance between two inversely oriented recognition sites affects DNA cleavage efficiency. We determined that EcoP15I cleaves DNA efficiently even for two adjacent head to head or tail to tail oriented target sites. Hence, DNA translocation appears not to be required for initiating DNA cleavage in these cases. Furthermore, we report here that EcoP15I is able to cleave single-site substrates. When we analyzed the interaction of EcoP15I with DNA substrates containing adjacent target sites in the presence of non-hydrolyzable ATP analogues, we found that cleavage depended on the hydrolysis of ATP. Moreover, we show that cleavage occurs at only one of the two possible cleavage positions of an interacting pair of target sequences. When EcoP15I bound to a DNA substrate containing one recognition site in the absence of ATP, we observed a 36 nucleotide DNaseI-footprint that is asymmetric on both strands. All of our footprinting experiments showed that the enzyme did not cover the region around the cleavage site. Analyzing a DNA fragment with two head to head oriented recognition sites, EcoP15I protected 27-33 nucleotides around the recognition sequence, including an additional region of 26 bp between both cleavage sites. For all DNA substrates examined, the presence of ATP caused altered footprinting patterns. We assume that the altered patterns are most likely due to a conformational change of the enzyme. Overall, our data further refine the tracking-collision model for type III restriction enzymes.     

Scanning force microscopy of DNA translocation by the Type III restriction enzyme EcoP15I

Type III restriction enzymes are multifunctional heterooligomeric enzymes that cleave DNA at a fixed position downstream of a non-symmetric recognition site. For effective DNA cleavage these restriction enzymes need the presence of two unmethylated, inversely oriented recognition sites in the DNA molecule. DNA cleavage was proposed to result from ATP-dependent DNA translocation, which is expected to induce DNA loop formation, and collision of two enzyme-DNA complexes. We used scanning force microscopy to visualise the protein interaction with linear DNA molecules containing two EcoP15I recognition sites in inverse orientation. In the presence of the cofactors ATP and Mg(2+), EcoP15I molecules were shown to bind specifically to the recognition sites and to form DNA loop structures. One of the origins of the protein-clipped DNA loops was shown to be located at an EcoP15I recognition site, the other origin had an unspecific position in between the two EcoP15I recognition sites. The data demonstrate for the first time DNA translocation by the Type III restriction enzyme EcoP15I using scanning force microscopy. Moreover, our study revealed differences in the DNA-translocation processes mediated by Type I and Type III restriction enzymes.     

Characterization of mutations of the bacteriophage P1 mod gene encoding the recognition subunit of the EcoP1 restriction and modification system.

This study characterized several mutations of the bacteriophage P1 mod gene. This gene codes for the subunit of the EcoP1 restriction enzyme that is responsible for DNA sequence recognition and for modification methylation. We cloned the mutant mod genes into expression vectors and purified the mutant proteins to near homogeneity. Two of the mutant mod genes studied were the c2 clear-plaque mutants described by Scott (Virology 41:66-71, 1970). These mutant proteins can recognize EcoP1 sites in DNA and direct restriction but are unable to modify DNA. Methylation assays as well as S-adenosylmethionine (SAM) binding studies showed that the c2 mutants are methylation deficient because they do not bind SAM, and we conclude that the mutations destroy the SAM-binding site. Both of the c2 mutations lie within a region of the EcoP1 mod gene that is not conserved when compared with the mod gene of the related EcoP15 system. EcoP15 and EcoP1 recognize different DNA sequences, and we believe that this region of the protein may code for the DNA-binding site of the enzyme. The other mutants characterized were made by site-directed mutagenesis at codon 240. Evidence is presented that one of them, Ser-240----Pro, simultaneously lost the capacity to bind SAM and may also have changed its DNA sequence specificity.     

Single-stranded DNA binding and methylation by EcoP1I DNA methyltransferase

EcoP1I methyltransferase (M.EcoP1I) belongs to the type III restriction-modification system encoded by prophage P1 that infects Escherichia coli. Binding of M.EcoP1I to double-stranded DNA and single-stranded DNA has been characterized. Binding to both single- and double-stranded DNA could be competed out by unlabeled single-stranded DNA. Metal ions did not influence DNA binding. Interestingly, M.EcoP1I was able to methylate single-stranded DNA. Kinetic parameters were determined for single- and double-stranded DNA methylation. This feature of the enzyme probably functions in protecting the phage genome from restriction by type III restriction enzymes and thus could be considered as an anti-restriction system. This study describing in vitro methylation of single-stranded DNA by the type III methyltransferase EcoP1I allows understanding of the mechanism of action of these enzymes and also their role in the biology of single-stranded phages.     

Avoidance of DNA methylation. A virus-encoded methylase inhibitor and evidence for counterselection of methylase recognition sites in viral genomes

The ocr+ gene of bacterial virus T7 codes for the first protein recognized to inhibit a specific group of DNA methylases. The recognition sequences of several other DNA methylases, not susceptible to Ocr inhibition, are significantly suppressed in the virus genome. The bacterial virus T3 encodes an Ado-Met hydrolase, destroying the methyl donor and causing T3 DNA to be totally unmethylated. These observations could stimulate analogous investigations into the regulation of DNA methylation patterns of eukaryotic viruses and cells. For instance, an underrepresentation of methylation sites (5'-CG) is also true for animal DNA viruses. Moreover, we were able to disclose some novel properties of DNA restriction-modification enzymes concerning the protection of DNA recognition sequences in which only one strand can be methylated (e.g., type III enzyme EcoP15) and the primary resistance of (unmethylated) DNA recognition sites towards type II restriction endonuclease EcoRII.     

A mutation in the Mod subunit of EcoP15I restriction enzyme converts the DNA methyltransferase to a site-specific endonuclease

A closer inspection of the amino acid sequence of EcoP15I DNA methyltransferase revealed a region of similarity to the PDXn(D/E)XK catalytic site of type II restriction endonucleases, except for methionine in EcoP15I DNA methyltransferase instead of proline. Substitution of methionine at position 357 by proline converts EcoP15I DNA methyltransferase to a site-specific endonuclease. EcoP15I-M357P DNA methyltransferase specifically binds to the recognition sequence 5'-CAGCAG-3' and cleaves DNA asymmetrically EcoP151-M357P.DNA methyltransferase specifically binds to the recognition sequence 5'-CAGCAG-3' and cleaves DNA asymmetrically, 5'-CAGCAG(N)(10)-3', as indicated by the arrows, in presence of magnesium ions.     

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.     

S-adenosyl methionine prevents promiscuous DNA cleavage by the EcoP1I type III restriction enzyme

DNA cleavage by the type III restriction endonuclease EcoP1I was analysed on circular and catenane DNA in a variety of buffers with different salts. In the presence of the cofactor S-adenosyl methionine (AdoMet), and irrespective of buffer, only substrates with two EcoP1I sites in inverted repeat were susceptible to cleavage. Maximal activity was achieved at a Res2Mod2 to site ratio of approximately 1:1 yet resulted in cleavage at only one of the two sites. In contrast, the outcome of reactions in the absence of AdoMet was dependent upon the identity of the monovalent buffer components, in particular the identity of the cation. With Na+, cleavage was observed only on substrates with two sites in inverted repeat at elevated enzyme to site ratios (>15:1). However, with K+ every substrate tested was susceptible to cleavage above an enzyme to site ratio of approximately 3:1, including a DNA molecule with two directly repeated sites and even a DNA molecule with a single site. Above an enzyme to site ratio of 2:1, substrates with two sites in inverted repeat were cleaved at both cognate sites. The rates of cleavage suggested two separate events: a fast primary reaction for the first cleavage of a pair of inverted sites; and an order-of-magnitude slower secondary reaction for the second cleavage of the pair or for the first cleavage of all other site combinations. EcoP1I enzymes mutated in either the ATPase or nuclease motifs did not produce the secondary cleavage reactions. Thus, AdoMet appears to play a dual role in type III endonuclease reactions: Firstly, as an allosteric activator, promoting DNA association; and secondly, as a "specificity factor", ensuring that cleavage occurs only when two endonucleases bind two recognition sites in a designated orientation. However, given the right conditions, AdoMet is not strictly required for DNA cleavage by a type III enzyme.     

Functional consequences of mutating conserved SF2 helicase motifs in the Type III restriction endonuclease EcoP15I translocase domain

For efficient DNA hydrolysis, Type III restriction endonuclease EcoP15I interacts with two inversely oriented recognition sites in an ATP-dependent process. EcoP15I consists of two methylation (Mod) subunits and a single restriction (Res) subunit yielding a multifunctional enzyme complex able to methylate or to hydrolyse DNA. Comprehensive sequence alignments, limited proteolysis and mass spectroscopy suggested that the Res subunit is a fusion of a motor or translocase (Tr) domain of superfamily II helicases and an endonuclease domain with a catalytic PD…EXK motif. In the Tr domain, seven predicted helicase motifs (I, Ia, II–VI), a recently discovered Q-tip motif and three additional regions (IIIa, IVa, Va) conserved among Type III restriction enzymes have been identified that are predicted to be involved in DNA binding and ATP hydrolysis. Because DNA unwinding activity for EcoP15I (as for bona fide helicases) has never been found and EcoP15I ATPase rates are only low, the functional importance of the helicase motifs and regions was questionable and has never been probed systematically. Therefore, we mutated all helicase motifs and conserved regions predicted in Type III restriction enzyme EcoP15I and examined the functional consequences on EcoP15I enzyme activity and the structural integrity of the variants by CD spectroscopy. The resulting eleven enzyme variants all, except variant IVa, are properly folded showing the same secondary structure distribution as the wild-type enzyme. Classical helicase motifs I–VI are important for ATP and DNA cleavage by EcoP15I and mutations therein led to complete loss of ATPase and cleavage activity. Among the catalytically inactive enzyme variants three preserved the ability to bind ATP. In contrast, newly assigned motifs Q-tip, Ia and Va are not essential for EcoP15I activity and the corresponding enzyme variants were still catalytically active. DNA binding was only marginally reduced (2–7 fold) in all enzyme variants tested.     

Characterization of the Type III restriction endonuclease PstII from Providencia stuartii

A new Type III restriction endonuclease designated PstII has been purified from Providencia stuartii. PstII recognizes the hexanucleotide sequence 5′-CTGATG(N)_25-26/27-28-3′. Endonuclease activity requires a substrate with two copies of the recognition site in head-to-head repeat and is dependent on a low level of ATP hydrolysis (~40 ATP/site/min). Cleavage occurs at just one of the two sites and results in a staggered cut 25–26 nt downstream of the top strand sequence to generate a two base 5′-protruding end. Methylation of the site occurs on one strand only at the first adenine of 5′-CATCAG-3′. Therefore, PstII has characteristic Type III restriction enzyme activity as exemplified by EcoPI or EcoP15I. Moreover, sequence asymmetry of the PstII recognition site in the T7 genome acts as an historical imprint of Type III restriction activity in vivo. In contrast to other Type I and III enzymes, PstII has a more relaxed nucleotide specificity and can cut DNA with GTP and CTP (but not UTP). We also demonstrate that PstII and EcoP15I cannot interact and cleave a DNA substrate suggesting that Type III enzymes must make specific protein–protein contacts to activate endonuclease activity.     

DNA looping and translocation provide an optimal cleavage mechanism for the type III restriction enzymes

EcoP15I is a type III restriction enzyme that requires two recognition sites in a defined orientation separated by up to 3.5 kbp to efficiently cleave DNA. The mechanism through which site-bound EcoP15I enzymes communicate between the two sites is unclear. Here, we use atomic force microscopy to study EcoP15I-DNA pre-cleavage complexes. From the number and size distribution of loops formed, we conclude that the loops observed do not result from translocation, but are instead formed by a contact between site-bound EcoP15I and a nonspecific region of DNA. This conclusion is confirmed by a theoretical polymer model. It is further shown that translocation must play some role, because when translocation is blocked by a Lac repressor protein, DNA cleavage is similarly blocked. On the basis of these results, we present a model for restriction by type III restriction enzymes and highlight the similarities between this and other classes of restriction enzymes.     

Unidirectional translocation from recognition site and a necessary interaction with DNA end for cleavage by Type III restriction enzyme

Type III restriction enzymes have been demonstrated to require two unmethylated asymmetric recognition sites oriented head-to-head to elicit double-strand break 25–27 bp downstream of one of the two sites. The proposed DNA cleavage mechanism involves ATP-dependent DNA translocation. The sequence context of the recognition site was suggested to influence the site of DNA cleavage by the enzyme. In this investigation, we demonstrate that the cleavage site of the R.EcoP15I restriction enzyme does not depend on the sequence context of the recognition site. Strikingly, this study demonstrates that the enzyme can cleave linear DNA having either recognition sites in the same orientation or a single recognition site. Cleavage occurs predominantly at a site proximal to the DNA end in the case of multiple site substrates. Such cleavage can be abolished by the binding of Lac repressor downstream (3′ side) but not upstream (5′ side) of the recognition site. Binding of HU protein has also been observed to interfere with R.EcoP15I cleavage activity. In accordance with a mechanism requiring two enzyme molecules cooperating to elicit double-strand break on DNA, our results convincingly demonstrate that the enzyme translocates on DNA in a 5′ to 3′ direction from its recognition site and indicate a switch in the direction of enzyme motion at the DNA ends. This study demonstrates a new facet in the mode of action of these restriction enzymes.     

Type III restriction endonuclease EcoP15I is a heterotrimeric complex containing one Res subunit with several DNA-binding regions and ATPase activity

For efficient DNA cleavage, the Type III restriction endonuclease EcoP15I communicates with two inversely oriented recognition sites in an ATP-dependent process. EcoP15I consists of methylation (Mod) and restriction (Res) subunits forming a multifunctional enzyme complex able to methylate or to cleave DNA. In this study, we determined by different analytical methods that EcoP15I contains a single Res subunit in a Mod(2)Res stoichiometry. The Res subunit comprises a translocase (Tr) domain carrying functional motifs of superfamily 2 helicases and an endonuclease domain with a PD..D/EXK motif. We show that the isolated Tr domain retains ATP-hydrolyzing activity and binds single- and double-stranded DNA in a sequence-independent manner. To localize the regions of DNA binding, we screened peptide arrays representing the entire Res sequence for their ability to interact with DNA. We discovered four DNA-binding regions in the Tr domain and two DNA-binding regions in the endonuclease domain. Modelling of the Tr domain shows that these multiple DNA-binding regions are located on the surface, free to interact with DNA. Interestingly, the positions of the DNA-binding regions are conserved among other Type III restriction endonucleases.     

In vivo restriction. Sequence and structure of endonuclease II-dependent cleavage sites in bacteriophage T4 DNA.

Endonuclease II of bacteriophage T4 is required for in vivo restriction of cytosine-containing DNA from its host, Escherichia coli, (as well as from phage mutants lacking cytosine modification), normally the first step in the reutilization of host DNA nucleotides for synthesis of phage DNA in infected cells. The phage cytosine-DNA is fragmented incompletely to yield genetically defined fragments. This restriction is different from that of type I, II, or III restriction enzymes. We have located seven major endonuclease II-dependent restriction sites in the T4 genome, of which three were analyzed in detail; in addition, abundant sites were cleaved in less than or equal to 5% of all molecules. Sites I, II, and III shared the sequence 5'-CCGNNTTGGC-3' and were cleaved in about 25% (I and III) and 65% (II) of all molecules, predominantly staggered around the first or second of the central unspecified base pairs to yield fragments with one 5' base. The less frequently cleaved sites I and III deviated from site II in predicted helical structure when viewed from the consensus strand, and in sequence when viewed from the opposite strand. Thus, interaction with a particular helical structure as well as recognition of the bases in DNA appears important for efficient cleavage.     

Methylation and cleavage sequences of the EcoP1 restriction-modification enzyme.

EcoP1 is a restriction modification enzyme encoded by bacteriophage P1. It requires ATP for cleavage and S-adenosyl methionine for methylation of DNA. We have mapped the sites of both cleavage and methylation in simian virus 40 DNA and determined their sequences. The enzyme methylates the sequence A-G-mA-C-C and cuts the DNA 25 to 27 base-pairs from the site of methylation in the 3′ direction, with a two to four base-pair stagger between cuts. Consistent with the fact that the methylation sequence is asymmetric, the enzyme methylates only one strand in vitro. One variant of simian virus 40 has acquired an additional EcoP1 methylation and cleavage site by changing a A-G-A-A-C sequence to A-G-A-C-C.     

Identification and mutational analysis of Mg2+ binding site in EcoP15I DNA methyltransferase: involvement in target base eversion

EcoP15I DNA methyltransferase catalyzes the transfer of the methyl group of S-adenosyl-l-methionine to the N6 position of the second adenine within the double-stranded DNA sequence 5'-CAGCAG-3'. To achieve catalysis, the enzyme requires a magnesium ion. Binding of magnesium to the enzyme induces significant conformational changes as monitored by circular dichroism spectroscopy. EcoP15I DNA methyltransferase was rapidly inactivated by micromolar concentrations of ferrous sulfate in the presence of ascorbate at pH 8.0. The inactivated enzyme was cleaved into two fragments with molecular masses of 36 and 35 kDa. Using this affinity cleavage assay, we have located the magnesium binding-like motif to amino acids 355-377 of EcoP15I DNA methyltransferase. Sequence homology comparisons between EcoP15I DNA methyltransferase and other restriction endonucleases allowed us to identify a PD(X)n(D/E)XK-like sequence as the putative magnesium ion binding site. Point mutations generated in this region were analyzed for their role in methyltransferase activity, metal coordination, and substrate binding. Although the mutant methyltransferases bind DNA and S-adenosyl-l-methionine as well as the wild-type enzyme does, they are inactive primarily because of their inability to flip the target base. Collectively, these data are consistent with the fact that acidic amino acid residues of the region 355-377 in EcoP15I DNA methyltransferase are important for the critical positioning of magnesium ions for catalysis. This is the first example of metal-dependent function of a DNA methyltransferase. These findings provide impetus for exploring the role(s) of metal ions in the structure and function of DNA methyltransferases.