Recycling of protein subunits during DNA translocation and cleavage by Type I restriction-modification enzymes

The Type I restriction-modification enzymes comprise three protein subunits; HsdS and HsdM that form a methyltransferase (MTase) and HsdR that associates with the MTase and catalyses Adenosine-5'-triphosphate (ATP)-dependent DNA translocation and cleavage. Here, we examine whether the MTase and HsdR components can 'turnover' in vitro, i.e. whether they can catalyse translocation and cleavage events on one DNA molecule, dissociate and then re-bind a second DNA molecule. Translocation termination by both EcoKI and EcoR124I leads to HsdR dissociation from linear DNA but not from circular DNA. Following DNA cleavage, the HsdR subunits appear unable to dissociate even though the DNA is linear, suggesting a tight interaction with the cleaved product. The MTases of EcoKI and EcoAI can dissociate from DNA following either translocation or cleavage and can initiate reactions on new DNA molecules as long as free HsdR molecules are available. In contrast, the MTase of EcoR124I does not turnover and additional cleavage of circular DNA is not observed by inclusion of RecBCD, a helicase-nuclease that degrades the linear DNA product resulting from Type I cleavage. Roles for Type I restriction endonuclease subunit dynamics in restriction alleviation in the cell are discussed.     

Assembly of EcoKI DNA methyltransferase requires the C-terminal region of the HsdM modification subunit

The methyltransferase component of type I DNA restriction and modification systems comprises three subunits, one DNA sequence specificity subunit and two DNA modification subunits. Limited proteolysis of the EcoKI methyltransferase shows that a 55-kDa N-terminal fragment of the 59-kDa modification subunit is resistant to degradation. We have purified this fragment and determined by mass spectrometry that proteolysis removes 43 or 44 amino acids from the C-terminus. The fragment fails to interact with the other subunits even though it still possesses secondary and tertiary structure and the ability to bind the S-adenosylmethionine cofactor. We conclude that the C-terminal region of the modification subunit of EcoKI is essential for the assembly of the EcoKI methyltransferase.     

Removal of a frameshift between the hsdM and hsdS genes of the EcoKI Type IA DNA restriction and modification system produces a new type of system and links the different families of Type I systems

The EcoKI DNA methyltransferase is a trimeric protein comprised of two modification subunits (M) and one sequence specificity subunit (S). This enzyme forms the core of the EcoKI restriction/modification (RM) enzyme. The 3′ end of the gene encoding the M subunit overlaps by 1 nt the start of the gene for the S subunit. Translation from the two different open reading frames is translationally coupled. Mutagenesis to remove the frameshift and fuse the two subunits together produces a functional RM enzyme in vivo with the same properties as the natural EcoKI system. The fusion protein can be purified and forms an active restriction enzyme upon addition of restriction subunits and of additional M subunit. The Type I RM systems are grouped into families, IA to IE, defined by complementation, hybridization and sequence similarity. The fusion protein forms an evolutionary intermediate form lying between the Type IA family of RM enzymes and the Type IB family of RM enzymes which have the frameshift located at a different part of the gene sequence.     

The structure of M.EcoKI Type I DNA methyltransferase with a DNA mimic antirestriction protein

Type-I DNA restriction–modification (R/M) systems are important agents in limiting the transmission of mobile genetic elements responsible for spreading bacterial resistance to antibiotics. EcoKI, a Type I R/M enzyme from Escherichia coli, acts by methylation- and sequence-specific recognition, leading to either methylation of DNA or translocation and cutting at a random site, often hundreds of base pairs away. Consisting of one specificity subunit, two modification subunits, and two DNA translocase/endonuclease subunits, EcoKI is inhibited by the T7 phage antirestriction protein ocr, a DNA mimic. We present a 3D density map generated by negative-stain electron microscopy and single particle analysis of the central core of the restriction complex, the M.EcoKI M₂S₁ methyltransferase, bound to ocr. We also present complete atomic models of M.EcoKI in complex with ocr and its cognate DNA giving a clear picture of the overall clamp-like operation of the enzyme. The model is consistent with a large body of experimental data on EcoKI published over 40 years.     

Roles of PriA protein and double-strand DNA break repair functions in UV-induced restriction alleviation in Escherichia coli

It has been widely considered that DNA modification protects the chromosome of bacteria E. coli K-12 against their own restriction-modification systems. Chromosomal DNA is protected from degradation by methylation of target sequences. However, when unmethylated target sequences are generated in the host chromosome, the endonuclease activity of the EcoKI restriction-modification enzyme is inactivated by the ClpXP protease and DNA is protected. This process is known as restriction alleviation (RA) and it can be induced by UV irradiation (UV-induced RA). It has been proposed that chromosomal unmethylated target sequences, a signal for the cell to protect its own DNA, can be generated by homologous recombination during the repair of damaged DNA. In this study, we wanted to further investigate the genetic requirements for recombination proteins involved in the generation of unmethylated target sequences. For this purpose, we monitored the alleviation of EcoKI restriction by measuring the survival of unmodified lambda in UV-irradiated cells. Our genetic analysis showed that UV-induced RA is dependent on the excision repair protein UvrA, the RecA-loading activity of the RecBCD enzyme, and the primosome assembly activity of the PriA helicase and is partially dependent on RecFOR proteins. On the basis of our results, we propose that unmethylated target sequences are generated at the D-loop by the strand exchange of two hemi-methylated duplex DNAs and subsequent initiation of DNA replication.     

Tracking EcoKI and DNA fifty years on: a golden story full of surprises

1953 was a historical year for biology, as it marked the birth of the DNA helix, but also a report by Bertani and Weigle on ‘a barrier to infection’ of bacteriophage λ in its natural host, Escherichia coli K-12, that could be lifted by ‘host-controlled variation’ of the virus. This paper lay dormant till Nobel laureate Arber and PhD student Dussoix showed that the λ DNA was rejected and degraded upon infection of different bacterial hosts, unless it carried host-specific modification of that DNA, thus laying the foundations for the phenomenon of restriction and modification (R-M). The restriction enzyme of E.coli K-12, EcoKI, was purified in 1968 and required S-adenosylmethionine (AdoMet) and ATP as cofactors. By the end of the decade there was substantial evidence for a chromosomal locus hsdK with three genes encoding restriction (R), modification (M) and specificity (S) subunits that assembled into a large complex of >400 kDa. The 1970s brought the message that EcoKI cut away from its DNA recognition target, to which site the enzyme remained bound while translocating the DNA past itself, with concomitant ATP hydrolysis and subsequent double-strand nicks. This translocation event created clearly visible DNA loops in the electron microscope. EcoKI became the archetypal Type I R-M enzyme with curious DNA translocating properties reminiscent of helicases, recognizing the bipartite asymmetric site AAC(N6)GTGC. Cloning of the hsdK locus in 1976 facilitated molecular understanding of this sophisticated R-M complex and in an elegant ‘pas de deux’ Murray and Dryden constructed the present model based on a large body of experimental data plus bioinformatics. This review celebrates the golden anniversary of EcoKI and ends with the exciting progress on the vital issue of restriction alleviation after DNA damage, also first reported in 1953, which involves intricate control of R subunit activity by the bacterial proteasome ClpXP, important results that will keep scientists on the EcoKI track for another 50 years to come.     

Alleviation of restriction by DNA condensation and non-specific DNA binding ligands

During conditions of cell stress, the type I restriction and modification enzymes of bacteria show reduced, but not zero, levels of restriction of unmethylated foreign DNA. In such conditions, chemically identical unmethylated recognition sequences also occur on the chromosome of the host but restriction alleviation prevents the enzymes from destroying the host DNA. How is this distinction between chemically identical DNA molecules achieved? For some, but not all, type I restriction enzymes, alleviation is partially due to proteolytic degradation of a subunit of the enzyme. We identify that the additional alleviation factor is attributable to the structural difference between foreign DNA entering the cell as a random coil and host DNA, which exists in a condensed nucleoid structure coated with many non-specific ligands. The type I restriction enzyme is able to destroy the ‘naked’ DNA using a complex reaction linked to DNA translocation, but this essential translocation process is inhibited by DNA condensation and the presence of non-specific ligands bound along the DNA.     

On the DNA cleavage mechanism of Type I restriction enzymes

Although the DNA cleavage mechanism of Type I restriction–modification enzymes has been extensively studied, the mode of cleavage remains elusive. In this work, DNA ends produced by EcoKI, EcoAI and EcoR124I, members of the Type IA, IB and IC families, respectively, have been characterized by cloning and sequencing restriction products from the reactions with a plasmid DNA substrate containing a single recognition site for each enzyme. Here, we show that all three enzymes cut this substrate randomly with no preference for a particular base composition surrounding the cleavage site, producing both 5′- and 3′-overhangs of varying lengths. EcoAI preferentially generated 3′-overhangs of 2–3 nt, whereas EcoKI and EcoR124I displayed some preference for the formation of 5′-overhangs of a length of ~6–7 and 3–5 nt, respectively. A mutant EcoAI endonuclease assembled from wild-type and nuclease-deficient restriction subunits generated a high proportion of nicked circular DNA, whereas the wild-type enzyme catalyzed efficient cleavage of both DNA strands. We conclude that Type I restriction enzymes require two restriction subunits to introduce DNA double-strand breaks, each providing one catalytic center for phosphodiester bond hydrolysis. Possible models for DNA cleavage are discussed.     

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.     

The type I restriction endonuclease EcoR124I, couples ATP hydrolysis to bidirectional DNA translocation

Type I restriction endonuclease holoenzymes contain methylase (M), restriction (R) and specificity (S) subunits, present in an M2:R2:S1 stoichiometry. These enzymes bind to specific DNA sequences and translocate dsDNA in an ATP-dependent manner toward the holoenzyme anchored at the recognition sequence. Once translocation is impeded, DNA restriction, which functions to protect the host cell from invading DNA, takes place. Translocation and DNA cleavage are afforded by the two diametrically opposed R-subunits. To gain insight into the mechanism of translocation, a detailed characterization of the ATPase activity of EcoR124I was done. Results show that following recognition sequence binding, ATP hydrolysis-coupled, bidirectional DNA translocation by EcoR124I ensues, with the R-subunits transiently disengaging, on average, every 515 bp. Macroscopic processivity of 2031(+/-184)bp is maintained, as the R-subunits remain in close proximity to the DNA through association with the methyltransferase. Transient uncoupling of ATP hydrolysis from translocation results in 3.1(+/-0.4) ATP molecules being hydrolyzed per base-pair translocated per R-subunit. This is the first clear demonstration of the coupling of ATP hydrolysis to dsDNA translocation, albeit inefficient. Once translocation is impeded on supercoiled DNA, the DNA is cleaved. DNA cleavage inactivates the EcoR124I holoenzyme partially and reversibly, which explains the stoichiometric behaviour of type I restriction enzymes. Inactivated holoenzyme remains bound to the DNA at the recognition sequence and immediately releases the nascent ends. The release of nascent ends was demonstrated using a novel, fluorescence-based, real-time assay that takes advantage of the ability of the Escherichia coli RecBCD enzyme to unwind restricted dsDNA. The resulting unwinding of EcoR124I-restricted DNA by RecBCD reveals coordination between the restriction-modification and recombination systems that functions to destroy invading DNA efficiently. In addition, we demonstrate the displacement of EcoR124I following DNA cleavage by the translocating RecBCD enzyme, resulting in the restoration of catalytic function to EcoR124I.     

Translocation-independent dimerization of the EcoKI endonuclease visualized by atomic force microscopy

Bacterial type I restriction/modification systems are capable of performing multiple actions in response to the methylation pattern on their DNA recognition sequences. The enzymes making up these systems serve to protect the bacterial cells against viral infection by binding to their recognition sequences on the invading DNA and degrading it after extensive ATP-driven translocation. DNA cleavage has been thought to occur as the result of a collision between two translocating enzyme complexes. Using atomic force microscopy (AFM), we show here that EcoKI dimerizes rapidly when bound to a plasmid containing two recognition sites for the enzyme. Dimerization proceeds in the absence of ATP and is also seen with an EcoKI mutant (K477R) that is unable to translocate DNA. Only monomers are seen when the enzyme complex binds to a plasmid containing a single recognition site. Based on our results, we propose that the binding of EcoKI to specific DNA target sequences is accompanied by a conformational change that leads rapidly to dimerization. This event is followed by ATP-dependent translocation and cleavage of the DNA.     

The DNA translocation and ATPase activities of restriction-deficient mutants of Eco KI.

Eco KI, a type I restriction enzyme, specifies DNA methyltransferase, ATPase, endonuclease and DNA translocation activities. One subunit (HsdR) of the oligomeric enzyme contributes to those activities essential for restriction. These activities involve ATP-dependent DNA translocation and DNA cleavage. Mutations that change amino acids within recognisable motifs in HsdR impair restriction. We have used an in vivo assay to monitor the effect of these mutations on DNA translocation. The assay follows the Eco KI-dependent entry of phage T7 DNA from the phage particle into the host cell. Earlier experiments have shown that mutations within the seven motifs characteristic of the DEAD-box family of proteins that comprise known or putative helicases severely impair the ATPase activity of purified enzymes. We find that the mutations abolish DNA translocation in vivo. This provides evidence that these motifs are relevant to the coupling of ATP hydrolysis to DNA translocation. Mutations that identify an endonuclease motif similar to that found at the active site of type II restriction enzymes and other nucleases have been shown to abolish DNA nicking activity. When conservative changes are made at these residues, the enzymes lack nuclease activity but retain the ability to hydrolyse ATP and to translocate DNA at wild-type levels. It has been speculated that nicking may be necessary to resolve the topological problems associated with DNA translocation by type I restriction and modification systems. Our experiments show that loss of the nicking activity associated with the endonuclease motif of Eco KI has no effect on ATPase activity in vitro or DNA translocation of the T7 genome in vivo.     

StpA protein from Escherichia coli condenses supercoiled DNA in preference to linear DNA and protects it from digestion by DNase I and EcoKI

The nucleoid-associated protein, StpA, of Escherichia coli binds non-specifically to double-stranded DNA (dsDNA) and apparently forms bridges between adjacent segments of the DNA. Such a coating of protein on the DNA would be expected to hinder the action of nucleases. We demonstrate that StpA binding hinders dsDNA cleavage by both the non-specific endonuclease, DNase I, and by the site-specific type I restriction endonuclease, EcoKI. It requires approximately one StpA molecule per 250–300 bp of supercoiled DNA and approximately one StpA molecule per 60–100 bp on linear DNA for strong inhibition of the nucleases. These results support the role of StpA as a nucleoid-structuring protein which binds DNA segments together. The inhibition of EcoKI, which cleaves DNA at a site remote from its initial target sequence after extensive DNA translocation driven by ATP hydrolysis, suggests that these enzymes would be unable to function on chromosomal DNA even during times of DNA damage when potentially lethal, unmodified target sites occur on the chromosome. This supports a role for nucleoid-associated proteins in restriction alleviation during times of cell stress.     

Determination of DNA sequences containing methylcytosine in Bacillus subtilis Marburg.

The methylcytosine-containing sequences in the DNA of Bacillus subtilis 168 Marburg (restriction-modification type BsuM) were determined by three different methods: (i) examination of in vivo-methylated DNA by restriction enzyme digestion and, whenever possible, analysis for methylcytosine at the 5' end; (ii) methylation in vitro of unmethylated DNA with B. subtilis DNA methyltransferase and determination of the methylated sites; and (iii) the methylatability of unmethylated DNA by B. subtilis methyltransferase after potential sites have been destroyed by digestion with restriction endonucleases. The results obtained by these methods, taken together, show that methylcytosine was present only within the sequence 5'-TCGA-3'. The presence of methylcytosine at the 5' end of the DNA fragments generated by restriction endonuclease AsuII digestion and the fact that in vivo-methylated DNA could not be digested by the enzyme XhoI showed that the recognition sequences of these two enzymes contained methylcytosine. As these two enzymes recognized a similar sequence containing a 5' pyrimidine (Py) and a 3' purine (Pu), 5'-PyTCGAPu-3', the possibility that methylcytosine is present in the complementary sequences 5'-TTCGAG-3' and 5'-CTCGAA-3' was postulated. This was verified by the methylation in vitro, with B. subtilis enzyme, of a 2.6-kilobase fragment of lambda DNA containing two such sites and devoid of AsuII or XhoI recognition sequences. By analyzing the methylatable sites, it was found that in one of the two PyTCGAPu sequences, cytosine was methylated in vitro in both DNA strands. It is concluded that the sequence 5'-PyTCGAPu-3' is methylated by the DNA methyltransferase (of cytosine) of B. subtilis Marburg.     

The DNA restriction endonuclease of Escherichia coli B. I. Studies of the DNA translocation and the ATPase activities

Electron microscopic examination of DNA intermediates formed by the restriction endonuclease of Escherichia coli B revealed supercoiled loops that are presumably formed during an ATP-dependent DNA translocation process in which the enzyme remains bound to the recognition site while tracking along the DNA helix to a cleavage site. The rate of DNA translocation during this process is at least 5000 base pairs/min at 37 degrees C. Even after all cleavages have been completed, complexes are seen that contain terminal loops or loop plus tail structures. During this later phase of the reaction, ATP is hydrolyzed at a rate which is dependent upon the size of the largest possible loop (or loop plus tail); this ATP hydrolysis can be terminated by one double-strand cleavage within the loop region between the recognition site and the terminus. To explain these results, it is hypothesized that after cleavage the enzyme cycles between a tracking (and possibly back-tracking) mode which is fueled by ATP hydrolysis and a relatively long static period in which ATP hydrolysis does not occur. While tracking, the enzyme would be bound both to the recognition site and to a distal site but, while static, the enzyme would be bound only at the recognition site of nonlooped molecules. This post-nuclease phase of the reaction is hypothesized to reflect a reaction whereby the enzyme initially scans DNA molecules before making a strand cleavage.     

S-adenosyl methionine alters the DNA contacts of the EcoKI methyltransferase.

The EcoKI methyltransferase methylates two adenines on opposite strands of its bipartite DNA recognition sequence AAC(N6)GTGC. The enzyme has a strong preference for hemimethylated DNA substrates, but the methylation state of the DNA does not influence its binding affinity. Methylation interference was used to compare the contacts made by the EcoKI methyltransferase with unmodified, hemimethylated or fully modified DNAs. Contacts were seen at or near the N7 position of guanine, in the major groove, for all of the guanines in the EcoKI recognition sequence, and at two guanines on the edge of the intervening spacer sequence. The presence of the cofactor and methyl donor S-adenosyl methionine had a striking effect on the interference pattern for unmodified DNA which could not be mimicked by the presence of the cofactor analogue S-adenosyl homocysteine. In contrast, S-adenosyl methionine had no effect on the interference patterns for either kind of hemimethylated DNA, or for fully modified DNA. Differences between the interference patterns for the unmodified DNA and any of the three forms of methylated DNA provide evidence that methylation of the target sequence influences the conformation of the protein-DNA interface, and illustrate the importance of S-adenosyl methionine in the distinction between unmodified and methylated DNA by the methyltransferase.     

Activation of mammalian DNA methyltransferase by cleavage of a Zn binding regulatory domain.

Mammalian DNA (cytosine-5) methyltransferase contains a C-terminal domain that is closely related to bacterial cytosine-5 restriction methyltransferase. This methyltransferase domain is linked to a large N-terminal domain. It is shown here that the N-terminal domain contains a Zn binding site and that the N- and C-terminal domains can be separated by cleavage with trypsin or Staphylococcus aureus protease V8; the protease V8 cleavage site was determined by Edman degradation to lie 10 residues C-terminal of the run of alternating lysyl and glycyl residues which joins the two domains and six residues N-terminal of the first sequence motif conserved between the mammalian and bacterial cytosine methyltransferases. While the intact enzyme had little activity on unmethylated DNA substrates, cleavage between the domains caused a large stimulation of the initial velocity of methylation of unmethylated DNA without substantial change in the rate of methylation of hemimethylated DNA. These findings indicate that the N-terminal domain of DNA methyltransferase ensures the clonal propagation of methylation patterns through inhibition of the de novo activity of the C-terminal domain. Mammalian DNA methyltransferase is likely to have arisen via fusion of a prokaryotic-like restriction methyltransferase and an unrelated DNA binding protein. Stimulation of the de novo activity of DNA methyltransferase by proteolytic cleavage in vivo may contribute to the process of ectopic methylation observed in the DNA of aging animals, tumors and in lines of cultured cells.     

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.     

A new type of illegitimate recombination is dependent on restriction and homologous interaction.

Illegitimate (nonhomologous) recombination requires little or no sequence homology between recombining DNAs and has been regarded as being a process distinct from homologous recombination, which requires a long stretch of homology between recombining DNAs. Under special conditions in Escherichia coli, we have found a new type of illegitimate recombination that requires an interaction between homologous DNA sequences. It was detected when a plasmid that carried 2-kb-long inverted repeats was subjected to type II restriction in vitro and type I (EcoKI) restriction in vivo within a delta rac recBC recG ruvC strain. Removal of one of the repeats or its replacement with heterologous DNA resulted in a reduction in the level of recombination. The recombining sites themselves shared, at most, a few base pairs of homology. Many of the recombination events joined a site in one of the repeats with a site in another repeat. In two of the products, one of the recombining sites was at the end of one of the repeats. Removal of one of the EcoKI sites resulted in decreased recombination. We discuss the possibility that some structure made by homologous interaction between the long repeats is used by the EcoKI restriction enzyme to promote illegitimate recombination. The possible roles and consequences of this type of homologous interaction are discussed.     

Unusual 2-aminopurine fluorescence from a complex of DNA and the EcoKI methyltransferase

The methyltransferase, M.EcoKI, recognizes the DNA sequence 5'-AACNNNNNNGTGC-3' and methylates adenine at the underlined positions. DNA methylation has been shown by crystallography to occur via a base flipping mechanism and is believed to be a general mechanism for all methyltransferases. If no structure is available, the fluorescence of 2-aminopurine is often used as a signal for base flipping as it shows enhanced fluorescence when its environment is perturbed. We find that 2-aminopurine gives enhanced fluorescence emission not only when it is placed at the M.EcoKI methylation sites but also at a location adjacent to the target adenine. Thus it appears that 2-aminopurine fluorescence intensity is not a clear indicator of base flipping but is a more general measure of DNA distortion. Upon addition of the cofactor S-adenosyl-methionine to the M.EcoKI:DNA complex, the 2-aminopurine fluorescence changes to that of a new species showing excitation at 345 nm and emission at 450 nm. This change requires a fully active enzyme, the correct cofactor and the 2-aminopurine located at the methylation site. However, the new fluorescent species is not a covalently modified form of 2-aminopurine and we suggest that it represents a hitherto undetected physicochemical form of 2-aminopurine.