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.     

S-adenosyl-L-methionine is required for DNA cleavage by type III restriction enzymes.

The requirement of S-adenosyl-L-methionine (AdoMet) in the cleavage reaction carried out by type III restriction-modification enzymes has been investigated. We show that DNA restriction by EcoPI restriction enzyme does not take place in the absence of exogenously added AdoMet. Interestingly, the closely related EcoP15I enzyme has endogenously bound AdoMet and therefore does not require the addition of the cofactor for DNA cleavage. By employing a variety of AdoMet analogs, which differ structurally from AdoMet, this study demonstrates that the carboxyl group and any substitution at the epsilon carbon of methionine is absolutely essential for DNA cleavage. Such analogs could bring about the necessary conformational change(s) in the enzyme, which make the enzyme proficient in DNA cleavage. Our studies, which include native polyacrylamide gel electrophoresis, molecular size exclusion chromatography, UV, fluorescence and circular dichroism spectroscopy, clearly demonstrate that the holoenzyme and apoenzyme forms of EcoP15I restriction enzyme have different conformations. Furthermore, the Res and Mod subunits of the EcoP15I restriction enzyme can be separated by gel filtration chromatography in the presence of 2 M NaCl. Reconstitution experiments, which involve mixing of the isolated subunits, result in an apoenzyme form, which is restriction proficient in the presence of AdoMet. However, mixing the Res subunit with Mod subunit deficient in AdoMet binding does not result in a functional restriction enzyme. These observations are consistent with the fact that AdoMet is required for DNA cleavage. In vivo complementation of the defective mod allele with a wild-type mod allele showed that an active restriction enzyme could be formed. Furthermore, we show that while the purified c2-134 mutant restriction enzyme is unable to cleave DNA, the c2-440 mutant enzyme is able to cleave DNA albeit poorly. Taken together, these results suggest that AdoMet binding causes conformational changes in the restriction enzyme and is necessary to bring about DNA cleavage.     

DNA translocation blockage, a general mechanism of cleavage site selection by type I restriction enzymes

Type I restriction enzymes bind to a specific DNA sequence and subsequently translocate DNA past the complex to reach a non-specific cleavage site. We have examined several potential blocks to DNA translocation, such as positive supercoiling or a Holliday junction, for their ability to trigger DNA cleavage by type I restriction enzymes. Introduction of positive supercoiling into plasmid DNA did not have a significant effect on the rate of DNA cleavage by EcoAI endonuclease nor on the enzyme's ability to select cleavage sites randomly throughout the DNA molecule. Thus, positive supercoiling does not prevent DNA translocation. EcoR124II endonuclease cleaved DNA at Holliday junctions present on both linear and negatively supercoiled substrates. The latter substrate was cleaved by a single enzyme molecule at two sites, one on either side of the junction, consistent with a bi-directional translocation model. Linear DNA molecules with two recognition sites for endonucleases from different type I families were cut between the sites when both enzymes were added simultaneously but not when a single enzyme was added. We propose that type I restriction enzymes can track along a DNA substrate irrespective of its topology and cleave DNA at any barrier that is able to halt the translocation process.     

Kinetic models of translocation, head-on collision, and DNA cleavage by type I restriction endonucleases

Digestion of linear DNA by type I restriction endonucleases is generally activated following the head-on collision of two translocating enzymes. However, the resulting distributions of cleavage loci along the DNA vary with different enzymes; in some cases, cleavage is located in a discrete region midway between a pair of recognition sites while in other cases cleavage is broadly distributed and occurs at nearly every intervening locus. Statistical models for DNA translocation, collision, and cleavage are described that can account for these observations and that are generally applicable to other DNA-based motor proteins. If translocation is processive (stepping forward is significantly more likely than DNA dissociation), then the linear distribution of an ensemble of proteins can be described simply using a Poisson relationship. The pattern of cleavage sites resulting from collision between two processive type I enzymes over a distance d can then be described by a binomial distribution with a standard deviation 0.5 x d1/2. Alternatively, if translocation is nonprocessive (stepping forward or dissociating become equally likely events), the linear distribution is described by a continuum of populated states and is thus extended. Comparisons of model data to the kinetics of DNA translocation and cleavage discount the nonprocessive model. Instead, the observed differences between enzymes are due to asynchronous events that occur upon collision. Therefore, type I restriction enzymes can be described as having processive DNA translocation but, in some cases, nonprocessive DNA cleavage.     

DNA cleavage reactions by type II restriction enzymes that require two copies of their recognition sites

Several type II restriction endonucleases interact with two copies of their target sequence before they cleave DNA. Three such enzymes, NgoMIV, Cfr10I and NaeI, were tested on plasmids with one or two copies of their recognition sites, and on catenanes containing two interlinked rings of DNA with one site in each ring. The enzymes showed distinct patterns of behaviour. NgoMIV and NaeI cleaved the plasmid with two sites faster than that with one site and the catenanes at an intermediate rate, while Cfr10I gave similar steady-state rates on all three substrates. Both Cfr10I and NgoMIV converted the majority of the substrates with two sites directly to the products cut at both sites, while NaeI cleaved just one site at a time. All three enzymes thus synapse two DNA sites through three-dimensional space before cleaving DNA. With Cfr10I and NgoMIV, both sites are cleaved in one turnover, in a manner consistent with their tetrameric structures, while the cleavage of a single site by NaeI indicates that the second site acts not as a substrate but as an activator, as reported previously. The complexes spanning two sites have longer lifetimes on catenanes with one site in each ring than on circular DNA with two sites, which indicates that the catenanes have more freedom for site juxtaposition than plasmids with sites in cis.     

A comparison of DNA cleavage by the restriction enzymes SalPI and PstI.

Methods for obtaining highly active, exonuclease-free, stable preparations of the Streptomyces albus P restriction enzyme SalPI are described. SalPI and its isoschizomer PstI (from the taxonomically distant Providencia stuartii 164) both cleave their recognition sequence (5'-CTGCAG-3') to generate fragments terminating in tetranucleotide 3' extensions whose sequence is 5'-TGCA-3'. Bacteriophage R4G2 DNA, protected against SalPI cleavage by pregrowth on S. albus P, is also protected against PstI cleavage; and total DNA of both S. albus P and P. stuartii 164 is resistant to cleavage by both enzymes.     

Cleavage of DNA.RNA hybrids by type II restriction enzymes.

The action of a number of restriction enzymes on DNA.RNA hybrids has been examined using hybrids synthesised with RNAs of cucumber mosaic virus as templates. The enzymes EcoRI, HindII, SalI, MspI, HhaI, AluI, TaqI and HaeIII cleaved the DNA strand of the hybrids (and possible also the RNA strand) into specific fragments. For four of these enzymes, HhaI, AluI, TaqI and HaeIII, comparison of the restriction fragments produced with the known sequences of the viral RNAs confirmed that they were recognising and cleaving the DNA strand of the hybrids at their correct recognition sequences. It is likely that the ability to utilise DNA.RNA hybrids as substrates is a general property of Type II restriction enzymes.     

Analysis of DNA looping interactions by type II restriction enzymes that require two copies of their recognition sites

Before cleaving DNA substrates with two recognition sites, the Cfr10I, NgoMIV, NaeI and SfiI restriction endonucleases bridge the two sites through 3D space, looping out the intervening DNA. To characterise their looping interactions, the enzymes were added to plasmids with two recognition sites interspersed with two res sites for site-specific recombination by Tn21 resolvase, in buffers that contained either EDTA or CaCl2 so as to preclude DNA cleavage by the endonuclease; the extent to which the res sites were sequestered into separate loops was evaluated from the degree of inhibition of resolvase. With Cfr10I, a looped complex was detected in the presence but not in the absence of Ca(2+); it had a lifetime of about 90 seconds. Neither NgoMIV nor NaeI gave looped complexes of sufficient stability to be detected by this method. In contrast, SfiI with Ca(2+) produced a looped complex that survived for more than seven hours, whereas its looping interaction in EDTA lasts for about four minutes. When resolvase was added to a SfiI binding reaction in EDTA followed immediately by CaCl2, the looped DNA was blocked from recombination while the unlooped DNA underwent recombination. By measuring the distribution between looped and unlooped DNA at various SfiI concentrations, and by fitting the data to a model for DNA binding by a tetrameric protein to two sites in cis, an equilibrium constant for the looping interaction was determined. The equilibrium constant was essentially independent of the length of DNA between the SfiI sites.     

DNA recognition by a new family of type I restriction enzymes: a unique relationship between two different DNA specificities.

The DNA sequences recognized by the allelic type I restriction enzymes EcoR124 and EcoR124/3 were determined. EcoR124 recognizes 5'-GAA(N6)RTCG-3' and EcoR124/3 recognizes 5'-GAA(N7)RTCG-3'. These are typical of sequences recognized by type I recognition enzymes in that they consist of two specific domains separated by a non-specific spacer sequence. For these two enzymes, the specific sequences are identical but the length of the non-specific spacer is different. The specific domains of EcoR124/3 are thus 3.4 A further apart than those of EcoR124 and rotated with respect to each other through a further 36 degrees.     

Two type I restriction enzymes from Salmonella species. Purification and DNA recognition sequences

We have purified the type I restriction enzymes SB and SP from Salmonella typhimurium and S. potsdam, respectively, and determined the DNA sequences that they recognize. These sequences resemble those previously determined for the type I enzymes, EcoB, EcoK and EcoA, in that the specific part of the sequence is divided into two domains by a spacer of non-specific sequence that has a fixed length for each enzyme. Two main differences from the previously determined sequences are seen. Both of the new sequences are degenerate and one of them, SB, has one trinucleotide and one pentanucleotide-specific domain rather than the trinucleotide and tetranucleotide domains seen for all of the other enzymes. The only conserved features of the recognition sequences are the adenosyl residues that are methylated in the modification reaction. For all of the enzymes these are situated ten or 11 base-pairs apart, one on each strand of the DNA. This suggests that the enzymes bind to DNA along one face of the double helix making protein-DNA interaction in two successive major grooves with most of the non-specific spacer sequence in the intervening minor groove.     

DNA communications by Type III restriction endonucleases--confirmation of 1D translocation over 3D looping

DNA cleavage by Type III restriction enzymes is governed strictly by the relative arrangement of recognition sites on a DNA substrate—endonuclease activity is usually only triggered by sequences in head-to-head orientation. Tens to thousands of base pairs can separate these sites. Long distance communication over such distances could occur by either one-dimensional (1D) DNA translocation or 3D DNA looping. To distinguish between these alternatives, we analysed the activity of EcoPI and EcoP15I on DNA catenanes in which the recognition sites were either on the same or separate rings. While substrates with a pair of sites located on the same ring were cleaved efficiently, catenanes with sites on separate rings were not cleaved. These results exclude a simple 3D DNA-looping activity. To characterize the interactions further, EcoPI was incubated with plasmids carrying two recognition sites interspersed with two 21res sites for site-specific recombination by Tn21 resolvase; inhibition of recombination would indicate the formation of stable DNA loops. No inhibition was observed, even under conditions where EcoPI translocation could also occur.     

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.     

Differential dependence on DNA ligase of type II restriction enzymes: a practical way toward ligase-free DNA automaton

DNA computing study is a new paradigm in computer science and biological computing fields. As one of DNA computing approaches, DNA automaton is composed of the hardware, input DNA molecule and state transition molecules. By now restriction enzymes are key hardware for DNA computing automaton. It has been found that DNA computing efficiency may be independent on DNA ligases when type IIS restriction enzymes like FokI are used as hardware. In this study, we compared FokI with four other distinct enzymes HgaI, BsmFI, BbsI, and BseMII, and found their differential independence on T4 DNA ligase when performing automaton reactions. Since DNA automaton is a potential powerful tool to tackle gene relationship in genomic network scale, the feasible ligase-free DNA automaton may set an initial base to develop functional DNA automata for various DNA technology development and implications in genetics study in the near future.     

Real-time observation of DNA translocation by the type I restriction modification enzyme EcoR124I

Type I restriction enzymes bind sequence-specifically to unmodified DNA and subsequently pull the adjacent DNA toward themselves. Cleavage then occurs remotely from the recognition site. The mechanism by which these members of the superfamily 2 (SF2) of helicases translocate DNA is largely unknown. We report the first single-molecule study of DNA translocation by the type I restriction enzyme EcoR124I. Mechanochemical parameters such as the translocation rate and processivity, and their dependence on force and ATP concentration, are presented. We show that the two motor subunits of EcoR124I work independently. By using torsionally constrained DNA molecules, we found that the enzyme tracks along the helical pitch of the DNA molecule. This assay may be directly applicable to investigating the tracking of other DNA-translocating motors along their DNA templates.     

Re-evaluating the kinetics of ATP hydrolysis during initiation of DNA sliding by Type III restriction enzymes

DNA cleavage by the Type III restriction enzymes requires long-range protein communication between recognition sites facilitated by thermally-driven 1D diffusion. This ‘DNA sliding’ is initiated by hydrolysis of multiple ATPs catalysed by a helicase-like domain. Two distinct ATPase phases were observed using short oligoduplex substrates; the rapid consumption of ∼10 ATPs coupled to a protein conformation switch followed by a slower phase, the duration of which was dictated by the rate of dissociation from the recognition site. Here, we show that the second ATPase phase is both variable and only observable when DNA ends are proximal to the recognition site. On DNA with sites more distant from the ends, a single ATPase phase coupled to the conformation switch was observed and subsequent site dissociation required little or no further ATP hydrolysis. The overall DNA dissociation kinetics (encompassing site release, DNA sliding and escape via a DNA end) were not influenced by the second phase. Although the data simplifies the ATP hydrolysis scheme for Type III restriction enzymes, questions remain as to why multiple ATPs are hydrolysed to prepare for DNA sliding.     

Engineering strand-specific DNA nicking enzymes from the type IIS restriction endonucleases BsaI, BsmBI, and BsmAI

To determine the extent to which protein folding rates and free energy landscapes have been shaped by natural selection, we have examined the folding kinetics of five proteins generated using computational design methods and, hence, never exposed to natural selection. Four of these proteins are complete computer-generated redesigns of naturally occurring structures and the fifth protein, called Top7, has a computer-generated fold not yet observed in nature. We find that three of the four redesigned proteins fold much faster than their naturally occurring counterparts. While natural selection thus does not appear to operate on protein folding rates, the majority of the designed proteins unfold considerably faster than their naturally occurring counterparts, suggesting possible selection for a high free energy barrier to unfolding. In contrast to almost all naturally occurring proteins of less than 100 residues but consistent with simple computational models, the folding energy landscape for Top7 appears to be quite complex, suggesting the smooth energy landscapes and highly cooperative folding transitions observed for small naturally occurring proteins may also reflect the workings of natural selection.     

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.     

Leishmania proteins derived from recombinant DNA: current status and next steps

The parasite Leishmania is a major cause of disease worldwide. In the past 15 years, many groups have analysed DNA-derived proteins from Leishmania. Large amounts of data obtained by these groups can be collated to direct future research into Leishmania and to find novel immunological mechanisms and information about its metabolism. International coordination will increase both the basic knowledge about Leishmania and the capacity to apply this knowledge to combat leishmaniases.     

Families of restriction enzymes: an analysis prompted by molecular and genetic data for type ID restriction and modification systems

Current genetic and molecular evidence places all the known type I restriction and modification systems of Escherichia coli and Salmonella enterica into one of four discrete families: type IA, IB, IC or ID. StySBLI is the founder member of the ID family. Similarities of coding sequences have identified restriction systems in E.coli and Klebsiella pneumoniae as probable members of the type ID family. We present complementation tests that confirm the allocation of EcoR9I and KpnAI to the ID family. An alignment of the amino acid sequences of the HsdS subunits of StySBLI and EcoR9I identify two variable regions, each predicted to be a target recognition domain (TRD). Consistent with two TRDs, StySBLI was shown to recognise a bipartite target sequence, but one in which the adenine residues that are the substrates for methylation are separated by only 6 bp. Implications of family relationships are discussed and evidence is presented that extends the family affiliations identified in enteric bacteria to a wide range of other genera.