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.     

Domain movement within a gene: a novel evolutionary mechanism for protein diversification

A protein function is carried out by a specific domain localized at a specific position. In the present study, we report that, within a gene, a specific amino acid sequence can move between a certain position and another position. This was discovered when the sequences of restriction-modification systems within the bacterial species Helicobacter pylori were compared. In the specificity subunit of Type I restriction-modification systems, DNA sequence recognition is mediated by target recognition domain 1 (TRD1) and TRD2. To our surprise, several sequences are shared by TRD1 and TRD2 of genes (alleles) at the same locus (chromosomal location); these domains appear to have moved between the two positions. The gene/protein organization can be represented as x-(TRD1)-y-x-(TRD2)-y, where x and y represent repeat sequences. Movement probably occurs by recombination at these flanking DNA repeats. In accordance with this hypothesis, recombination at these repeats also appears to decrease two TRDs into one TRD or increase these two TRDs to three TRDs (TRD1-TRD2-TRD2) and to allow TRD movement between genes even at different loci. Similar movement of domains between TRD1 and TRD2 was observed for the specificity subunit of a Type IIG restriction enzyme. Similar movement of domain between TRD1 and TRD2 was observed for Type I restriction-modification enzyme specificity genes in two more eubacterial species, Streptococcus pyogenes and Mycoplasma agalactiae. Lateral domain movements within a protein, which we have designated DOMO (domain movement), represent novel routes for the diversification of proteins.     

Identification of a subdomain within DNA-(cytosine-C5)-methyltransferases responsible for the recognition of the 5' part of their DNA target.

In previous work on DNA-(cytosine-C5)-methyltransferases (C5-MTases), domains had been identified which are responsible for the sequence specificity of the different enzymes (target-recognizing domains, TRDs). Here we have analyzed the DNA methylation patterns of two C5-MTases containing reciprocal chimeric TRDs, consisting of the N- and C-terminal parts derived from two different parental TRDs specifying the recognition of 5'-CC(A/T)GG-3' and 5'-GCNGC-3'. Sequences recognized by these engineered MTases were non-symmetrical and degenerate, but contained at their 5' part a consensus sequence which was very similar to the 5' part of the target recognized by the parental TRD which contributed the N-terminal moiety of the chimeric TRD. The results are discussed in connection with the present understanding of the mechanism of DNA target recognition by C5-MTases. They demonstrate the possibility of designing C5-MTases with novel DNA methylation specificities.     

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 genetic and functional analysis of the unusually large variable region in the M·Alu I DNA-(cytosine C5 )-methyltransferase

The M·AluI DNA-(cytosine C5)-methyltransferase (5mC methylase) acts on the sequence 5′-AGCT-3′. The amino acid sequences of known 5mC methylases contain ten conserved motifs, with a variable region between Motifs VIII and IX that contains one or more “target-recognizing domains” (TRDs) responsible for DNA sequence specificity. Monospecific 5mC methylases are believed to have only one TRD, while multispecific 5mC methylases have as many as five. M·AluI has the second-largest variable region of all known 5mC methylases, and sequence analysis reveals five candidate TRDs. In testing whether M·AluI is in fact monospecific it was found that AGCT methylation represents only 80–90% of the methylating activity of this enzyme, while control experiments with the enzyme M·HhaI gave no unexplained activity. Because individual TRDs can be deleted from multispecific methylases without general loss of activity, a series of insertion and deletion mutants of the M·AluI variable region were prepared. All deletions that removed more than single amino acids from the variable region caused significant loss of activity; a sensitive in vivo assay for methylase activity based on McrBC restriction suggested that the central portion of the variable region is particularly important. In some cases, multispecific methylases can accommodate a TRD from another multispecific methylase, thereby acquiring an additional specificity. When TRDs were moved from a multispecific methylase into two different locations in the variable region of M·AluI, all hybrid enzymes had greatly reduced activity and no new specificities. M·AluI thus behaves in most respects as a monospecific methylase despite the remarkable size of its variable region.     

M.(phi)BssHII, a novel cytosine-C5-DNA-methyltransferase with target-recognizing domains at separated locations of the enzyme.

In all cytosine-C5-DNA-methyltransferases (MTases) from prokaryotes and eukaryotes, remarkably conserved amino acid sequence elements responsible for general enzymatic functions are arranged in the same canonical order. In addition, one variable region, which includes the target-recognizing domain(s) (TRDs) characteristic for each enzyme, has been localized in one region between the same blocks of these conserved elements. This conservation in the order of conserved and variable sequences suggests stringent structural constraints in the primary structure to obtain the correct folding of the enzymes. Here we report the characterization of a new type of a multispecific MTase, M.(phiphi)BssHII, which is expressed as two isoforms. Isoform I is an entirely novel type of MTase which has, in addition to the TRDs at the conventional location, one TRD located at a non-canonical position at its N-terminus. Isoform II is represented by the same MTase, but without the N-terminal TRD. The N-terminal TRD provides HaeII methylation specificity to isoform I. The TRD is fully functional when engineered into either the conventional variable region of M.(phiphi)BssHII or the related monospecific M.phi3TII MTase. The implications of this structural plasticity with respect to the evolution of MTases are discussed.     

Localization of a protein-DNA interface by random mutagenesis.

The type I restriction and modification enzymes do not possess obvious DNA-binding motifs within their target recognition domains (TRDs) of 150-180 amino acids. To identify residues involved in DNA recognition, changes were made in the amino-TRD of EcoKI by random mutagenesis. Most of the 101 substitutions affecting 79 residues had no effect on the phenotype. Changes at only seven positions caused the loss of restriction and modification activities. The seven residues identified by mutation are not randomly distributed throughout the primary sequence of the TRD: five are within the interval between residues 80 and 110. Sequence analyses have led to the suggestion that the TRDs of type I restriction enzymes include a tertiary structure similar to the TRD of the HhaI methyltransferase, and to a model for a DNA-protein interface in EcoKI. In this model, the residues within the interval identified by the five mutations are close to the protein-DNA interface. Three additional residues close to the DNA in the model were changed; each substitution impaired both activities. Proteins from twelve mutants were purified: six from mutants with partial or wild-type activity and six from mutants lacking activity. There is a strong correlation between phenotype and DNA-binding affinity, as determined by fluorescence anisotropy.     

Recombination of constant and variable modules alters DNA sequence recognition by type IC restriction-modification enzymes.

EcoR124 and EcoDXXI are allelic type I restriction-modification (R-M) systems whose specificity genes consist of common structural elements: two variable regions are separated by a constant, homologous region containing a number of repetitive sequence elements. In vitro recombination of variable and constant elements has led to fully active, hybrid R-M systems exhibiting new and predictable target site specificities. Methylation of synthetic DNA sequences with purified, hybrid modification methylases was used to confirm the proposed recognition sequences. The results clearly demonstrate the correlation between protein domains and target site specificity. Our data suggest that a bacterial population may switch the recognition sequences of its type I R-M system by single recombination events and thus is able to maintain a prokaryotic analogue of the immune system of variable specificity.     

Target recognition by EcoKI: the recognition domain is robust and restriction-deficiency commonly results from the proteolytic control of enzyme activity

We report a genetic and biochemical analysis of a target recognition domain (TRD) of EcoKI, a type I restriction and modification enzyme. The TRDs of type I R-M systems are within the specificity subunit (HsdS) and HsdS confers sequence specificity to a complex endowed with both restriction and modification activities. Random mutagenesis has revealed that most substitutions within the amino TRD of EcoKI, a region comprising 157 amino acid residues, have no detectable effect on the phenotype of the bacterium, even when the substitutions are non- conservative. The structure of the TRD appears to be robust. All but one of the six substitutions that confer a restriction-deficient, modification-deficient (r(-)m(-)) phenotype were found to be in the interval between residues 80 and 110, a region predicted by sequence comparisons to form part of the protein-DNA interface. Additional site-directed mutations affecting this interval commonly impair both restriction and modification. However, we show that an r(-) phenotype cannot be taken as evidence that the EcoKI complex lacks endonuclease activity; in response to even a slightly impaired modification efficiency, the endonuclease activity of EcoKI is destroyed by a process dependent upon the ClpXP protease.Enzymes from mutants with an r(-)m(-) phenotype commonly retain some sequence-specific activity; methylase activity can be detected on hemimethylated DNA substrates and residual endonuclease activity is implied whenever the viability of the r(-)m(-) bacterium is dependent on ClpXP. Conversely, the viability of ClpX(-) r(-)m(-) bacteria can be used as evidence for little, or no, endonuclease activity. Of 14 mutants with an r(-)m(-) phenotype, only six are viable in the absence of ClpXP. The significance of four of the six residues (G91, G105, F107 and G141) is enhanced by the finding that even conservative substitutions for these residues impair modification, thereby conferring an r(-)m(-) phenotype.     

Cytosine-specific type II DNA methyltransferases. A conserved enzyme core with variable target-recognizing domains

Comparisons of the amino acid sequences of m5C DNA methyltransferases (Mtases) from 11 prokaryotes and one eukaryote reveal a very similar organization. Among all the enzymes one can distinguish highly conserved "core" sequences and "variable" regions. The core sequences apparently mediate steps of the methylation reaction that are common to all the enzymes. The major variable region has been shown in our previous studies on multispecific phage Mtases to contain the target-recognizing domains (TRDs) of these enzymes. Here we have compared the amino acid sequences of various TRDs from phage Mtases. This has revealed the presence of both highly conserved and variable amino acids. We postulate that the conserved residues represent a "consensus" sequence defining a TRD, whereas the specificity of the TRD is determined by the variable residues. We have observed similarity between this consensus sequence and sequences in the variable region of the monospecific Mtases. We predict that the regions thus identified represent part of the TRDs of monospecific Mtases.     

High plasticity of multispecific DNA methyltransferases in the region carrying DNA target recognizing enzyme modules.

Multispecific cytosine C5 DNA methyltransferases (MTases) methylate more than one specific DNA target. This is due to the presence of several target recognizing domains (TRDs) in these enzymes. Such TRDs form part of a variable centre in the MTase primary sequence, which separates conserved enzyme core sequences responsible for general steps in the methylation reaction. By deleting, rearranging and exchanging several TRDs of multispecific MTases, we demonstrate their modular character; they mediate target recognition independent of a particular TRD or core sequence context. We show also that multispecific MTases can accommodate inert material of non-MTase origin within their variable region without losing their activity. The remarkable plasticity with respect to the material that can be integrated into this region suggests that the enzyme core sequences preceding or following it form separable functional domains. In spite of the documented flexibility multispecific MTases could not be endowed with novel specificities by integration of putative TRDs of monospecific MTases, pointing to differences between multi- and monospecific MTases in the way their core and TRD sequences interact.     

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.     

The EcoR124 and EcoR124/3 restriction and modification systems: Cloning the genes

The Escherichia coli plasmid R124 codes for a type I restriction and modification system EcoR124 and carries genetic information, most probably in the form of a "silent copy," for the expression of a different R-M specificity R124/3. Characteristic DNA rearrangements have been shown to accompany the switch in specificity from R124 to R124/3 and vice versa. We have cloned a 14.2-kb HindIII fragment from R124 and shown that it contains the hsdR, hsdM, and hsdS genes which code for the EcoR124 R-M system. An equivalent fragment from the plasmid R124/3 following the switch in R-M specificity has also been cloned and shown to contain the genes coding for the EcoR124/3 R-M system. These fragments, however, lack a component present on the wild-type plasmid essential for the switch in specificity. Restriction fragment maps and preliminary heteroduplex analysis indicate the near identity of the genes that encode the two different DNA recognition specificities. Transposon mutagenesis was used to locate the positions of the hsdR, hsdM, and hsdS genes on the cloned fragments in conjunction with complementation tests for gene function. Indirect evidence indicates that hsdR is expressed from its own promoter and that hsdM and hsdS are expressed from a single promoter, unidirectionally.     

DNA binding properties in vivo and target recognition domain sequence alignment analyses of wild-type and mutant RsrI [N6-adenine] DNA methyltransferases

A genetic selection method, the P22 challenge-phage assay, was used to characterize DNA binding in vivo by the prokaryotic beta class [N:6-adenine] DNA methyltransferase M.RSR:I. M.RSR:I mutants with altered binding affinities in vivo were isolated. Unlike the wild-type enzyme, a catalytically compromised mutant, M.RSR:I (L72P), demonstrated site-specific DNA binding in vivo. The L72P mutation is located near the highly conserved catalytic motif IV, DPPY (residues 65-68). A double mutant, M.RSR:I (L72P/D173A), showed less binding in vivo than did M.RSR:I (L72P). Thus, introduction of the D173A mutation deleteriously affected DNA binding. D173 is located in the putative target recognition domain (TRD) of the enzyme. Sequence alignment analyses of several beta class MTases revealed a TRD sequence element that contains the D173 residue. Phylogenetic analysis suggested that divergence in the amino acid sequences of these methyltransferases correlated with differences in their DNA target recognition sequences. Furthermore, MTases of other classes (alpha and gamma) having the same DNA recognition sequence as the beta class MTases share related regions of amino acid sequences in their TRDs.     

Conservation of organization in the specificity polypeptides of two families of type I restriction enzymes

We have identified the recognition sequence for the Citrobacter freundii restriction endonuclease CfrA, a member of the A-family of type I R-M enzymes. This bipartite target sequence differs in both its components from those of other type I enzymes. We determined the nucleotide sequence of its specificity gene (hsdS) and a comparison of this with its relative EcoA identifies two extensive variable regions, an organization analogous to that found in the K-family of type I R-M enzymes. The specificity polypeptides of the A-family, unlike those of K, have an N-terminal conserved region, and this includes a sequence repeated within the central conserved region. A second repeat sequence, identified at the amino acid level, coincides with the only sequence similarity common to all type I S polypeptides. Sequences immediately downstream from the hsdS genes of EcoA, CfrA, EcoK, B and D are almost identical, consistent with an allelic chromosomal location.     

The amino acid sequence of the CCGG recognizing DNA methyltransferase M.BsuFI: implications for the analysis of sequence recognition by cytosine DNA methyltransferases.

The Bacillus subtilis FI DNA methyltransferase (M.BsuFI) modifies the outer cytosine of the DNA sequence CCGG, causing resistance against R.BsuFI and R.MspI restriction. The M.BsuFI gene was cloned and expressed in B.subtilis and Escherichia coli. As derived from the nucleotide sequence, the M.BsuFI protein has 409 amino acids, corresponding to a molecular mass of 46,918 daltons. Including these data we have compared the nucleotide and amino acid sequences of different CCGG recognizing enzymes. These analyses showed that M.BsuFI is highly related to two other CCGG specific methyltransferases, M.MspI and M.HpaII, which were isolated from Gram-negative bacteria. Between M.BsuFI and M.MspI the sequence similarity is particularly significant in a region, which has been postulated to contain the target recognition domains (TRDs) of cytosine-specific DNA methyltransferases. Apparently M.BsuFI and M.MspI, derived from phylogenetic distant organisms, use highly conserved structural elements for the recognition of the CCGG target sequence. In contrast the very same region of M.HpaII is quite different from those of M.BsuFI and M.MspI. We attribute this difference to the different targeting of methylation within the sequence CCGG, where M.HpaII methylates the inner, M.BsuFI/M.MspI the outer cytosine. Also the CCGG recognizing TRD of the multispecific B.subtilis phage SPR Mtase is distinct from that of the host enzyme, possibly indicating different requirements for TRDs operative in mono- and multispecific enzymes.     

Structural and functional analysis of the symmetrical Type I restriction endonuclease R.EcoR124I(NT)

Type I restriction-modification (RM) systems are comprised of two multi-subunit enzymes, the methyltransferase (～160 kDa), responsible for methylation of DNA, and the restriction endonuclease (～400 kDa), responsible for DNA cleavage. Both enzymes share a number of subunits. An engineered RM system, EcoR124I(NT), based on the N-terminal domain of the specificity subunit of EcoR124I was constructed that recognises the symmetrical sequence GAAN(7)TTC and is active as a methyltransferase. Here, we investigate the restriction endonuclease activity of R. EcoR124I(NT)in vitro and the subunit assembly of the multi-subunit enzyme. Finally, using small-angle neutron scattering and selective deuteration, we present a low-resolution structural model of the endonuclease and locate the motor subunits within the multi-subunit enzyme. We show that the covalent linkage between the two target recognition domains of the specificity subunit is not required for subunit assembly or enzyme activity, and discuss the implications for the evolution of Type I enzymes.     

Novel subtype of type IIs restriction enzymes. BfiI endonuclease exhibits similarities to the EDTA-resistant nuclease Nuc of Salmonella typhimurium

The type IIs restriction enzyme BfiI recognizes the non-palindromic nucleotide sequence 5'-ACTGGG-3' and cleaves complementary DNA strands 5/4 nucleotides downstream of the recognition sequence. The genes coding for the BfiI restriction-modification (R-M) system were cloned/sequenced and biochemical characterization of BfiI restriction enzyme was performed. The BfiI R-M system contained three proteins: two N4-methylcytosine methyltransferases and a restriction enzyme. Sequencing of bisulfite-treated methylated DNA indicated that each methyltransferase modifies cytosines on opposite strands of the recognition sequence. The N-terminal part of the BfiI restriction enzyme amino acid sequence revealed intriguing similarities to an EDTA-resistant nuclease of Salmonella typhimurium. Biochemical analyses demonstrated that BfiI, like the nuclease of S. typhimurium, cleaves DNA in the absence of Mg(2+) ions and hydrolyzes an artificial substrate bis(p-nitrophenyl) phosphate. However, unlike the nonspecific S. typhimurium nuclease, BfiI restriction enzyme cleaves DNA specifically. We propose that the DNA-binding specificity of BfiI stems from the C-terminal part of the protein. The catalytic N-terminal subdomain of BfiI radically differs from that of type II restriction enzymes and is presumably similar to the EDTA-resistant nonspecific nuclease of S. typhimurium; therefore, BfiI did not require metal ions for catalysis. We suggest that BfiI represents a novel subclass of type IIs restriction enzymes that differs from the archetypal FokI endonuclease by the fold of its cleavage domain, the domain location, and reaction mechanism.