A deletion mutant of the type IC restriction endonuclease EcoR1241 expressing a novel DNA specificity

Characterization of the Staphylococcus xylosus methylome reveals a new variant of type I restriction modification system in staphylococci

Restriction modification (RM) systems are known to provide a strong barrier to the exchange of DNA between and within bacterial species. Likewise, DNA methylation is known to have an important function in bacterial epigenetics regulating essential pathways such as DNA replication and the phase variable expression of prokaryotic phenotypes. To date, research on staphylococcal DNA methylation focused mainly on the two species Staphylococcus aureus and S. epidermidis. Less is known about other members of the genus such as S. xylosus, a coagulase-negative commensal of mammalian skin. The species is commonly used as starter organism in food fermentations but is also increasingly considered to have an as yet elusive function in bovine mastitis infections. We analyzed the methylomes of 14 S. xylosus strains using single-molecular, real-time (SMRT) sequencing. Subsequent in silico sequence analysis allowed identification of the RM systems and assignment of the respective enzymes to the discovered modification patterns. Hereby the presence of type I, II, III and IV RM systems in varying numbers and combinations among the different strains was revealed, clearly distinguishing the species from what is known for other members of the genus so far. In addition, the study characterizes a newly discovered type I RM system, encoded by S. xylosus but also by a variety of other staphylococcal species, with a hitherto unknown gene arrangement that involves two specificity units instead of one (hsdRSMS). Expression of different versions of the operon in E. coli showed proper base modification only when genes encoding both hsdS subunits were present. This study provides new insights into the general understanding of the versatility and function of RM systems as well as the distribution and variations in the genus Staphylococcus.

Expression and Purification of BsaXI Restriction Endonuclease and Engineering New Specificity From BsaXI Specificity Subunit

It is stated that BsaXI is a Type IIB restriction endonuclease (REase) that cleaves both sides of its recognition sequence 5′↓N9 AC N5 CTCC N10↓ 3′ (complement strand 5′ ↓N7 GGAG N5 GT N12↓ 3′), creating 3-base 3′ overhangs. Here we report the cloning and expression of bsaXIS and bsaXIRM genes in Escherichia coli. The BsaXI activity was successfully reconstituted by mixing the BsaXI RM fusion subunit with the BsaXI S subunit and the enzyme complex further purified by chromatography over 6 columns. As expected, the S subunit consisted of two subdomains encoding TRD1-CR1 [target recognition domain (TRD), conserved region (CR)] for 5′ AC 3′, and TRD2-CR2 presumably specifying 5′ CTCC 3′. TRD1-CR1 (TRD2-CR2 deletion) or duplication of TRD1 (TRD1-CR1-TRD1-CR2) both generated a new specificity 5′ AC N5 GT 3′ when the S variants were complexed with the RM subunits. The circular permutation of TRD1 and TRD2, i.e., the relocation of TRD2-CR2 to the N-terminus and TRD1-CR1 to the C-terminus generated the same specificity with the RM subunits, although some wobble cleavage was detected. The TRD2 domain in the BsaXI S subunit can be substituted by a close homolog (∼59% sequence identity) and generated the same specificity. However, TRD2-CR2 domain alone failed to express in E. coli, but CR1-TRD2-CR2 protein could be expressed and purified which showed partial nicking activity with the RM subunits. This work demonstrated that like Type I restriction systems, the S subunit of a Type IIB system could also be manipulated to create new specificities. The genome mining of BsaXI TRD2 homologs in GenBank found more than 36 orphan TRD2 homologs, implying that quite a few orphan TRD2s are present in microbial genomes that may be potentially paired with other TRDs to create new restriction specificities.

Excision-reintegration at a pneumococcal phase-variable restriction-modification locus drives within- and between-strain epigenetic differentiation and inhibits gene acquisition

Phase-variation of Type I restriction-modification systems can rapidly alter the sequence motifs they target, diversifying both the epigenetic patterns and endonuclease activity within clonally descended populations. Here, we characterize the Streptococcus pneumoniae SpnIV phase-variable Type I RMS, encoded by the translocating variable restriction (tvr) locus, to identify its target motifs, mechanism and regulation of phase variation, and effects on exchange of sequence through transformation. The specificity-determining hsdS genes were shuffled through a recombinase-mediated excision-reintegration mechanism involving circular intermediate molecules, guided by two types of direct repeat. The rate of rearrangements was limited by an attenuator and toxin-antitoxin system homologs that inhibited recombinase gene transcription. Target motifs for both the SpnIV, and multiple Type II, MTases were identified through methylation-sensitive sequencing of a panel of recombinase-null mutants. This demonstrated the species-wide diversity observed at the tvr locus can likely specify nine different methylation patterns. This will reduce sequence exchange in this diverse species, as the native form of the SpnIV RMS was demonstrated to inhibit the acquisition of genomic islands by transformation. Hence the tvr locus can drive variation in genome methylation both within and between strains, and limits the genomic plasticity of S. pneumoniae.

A model for the evolution of prokaryotic DNA restriction-modification systems based upon the structural malleability of Type I restriction-modification enzymes

Restriction Modification (RM) systems prevent the invasion of foreign genetic material into bacterial cells by restriction and protect the host's genetic material by methylation. They are therefore important in maintaining the integrity of the host genome. RM systems are currently classified into four types (I to IV) on the basis of differences in composition, target recognition, cofactors and the manner in which they cleave DNA. Comparing the structures of the different types, similarities can be observed suggesting an evolutionary link between these different types. This work describes the ‘deconstruction’ of a large Type I RM enzyme into forms structurally similar to smaller Type II RM enzymes in an effort to elucidate the pathway taken by Nature to form these different RM enzymes. Based upon the ability to engineer new enzymes from the Type I ‘scaffold’, an evolutionary pathway and the evolutionary pressures required to move along the pathway from Type I RM systems to Type II RM systems are proposed. Experiments to test the evolutionary model are discussed.

DNA target recognition domains in the Type I restriction and modification systems of Staphylococcus aureus

Staphylococcus aureus displays a clonal population structure in which horizontal gene transfer between different lineages is extremely rare. This is due, in part, to the presence of a Type I DNA restriction–modification (RM) system given the generic name of Sau1, which maintains different patterns of methylation on specific target sequences on the genomes of different lineages. We have determined the target sequences recognized by the Sau1 Type I RM systems present in a wide range of the most prevalent S. aureus lineages and assigned the sequences recognized to particular target recognition domains within the RM enzymes. We used a range of biochemical assays on purified enzymes and single molecule real-time sequencing on genomic DNA to determine these target sequences and their patterns of methylation. Knowledge of the main target sequences for Sau1 will facilitate the synthesis of new vectors for transformation of the most prevalent lineages of this ‘untransformable’ bacterium.

Comparative Methylome Analysis of the Occasional Ruminant Respiratory Pathogen Bibersteinia trehalosi

We examined and compared both the methylomes and the modification-related gene content of four sequenced strains of Bibersteinia trehalosi isolated from the nasopharyngeal tracts of Nebraska cattle with symptoms of bovine respiratory disease complex. The methylation patterns and the encoded DNA methyltransferase (MTase) gene sets were different between each strain, with the only common pattern being that of Dam (GATC). Among the observed patterns were three novel motifs attributable to Type I restriction-modification systems. In some cases the differences in methylation patterns corresponded to the gain or loss of MTase genes, or to recombination at target recognition domains that resulted in changes of enzyme specificity. However, in other cases the differences could be attributed to differential expression of the same MTase gene across strains. The most obvious regulatory mechanism responsible for these differences was slipped strand mispairing within short sequence repeat regions. The combined action of these evolutionary forces allows for alteration of different parts of the methylome at different time scales. We hypothesize that pleiotropic transcriptional modulation resulting from the observed methylomic changes may be involved with the switch between the commensal and pathogenic states of this common member of ruminant microflora.

Type I restriction enzymes and their relatives

Type I restriction enzymes (REases) are large pentameric proteins with separate restriction (R), methylation (M) and DNA sequence-recognition (S) subunits. They were the first REases to be discovered and purified, but unlike the enormously useful Type II REases, they have yet to find a place in the enzymatic toolbox of molecular biologists. Type I enzymes have been difficult to characterize, but this is changing as genome analysis reveals their genes, and methylome analysis reveals their recognition sequences. Several Type I REases have been studied in detail and what has been learned about them invites greater attention. In this article, we discuss aspects of the biochemistry, biology and regulation of Type I REases, and of the mechanisms that bacteriophages and plasmids have evolved to evade them. Type I REases have a remarkable ability to change sequence specificity by domain shuffling and rearrangements. We summarize the classic experiments and observations that led to this discovery, and we discuss how this ability depends on the modular organizations of the enzymes and of their S subunits. Finally, we describe examples of Type II restriction-modification systems that have features in common with Type I enzymes, with emphasis on the varied Type IIG enzymes.

The complex methylome of the human gastric pathogen Helicobacter pylori

The genome of Helicobacter pylori is remarkable for its large number of restriction-modification (R-M) systems, and strain-specific diversity in R-M systems has been suggested to limit natural transformation, the major driving force of genetic diversification in H. pylori. We have determined the comprehensive methylomes of two H. pylori strains at single base resolution, using Single Molecule Real-Time (SMRT®) sequencing. For strains 26695 and J99-R3, 17 and 22 methylated sequence motifs were identified, respectively. For most motifs, almost all sites occurring in the genome were detected as methylated. Twelve novel methylation patterns corresponding to nine recognition sequences were detected (26695, 3; J99-R3, 6). Functional inactivation, correction of frameshifts as well as cloning and expression of candidate methyltransferases (MTases) permitted not only the functional characterization of multiple, yet undescribed, MTases, but also revealed novel features of both Type I and Type II R-M systems, including frameshift-mediated changes of sequence specificity and the interaction of one MTase with two alternative specificity subunits resulting in different methylation patterns. The methylomes of these well-characterized H. pylori strains will provide a valuable resource for future studies investigating the role of H. pylori R-M systems in limiting transformation as well as in gene regulation and host interaction.

Impact of target site distribution for Type I restriction enzymes on the evolution of methicillin-resistant Staphylococcus aureus (MRSA) populations

A limited number of Methicillin-resistant Staphylococcus aureus (MRSA) clones are responsible for MRSA infections worldwide, and those of different lineages carry unique Type I restriction-modification (RM) variants. We have identified the specific DNA sequence targets for the dominant MRSA lineages CC1, CC5, CC8 and ST239. We experimentally demonstrate that this RM system is sufficient to block horizontal gene transfer between clinically important MRSA, confirming the bioinformatic evidence that each lineage is evolving independently. Target sites are distributed randomly in S. aureus genomes, except in a set of large conjugative plasmids encoding resistance genes that show evidence of spreading between two successful MRSA lineages. This analysis of the identification and distribution of target sites explains evolutionary patterns in a pathogenic bacterium. We show that a lack of specific target sites enables plasmids to evade the Type I RM system thereby contributing to the evolution of increasingly resistant community and hospital MRSA.

The complete genome and phenome of a community-acquired Acinetobacter baumannii

Many sequenced strains of Acinetobacter baumannii are established nosocomial pathogens capable of resistance to multiple antimicrobials. Community-acquired A. baumannii in contrast, comprise a minor proportion of all A. baumannii infections and are highly susceptible to antimicrobial treatment. However, these infections also present acute clinical manifestations associated with high reported rates of mortality. We report the complete 3.70 Mbp genome of A. baumannii D1279779, previously isolated from the bacteraemic infection of an Indigenous Australian; this strain represents the first community-acquired A. baumannii to be sequenced. Comparative analysis of currently published A. baumannii genomes identified twenty-four accessory gene clusters present in D1279779. These accessory elements were predicted to encode a range of functions including polysaccharide biosynthesis, type I DNA restriction-modification, and the metabolism of novel carbonaceous and nitrogenous compounds. Conversely, twenty genomic regions present in previously sequenced A. baumannii strains were absent in D1279779, including gene clusters involved in the catabolism of 4-hydroxybenzoate and glucarate, and the A. baumannii antibiotic resistance island, known to bestow resistance to multiple antimicrobials in nosocomial strains. Phenomic analysis utilising the Biolog Phenotype Microarray system indicated that A. baumannii D1279779 can utilise a broader range of carbon and nitrogen sources than international clone I and clone II nosocomial isolates. However, D1279779 was more sensitive to antimicrobial compounds, particularly beta-lactams, tetracyclines and sulphonamides. The combined genomic and phenomic analyses have provided insight into the features distinguishing A. baumannii isolated from community-acquired and nosocomial infections.

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.

Structure and operation of the DNA-translocating type I DNA restriction enzymes

Type I DNA restriction/modification (RM) enzymes are molecular machines found in the majority of bacterial species. Their early discovery paved the way for the development of genetic engineering. They control (restrict) the influx of foreign DNA via horizontal gene transfer into the bacterium while maintaining sequence-specific methylation (modification) of host DNA. The endonuclease reaction of these enzymes on unmethylated DNA is preceded by bidirectional translocation of thousands of base pairs of DNA toward the enzyme. We present the structures of two type I RM enzymes, EcoKI and EcoR124I, derived using electron microscopy (EM), small-angle scattering (neutron and X-ray), and detailed molecular modeling. DNA binding triggers a large contraction of the open form of the enzyme to a compact form. The path followed by DNA through the complexes is revealed by using a DNA mimic anti-restriction protein. The structures reveal an evolutionary link between type I RM enzymes and type II RM enzymes.

Deletion of one nucleotide within the homonucleotide tract present in the hsdS gene alters the DNA sequence specificity of type I restriction-modification system NgoAV

As a result of a frameshift mutation, the hsdS locus of the NgoAV type IC restriction and modification (RM) system comprises two genes, hsdS(NgoAV1) and hsdS(NgoAV2). The specificity subunit, HsdS(NgoAV), the product of the hsdS(NgoAV1) gene, is a naturally truncated form of an archetypal specificity subunit (208 N-terminal amino acids instead of 410). The presence of a homonucleotide tract of seven guanines (poly[G]) at the 3' end of the hsdS(NgoAV1) gene makes the NgoAV system a strong candidate for phase variation, i.e., stochastic addition or reduction in the guanine number. We have constructed mutants with 6 guanines instead of 7 and demonstrated that the deletion of a single nucleotide within the 3' end of the hsdS(NgoAV1) gene restored the fusion between the hsdS(NgoAV1) and hsdS(NgoAV2) genes. We have demonstrated that such a contraction of the homonucleotide tract may occur in vivo: in a Neisseria gonorrhoeae population, a minor subpopulation of cells appeared to have only 6 guanines at the 3' end of the hsdS(NgoAV1) gene. Escherichia coli cells carrying the fused gene and expressing the NgoAVΔ RM system were able to restrict λ phage at a level comparable to that for the wild-type NgoAV system. NgoAV recognizes the quasipalindromic interrupted sequence 5'-GCA(N(8))TGC-3' and methylates both strands. NgoAVΔ recognizes DNA sequences 5'-GCA(N(7))GTCA-3' and 5'-GCA(N(7))CTCA-3', although the latter sequence is methylated only on the complementary strand within the 5'-CTCA-3' region of the second recognition target sequence.

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.

Structural and functional analysis of the engineered type I DNA methyltransferase EcoR124I(NT)

The Type I R-M system EcoR124I is encoded by three genes. HsdM is responsible for modification (DNA methylation), HsdS for DNA sequence specificity and HsdR for restriction endonuclease activity. The trimeric methyltransferase (M(2)S) recognises the asymmetric sequence (GAAN(6)RTCG). An engineered R-M system, denoted EcoR124I(NT), has two copies of the N-terminal domain of the HsdS subunit of EcoR124I, instead of a single S subunit with two domains, and recognises the symmetrical sequence GAAN(7)TTC. We investigate the methyltransferase activity of EcoR124I(NT), characterise the enzyme and its subunits by analytical ultracentrifugation and obtain low-resolution structural models from small-angle neutron scattering experiments using contrast variation and selective deuteration of subunits.

Comparative genomic analyses of attenuated strains of Mycoplasma gallisepticum

Mycoplasma gallisepticum is a significant respiratory and reproductive pathogen of domestic poultry. While the complete genomic sequence of the virulent, low-passage M. gallisepticum strain R (R(low)) has been reported, genomic determinants responsible for differences in virulence and host range remain to be completely identified. Here, we utilize genome sequencing and microarray-based comparative genomic data to identify these genomic determinants of virulence and to elucidate genomic variability among strains of M. gallisepticum. Analysis of the high-passage, attenuated derivative of R(low), R(high), indicated that relatively few total genomic changes (64 loci) occurred, yet they are potentially responsible for the observed attenuation of this strain. In addition to previously characterized mutations in cytadherence-related proteins, changes included those in coding sequences of genes involved in sugar metabolism. Analyses of the genome of the M. gallisepticum vaccine strain F revealed numerous differences relative to strain R, including a highly divergent complement of vlhA surface lipoprotein genes, and at least 16 genes absent or significantly fragmented relative to strain R. Notably, an R(low) isogenic mutant in one of these genes (MGA_1107) caused significantly fewer severe tracheal lesions in the natural host compared to virulent M. gallisepticum R(low). Comparative genomic hybridizations indicated few genetic loci commonly affected in F and vaccine strains ts-11 and 6/85, which would correlate with proteins affecting strain R virulence. Together, these data provide novel insights into inter- and intrastrain M. gallisepticum genomic variability and the genetic basis of M. gallisepticum virulence.

EcoR124I: from plasmid-encoded restriction-modification system to nanodevice

SUMMARY

Plasmid R124 was first described in 1972 as being a new member of incompatibility group IncFIV, yet early physical investigations of plasmid DNA showed that this type of classification was more complex than first imagined. Throughout the history of the study of this plasmid, there have been many unexpected observations. Therefore, in this review, we describe the history of our understanding of this plasmid and the type I restriction-modification (R-M) system that it encodes, which will allow an opportunity to correct errors, or misunderstandings, that have arisen in the literature. We also describe the characterization of the R-M enzyme EcoR124I and describe the unusual properties of both type I R-M enzymes and EcoR124I in particular. As we approached the 21st century, we began to see the potential of the EcoR124I R-M enzyme as a useful molecular motor, and this leads to a description of recent work that has shown that the R-M enzyme can be used as a nanoactuator. Therefore, this is a history that takes us from a plasmid isolated from (presumably) an infected source to the potential use of the plasmid-encoded R-M enzyme in bionanotechnology.

Structural model for the multisubunit Type IC restriction-modification DNA methyltransferase M.EcoR124I in complex with DNA

Recent publication of crystal structures for the putative DNA-binding subunits (HsdS) of the functionally uncharacterized Type I restriction–modification (R-M) enzymes MjaXIP and MgeORF438 have provided a convenient structural template for analysis of the more extensively characterized members of this interesting family of multisubunit molecular motors. Here, we present a structural model of the Type IC M.EcoR124I DNA methyltransferase (MTase), comprising the HsdS subunit, two HsdM subunits, the cofactor AdoMet and the substrate DNA molecule. The structure was obtained by docking models of individual subunits generated by fold-recognition and comparative modelling, followed by optimization of inter-subunit contacts by energy minimization. The model of M.EcoR124I has allowed identification of a number of functionally important residues that appear to be involved in DNA-binding. In addition, we have mapped onto the model the location of several new mutations of the hsdS gene of M.EcoR124I that were produced by misincorporation mutagenesis within the central conserved region of hsdS, we have mapped all previously identified DNA-binding mutants of TRD2 and produced a detailed analysis of the location of surface-modifiable lysines. The model structure, together with location of the mutant residues, provides a better background on which to study protein–protein and protein–DNA interactions in Type I R-M systems.

Four new type I restriction enzymes identified in Escherichia coli clinical isolates

Using a plasmid transformation method and the RM search computer program, four type I restriction enzymes with new recognition sites and two isoschizomers (EcoBI and Eco377I) were identified in a collection of clinical Escherichia coli isolates. These new enzymes were designated Eco394I, Eco826I, Eco851I and Eco912I. Their recognition sequences were determined to be GAC(5N)RTAAY, GCA(6N)CTGA, GTCA(6N)TGAY and CAC(5N)TGGC, respectively. A methylation sensitivity assay, using various synthetic oligonucleotides, was used to identify the adenines that prevent cleavage when methylated (underlined). These results suggest that type I enzymes are abundant in E.coli and many other bacteria, as has been inferred from bacterial genome sequencing projects.

Tetra-amino-acid tandem repeats are involved in HsdS complementation in type IC restriction-modification systems

All known type I restriction and modification (R-M) systems of Escherichia coli and Salmonella enterica belong to one of four discrete families: type IA, IB, IC or ID. The classification of type I systems from a wide range of other genera is mainly based on complementation and molecular evidence derived from the comparison of the amino acid similarity of the corresponding subunits. This affiliation was seldom based on the strictest requirement for membership of a family, which depends on relatedness as demonstrated by complementation tests. This paper presents data indicating that the type I NgoAV R-M system from Neisseria gonorrhoeae, despite the very high identity of HsdM and HsdR subunits with members of the type IC family, does not show complementation with E. coli type IC R-M systems. Sequence analysis of the HsdS subunit of several different potential type IC R-M systems shows that the presence of different tetra-amino-acid sequence repeats, e.g. TAEL, LEAT, SEAL, TSEL, is characteristic for type IC R-M systems encoded by distantly related bacteria. The other regions of the HsdS subunits potentially responsible for subunit interaction are also different between a group of distantly related bacteria, but show high similarity within these bacteria. Complementation between the NgoAV R-M system and members of the EcoR124 R-M family can be restored by changing the tetra-amino-acid repeat within the HsdS subunit. The authors propose that the type IC family of R-M systems could consist of several complementation subgroups whose specificity would depend on differences in the conserved regions of the HsdS polypeptide.

Characterization of an EcoR124I restriction-modification enzyme produced from a deleted form of the DNA-binding subunit, which results in a novel DNA specificity

We purified and characterized both the methyltransferase and the endonuclease containing the HsdS delta 50 subunit (type I restriction endonucleases are composed of three subunits--HsdR required for restriction, HsdM required for methylation and HsdS responsible for DNA recognition) produced from the deletion mutation hsdS delta 50 of the type IC R-M system EcoR 124I; this mutant subunit lacks the C-terminal 163 residues of HsdS and produces a novel DNA specificity. Analysis of the purified HsDs delta 50 subunit indicated that during purification it is subject to partial proteolysis resulting in removal of approximately 1 kDa of the polypeptide at the C-terminus. This proteolysis prevented the purification of further deletion mutants, which were determined as having a novel DNA specificity in vivo. After biochemical characterization of the mutant DNA methyltransferase (MTase) and restriction endonuclease we found only one difference comparing with the wild-type enzyme--a significantly higher binding affinity of the MTase for the two substrates of hemimethylated and fully methylated DNA. This indicates that MTase delta 50 is less able to discriminate the methylation status of the DNA during its binding. However, the mutant MTase still preferred hemimethylated DNA as the substrate for methylation. We fused the hsdM and hsdS delta 50 genes and showed that the HsdM-HsdS delta 50 fusion protein is capable of dimerization confirming the model for assembly of this deletion mutant.

Purification and characterisation of a novel DNA methyltransferase, M.AhdI

We have cloned the M and S genes of the restriction-modification (R-M) system AhdI and have purified the resulting methyltransferase to homogeneity. M.AhdI is found to form a 170 kDa tetrameric enzyme having a subunit stoichiometry M2S2 (where the M and S subunits are responsible for methylation and DNA sequence specificity, respectively). Sedimentation equilibrium experiments show that the tetrameric enzyme dissociates to form a heterodimer at low concentration, with K(d) approximately 2 microM. The intact (tetrameric) enzyme binds specifically to a 30 bp DNA duplex containing the AhdI recognition sequence GACN5GTC with high affinity (K(d) approximately 50 nM), but at low enzyme concentration the DNA binding activity is governed by the dissociation of the tetramer into dimers, leading to a sigmoidal DNA binding curve. In contrast, only non-specific binding is observed if the duplex lacks the recognition sequence. Methylation activity of the purified enzyme was assessed by its ability to prevent restriction by the cognate endonuclease. The subunit structure of the M.AhdI methyltransferase resembles that of type I MTases, in contrast to the R.AhdI endonuclease which is typical of type II systems. AhdI appears to be a novel R-M system with properties intermediate between simple type II systems and more complex type I systems, and may represent an intermediate in the evolution of R-M systems.

Complex restriction enzymes: NTP-driven molecular motors

Survival is assuredly the prime directive for all living organisms either as individuals or as a species. One of the main challenges encountered by bacterial populations is the danger of bacteriophage attacks, since infection of a single bacterium may rapidly propagate, decimating the entire population. In order to protect themselves against this acute threat, bacteria have developed an array of defence mechanisms, which range from preventing the infection itself via interference with bacteriophage adsorption to the cell surface and prevention of phage DNA injection, to degradation of the injected phage DNA. This last defence mechanism is catalysed by the bacterial restriction-modification (R-M) systems, and in particular, by nucleoside 5'-triphosphate (NTP)-dependent restriction enzymes, e.g. type I and type III R-M systems or the modification-dependent endonucleases. Type I and type III restriction systems have dual properties. They may either act as methylases and protect the host's own DNA against restriction by methylating specific residues, or they catalyse ATP-dependent endonuclease activity so that invading foreign DNA lacking the host-specific methylation is degraded. These defence mechanism systems are further complemented by the presence of methylation-dependent, GTP-dependent endonucleases, that restricts specifically methylated DNA. Although all three types of endonucleases are structurally very different, they share a common functional mechanism. They recognise and bind to specific DNA sequences but do not cleave DNA within those target sites. They belong to the general class of DNA motor proteins, which use the free energy associated with nucleoside 5'-triphosphate hydrolysis to translocate DNA so that the subsequent DNA cleavage event occurs at a distance from the endonuclease recognition site. Moreover, DNA cleavage appears to be a random process triggered upon stalling of the DNA translocation process and requiring dimerisation of the bound endonucleases for a concerted break of both DNA strands. In this review, we present a detailed description and analysis of the functional mechanism of the three known NTP-dependent restriction systems: type I and type III restriction-modification enzymes, as well as the methylation-dependent McrBC endonuclease.

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

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

Domain structure and subunit interactions in the type I DNA methyltransferase M.EcoR124I

The type IC DNA methyltransferase M.EcoR124I is a trimeric enzyme of 162 kDa consisting of two modification subunits, HsdM, and a single specificity subunit, HsdS. Studies have been largely restricted to the HsdM subunit or to the intact methyltransferase since the HsdS subunit is insoluble when over-expressed independently of HsdM. Two soluble fragments of the HsdS subunit have been cloned, expressed and purified; a 25 kDa N-terminal fragment (S3) comprising the N-terminal target recognition domain together with the central conserved domain, and a 8.6 kDa fragment (S11) comprising the central conserved domain alone. Analytical ultracentrifugation shows that the S3 subunit exists principally as a dimer of 50 kDa. Gel retardation and competition assays show that both S3 and S11 are able to bind to HsdM, each with a subunit stoichiometry of 1:1. The tetrameric complex (S3/HsdM)(2) is required for effective DNA binding. Cooperative binding is observed and at low enzyme concentration, the multisubunit complex dissociates, leading to a loss of DNA binding activity. The (S3/HsdM)(2) complex is able to bind to both the EcoR124I DNA recognition sequence GAAN(6)RTCG and a symmetrical DNA sequence GAAN(7)TTC, but has a 30-fold higher affinity binding for the latter DNA sequence. Exonuclease III footprinting of the (S3/HsdM)(2) -DNA complex indicates that 29 nucleotides are protected on each strand, corresponding to a region 8 bp on both the 3' and 5' sides of the recognition sequence bound by the (S3/HsdM)(2) complex.

A novel mutant of the type I restriction-modification enzyme EcoR124I is altered at a key stage of the subunit assembly pathway

The HsdS subunit of a type I restriction-modification (R-M) system plays an essential role in the activity of both the modification methylase and the restriction endonuclease. This subunit is responsible for DNA binding, but also contains conserved amino acid sequences responsible for protein-protein interactions. The most important protein-protein interactions are those between the HsdS subunit and the HsdM (methylation) subunit that result in assembly of an independent methylase (MTase) of stoichiometry M(2)S(1). Here, we analysed the impact on the restriction and modification activities of the change Trp(212)-->Arg in the distal border of the central conserved region of the EcoR124I HsdS subunit. We demonstrate that this point mutation significantly influences the ability of the mutant HsdS subunit to assemble with the HsdM subunit to produce a functional MTase. As a consequence of this, the mutant MTase has drastically reduced DNA binding, which is restored only when the HsdR (restriction) subunit binds with the MTase. Therefore, HsdR acts as a chaperon allowing not only binding of the enzyme to DNA, but also restoring the methylation activity and, at sufficiently high concentrations in vitro of HsdR, restoring restriction activity.

Type I restriction systems: sophisticated molecular machines (a legacy of Bertani and Weigle)

Restriction enzymes are well known as reagents widely used by molecular biologists for genetic manipulation and analysis, but these reagents represent only one class (type II) of a wider range of enzymes that recognize specific nucleotide sequences in DNA molecules and detect the provenance of the DNA on the basis of specific modifications to their target sequence. Type I restriction and modification (R-M) systems are complex; a single multifunctional enzyme can respond to the modification state of its target sequence with the alternative activities of modification or restriction. In the absence of DNA modification, a type I R-M enzyme behaves like a molecular motor, translocating vast stretches of DNA towards itself before eventually breaking the DNA molecule. These sophisticated enzymes are the focus of this review, which will emphasize those aspects that give insights into more general problems of molecular and microbial biology. Current molecular experiments explore target recognition, intramolecular communication, and enzyme activities, including DNA translocation. Type I R-M systems are notable for their ability to evolve new specificities, even in laboratory cultures. This observation raises the important question of how bacteria protect their chromosomes from destruction by newly acquired restriction specifities. Recent experiments demonstrate proteolytic mechanisms by which cells avoid DNA breakage by a type I R-M system whenever their chromosomal DNA acquires unmodified target sequences. Finally, the review will reflect the present impact of genomic sequences on a field that has previously derived information almost exclusively from the analysis of bacteria commonly studied in the laboratory.

ATP-dependent restriction enzymes

The phenomenon of restriction and modification (R-M) was first observed in the course of studies on bacteriophages in the early 1950s. It was only in the 1960s that work of Arber and colleagues provided a molecular explanation for the host specificity. DNA restriction and modification enzymes are responsible for the host-specific barriers to interstrain and interspecies transfer of genetic information that have been observed in a variety of bacterial cell types. R-M systems comprise an endonuclease and a methyltransferase activity. They serve to protect bacterial cells against bacteriophage infection, because incoming foreign DNA is specifically cleaved by the restriction enzyme if it contains the recognition sequence of the endonuclease. The DNA is protected from cleavage by a specific methylation within the recognition sequence, which is introduced by the methyltransferase. Classic R-M systems are now divided into three types on the basis of enzyme complexity, cofactor requirements, and position of DNA cleavage, although new systems are being discovered that do not fit readily into this classification. This review concentrates on multisubunit, multifunctional ATP-dependent restriction enzymes. A growing number of these enzymes are being subjected to biochemical and genetic studies that, when combined with ongoing structural analyses, promise to provide detailed models for mechanisms of DNA recognition and catalysis. It is now clear that DNA cleavage by these enzymes involves highly unusual modes of interaction between the enzymes and their substrates. These unique features of mechanism pose exciting questions and in addition have led to the suggestion that these enzymes may have biological functions beyond that of restriction and modification. The purpose of this review is to describe the exciting developments in our understanding of how the ATP-dependent restriction enzymes recognize specific DNA sequences and cleave or modify DNA.

Interaction of the type I methyltransferase M.EcoR124I with modified DNA substrates: sequence discrimination and base flipping

We have analysed the DNA-protein contacts made between the type I DNA methyltransferase M.EcoR124I and its recognition sequence. The effects of base modifications have been probed by measuring the affinity of M.EcoR124I for the modified sequences relative to that for the wild-type sequence by using gel-retardation competition assays. These results, along with those from methylation interference footprinting and photo-affinity cross-linking have identified the location of potential DNA contacts within the DNA recognition site. Substitution of 6-thioguanosine for each of the three specific guanines in the recognition sequence leads to a large (10-20-fold) decrease in the strength of DNA binding, indicating the importance of hydrogen-bonding interactions in the major groove of DNA. In contrast, replacement of either (or both) of the adenines at the target site for methylation by the enzyme, to produce either a base pair mismatch or loss of the base, leads to a marked increase in DNA-binding affinity. The results strongly support the proposal that type I methyltransferases employ a base-flipping mechanism to methylate their target base.

The DNA recognition subunit of the type IB restriction-modification enzyme EcoAI tolerates circular permutions of its polypeptide chain

The DNA specificity subunit (HsdS) of type I restriction-modification enzymes is composed of two independent target recognition domains and several regions whose amino acid sequence is conserved within an enzyme family. The conserved regions participate in intersubunit interactions with two modification subunits (HsdM) and two restriction subunits (HsdR) to form the complete endonuclease. It has been proposed that the domains of the HsdS subunit have a circular organisation providing the required symmetry for their interaction with the other subunits and with the bipartite DNA target. To test this model, we circularly permuted the HsdS subunit of the type IB R-M enzyme EcoAI at the DNA level by direct linkage of codons for original termini and introduction of new termini elsewhere along the N-terminal and central conserved regions. By analysing the activity of mutant enzymes, two circularly permuted variants of HsdS that had termini located at equivalent positions in the N-terminal and central repeats, respectively, were found to fold into a functional DNA recognition subunit with wild-type specificity, suggesting a close proximity of the N and C termini in the native protein. The wild-type HsdS subunit was purified to homogeneity and shown to form a stable trimeric complex with HsdM, M2S1, which was fully active as a DNA methyltransferase. Gel electrophoretic mobility shift assays revealed that the HsdS protein alone was not able to form a specific complex with a 30-mer oligoduplex containing a single EcoAI recognition site. However, addition of stoichiometric amounts of HsdM to HsdS led to efficient specific DNA binding. Our data provide evidence for the circular organisation of domains of the HsdS subunit. In addition, they suggest a possible role of HsdM subunits in the formation of this structure.

Genomic structure of the human DNA methyltransferase gene

We determined the genomic structure of the gene encoding human DNA methyltransferase (DNA MTase). Six overlapping human genomic DNA clones which include all of the known cDNA sequence were isolated. Analysis of these clones demonstrates that the human DNA MTase gene consists of at least 40 exons and 39 introns spanning a distance of 60 kilobases. Elucidation of the chromosomal organization of the human DNA MTase gene provides the template for future structure-function analysis of the properties of mammalian DNA MTase.

Expression and characterisation of the N-terminal fragment of the HsdS subunit of M.EcoR124I

The type IC modification methyltransferase M.EcoR124I is a trimeric enzyme of 162 kDa consisting of two copies of the modification subunit, HsdM, and a single DNA specificity subunit, HsdS. Studies to date have been largely restricted to the HsdM subunit or the intact methyltransferase, since the HsdS subunit is insoluble when expressed independently of HsdM. Using PCR, we have cloned and expressed 13 fragments of the gene for the HsdS subunit, including the sequences encoding each of the variable and conserved domains and various combinations of these. Only two of these fragments were found to be soluble, a 8.6 kDa fragment (S11) comprising the central conserved domain and a 25 kDa N-terminal fragment (S3) containing the N-terminal variable domain and the central conserved domain. Analysis of the larger of these fragments by gel retardation shows that the protein binds DNA in the presence of HsdM at a subunit stoichiometry of 1:1. Gel filtration and CD spectroscopy indicate that the protein is monomeric and predominantly alpha-helical.

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.

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

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

The HsdR subunit of R.EcoR124II: cloning and over-expression of the gene and unexpected properties of the subunit

Type I restriction endonucleases are composed of three subunits, HsdR, HsdM and HsdS. The HsdR subunit is absolutely required for restriction activity; while an independent methylase is composed of HsdM and HsdS subunits. DNA cleavage is associated with a powerful ATPase activity during which DNA is translocated by the enzyme prior to cleavage. The presence of a Walker type I ATP-binding site within the HsdR subunit suggested that the subunit may be capable of independent enzymatic activity. Therefore, we have, for the first time, cloned and over-expressed the hsdRgene of the type IC restriction endonuclease EcoR124II. The purified HsdR subunit was found to be a soluble monomeric protein capable of DNA- and Mg2+-dependent ATP hydrolysis. The subunit was found to have a weak nuclease activity both in vivo and in vitro, and to bind plasmid DNA; although was not capable of binding a DNA oligoduplex. We were also able to reconstitute the fully active endonuclease from purified M. EcoR124I and HsdR. This is the first clear demonstration that the HsdR subunit of a type I restriction endonuclease is capable of independent enzyme activity, and suggests a mechanism for the evolution of the endonuclease from the independent methylase.

Repercussions of DNA tracking by the type IC restriction endonuclease EcoR124I on linear, circular and catenated substrates

Type I restriction endonucleases such as EcoR124I cleave DNA at undefined loci, distant from their recognition sequences, by a mechanism that involves the enzyme tracking along the DNA between recognition and cleavage sites. This mechanism was examined on plasmids that carried recognition sites for EcoR124I and recombination sites for resolvase, the latter to create DNA catenanes. Supercoiled substrates with either one or two restriction sites were linearized by EcoR124I at similar rates, although the two-site molecule underwent further cleavage more readily than the one-site DNA. The catenane from the plasmid with one EcoR124I site, carrying the site on the smaller of the two rings, was cleaved by EcoR124I exclusively in the small ring, and this underwent multiple cleavage akin to the two-site plasmid. Linear substrates derived from the plasmids were cleaved by EcoR124I at very slow rates. The communication between recognition and cleavage sites therefore cannot stem from random looping. Instead, it must follow the DNA contour between the sites. On a circular DNA, the translocation of non-specific DNA past the specifically bound protein should increase negative supercoiling in one domain and decrease it in the other. The ensuing topological barrier may be the trigger for DNA cleavage.

Generation of new DNA binding specificity by truncation of the type IC EcoDXXI hsdS gene

The hsdS subunit of a type IC restriction-modification enzyme is responsible for the enzyme's DNA binding specificity. Type I recognition sites are characterized by two defined half-sites separated by a non-specific spacer of defined length. The hsdS subunit contains two independent DNA binding domains, each targeted towards one DNA half-site. We have shown previously that the 5' half of hsdS can code for a functional substitute of the full-length hsdS. Here we demonstrate that the 3' half of the gene, when fused to the appropriate transcriptional and translational start signals, also codes for a peptide which imparts DNA binding specificity to the enzyme. About half the natural hsdS size, the mutant peptide contains a single DNA recognition domain flanked by one copy of each internal repeat found in the full-length hsdS. Deletion of either repeat sequence results in loss of activity. Like the 5' hsdS mutant, the 3' mutant recognizes an interrupted palindrome, GAAYN(5)RTTC, suggesting that two truncated subunits participate in DNA recognition. Co-expression of the 5' hsdS mutant and the 3' hsdS mutant along with hsdM regenerates the wild-type methylation specificity. Thus, there is a free assortment of subunits in the cell.

The diversity of alleles at the hsd locus in natural populations of Escherichia coli

In enteric bacteria three discrete families of type I restriction and modification systems (IA, IB and ID) are encoded by alleles of the serB-linked hsd locus. Probes specific for each of the three families were used to monitor the distribution of related systems in 37 of the 72 wild-type Escherichia coli strains comprising the ECOR collection. All 25 members of group A in this collection were screened; 12 were probe-positive, nine have hsd genes in the IA family, two in the IB and one in the ID. Twelve strains, representing all groups other than A, were screened; five were probe-positive, one has hsd genes in the IA family, one in the IB and three in the ID. The type ID genes are the first representatives of this family in E. coli, the probe-negative strains could have alternative families of hsd genes. The type IA and IB systems added at least five new specificities to the five already identified in natural isolates of E. coli. The distribution of alleles is inconsistent with the dendrogram of the bacterial strains derived from other criteria. This discrepancy and the dissimilar coding sequences of allelic hsd genes both imply lateral transfer of hsd genes.

A motif conserved among the type I restriction-modification enzymes and antirestriction proteins: a possible basis for mechanism of action of plasmid-encoded antirestriction functions

Antirestriction proteins Ard encoded by some self-transmissible plasmids specifically inhibit restriction by members of all three families of type I restriction-modification (R-M) systems in E.coli. Recently, we have identified the amino acid region, 'antirestriction' domain, that is conserved within different plasmid and phage T7-encoded antirestriction proteins and may be involved in interaction with the type I R-M systems. In this paper we demonstrate that this amino acid sequence shares considerable similarity with a well-known conserved sequence (the Argos repeat) found in the DNA sequence specificity (S) polypeptides of type I systems. We suggest that the presence of these similar motifs in restriction and antirestriction proteins may give a structural basis for their interaction and that the antirestriction action of Ard proteins may be a result of the competition between the 'antirestriction' domains of Ard proteins and the similar conserved domains of the S subunits that are believed to play a role in the subunit assembly of type I R-M systems.

Restriction enzymes in cells, not eppendorfs

Restriction enzymes are essential reagents to molecular biologists, but their relevance to bacterial populations is less obvious. Most bacteria encode restriction and modification systems and these are commonly considered to be a barrier to phage infection. Current evidence also supports a more general role for them in genetic recombination.

The domains of a type I DNA methyltransferase. Interactions and role in recognition of DNA methylation

The DNA methyltransferases of type I restriction-modification systems are trimeric enzymes composed of one DNA specificity (S) subunit and two modification (M) subunits. The S subunit contains two large regions, each of which recognizes one part of the split, asymmetrical DNA target sequence. Each M subunit contains an amino acid motif for binding the methyl group donor and cofactor, S-adenosyl methionine. The EcoKI methyltransferase has a strong preference for methylating a hemimethylated DNA target rather than an unmodified target. We have used partial proteolytic digestion of EcoKI methyltransferase to generate polypeptide domains that we have identified by amino acid sequencing. The S subunit was cut into two large, folded domains each containing one DNA binding region. Binding of DNA partially protected the S subunit from digestion. The M subunit was also cut into two large domains joined together by a short flexible loop, and a C-terminal tail region. The short loop contained part of the S-adenosyl methionine binding motif, and cofactor binding protected the loop and the two large domains from proteolysis. The C-terminal domain of M remained associated with the N-terminal domain of the S subunit even after the rest of the protein had been digested. The conformation of the tail region of the M subunit was sensitive to the methylation state of DNA in ternary complexes also containing S-adenosyl methionine, and could differentiate between unmethylated and hemimethylated DNA substrates.