Cloning and analysis of a bifunctional methyltransferase/restriction endonuclease TspGWI, the prototype of a Thermus sp. enzyme family

Novel parameter describing restriction endonucleases: Secondary-Cognate-Specificity and chemical stimulation of TsoI leading to substrate specificity change

Over 470 prototype Type II restriction endonucleases (REases) are currently known. Most recognise specific DNA sequences 4–8 bp long, with very few exceptions cleaving DNA more frequently. TsoI is a thermostable Type IIC enzyme that recognises the DNA sequence TARCCA (R = A or G) and cleaves downstream at N11/N9. The enzyme exhibits extensive top-strand nicking of the supercoiled single-site DNA substrate. The second DNA strand of such substrate is specifically cleaved only in the presence of duplex oligonucleotides containing a cognate site. We have previously shown that some Type IIC/IIG/IIS enzymes from the Thermus-family exhibit ‘affinity star’ activity, which can be induced by the S-adenosyl-L-methionine (SAM) cofactor analogue—sinefungin (SIN). Here, we define a novel type of inherently built-in ‘star’ activity, exemplified by TsoI. The TsoI ‘star’ activity cannot be described under the definition of the classic ‘star’ activity as it is independent of the reaction conditions used and cannot be separated from the cognate specificity. Therefore, we define this phenomenon as Secondary-Cognate-Specificity (SCS). The TsoI SCS comprises several degenerated variants of the cognate site. Although the efficiency of TsoI SCS cleavage is lower in comparison to the cognate TsoI recognition sequence, it can be stimulated by S-adenosyl-L-cysteine (SAC). We present a new route for the chemical synthesis of SAC. The TsoI/SAC REase may serve as a novel tool for DNA manipulation.

Structure, subunit organization and behavior of the asymmetric Type IIT restriction endonuclease BbvCI

BbvCI, a Type IIT restriction endonuclease, recognizes and cleaves the seven base pair sequence 5'-CCTCAGC-3', generating 3-base, 5'-overhangs. BbvCI is composed of two protein subunits, each containing one catalytic site. Either site can be inactivated by mutation resulting in enzyme variants that nick DNA in a strand-specific manner. Here we demonstrate that the holoenzyme is labile, with the R1 subunit dissociating at low pH. Crystallization of the R2 subunit under such conditions revealed an elongated dimer with the two catalytic sites located on opposite sides. Subsequent crystallization at physiological pH revealed a tetramer comprising two copies of each subunit, with a pair of deep clefts each containing two catalytic sites appropriately positioned and oriented for DNA cleavage. This domain organization was further validated with single-chain protein constructs in which the two enzyme subunits were tethered via peptide linkers of variable length. We were unable to crystallize a DNA-bound complex; however, structural similarity to previously crystallized restriction endonucleases facilitated creation of an energy-minimized model bound to DNA, and identification of candidate residues responsible for target recognition. Mutation of residues predicted to recognize the central C:G base pair resulted in an altered enzyme that recognizes and cleaves CCTNAGC (N = any base).

New bifunctional restriction-modification enzyme AloI isoschizomer (PcoI): Bioinformatics analysis, purification and activity confirmation

Type II restriction endonucleases and modification DNA-methyltransferases are key instruments of genetic engineering. Recently the number of proteins assigned to this group exceeds 8500. Subtype IIC organizes bifunctional endonuclease-methyltransferase enzymes and currently consists of 16 described members. Here we present phylogenetic tree of 22 new potential bifunctional endonucleases. The majority of them are thought to be fusions of a restriction nuclease with a DNA-methyltransferase and a target recognition subunit of type I restriction-modification systems (R-M-S structure). A RM.AloI isoschizomer from Prevotella copri DSM-18205, PcoI, has been cloned, purified and its REase activity demonstrated. It cuts DNA in magnesium-dependent manner and demonstrates high affinity to DNA, which probably reflects its mechanism of action. This work provides additional proves that gene fusion might play an important role in evolution of restriction-modification systems and other DNA-modifying proteins.

Thermostable proteins bioprocesses: The activity of restriction endonuclease-methyltransferase from Thermus thermophilus (RM.TthHB27I) cloned in Escherichia coli is critically affected by the codon composition of the synthetic gene

Obtaining thermostable enzymes (thermozymes) is an important aspect of biotechnology. As thermophiles have adapted their genomes to high temperatures, their cloned genes’ expression in mesophiles is problematic. This is mainly due to their high GC content, which leads to the formation of unfavorable secondary mRNA structures and codon usage in Escherichia coli (E. coli). RM.TthHB27I is a member of a family of bifunctional thermozymes, containing a restriction endonuclease (REase) and a methyltransferase (MTase) in a single polypeptide. Thermus thermophilus HB27 (T. thermophilus) produces low amounts of RM.TthHB27I with a unique DNA cleavage specificity. We have previously cloned the wild type (wt) gene into E. coli, which increased the production of RM.TthHB27I over 100-fold. However, its enzymatic activities were extremely low for an ORF expressed under a T7 promoter. We have designed and cloned a fully synthetic tthHB27IRM gene, using a modified ‘codon randomization’ strategy. Codons with a high GC content and of low occurrence in E. coli were eliminated. We incorporated a stem-loop circuit, devised to negatively control the expression of this highly toxic gene by partially hiding the ribosome-binding site (RBS) and START codon in mRNA secondary structures. Despite having optimized 59% of codons, the amount of produced RM.TthHB27I protein was similar for both recombinant tthHB27IRM gene variants. Moreover, the recombinant wt RM.TthHB27I is very unstable, while the RM.TthHB27I resulting from the expression of the synthetic gene exhibited enzymatic activities and stability equal to the native thermozyme isolated from T. thermophilus. Thus, we have developed an efficient purification protocol using the synthetic tthHB27IRM gene variant only. This suggests the effect of co-translational folding kinetics, possibly affected by the frequency of translational errors. The availability of active RM.TthHB27I is of practical importance in molecular biotechnology, extending the palette of available REase specificities.

The third restriction-modification system from Thermus aquaticus YT-1: solving the riddle of two TaqII specificities

Two restriction-modification systems have been previously discovered in Thermus aquaticus YT-1. TaqI is a 263-amino acid (aa) Type IIP restriction enzyme that recognizes and cleaves within the symmetric sequence 5'-TCGA-3'. TaqII, in contrast, is a 1105-aa Type IIC restriction-and-modification enzyme, one of a family of Thermus homologs. TaqII was originally reported to recognize two different asymmetric sequences: 5'-GACCGA-3' and 5'-CACCCA-3'. We previously cloned the taqIIRM gene, purified the recombinant protein from Escherichia coli, and showed that TaqII recognizes the 5'-GACCGA-3' sequence only. Here, we report the discovery, isolation, and characterization of TaqIII, the third R-M system from T. aquaticus YT-1. TaqIII is a 1101-aa Type IIC/IIL enzyme and recognizes the 5'-CACCCA-3' sequence previously attributed to TaqII. The cleavage site is 11/9 nucleotides downstream of the A residue. The enzyme exhibits striking biochemical similarity to TaqII. The 93% identity between their aa sequences suggests that they have a common evolutionary origin. The genes are located on two separate plasmids, and are probably paralogs or pseudoparalogs. Putative positions and aa that specify DNA recognition were identified and recognition motifs for 6 uncharacterized Thermus-family enzymes were predicted.

A putative Type IIS restriction endonuclease GeoICI from Geobacillus sp.--A robust, thermostable alternative to mezophilic prototype BbvI

Screening of extreme environments in search for novel microorganisms may lead to the discovery of robust enzymes with either new substrate specificities or thermostable equivalents of those already found in mesophiles, better suited for biotechnology applications. Isolates from Iceland geysers' biofilms, exposed to a broad range of temperatures, from ambient to close to water boiling point, were analysed for the presence of DNA-interacting proteins, including restriction endonucleases (REases). GeoICI, a member of atypical Type IIS REases, is the most thermostable isoschizomer of the prototype BbvI, recognizing/cleaving 5'-GCAGC(N8/12)-3'DNA sequences. As opposed to the unstable prototype, which cleaves DNA at 30°C, GeoICI is highly active at elevated temperatures, up to 73°C and over a very wide salt concentration range. Recognition/cleavage sites were determined by: (i) digestion of plasmid and bacteriophage lambda DNA (Λ); (ii) cleavage of custom PCR substrates, (iii) run-off sequencing of GeoICI cleavage products and (iv) shotgun cloning and sequencing of Λ DNA fragmented with GeoICI. Geobacillus sp. genomic DNA was PCR-screened for the presence of other specialized REases-MTases and as a result, another putative REase- MTase, GeoICII, related to the Thermus sp. family of bifunctional REases-methyltransferases (MTases) was detected.

Engineering TaqII bifunctional endonuclease DNA recognition fidelity: the effect of a single amino acid substitution within the methyltransferase catalytic site

The aim of this study was to improve a useful molecular tool-TaqII restriction endonuclease-methyltransferase-by rational protein engineering, as well as to show an application of our novel method of restriction endonuclease activity modulation through a single amino acid change in the NPPY motif of methyltransferase. An amino acid change was introduced using site-directed mutagenesis into the taqIIRM gene. The mutated gene was expressed in Escherichia coli. The protein variant was purified and characterized. Previously, we described a TspGWI variant with an amino acid change in the methyltransferase motif IV. Here, we investigate a complex, pleiotropic effect of an analogous amino acid change on its homologue-TaqII. The methyltransferase activity is reduced, but not abolished, while TaqII restriction endonuclease can be reactivated by sinefungin, with an increased DNA recognition fidelity. The general method for engineering of the IIS/IIC/IIG restriction endonuclease activity/fidelity is developed along with the generation of an improved TaqII enzyme for biotechnological applications. A successful application of our novel strategy for restriction endonuclease activity/fidelity alteration, based on bioinformatics analyses, mutagenesis and the use of cofactor-analogue activity modulation, is presented.

Two-stage gene assembly/cloning of a member of the TspDTI subfamily of bifunctional restriction endonucleases, TthHB27I

The Thermus sp. family of bifunctional type IIS/IIG/IIC restriction endonucleases (REase)-methyltransferases (MTase) comprises thermo-stable TaqII, TspGWI, TspDTI, TsoI, Tth111II/TthHB27I enzymes as well as a number of putative enzymes/open reading frames (ORFs). All of the family members share properties including a large protein size (ca. 120kDa), amino acid (aa) sequence homologies, enzymatic activity modulation by S-adenosylmethionine (SAM), recognition of similar asymmetric cognate DNA sites and cleavage at a distance of 11/9 nt. Analysis of the enzyme aa sequences and domain/motif organisation led to further Thermus sp. family division into the TspDTI and TspGWI subfamilies. The latter exhibits an unprecedented phenomenon of DNA recognition change upon substitution of SAM by its analogue, sinefungin (SIN), towards a very frequent DNA cleavage. We report cloning in Escherichia coli (E. coli), using a two-stage procedure and a putative tthHB27IRM gene, detected by bioinformatics analysis of the Thermus thermophilus HB27 (T. thermophilus) genome. The functionality of a 3366 base pair (bp)-/1121 aa-long, high GC content ORF was validated experimentally through the expression in E. coli. Protein features corroborated with the reclassification of TthHB27I into the TspDTI subfamily, which manifested in terms of aa-sequence/motif homologies and insensitivity to SIN-induced specificity shift. However, both SAM and SIN stimulated the REase DNA cleavage activity by at least 16-32 times; the highest was observed for the Thermus sp. family. The availability of TthHB27I and the need to include SAM or SIN in the reaction in order to convert the enzyme from "hibernation" status to efficient DNA cleavage is of practical significance in molecular biotechnology, extending the palette of available REase specificities.

A new prototype IIS/IIC/IIG endonuclease-methyltransferase TsoI from the thermophile Thermus scotoductus, recognising 5'-TARCCA(N11/9)-3' sequences

The Thermus sp. family of IIS/IIG/IIC enzymes includes the thermostable, bifunctional, fused restriction endonuclease (REase)-methyltransferases (MTase): TaqII, Tth111II/TthHB27I, TspGWI, TspDTI and TsoI. The enzymes are large proteins (approximately 120kDa), their enzymatic activities are affected by S-adenosylmethionine (SAM), they recognise similar asymmetric cognate sites and cleave at a distance of 11/9 nucleotides (nt). The enzymes exhibit similarities of their amino acid (aa) sequences and DNA catalytic motifs. Thermus sp. enzymes are an example of functional aa sequence homologies among REases recognising different, yet related DNA sequences. The family consists of TspGWI- and TspDTI-subfamilies. TsoI appears to be a non-identical 'triplet', related to TspDTI and Tth111II/TthHB27I. The discovery of TsoI, purified from Thermus scotoductus, is described. This prototype, displaying a novel specificity, which was determined by: (i) cleavage of a reference plasmid and bacteriophage DNA, (ii) cleavage of custom PCR DNA substrates, (iii) run-off sequencing of cleavage products and (iv) shotgun cloning and sequencing of bacteriophage lambda (λ) DNA digested with TsoI. The enzyme recognises a degenerated 5'-TARCCA-3' sequence, whereas DNA strands are cut 11/9 nt downstream. The discovery of the TsoI prototype is of practical importance in biotechnology, as it extends the palette of cleavage specificities for gene cloning.

Characterization of cleavage intermediate and star sites of RM.Tth111II

Tth111II is a thermostable Type IIGS restriction enzyme that recognizes DNA sites CAARCA (R = A or G) and cleaves downstream at N11/N9. Here, the tth111IIRM gene was cloned and expressed in E. coli, and Tth111II was purified. The purified enzyme contains internally-bound S-adenosylmethionine (SAM). When the internal SAM was removed, the endonuclease activity was stimulated by adding SAM or its analog sinefungin. The cleavage intermediate is mostly top-strand nicked DNA on a single-site plasmid. Addition of duplex oligos with a cognate site stimulates cleavage activity of the one-site substrate. Tth111II cleaves a two-site plasmid DNA with equal efficiency regardless of site orientation. We propose the top-strand nicking is carried out by a Tth111II monomer and bottom-strand cleavage is carried out by a transient dimer. Tth111II methylates cleavage product-like duplex oligos CAAACAN9, but the modification rate is estimated to be much slower than the top-strand nicking rate. We cloned and sequenced a number of Tth111II star sites which are 1-bp different from the cognate sites. A biochemical pathway is proposed for the restriction and methylation activities of Tth111II.

Cofactor analogue-induced chemical reactivation of endonuclease activity in a DNA cleavage/methylation deficient TspGWI N₄₇₃A variant in the NPPY motif

We reported previously that TspGWI, a prototype enzyme of a new Thermus sp. family of restriction endonucleases-methyltransferases (REases-MTases), undergoes the novel phenomenon of sinefungin (SIN)-caused specificity transition. Here we investigated mutant TspGWI N₄₇₃A, containing a single amino acid (aa) substitution in the NPPY motif of the MTase. Even though the aa substitution is located within the MTase polypeptide segment, DNA cleavage and modification are almost completely abolished, indicating that the REase and MTase are intertwined. Remarkably, the TspGWI N₄₇₃A REase functionality can be completely reconstituted by the addition of SIN. We hypothesize that SIN binds specifically to the enzyme and restores the DNA cleavage-competent protein tertiary structure. This indicates the significant role of allosteric effectors in DNA cleavage in Thermus sp. enzymes. This is the first case of REase mutation suppression by an S-adenosylmethionine (SAM) cofactor analogue. Moreover, the TspGWI N₄₇₃A clone strongly affects E. coli division control, acting as a ‘selfish gene’. The mutant lacks the competing MTase activity and therefore might be useful for applications in DNA manipulation. Here we present a case study of a novel strategy for REase activity/specificity alteration by a single aa substitution, based on the bioinformatic analysis of active motif locations, combining (a) aa sequence engineering (b) the alteration of protein enzymatic properties, and (c) the use of cofactor–analogue cleavage reconstitution and stimulation.

Modified 'one amino acid-one codon' engineering of high GC content TaqII-coding gene from thermophilic Thermus aquaticus results in radical expression increase

BACKGROUND

An industrial approach to protein production demands maximization of cloned gene expression, balanced with the recombinant host's viability. Expression of toxic genes from thermophiles poses particular difficulties due to high GC content, mRNA secondary structures, rare codon usage and impairing the host's coding plasmid replication.TaqII belongs to a family of bifunctional enzymes, which are a fusion of the restriction endonuclease (REase) and methyltransferase (MTase) activities in a single polypeptide. The family contains thermostable REases with distinct specificities: TspGWI, TaqII, Tth111II/TthHB27I, TspDTI and TsoI and a few enzymes found in mesophiles. While not being isoschizomers, the enzymes exhibit amino acid (aa) sequence homologies, having molecular sizes of ~120 kDa share common modular architecture, resemble Type-I enzymes, cleave DNA 11/9 nt from the recognition sites, their activity is affected by S-adenosylmethionine (SAM).

RESULTS

We describe the taqIIRM gene design, cloning and expression of the prototype TaqII. The enzyme amount in natural hosts is extremely low. To improve expression of the taqIIRM gene in Escherichia coli (E. coli), we designed and cloned a fully synthetic, low GC content, low mRNA secondary structure taqIIRM, codon-optimized gene under a bacteriophage lambda (λ) PR promoter. Codon usage based on a modified 'one amino acid-one codon' strategy, weighted towards low GC content codons, resulted in approximately 10-fold higher expression of the synthetic gene. 718 codons of total 1105 were changed, comprising 65% of the taqIIRM gene. The reason for we choose a less effective strategy rather than a resulting in high expression yields 'codon randomization' strategy, was intentional, sub-optimal TaqII in vivo production, in order to decrease the high 'toxicity' of the REase-MTase protein.

CONCLUSIONS

Recombinant wt and synthetic taqIIRM gene were cloned and expressed in E. coli. The modified 'one amino acid-one codon' method tuned for thermophile-coded genes was applied to obtain overexpression of the 'toxic' taqIIRM gene. The method appears suited for industrial production of thermostable 'toxic' enzymes in E. coli. This novel variant of the method biased toward increasing a gene's AT content may provide economic benefits for industrial applications.

Naturally-occurring, dually-functional fusions between restriction endonucleases and regulatory proteins

Background

Restriction-modification (RM) systems appear to play key roles in modulating gene flow among bacteria and archaea. Because the restriction endonuclease (REase) is potentially lethal to unmethylated new host cells, regulation to ensure pre-expression of the protective DNA methyltransferase (MTase) is essential to the spread of RM genes. This is particularly true for Type IIP RM systems, in which the REase and MTase are separate, independently-active proteins. A substantial subset of Type IIP RM systems are controlled by an activator-repressor called C protein. In these systems, C controls the promoter for its own gene, and for the downstream REase gene that lacks its own promoter. Thus MTase is expressed immediately after the RM genes enter a new cell, while expression of REase is delayed until sufficient C protein accumulates. To study the variation in and evolution of this regulatory mechanism, we searched for RM systems closely related to the well-studied C protein-dependent PvuII RM system. Unexpectedly, among those found were several in which the C protein and REase genes were fused.

Results

The gene for CR.NsoJS138I fusion protein (nsoJS138ICR, from the bacterium Niabella soli) was cloned, and the fusion protein produced and partially purified. Western blots provided no evidence that, under the conditions tested, anything other than full-length fusion protein is produced. This protein had REase activity in vitro and, as expected from the sequence similarity, its specificity was indistinguishable from that for PvuII REase, though the optimal reaction conditions were different. Furthermore, the fusion was active as a C protein, as revealed by in vivo activation of a lacZ reporter fusion to the promoter region for the nsoJS138ICR gene.

Conclusions

Fusions between C proteins and REases have not previously been characterized, though other fusions have (such as between REases and MTases). These results reinforce the evidence for impressive modularity among RM system proteins, and raise important questions about the implications of the C-REase fusions on expression kinetics of these RM systems.

Three-stage biochemical selection: cloning of prototype class IIS/IIC/IIG restriction endonuclease-methyltransferase TsoI from the thermophile Thermus scotoductus

BACKGROUND

In continuing our research into the new family of bifunctional restriction endonucleases (REases), we describe the cloning of the tsoIRM gene. Currently, the family includes six thermostable enzymes: TaqII, Tth111II, TthHB27I, TspGWI, TspDTI, TsoI, isolated from various Thermus sp. and two thermolabile enzymes: RpaI and CchII, isolated from mesophilic bacteria Rhodopseudomonas palustris and Chlorobium chlorochromatii, respectively. The enzymes have several properties in common. They are large proteins (molecular size app. 120 kDa), coded by fused genes, with the REase and methyltransferase (MTase) in a single polypeptide, where both activities are affected by S-adenosylmethionine (SAM). They recognize similar asymmetric cognate sites and cleave at a distance of 11/9 nt from the recognition site. Thus far, we have cloned and characterised TaqII, Tth111II, TthHB27I, TspGWI and TspDTI.

RESULTS

TsoI REase, which originate from thermophilic Thermus scotoductus RFL4 (T. scotoductus), was cloned in Escherichia coli (E. coli) using two rounds of biochemical selection of the T. scotoductus genomic library for the TsoI methylation phenotype. DNA sequencing of restriction-resistant clones revealed the common open reading frame (ORF) of 3348 bp, coding for a large polypeptide of 1116 aminoacid (aa) residues, which exhibited a high level of similarity to Tth111II (50% identity, 60% similarity). The ORF was PCR-amplified, subcloned into a pET21 derivative under the control of a T7 promoter and was subjected to the third round of biochemical selection in order to isolate error-free clones. Induction experiments resulted in synthesis of an app. 125 kDa protein, exhibiting TsoI-specific DNA cleavage. Also, the wild-type (wt) protein was purified and reaction optima were determined.

CONCLUSIONS

Previously we identified and cloned the Thermus family RM genes using a specially developed method based on partial proteolysis of thermostable REases. In the case of TsoI the classic biochemical selection method was successful, probably because of the substantially lower optimal reaction temperature of TsoI (app. 10-15°C). That allowed for sufficient MTase activity in vivo in recombinant E. coli. Interestingly, TsoI originates from bacteria with a high optimum growth temperature of 67°C, which indicates that not all bacterial enzymes match an organism's thermophilic nature, and yet remain functional cell components. Besides basic research advances, the cloning and characterisation of the new prototype REase from the Thermus sp. family enzymes is also of practical importance in gene manipulation technology, as it extends the range of available DNA cleavage specificities.

A new genomic tool, ultra-frequently cleaving TaqII/sinefungin endonuclease with a combined 2.9-bp recognition site, applied to the construction of horse DNA libraries

Background

Genomics and metagenomics are currently leading research areas, with DNA sequences accumulating at an exponential rate. Although enormous advances in DNA sequencing technologies are taking place, progress is frequently limited by factors such as genomic contig assembly and generation of representative libraries. A number of DNA fragmentation methods, such as hydrodynamic sharing, sonication or DNase I fragmentation, have various drawbacks, including DNA damage, poor fragmentation control, irreproducibility and non-overlapping DNA segment representation. Improvements in these limited DNA scission methods are consequently needed. An alternative method for obtaining higher quality DNA fragments involves partial digestion with restriction endonucleases (REases).

We have shown previously that class-IIS/IIC/IIG TspGWI REase, the prototype member of the Thermus sp. enzyme family, can be chemically relaxed by a cofactor analogue, allowing it to recognize very short DNA sequences of 3-bp combined frequency. Such frequently cleaving REases are extremely rare, with CviJI/CviJI*, SetI and FaiI the only other ones found in nature. Their unusual features make them very useful molecular tools for the development of representative DNA libraries.

Results

We constructed a horse genomic library and a deletion derivative library of the butyrylcholinesterase cDNA coding region using a novel method, based on TaqII, Thermus sp. family bifunctional enzyme exhibiting cofactor analogue specificity relaxation. We used sinefungin (SIN) – an S-adenosylmethionine (SAM) analogue with reversed charge pattern, and dimethylsulfoxide (DMSO), to convert the 6-bp recognition site TaqII (5′-GACCGA-3′ [11/9]) into a theoretical 2.9-bp REase, with 70 shortened variants of the canonical recognition sequence detected. Because partial DNA cleavage is an inherent feature of the Thermus sp. enzyme family, this modified TaqII is uniquely suited to quasi-random library generation.

Conclusions

In the presence of SIN/DMSO, TaqII REase is transformed from cleaving every 4096 bp on average to cleaving every 58 bp. TaqII SIN/DMSO thus extends the palette of available REase prototype specificities. This phenomenon, employed under partial digestion conditions, was applied to quasi-random DNA fragmentation. Further applications include high sensitivity probe generation and metagenomic DNA amplification.

Related bifunctional restriction endonuclease-methyltransferase triplets: TspDTI, Tth111II/TthHB27I and TsoI with distinct specificities

BACKGROUND

We previously defined a family of restriction endonucleases (REases) from Thermus sp., which share common biochemical and biophysical features, such as the fusion of both the nuclease and methyltransferase (MTase) activities in a single polypeptide, cleavage at a distance from the recognition site, large molecular size, modulation of activity by S-adenosylmethionine (SAM), and incomplete cleavage of the substrate DNA. Members include related thermophilic REases with five distinct specificities: TspGWI, TaqII, Tth111II/TthHB27I, TspDTI and TsoI.

RESULTS

TspDTI, TsoI and isoschizomers Tth111II/TthHB27I recognize different, but related sequences: 5'-ATGAA-3', 5'-TARCCA-3' and 5'-CAARCA-3' respectively. Their amino acid sequences are similar, which is unusual among REases of different specificity. To gain insight into this group of REases, TspDTI, the prototype member of the Thermus sp. enzyme family, was cloned and characterized using a recently developed method for partially cleaving REases.

CONCLUSIONS

TspDTI, TsoI and isoschizomers Tth111II/TthHB27I are closely related bifunctional enzymes. They comprise a tandem arrangement of Type I-like domains, like other Type IIC enzymes (those with a fusion of a REase and MTase domains), e.g. TspGWI, TaqII and MmeI, but their sequences are only remotely similar to these previously characterized enzymes. The characterization of TspDTI, a prototype member of this group, extends our understanding of sequence-function relationships among multifunctional restriction-modification enzymes.

Characterization of MspNI (G/GWCC) and MspNII (R/GATCY), novel thermostable Type II restriction endonucleases from Meiothermus sp., isoschizomers of AvaII and BstYI

MspNI and MspNII, isoschizomers of prototype Type II restriction endonucleases AvaII and BstYI, were extracted from an extreme thermophile bacterium belonging to the genus Meiothermus, isolated from the hot sulphur springs in north Himalayan region of India where temperature and pH ranged from 60 to 80°C and 7.5 to 8.5, respectively. The two enzymes were purified to homogeneity using Cibacron-Blue 3GA Agarose, Q-Sepharose and SP-Sepharose chromatography and were homodimers with subunit molecular weights of 27 and 45 kDa, respectively. Restriction mapping and run-off sequencing of MspNI and MspNII cleaved pBR322 DNA showed that they recognized and cleaved 5'-G/GWCC-3' and 5'-R/GATCY-3' sites, respectively. MspNI and MspNII worked optimally at 60 and 70°C, 6 and 5 mM MgCl(2), respectively and showed no star activity in organic solvents. Both were resistant to sequence methylation and were stable up to 25 PCR cycles.

Bifunctional TaqII restriction endonuclease: redefining the prototype DNA recognition site and establishing the Fidelity Index for partial cleaving

Background

The TaqII enzyme is a member of the Thermus sp. enzyme family that we propounded previously within Type IIS restriction endonucleases, containing related thermophilic bifunctional endonucleases-methyltransferases from various Thermus sp.: TaqII, Tth111II, TthHB27I, TspGWI, TspDTI and TsoI. These enzymes show significant nucleotide and amino acid sequence similarities, a rare phenomenon among restriction endonucleases, along with similarities in biochemical properties, molecular size, DNA recognition sequences and cleavage sites. They also feature some characteristics of Types I and III.

Results

Barker et al. reported the Type IIS/IIC restriction endonuclease TaqII as recognizing two distinct cognate site variants (5'-GACCGA-3' and 5'-CACCCA-3') while cleaving 11/9 nucleotides downstream. We used four independent methods, namely, shotgun cloning and sequencing, restriction pattern analysis, digestion of particular custom substrates and GeneScan analysis, to demonstrate that the recombinant enzyme recognizes only 5'-GACCGA-3' sites and cleaves 11/9 nucleotides downstream. We did not observe any 5'-CACCCA-3' cleavage under a variety of conditions and site arrangements tested. We also characterized the enzyme biochemically and established new digestion conditions optimal for practical enzyme applications. Finally, we developed and propose a new version of the Fidelity Index - the Fidelity Index for Partial Cleavage (FI-PC).

Conclusions

The DNA recognition sequence of the bifunctional prototype TaqII endonuclease-methyltransferase from Thermus aquaticus has been redefined as recognizing only 5'-GACCGA-3' cognate sites. The reaction conditions (pH and salt concentrations) were designed either to minimize (pH = 8.0 and 10 mM ammonium sulphate) or to enhance star activity (pH = 6.0 and no salt). Redefinition of the recognition site and reaction conditions makes this prototype endonuclease a useful tool for DNA manipulation; as yet, this enzyme has no practical applications. The extension of the Fidelity Index will be helpful for DNA manipulation with enzymes only partially cleaving DNA.

Chemically-induced affinity star restriction specificity: a novel TspGWI/sinefungin endonuclease with theoretical 3-bp cleavage frequency

The type IIS/IIC restriction endonuclease TspGWI recognizes the sequence 5'-ACGGA-3', cleaving DNA 11/9 nucleotides downstream. Here we show that sinefungin, a cofactor analog of S-adenosyl methionine, induces a unique type of relaxation in DNA recognition specificity. In the presence of sinefungin, TspGWI recognizes and cleaves at least 12 degenerate variants of the original recognition sequence that vary by single base pair changes from the original 5-bp restriction site with only a single degeneracy per variant appearing to be allowed. In addition, sinefungin was found to have a stimulatory effect on cleavage at these nondegenerate TspGWI recognition sites, irrespective of their number or the DNA topology. Interestingly, no fixed "core" could be identified among the new recognition sequences. Theoretically, TspGWI cleaves DNA every 1024 bp, while sinefungin-induced activity cleaves every 78.8 bp, corresponding to a putative 3-bp long recognition site. Thus, the combination of sinefungin and TspGWI represents a novel frequent cutter, next only to CviJI/CviJI*, that should prove useful in DNA cloning methodologies.

Kinetics of Methylation by EcoP1I DNA Methyltransferase

EcoP1I DNA MTase (M.EcoP1I), an N⁶-adenine MTase from bacteriophage P1, is a part of the EcoP1I restriction-modification (R-M) system which belongs to the Type III R-M system. It recognizes the sequence 5′-AGACC-3′ and methylates the internal adenine. M.EcoP1I requires Mg²⁺ for the transfer of methyl groups to DNA. M.EcoP1I is shown to exist as dimer in solution, and even at high salt concentrations (0.5 M) the dimeric M.EcoP1I does not dissociate into monomers suggesting a strong interaction between the monomer subunits. Preincubation and isotope partitioning studies with M.EcoP1I indicate a kinetic mechanism where the duplex DNA binds first followed by AdoMet. Interestingly, M.EcoP1I methylates DNA substrates in the presence of Mn²⁺ and Ca²⁺ other than Mg²⁺ with varying affinities. Amino acid analysis and methylation assays in the presence of metal ions suggest that M.EcoP1I has indeed two metal ion-binding sites [³⁵⁸ID(x)_n … ExK⁴⁰¹ and ⁶⁰⁰DxDxD⁶⁰⁴ motif]. EcoP1I DNA MTase catalyzes the transfer of methyl groups using a distributive mode of methylation on DNA containing more than one recognition site. A chemical modification of EcoP1I DNA MTase using N-ethylmaleimide resulted in an irreversible inactivation of enzyme activity suggesting the possible role of cysteine residues in catalysis.

Diversity of DNA methyltransferases that recognize asymmetric target sequences

DNA methyltransferases (MTases) are a group of enzymes that catalyze the methyl group transfer from S-adenosyl-L-methionine in a sequence-specific manner. Orthodox Type II DNA MTases usually recognize palindromic DNA sequences and add a methyl group to the target base (either adenine or cytosine) on both strands. However, there are a number of MTases that recognize asymmetric target sequences and differ in their subunit organization. In a bacterial cell, after each round of replication, the substrate for any MTase is hemimethylated DNA, and it therefore needs only a single methylation event to restore the fully methylated state. This is in consistent with the fact that most of the DNA MTases studied exist as monomers in solution. Multiple lines of evidence suggest that some DNA MTases function as dimers. Further, functional analysis of many restriction-modification systems showed the presence of more than one or fused MTase genes. It was proposed that presence of two MTases responsible for the recognition and methylation of asymmetric sequences would protect the nascent strands generated during DNA replication from cognate restriction endonuclease. In this review, MTases recognizing asymmetric sequences have been grouped into different subgroups based on their unique properties. Detailed characterization of these unusual MTases would help in better understanding of their specific biological roles and mechanisms of action. The rapid progress made by the genome sequencing of bacteria and archaea may accelerate the identification and study of species- and strain-specific MTases of host-adapted bacteria and their roles in pathogenic mechanisms.