Mva1269I: a monomeric type IIS restriction endonuclease from Micrococcus varians with two EcoRI- and FokI-like catalytic domains

BtsCI and BseGI display sequence preference in the nucleotides flanking the recognition sequence

Restriction enzymes are the bread and butter of Molecular Biology. Nonetheless, how restriction enzymes recognize and cleave their target is not always clear. When developing a method for the enzymatic production of oligonucleotides, we noticed that type II endonucleases BtsCI and BseGI, which recognize the sequence GGATGNN^, perform incomplete digestions of DNA hairpins, with the top strand nick not always occurring correctly. We tested the cutting of synthetic hairpins containing all possible combinations of dinucleotides following the recognition site and our results show that all sequences containing one adenine following GGATG were digested more efficiently. We further show that the same sequence preference is also observable in double stranded DNA at higher Mg²⁺ concentrations and even in optimal conditions. Kinetic results show that BtsCI has a noteworthy difference in the first-rate constants between different sequences and between the two catalytic domains. An increase in Mg²⁺ resulted in a drastic decrease in the catalytic activity of the top (sense) strand that wasn’t always accompanied by a nick in the bottom strand (antisense).

Peculiarities of the interaction of the restriction endonuclease BspD6I with DNA containing its recognition site

BACKGROUND

Nicking endonucleases are enzymes that recognize specific sites in double-stranded DNA and cleave only one strand at a predetermined position. These enzymes are involved in DNA replication and repair; they can also function as subunits of bacterial heterodimeric restriction endonucleases. One example of such a proteins is the restriction endonuclease BspD6I (R.BspD6I) from Bacillus species strain D6, which consists of the large subunit - nicking endonuclease BspD6I (Nt.BspD6I), and the small subunit (ss.BspD6I). Nt.BspD6I can function independently. Similar enzymes are now widely used in numerous biotechnological applications. The aim of this study was to investigate the fundamental properties of two subunits of R.BspD6I and their interdependence in the course of R.BspD6I activity.

METHODS

The binding and hydrolysis of DNA duplexes by R.BspD6I are primary analyzed by gel electrophoresis. To elucidate the difference between Nt.BspD6I interaction with the substrate and product of hydrolysis, the thickness shear mode acoustic method is used.

RESULTS AND CONCLUSIONS

The thermodynamic and kinetic parameters of the Nt.BspD6I interaction with DNA are determined. For the first time we demonstrated that Nt.BspD6I bends the DNA during complex formation. Nt.BspD6I is able to form complexes with the product nicked in the top strand and ss.BspD6I cleaves the bottom strand of the DNA consecutively. Furthermore, the influence of dA methylation in the R.BspD6I recognition site on ss.BspD6I activity is analyzed.

GENERAL SIGNIFICANCE

The obtained results provide evidence that Nt.BspD6I coordinates the activity of R.BspD6I by strictly coupling of the bottom strand cleavage by ss.BspD6I to the top strand cleavage.

Engineering a Nickase on the Homing Endonuclease I-DmoI Scaffold

Homing endonucleases are useful tools for genome modification because of their capability to recognize and cleave specifically large DNA targets. These endonucleases generate a DNA double strand break that can be repaired by the DNA damage response machinery. The break can be repaired by homologous recombination, an error-free mechanism, or by non-homologous end joining, a process susceptible to introducing errors in the repaired sequence. The type of DNA cleavage might alter the balance between these two alternatives. The use of "nickases" producing a specific single strand break instead of a double strand break could be an approach to reduce the toxicity associated with non-homologous end joining by promoting the use of homologous recombination to repair the cleavage of a single DNA break. Taking advantage of the sequential DNA cleavage mechanism of I-DmoI LAGLIDADG homing endonuclease, we have developed a new variant that is able to cut preferentially the coding DNA strand, generating a nicked DNA target. Our structural and biochemical analysis shows that by decoupling the action of the catalytic residues acting on each strand we can inhibit one of them while keeping the other functional.

Type II restriction endonucleases--a historical perspective and more

This article continues the series of Surveys and Summaries on restriction endonucleases (REases) begun this year in Nucleic Acids Research. Here we discuss 'Type II' REases, the kind used for DNA analysis and cloning. We focus on their biochemistry: what they are, what they do, and how they do it. Type II REases are produced by prokaryotes to combat bacteriophages. With extreme accuracy, each recognizes a particular sequence in double-stranded DNA and cleaves at a fixed position within or nearby. The discoveries of these enzymes in the 1970s, and of the uses to which they could be put, have since impacted every corner of the life sciences. They became the enabling tools of molecular biology, genetics and biotechnology, and made analysis at the most fundamental levels routine. Hundreds of different REases have been discovered and are available commercially. Their genes have been cloned, sequenced and overexpressed. Most have been characterized to some extent, but few have been studied in depth. Here, we describe the original discoveries in this field, and the properties of the first Type II REases investigated. We discuss the mechanisms of sequence recognition and catalysis, and the varied oligomeric modes in which Type II REases act. We describe the surprising heterogeneity revealed by comparisons of their sequences and structures.

Cas9-crRNA ribonucleoprotein complex mediates specific DNA cleavage for adaptive immunity in bacteria

Clustered, regularly interspaced, short palindromic repeats (CRISPR)/CRISPR-associated (Cas) systems provide adaptive immunity against viruses and plasmids in bacteria and archaea. The silencing of invading nucleic acids is executed by ribonucleoprotein complexes preloaded with small, interfering CRISPR RNAs (crRNAs) that act as guides for targeting and degradation of foreign nucleic acid. Here, we demonstrate that the Cas9-crRNA complex of the Streptococcus thermophilus CRISPR3/Cas system introduces in vitro a double-strand break at a specific site in DNA containing a sequence complementary to crRNA. DNA cleavage is executed by Cas9, which uses two distinct active sites, RuvC and HNH, to generate site-specific nicks on opposite DNA strands. Results demonstrate that the Cas9-crRNA complex functions as an RNA-guided endonuclease with RNA-directed target sequence recognition and protein-mediated DNA cleavage. These findings pave the way for engineering of universal programmable RNA-guided DNA endonucleases.

Rational engineering of sequence specificity in R.MwoI restriction endonuclease

R.MwoI is a Type II restriction endonucleases enzyme (REase), which specifically recognizes a palindromic interrupted DNA sequence 5′-GCNNNNNNNGC-3′ (where N indicates any nucleotide), and hydrolyzes the phosphodiester bond in the DNA between the 7th and 8th base in both strands. R.MwoI exhibits remote sequence similarity to R.BglI, a REase with known structure, which recognizes an interrupted palindromic target 5′-GCCNNNNNGGC-3′. A homology model of R.MwoI in complex with DNA was constructed and used to predict functionally important amino acid residues that were subsequently targeted by mutagenesis. The model, together with the supporting experimental data, revealed regions important for recognition of the common bases in DNA sequences recognized by R.BglI and R.MwoI. Based on the bioinformatics analysis, we designed substitutions of the S310 residue in R.MwoI to arginine or glutamic acid, which led to enzyme variants with altered sequence selectivity compared with the wild-type enzyme. The S310R variant of R.MwoI preferred the 5′-GCCNNNNNGGC-3′ sequence as a target, similarly to R.BglI, whereas the S310E variant preferentially cleaved a subset of the MwoI sites, depending on the identity of the 3rd and 9th nucleotide residues. Our results represent a case study of a REase sequence specificity alteration by a single amino acid substitution, based on a theoretical model in the absence of a crystal structure.

Restriction endonucleases: natural and directed evolution

Type II restriction endonucleases (REs) are highly sequence-specific compared with other classes of nucleases. PD-(D/E)XK nucleases, initially represented by only type II REs, now comprise a large and extremely diverse superfamily of proteins and, although sharing a structurally conserved core, typically display little or no detectable sequence similarity except for the active site motifs. Sequence similarity can only be observed in methylases and few isoschizomers. As a consequence, REs are classified according to combinations of functional properties rather than on the basis of genetic relatedness. New alignment matrices and classification systems based on structural core connectivity and cleavage mechanisms have been developed to characterize new REs and related proteins. REs recognizing more than 300 distinct specificities have been identified in RE database (REBASE: http://rebase.neb.com/cgi-bin/statlist ) but still the need for newer specificities is increasing due to the advancement in molecular biology and applications. The enzymes have undergone constant evolution through structural changes in protein scaffolds which include random mutations, homologous recombinations, insertions, and deletions of coding DNA sequences but rational mutagenesis or directed evolution delivers protein variants with new functions in accordance with defined biochemical or environmental pressures. Redesigning through random mutation, addition or deletion of amino acids, methylation-based selection, synthetic molecules, combining recognition and cleavage domains from different enzymes, or combination with domains of additional functions change the cleavage specificity or substrate preference and stability. There is a growing number of patents awarded for the creation of engineered REs with new and enhanced properties.

The Streptococcus thermophilus CRISPR/Cas system provides immunity in Escherichia coli

The CRISPR/Cas adaptive immune system provides resistance against phages and plasmids in Archaea and Bacteria. CRISPR loci integrate short DNA sequences from invading genetic elements that provide small RNA-mediated interference in subsequent exposure to matching nucleic acids. In Streptococcus thermophilus, it was previously shown that the CRISPR1/Cas system can provide adaptive immunity against phages and plasmids by integrating novel spacers following exposure to these foreign genetic elements that subsequently direct the specific cleavage of invasive homologous DNA sequences. Here, we show that the S. thermophilus CRISPR3/Cas system can be transferred into Escherichia coli and provide heterologous protection against plasmid transformation and phage infection. We show that interference is sequence-specific, and that mutations in the vicinity or within the proto-spacer adjacent motif (PAM) allow plasmids to escape CRISPR-encoded immunity. We also establish that cas9 is the sole cas gene necessary for CRISPR-encoded interference. Furthermore, mutation analysis revealed that interference relies on the Cas9 McrA/HNH- and RuvC/RNaseH-motifs. Altogether, our results show that active CRISPR/Cas systems can be transferred across distant genera and provide heterologous interference against invasive nucleic acids. This can be leveraged to develop strains more robust against phage attack, and safer organisms less likely to uptake and disseminate plasmid-encoded undesirable genetic elements.

The reaction mechanism of FokI excludes the possibility of targeting zinc finger nucleases to unique DNA sites

The FokI endonuclease is a monomeric protein with discrete DNA-recognition and catalytic domains. The latter has only one active site so, to cut both strands, the catalytic domains from two monomers associate to form a dimer. The dimer involving a monomer at the recognition site and another from free solution is less stable than that from two proteins tethered to the same DNA. FokI thus cleaves DNA with two sites better than one-site DNA. The two sites can be immediately adjacent, but they can alternatively be many hundreds of base pairs apart, in either inverted or repeated orientations. The catalytic domain of FokI is often a component of zinc finger nucleases. Typically, the zinc finger domains of two such nucleases are designed to recognize two neighbouring DNA sequences, with the objective of cutting the DNA exclusively between the target sequences. However, this strategy fails to take account of the fact that the catalytic domains of FokI can dimerize across distant sites or even at a solitary site. Additional copies of either target sequence elsewhere in the chromosome must elicit off-target cleavages.

Degenerate sequence recognition by the monomeric restriction enzyme: single mutation converts BcnI into a strand-specific nicking endonuclease

Unlike orthodox Type II restriction endonucleases that are homodimers and interact with the palindromic 4–8-bp DNA sequences, BcnI is a monomer which has a single active site but cuts both DNA strands within the 5′-CC↓CGG-3′/3′-GGG↓CC-5′ target site (‘↓’ designates the cleavage position). Therefore, after cutting the first strand, the BcnI monomer must re-bind to the target site in the opposite orientation; but in this case, it runs into a different central base because of the broken symmetry of the recognition site. Crystal-structure analysis shows that to accept both the C:G and G:C base pairs at the center of its target site, BcnI employs two symmetrically positioned histidines H77 and H219 that presumably change their protonation state depending on the binding mode. We show here that a single mutation of BcnI H77 or H219 residues restricts the cleavage activity of the enzyme to either the 5′-CCCGG-3′ or the 5′-CCGGG-3′ strand, thereby converting BcnI into a strand-specific nicking endonuclease. This is a novel approach for engineering of monomeric restriction enzymes into strand-specific nucleases.

Natural and engineered nicking endonucleases--from cleavage mechanism to engineering of strand-specificity

Restriction endonucleases (REases) are highly specific DNA scissors that have facilitated the development of modern molecular biology. Intensive studies of double strand (ds) cleavage activity of Type IIP REases, which recognize 4–8 bp palindromic sequences, have revealed a variety of mechanisms of molecular recognition and catalysis. Less well-studied are REases which cleave only one of the strands of dsDNA, creating a nick instead of a ds break. Naturally occurring nicking endonucleases (NEases) range from frequent cutters such as Nt.CviPII (^CCD; ^ denotes the cleavage site) to rare-cutting homing endonucleases (HEases) such as I-HmuI. In addition to these bona fida NEases, individual subunits of some heterodimeric Type IIS REases have recently been shown to be natural NEases. The discovery and characterization of more REases that recognize asymmetric sequences, particularly Types IIS and IIA REases, has revealed recognition and cleavage mechanisms drastically different from the canonical Type IIP mechanisms, and has allowed researchers to engineer highly strand-specific NEases. Monomeric LAGLIDADG HEases use two separate catalytic sites for cleavage. Exploitation of this characteristic has also resulted in useful nicking HEases. This review aims at providing an overview of the cleavage mechanisms of Types IIS and IIA REases and LAGLIDADG HEases, the engineering of their nicking variants, and the applications of NEases and nicking HEases.

Engineering Nt.BtsCI and Nb.BtsCI nicking enzymes and applications in generating long overhangs

Type IIS restriction endonuclease BtsCI (GGATG 2/0) is a neoschizomer of FokI (GGATG 9/13) and cleaves closer to the recognition sequence. Although M.BtsCI shows 62% amino acid sequence identity to M.FokI, BtsCI and FokI restriction endonucleases do not share significant amino acid sequence similarity. BtsCI belongs to a group of Type IIS restriction endonucleases, BsmI, Mva1269I and BsrI, that carry two different catalytic sites in a single polypeptide. By inactivating one of the catalytic sites through mutagenesis, we have generated nicking variants of BtsCI that specifically nick the bottom-strand or the top-strand of the target site. By treating target DNA sequentially with the appropriate combinations of FokI and BtsCI nicking variants, we are able to generate long overhangs suitable for fluorescent labeling through end-filling or other techniques based on annealing of complementary DNA sequences.

Targeting individual subunits of the FokI restriction endonuclease to specific DNA strands

Many restriction endonucleases are dimers that act symmetrically at palindromic DNA sequences, with each active site cutting one strand. In contrast, FokI acts asymmetrically at a non-palindromic sequence, cutting ‘top’ and ‘bottom’ strands 9 and 13 nucleotides downstream of the site. FokI is a monomeric protein with one active site and a single monomer covers the entire recognition sequence. To cut both strands, the monomer at the site recruits a second monomer from solution, but it is not yet known which DNA strand is cut by the monomer bound to the site and which by the recruited monomer. In this work, mutants of FokI were used to show that the monomer bound to the site made the distal cut in the bottom strand, whilst the recruited monomer made in parallel the proximal cut in the top strand. Procedures were also established to direct FokI activity, either preferentially to the bottom strand or exclusively to the top strand. The latter extends the range of enzymes for nicking specified strands at specific sequences, and may facilitate further applications of FokI in gene targeting.

Oligomeric structure diversity within the GIY-YIG nuclease family

The GIY-YIG nuclease domain has been identified in homing endonucleases, DNA repair and recombination enzymes, and restriction endonucleases. The Type II restriction enzyme Eco29kI belongs to the GIY-YIG nuclease superfamily and, like most of other family members, including the homing endonuclease I-TevI, is a monomer. It recognizes the palindromic sequence 5'-CCGC/GG-3' ("/" marks the cleavage position) and cuts it to generate 3'-staggered ends. The Eco29kI monomer, which contains a single active site, either has to nick sequentially individual DNA strands or has to form dimers or even higher-order oligomers upon DNA binding to make a double-strand break at its target site. Here, we provide experimental evidence that Eco29kI monomers dimerize on a single cognate DNA molecule forming the catalytically active complex. The mechanism described here for Eco29kI differs from that of Cfr42I isoschisomer, which also belongs to the GIY-YIG family but is functional as a tetramer. This novel mechanism may have implications for the function of homing endonucleases and other enzymes of the GIY-YIG family.

Bioinformatic and partial functional analysis of pEspA and pEspB, two plasmids from Exiguobacterium arabatum sp. nov. RFL1109

The complete nucleotide sequences of two plasmids from Exiguobacterium arabatum sp. nov. RFL1109, pEspA (4563bp) and pEspB (38,945bp), have been determined. Five ORFs were identified in the pEspA plasmid, and putative functions were assigned to two of them. Using deletion mapping approach, the Rep-independent replication region of pEspA, which functions in Bacillus subtilis, was localized within a 0.6kb DNA region. Analysis of the pEspB sequence revealed 42 ORFs. From these, function of two genes encoding enzymes of the Lsp1109I restriction-modification system was confirmed experimentally, while putative functions of another 18 ORFs were suggested based on comparative analysis. Three functional regions have been proposed for the pEspB plasmid: the putative conjugative transfer region, the region involved in plasmid replication and maintenance, and the region responsible for transposition of the IS21 family-like transposable elements.

Domain organization and functional analysis of type IIS restriction endonuclease Eco31I

Type IIS restriction endonuclease Eco31I harbors a single HNH active site and cleaves both DNA strands close to its recognition sequence, 5'-GGTCTC(1/5). A two-domain organization of Eco31I was determined by limited proteolysis. Analysis of proteolytic fragments revealed that the N-terminal domain of Eco31I is responsible for the specific DNA binding, while the C-terminal domain contains the HNH nuclease-like active site. Gel-shift and gel-filtration experiments revealed that a monomer of the N-terminal domain of Eco31I is able to bind a single copy of cognate DNA. However, in contrast to other studied type IIS enzymes, the isolated catalytic domain of Eco31I was inactive. Steady-state and transient kinetic analysis of Eco31I reactions was inconsistent with dimerization of Eco31I on DNA. Thus, we propose that Eco31I interacts with individual copies of its recognition sequence in its monomeric form and presumably remains a monomer as it cleaves both strands of double-stranded DNA. The domain organization and reaction mechanism established for Eco31I should be common for a group of evolutionary related type IIS restriction endonucleases Alw26I, BsaI, BsmAI, BsmBI and Esp3I that recognize DNA sequences bearing the common pentanucleotide 5'-GTCTC.

Structural and evolutionary classification of Type II restriction enzymes based on theoretical and experimental analyses

For a very long time, Type II restriction enzymes (REases) have been a paradigm of ORFans: proteins with no detectable similarity to each other and to any other protein in the database, despite common cellular and biochemical function. Crystallographic analyses published until January 2008 provided high-resolution structures for only 28 of 1637 Type II REase sequences available in the Restriction Enzyme database (REBASE). Among these structures, all but two possess catalytic domains with the common PD-(D/E)XK nuclease fold. Two structures are unrelated to the others: R.BfiI exhibits the phospholipase D (PLD) fold, while R.PabI has a new fold termed 'half-pipe'. Thus far, bioinformatic studies supported by site-directed mutagenesis have extended the number of tentatively assigned REase folds to five (now including also GIY-YIG and HNH folds identified earlier in homing endonucleases) and provided structural predictions for dozens of REase sequences without experimentally solved structures. Here, we present a comprehensive study of all Type II REase sequences available in REBASE together with their homologs detectable in the nonredundant and environmental samples databases at the NCBI. We present the summary and critical evaluation of structural assignments and predictions reported earlier, new classification of all REase sequences into families, domain architecture analysis and new predictions of three-dimensional folds. Among 289 experimentally characterized (not putative) Type II REases, whose apparently full-length sequences are available in REBASE, we assign 199 (69%) to contain the PD-(D/E)XK domain. The HNH domain is the second most common, with 24 (8%) members. When putative REases are taken into account, the fraction of PD-(D/E)XK and HNH folds changes to 48% and 30%, respectively. Fifty-six characterized (and 521 predicted) REases remain unassigned to any of the five REase folds identified so far, and may exhibit new architectures. These enzymes are proposed as the most interesting targets for structure determination by high-resolution experimental methods. Our analysis provides the first comprehensive map of sequence-structure relationships among Type II REases and will help to focus the efforts of structural and functional genomics of this large and biotechnologically important class of enzymes.

Discovery of natural nicking endonucleases Nb.BsrDI and Nb.BtsI and engineering of top-strand nicking variants from BsrDI and BtsI

BsrDI and BtsI restriction endonucleases recognize and cleave double-strand DNA at the sequences GCAATG (2/0) and GCAGTG (2/0), respectively. We have purified and partially characterized these two enzymes, and analyzed the genes that encode them. BsrDI and BtsI are unusual in two respects: each cleaves DNA as a heterodimer of one large subunit (B subunit) and one small subunit (A subunit); and, in the absence of their small subunits, the large subunits behave as sequence-specific DNA nicking enzymes and only nick the bottom strand of the sequences at these respective positions: GCAATG (-/0) and GCAGTG (-/0). We refer to the single subunit, the bottom-strand nicking forms as 'hemidimers'. Amino acid sequence comparisons reveal that BsrDI and BtsI belong to a family of restriction enzymes that possess two catalytic sites: a canonical PD-X(n)-EXK and a second non-canonical PD-X(n)-E-X12-QR. Interestingly, the other family members, which include BsrI (ACTGG 1/-1) and BsmI/Mva1269I (GAATGC 1/-1) are single polypeptide chains, i.e. monomers, rather than heterodimers. In BsrDI and BtsI, the two catalytic sites are found in two separate subunits. Site-directed mutagenesis confirmed that the canonical catalytic site located at the N-terminus of the large subunit is responsible for the bottom-strand cleavage, whereas the non-canonical catalytic site located in the small subunit is responsible for hydrolysis of the top strand. Top-strand specific nicking variants, Nt.BsrDI and Nt.BtsI, were successfully engineered by combining the catalytic-deficient B subunit with wild-type A subunit.

Identification of a single HNH active site in type IIS restriction endonuclease Eco31I

Type IIS restriction endonuclease Eco31I is a "short-distance cutter", which cleaves DNA strands close to its recognition sequence, 5'-GGTCTC(1/5). Previously, it has been proposed that related endonucleases recognizing a common sequence core GTCTC possess two active sites for cleavage of both strands in the DNA substrate. Here, we present bioinformatic identification and experimental evidence for a single nuclease active site. We identified a short region of homology between Eco31I and HNH nucleases, constructed a three-dimensional model of the putative catalytic domain and validated our predictions by random and site-specific mutagenesis. The restriction mechanism of Eco31I is suggested by analogy to the mechanisms of phage T4 endonuclease VII and homing endonuclease I-PpoI. We propose that residues D311 and N334 coordinate the cofactor. H312 acts as a general base-activating water molecule for the nucleophilic attack. K337 together with R340 and D345 are located in close proximity to the active center and are essential for correct folding of catalytic motif, while D345 together with R264 and D273 could be directly involved in DNA binding. We also predict that the Eco31I catalytic domain contains a putative Zn-binding site, which is essential for its structural integrity. Our results suggest that the HNH-like active site is involved in the cleavage of both strands in the DNA substrate. On the other hand, analysis of site-specific mutants in the region, previously suggested to harbor the second active site, revealed its irrelevance to the nuclease activity. Thus, our data argue against the earlier prediction and indicate the presence of a single conserved active site in type IIS restriction endonucleases that recognize common sequence core GTCTC.

Nickase and a protein encoded by an open reading frame downstream from the nickase BspD6I gene form a restriction endonuclease complex

We are the first to have isolated a protein (186 amino acid residues) encoded by the open reading frame adjacent to the end of the BspD6I nickase (N.BspD6I) gene. Cleavage of both DNA strands near the sequence recognized by nickase (5 -GAGTC/5 -GACTC) occurs when this protein is added to the reaction mixture containing N.BspD6I. The protein encoded by the open reading frame and the nickase are suggested to be subunits of heterodimeric restriction endonuclease R.BspD6I.

Domain organization and metal ion requirement of the Type IIS restriction endonuclease MnlI

A two-domain structure of the Type IIS restriction endonuclease MnlI has been identified by limited proteolysis. An N-terminal domain of the enzyme mediates the sequence-specific interaction with DNA, whereas a monomeric C-terminal domain resembles bacterial colicin nucleases in its requirement for alkaline earth as well as transition metal ions for double- and single-stranded DNA cleavage activities. The results indicate that the fusion of the non-specific HNH-type nuclease to the DNA binding domain had transformed MnlI into a Mg(2+)-, Ni(2+)-, Co(2+)-, Mn(2+)-, Zn(2+)-, Ca(2+)-dependent sequence-specific enzyme. Nevertheless, MnlI retains a residual single-stranded DNA cleavage activity controlled by its C-terminal colicin-like nuclease domain.