The restriction fold turns to the dark side: a bacterial homing endonuclease with a PD-(D/E)-XK motif

The homing endonuclease I-Ssp6803I causes the insertion of a group I intron into a bacterial tRNA gene-the only example of an invasive mobile intron within a bacterial genome. Using a computational fold prediction, mutagenic screen and crystal structure determination, we demonstrate that this protein is a tetrameric PD-(D/E)-XK endonuclease - a fold normally used to protect a bacterial genome from invading DNA through the action of restriction endonucleases. I-Ssp6803I uses its tetrameric assembly to promote recognition of a single long target site, whereas restriction endonuclease tetramers facilitate cooperative binding and cleavage of two short sites. The limited use of the PD-(D/E)-XK nucleases by mobile introns stands in contrast to their frequent use of LAGLIDADG and HNH endonucleases - which in turn, are rarely incorporated into restriction/modification systems.     

Activity and Specificity of the Bacterial PD-(D/E)XK Homing Endonuclease I-Ssp6803I

The restriction endonuclease fold [a three-layer α-β sandwich containing variations of the PD-(D/E)XK nuclease motif] has been greatly diversified during evolution, facilitating its use for many biological functions. Here we characterize DNA binding and cleavage by the PD-(D/E)XK homing endonuclease I-Ssp6803I. Unlike most restriction endonucleases harboring the same core fold, the specificity profile of this enzyme extends over a long (17 bp) target site. The DNA binding and cleavage specificity profiles of this enzyme were independently determined and found to be highly correlated. However, the DNA target sequence contains several positions where binding and cleavage activities are not tightly coupled: individual DNA base-pair substitutions at those positions that significantly decrease cleavage activity have minor effects on binding affinity. These changes in the DNA target sequence appear to correspond to substitutions that uniquely increase the free energy change between the ground state and the transition state, rather than simply decreasing the overall DNA binding affinity. The specificity of the enzyme reflects constraints on its host gene and limitations imposed by the enzyme's quaternary structure and illustrate the highly diverse repertoire of DNA recognition specificities that can be adopted by the related folds surrounding the PD-(D/E)XK nuclease motif.     

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.     

Type II restriction endonuclease R.Eco29kI is a member of the GIY-YIG nuclease superfamily

Background

The majority of experimentally determined crystal structures of Type II restriction endonucleases (REases) exhibit a common PD-(D/E)XK fold. Crystal structures have been also determined for single representatives of two other folds: PLD (R.BfiI) and half-pipe (R.PabI), and bioinformatics analyses supported by mutagenesis suggested that some REases belong to the HNH fold. Our previous bioinformatic analysis suggested that REase R.Eco29kI shares sequence similarities with one more unrelated nuclease superfamily, GIY-YIG, however so far no experimental data were available to support this prediction. The determination of a crystal structure of the GIY-YIG domain of homing endonuclease I-TevI provided a template for modeling of R.Eco29kI and prompted us to validate the model experimentally.

Results

Using protein fold-recognition methods we generated a new alignment between R.Eco29kI and I-TevI, which suggested a reassignment of one of the putative catalytic residues. A theoretical model of R.Eco29kI was constructed to illustrate its predicted three-dimensional fold and organization of the active site, comprising amino acid residues Y49, Y76, R104, H108, E142, and N154. A series of mutants was constructed to generate amino acid substitutions of selected residues (Y49A, R104A, H108F, E142A and N154L) and the mutant proteins were examined for their ability to bind the DNA containing the Eco29kI site 5'-CCGCGG-3' and to catalyze the cleavage reaction. Experimental data reveal that residues Y49, R104, E142, H108, and N154 are important for the nuclease activity of R.Eco29kI, while H108 and N154 are also important for specific DNA binding by this enzyme.

Conclusion

Substitutions of residues Y49, R104, H108, E142 and N154 predicted by the model to be a part of the active site lead to mutant proteins with strong defects in the REase activity. These results are in very good agreement with the structural model presented in this work and with our prediction that R.Eco29kI belongs to the GIY-YIG superfamily of nucleases. Our study provides the first experimental evidence for a Type IIP REase that does not belong to the PD-(D/E)XK or HNH superfamilies of nucleases, and is instead a member of the unrelated GIY-YIG superfamily.     

Type II restriction endonuclease R.Hpy188I belongs to the GIY-YIG nuclease superfamily,but exhibits an unusual active site

Background  

Catalytic domains of Type II restriction endonucleases (REases) belong to a few unrelated three-dimensional folds. While the PD-(D/E)XK fold is most common among these enzymes, crystal structures have been also determined for single representatives of two other folds: PLD (R.BfiI) and half-pipe (R.PabI). Bioinformatics analyses supported by mutagenesis experiments suggested that some REases belong to the HNH fold (e.g. R.KpnI), and that a small group represented by R.Eco29kI belongs to the GIY-YIG fold. However, for a large fraction of REases with known sequences, the three-dimensional fold and the architecture of the active site remain unknown, mostly due to extreme sequence divergence that hampers detection of homology to enzymes with known folds.     

Unusual evolutionary history of the tRNA splicing endonuclease EndA: relationship to the LAGLIDADG and PD-(D/E)XK deoxyribonucleases

The tRNA splicing endoribonuclease EndA from Methanococcus jannaschii is a homotetramer formed via heterologous interaction between the two pairs of homodimers. Each monomer consists of two alpha/beta domains, the N-terminal domain (NTD) and the C-terminal domain (CTD) containing the RNase A-like active site. Comparison of the EndA coordinates with the publicly available protein structure database revealed the similarity of both domains to site-specific deoxyribonucleases: the NTD to the LAGLIDADG family and the CTD to the PD-(D/E)XK family. Superposition of the NTD on the catalytic domain of LAGLIDADG homing endonucleases allowed a suggestion to be made about which amino acid residues of the tRNA splicing nuclease might participate in formation of a presumptive cryptic deoxyribonuclease active site. On the other hand, the CTD and PD-(D/E)XK endonucleases, represented by restriction enzymes and a phage lambda exonuclease, were shown to share extensive similarities of the structural framework, to which entirely different active sites might be attached in two alternative locations. These findings suggest that EndA evolved from a fusion protein with at least two distinct endonuclease activities: the ribonuclease, which made it an essential "antitoxin" for the cells whose RNA genes were interrupted by introns, and the deoxyribonuclease, which provided the means for homing-like mobility. The residues of the noncatalytic CTDs from the positions corresponding to the catalytic side chains in PD-(D/E)XK deoxyribonucleases map to the surface at the opposite side to the tRNA binding site, for which no function has been implicated. Many restriction enzymes from the PD-(D/E)XK superfamily might have the potential to maintain an additional active or binding site at the face opposite the deoxyribonuclease active site, a property that can be utilized in protein engineering.     

The PD-(D/E)XK superfamily revisited: identification of new members among proteins involved in DNA metabolism and functional predictions for domains of (hitherto) unknown function

Background  

The PD-(D/E)XK nuclease superfamily, initially identified in type II restriction endonucleases and later in many enzymes involved in DNA recombination and repair, is one of the most challenging targets for protein sequence analysis and structure prediction. Typically, the sequence similarity between these proteins is so low, that most of the relationships between known members of the PD-(D/E)XK superfamily were identified only after the corresponding structures were determined experimentally. Thus, it is tempting to speculate that among the uncharacterized protein families, there are potential nucleases that remain to be discovered, but their identification requires more sensitive tools than traditional PSI-BLAST searches.     

Identification of a new subfamily of HNH nucleases and experimental characterization of a representative member, HphI restriction endonuclease

The restriction endonuclease (REase) R. HphI is a Type IIS enzyme that recognizes the asymmetric target DNA sequence 5'-GGTGA-3' and in the presence of Mg(2+) hydrolyzes phosphodiester bonds in both strands of the DNA at a distance of 8 nucleotides towards the 3' side of the target, producing a 1 nucleotide 3'-staggered cut in an unspecified sequence at this position. REases are typically ORFans that exhibit little similarity to each other and to any proteins in the database. However, bioinformatics analyses revealed that R.HphI is a member of a relatively big sequence family with a conserved C-terminal domain and a variable N-terminal domain. We predict that the C-terminal domains of proteins from this family correspond to the nuclease domain of the HNH superfamily rather than to the most common PD-(D/E)XK superfamily of nucleases. We constructed a three-dimensional model of the R.HphI catalytic domain and validated our predictions by site-directed mutagenesis and studies of DNA-binding and catalytic activities of the mutant proteins. We also analyzed the genomic neighborhood of R.HphI homologs and found that putative nucleases accompanied by a DNA methyltransferase (i.e. predicted REases) do not form a single group on a phylogenetic tree, but are dispersed among free-standing putative nucleases. This suggests that nucleases from the HNH superfamily were independently recruited to become REases in the context of RM systems multiple times in the evolution and that members of the HNH superfamily may be much more frequent among the so far unassigned REase sequences than previously thought.     

Realm of PD-(D/E)XK nuclease superfamily revisited: detection of novel families with modified transitive meta profile searches

Background  

PD-(D/E)XK nucleases constitute a large and highly diverse superfamily of enzymes that display little sequence similarity despite retaining a common core fold and a few critical active site residues. This makes identification of new PD-(D/E)XK nuclease families a challenging task as they usually escape detection with standard sequence-based methods. We developed a modified transitive meta profile search approach and to consider the structural diversity of PD-(D/E)XK nuclease fold more thoroughly we analyzed also lower than threshold Meta-BASIC hits to select potentially correct predictions placed among unreliable or incorrect ones.     

Tetrameric restriction enzymes: expansion to the GIY-YIG nuclease family

The GIY-YIG nuclease domain was originally identified in homing endonucleases and enzymes involved in DNA repair and recombination. Many of the GIY-YIG family enzymes are functional as monomers. We show here that the Cfr42I restriction endonuclease which belongs to the GIY-YIG family and recognizes the symmetric sequence 5′-CCGC/GG-3′ (‘/’ indicates the cleavage site) is a tetramer in solution. Moreover, biochemical and kinetic studies provided here demonstrate that the Cfr42I tetramer is catalytically active only upon simultaneous binding of two copies of its recognition sequence. In that respect Cfr42I resembles the homotetrameric Type IIF restriction enzymes that belong to the distinct PD-(E/D)XK nuclease superfamily. Unlike the PD-(E/D)XK enzymes, the GIY-YIG nuclease Cfr42I accommodates an extremely wide selection of metal-ion cofactors, including Mg²⁺, Mn²⁺, Co²⁺, Zn²⁺, Ni²⁺, Cu²⁺ and Ca²⁺. To our knowledge, Cfr42I is the first tetrameric GIY-YIG family enzyme. Similar structural arrangement and phenotypes displayed by restriction enzymes of the PD-(E/D)XK and GIY-YIG nuclease families point to the functional significance of tetramerization.     

Protein stability indicates divergent evolution of PD-(D/E)XK type II restriction endonucleases

Type II restriction endonucleases recognize 4-8 base-pair-long DNA sequences and catalyze their cleavage with remarkable specificity. Crystal structures of the PD-(DE)XK superfamily revealed a common alpha/beta core motif and similar active site. In contrast, these enzymes show little sequence similarity and use different strategies to interact with their substrate DNA. The intriguing question is whether this enzyme family could have evolved from a common origin. In our present work, protein structure stability elements were analyzed and compared in three parts of PD-(DE)XK type II restriction endonucleases: (1) core motif, (2) active-site residues, and (3) residues playing role in DNA recognition. High correlation was found between the active-site residues and those stabilization factors that contribute to preventing structural decay. DNA recognition sites were also observed to participate in stabilization centers. It indicates that recognition motifs and active sites in PD-(DE)XK type II restriction endonucleases should have been evolutionary more conserved than other parts of the structure. Based on this observation it is proposed that PD-(DE)XK type II restriction endonucleases have developed from a common ancestor with divergent evolution.     

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.     

Identification of new homologs of PD-(D/E)XK nucleases by support vector machines trained on data derived from profile-profile alignments

PD-(D/E)XK nucleases, initially represented by only Type II restriction enzymes, now comprise a large and extremely diverse superfamily of proteins. They participate in many different nucleic acids transactions including DNA degradation, recombination, repair and RNA processing. Different PD-(D/E)XK families, although sharing a structurally conserved core, typically display little or no detectable sequence similarity except for the active site motifs. This makes the identification of new superfamily members using standard homology search techniques challenging. To tackle this problem, we developed a method for the detection of PD-(D/E)XK families based on the binary classification of profile-profile alignments using support vector machines (SVMs). Using a number of both superfamily-specific and general features, SVMs were trained to identify true positive alignments of PD-(D/E)XK representatives. With this method we identified several PFAM families of uncharacterized proteins as putative new members of the PD-(D/E)XK superfamily. In addition, we assigned several unclassified restriction enzymes to the PD-(D/E)XK type. Results show that the new method is able to make confident assignments even for alignments that have statistically insignificant scores. We also implemented the method as a freely accessible web server at http://www.ibt.lt/bioinformatics/software/pdexk/.     

Grouping together highly diverged PD-(D/E)XK nucleases and identification of novel superfamily members using structure-guided alignment of sequence profiles

The PD-(D/E)XK nuclease domains, initially identified in type II restriction enzymes, serve as models for studying aspects of protein-DNA interactions, mechanisms of phosphodiester hydrolysis, and provide indispensable tools for techniques in genetic engineering and molecular medicine. However, the low degree of amino acid conservation hampers the possibility of identification of PD-(D/E)XK superfamily members based solely on sequence comparisons. In several proteins implicated in DNA recombination and repair the restriction enzyme-like nuclease domain has been found only after the corresponding structures were determined experimentally. Here, we identified highly diverged variants of the PD-(D/E)XK domain in many proteins and open reading frames using iterative database searches and progressive, structure-guided alignment of sequence profiles. We predicted the possible cellular function for many hypothetical proteins based on their relative similarity to characterized nucleases or observed presence of additional domains. We also identified the nuclease domain in genuine recombinases and restriction enzymes, whose homology to other PD-(D/E)XK enzymes has not been demonstrated previously. The first superfamily-wide comparative analysis, not limited to nucleases of known structure, will guide cloning and characterization of novel enzymes and planning new experiments to better understand those already studied.     

Identification of GATC- and CCGG-recognizing Type II REases and their putative specificity-determining positions using Scan2S--a novel motif scan algorithm with optional secondary structure constraints

Restriction endonucleases (REases) are DNA-cleaving enzymes that have become indispensable tools in molecular biology. Type II REases are highly divergent in sequence despite their common structural core, function and, in some cases, common specificities towards DNA sequences. This makes it difficult to identify and classify them functionally based on sequence, and has hampered the efforts of specificity-engineering. Here, we define novel REase sequence motifs, which extend beyond the PD-(D/E)XK hallmark, and incorporate secondary structure information. The automated search using these motifs is carried out with a newly developed fast regular expression matching algorithm that accommodates long patterns with optional secondary structure constraints. Using this new tool, named Scan2S, motifs derived from REases with specificity towards GATC- and CGGG-containing DNA sequences successfully identify REases of the same specificity. Notably, some of these sequences are not identified by standard sequence detection tools. The new motifs highlight potential specificity-determining positions that do not fully overlap for the GATC- and the CCGG-recognizing REases and are candidates for specificity re-engineering.     

Mutational analysis of active‐site residues in the Mycobacterium leprae RecA intein,a LAGLIDADG homing endonuclease: Asp122 and Asp193 are crucial to the double‐stranded DNA cleavage activity whereas Asp218 is not

Mycobacterium leprae recA harbors an in‐frame insertion sequence that encodes an intein homing endonuclease (PI‐MleI). Most inteins (intein endonucleases) possess two conserved LAGLIDADG (DOD) motifs at their active center. A common feature of LAGLIDADG‐type homing endonucleases is that they recognize and cleave the same or very similar DNA sequences. However, PI‐MleI is distinctive from other members of the family of LAGLIDADG‐type HEases for its modular structure with functionally separable domains for DNA‐binding and cleavage, each with distinct sequence preferences. Sequence alignment analyses of PI‐MleI revealed three putative LAGLIDADG motifs; however, there is conflicting bioinformatics data in regard to their identity and specific location within the intein polypeptide. To resolve this conflict and to determine the active‐site residues essential for DNA target site recognition and double‐stranded DNA cleavage, we performed site‐directed mutagenesis of presumptive catalytic residues in the LAGLIDADG motifs. Analysis of target DNA recognition and kinetic parameters of the wild‐type PI‐MleI and its variants disclosed that the two amino acid residues, Asp¹²² (in Block C) and Asp¹⁹³ (in functional Block E), are crucial to the double‐stranded DNA endonuclease activity, whereas Asp²¹⁸ (in pseudo‐Block E) is not. However, despite the reduced catalytic activity, the PI‐MleI variants, like the wild‐type PI‐MleI, generated a footprint of the same length around the insertion site. The D122T variant showed significantly reduced catalytic activity, and D122A and D193A mutations although failed to affect their DNA‐binding affinities, but abolished the double‐stranded DNA cleavage activity. On the other hand, D122C variant showed approximately twofold higher double‐stranded DNA cleavage activity, compared with the wild‐type PI‐MleI. These results provide compelling evidence that Asp¹²² and Asp¹⁹³ in DOD motif I and II, respectively, are bona fide active‐site residues essential for DNA cleavage activity. The implications of these results are discussed in this report.     

Theoretical model of restriction endonuclease HpaI in complex with DNA, predicted by fold recognition and validated by site-directed mutagenesis

Type II restriction enzymes are commercially important deoxyribonucleases and very attractive targets for protein engineering of new specificities. At the same time they are a very challenging test bed for protein structure prediction methods. Typically, enzymes that recognize different sequences show little or no amino acid sequence similarity to each other and to other proteins. Based on crystallographic analyses that revealed the same PD-(D/E)XK fold for more than a dozen case studies, they were nevertheless considered to be related until the combination of bioinformatics and mutational analyses has demonstrated that some of these proteins belong to other, unrelated folds PLD, HNH, and GIY-YIG. As a part of a large-scale project aiming at identification of a three-dimensional fold for all type II REases with known sequences (currently approximately 1000 proteins), we carried out preliminary structure prediction and selected candidates for experimental validation. Here, we present the analysis of HpaI REase, an ORFan with no detectable homologs, for which we detected a structural template by protein fold recognition, constructed a model using the FRankenstein monster approach and identified a number of residues important for the DNA binding and catalysis. These predictions were confirmed by site-directed mutagenesis and in vitro analysis of the mutant proteins. The experimentally validated model of HpaI will serve as a low-resolution structural platform for evolutionary considerations in the subgroup of blunt-cutting REases with different specificities. The research protocol developed in the course of this work represents a streamlined version of the previously used techniques and can be used in a high-throughput fashion to build and validate models for other enzymes, especially ORFans that exhibit no sequence similarity to any other protein in the database.     

Type II restriction endonuclease R.KpnI is a member of the HNH nuclease superfamily

The restriction endonuclease (REase) R.KpnI is an orthodox Type IIP enzyme, which binds to DNA in the absence of metal ions and cleaves the DNA sequence 5′-GGTAC^C-3′ in the presence of Mg²⁺ as shown generating 3′ four base overhangs. Bioinformatics analysis reveals that R.KpnI contains a ββα-Me-finger fold, which is characteristic of many HNH-superfamily endonucleases, including homing endonuclease I-HmuI, structure-specific T4 endonuclease VII, colicin E9, sequence non-specific Serratia nuclease and sequence-specific homing endonuclease I-PpoI. According to our homology model of R.KpnI, D148, H149 and Q175 correspond to the critical D, H and N or H residues of the HNH nucleases. Substitutions of these three conserved residues lead to the loss of the DNA cleavage activity by R.KpnI, confirming their importance. The mutant Q175E fails to bind DNA at the standard conditions, although the DNA binding and cleavage can be rescued at pH 6.0, indicating a role for Q175 in DNA binding and cleavage. Our study provides the first experimental evidence for a Type IIP REase that does not belong to the PD…D/EXK superfamily of nucleases, instead is a member of the HNH superfamily.     

Mutability of an HNH nuclease imidazole general base and exchange of a deprotonation mechanism

Several unique protein folds that catalyze the hydrolysis of phosphodiester bonds have arisen independently in nature, including the PD(D/E)XK superfamily (typified by type II restriction endonucleases and many recombination and repair enzymes) and the HNH superfamily (found in an equally wide array of enzymes, including bacterial colicins and homing endonucleases). Whereas the identity and position of catalytic residues within the PD(D/E)XK superfamily are highly variable, the active sites of HNH nucleases are much more strongly conserved. In this study, the ability of an HNH nuclease to tolerate a mutation of its most conserved catalytic residue (its histidine general base), and the mechanism of the most active enzyme variant, were characterized. Conversion of this residue into several altered chemistries, glutamine, lysine, or glutamate, resulted in measurable activity. The histidine to glutamine mutant displays the highest residual activity and a pH profile similar to that of the wild-type enzyme. This activity is dependent on the presence of a neighboring imidazole ring, which has taken over as a less efficient general base for the reaction. This result implies that mutational pathways to alternative HNH-derived catalytic sites do exist but are not as extensively or successfully diverged or reoptimized in nature as variants of the PD(D/E)XK nuclease superfamily. This is possibly due to multiple steric constraints placed on the compact HNH motif, which is simultaneously involved in protein folding, DNA binding, and catalysis, as well as the use of a planar, aromatic imidazole group as a general base.     

Structure of Xanthomonas axonopodis pv. citri YaeQ reveals a new compact protein fold built around a variation of the PD-(D/E)XK nuclease motif

The YaeQ family of proteins are found in many Gram-negative and a few Gram-positive bacteria. We have determined the first structure of a member of the YaeQ family by X-ray crystallography. Comparisons with other structures indicate that YaeQ represents a new compact protein fold built around a variation of the PD-(D/E)XK nuclease motif found in type II endonucleases and enzymes involved in DNA replication, repair, and recombination. We show that catalytically important residues in the PD-(D/E)XK nuclease superfamily are spatially conserved in YaeQ and other highly conserved YaeQ residues may be poised to interact with nucleic acid structures.