Importance of a single base pair for discrimination between intron-containing and intronless alleles by endonuclease I-BmoI

Homing endonucleases initiate mobility of their host group I introns by binding to and cleaving lengthy recognition sequences that are typically centered on the intron insertion site (IS) of intronless alleles. Because the intron interrupts the endonucleases' recognition sequence, intron-containing alleles are immune to cleavage by their own endonuclease. I-TevI and I-BmoI are related GIY-YIG endonucleases that bind a homologous stretch of thymidylate synthase (TS)-encoding DNA but use different strategies to distinguish intronless from intron-containing substrates. I-TevI discriminates between substrates at the level of DNA binding, as its recognition sequence is centered on the intron IS. I-BmoI, in contrast, possesses a very asymmetric recognition sequence with respect to the intron IS, binds both intron-containing and intronless TS-encoding substrates, but efficiently cleaves only intronless substrate. Here, we show that I-BmoI is extremely tolerant of multiple substitutions around its cleavage sites and has a low specific activity. However, a single G-C base pair, at position -2 of a 39-base pair recognition sequence, is a major determinant for cleavage efficiency and distinguishes intronless from intron-containing alleles. Strikingly, this G-C base pair is universally conserved in phylogenetically diverse TS-coding sequences; this finding suggests that I-BmoI has evolved exquisite cleavage requirements to maximize the potential to spread to variant intronless alleles, while minimizing cleavage at its own intron-containing allele.     

Perpetuating the homing endonuclease life cycle: identification of mutations that modulate and change I-TevI cleavage preference

Homing endonucleases are sequence-tolerant DNA endonucleases that act as mobile genetic elements. The ability of homing endonucleases to cleave substrates with multiple nucleotide substitutions suggests a high degree of adaptability in that changing or modulating cleavage preference would require relatively few amino acid substitutions. Here, using directed evolution experiments with the GIY-YIG homing endonuclease I-TevI that targets the thymidylate synthase gene of phage T4, we readily isolated variants that dramatically broadened I-TevI cleavage preference, as well as variants that fine-tuned cleavage preference. By combining substitutions, we observed an ∼10 000-fold improvement in cleavage on some substrates not cleaved by the wild-type enzyme, correlating with a decrease in readout of information content at the cleavage site. Strikingly, we were able to change the cleavage preference of I-TevI to that of the isoschizomer I-BmoI which targets a different cleavage site in the thymidylate synthase gene, recapitulating the evolution of cleavage preference in this family of homing endonucleases. Our results define a strategy to isolate GIY-YIG nuclease domains with distinct cleavage preferences, and provide insight into how homing endonucleases may escape a dead-end life cycle in a population of saturated target sites by promoting transposition to different target sites.     

Divalent metal ion differentially regulates the sequential nicking reactions of the GIY-YIG homing endonuclease I-BmoI

Homing endonucleases are site-specific DNA endonucleases that function as mobile genetic elements by introducing double-strand breaks or nicks at defined locations. Of the major families of homing endonucleases, the modular GIY-YIG endonucleases are least understood in terms of mechanism. The GIY-YIG homing endonuclease I-BmoI generates a double-strand break by sequential nicking reactions during which the single active site of the GIY-YIG nuclease domain must undergo a substantial reorganization. Here, we show that divalent metal ion plays a significant role in regulating the two independent nicking reactions by I-BmoI. Rate constant determination for each nicking reaction revealed that limiting divalent metal ion has a greater impact on the second strand than the first strand nicking reaction. We also show that substrate mutations within the I-BmoI cleavage site can modulate the first strand nicking reaction over a 314-fold range. Additionally, in-gel DNA footprinting with mutant substrates and modeling of an I-BmoI-substrate complex suggest that amino acid contacts to a critical GC-2 base pair are required to induce a bottom-strand distortion that likely directs conformational changes for reaction progress. Collectively, our data implies mechanistic roles for divalent metal ion and substrate bases, suggesting that divalent metal ion facilitates the re-positioning of the GIY-YIG nuclease domain between sequential nicking reactions.     

Assessing the plasticity of DNA target site recognition of the PI-SceI homing endonuclease using a bacterial two-hybrid selection system

The PI-SceI protein from Saccharomyces cerevisiae is a member of the LAGLIDADG family of homing endonucleases that have been used in genomic engineering. To assess the flexibility of the PI-SceI-binding interaction and to make progress towards the directed evolution of homing endonucleases that cleave specified DNA targets, we applied a two-hybrid method to select PI-SceI variants from a randomized expression library that bind to different DNA substrates. In particular, the codon for Arg94, which is located in the protein splicing domain and makes essential contacts to two adjacent base-pairs, and the codons for four proximal residues were randomized. There is little conservation of the wild-type amino acid residues at the five randomized positions in the variants that were selected to bind to the wild-type site, yet one of the purified derivatives displays DNA-binding specificity and DNA endonuclease activity that is similar to that of the wild-type enzyme. A spectrum of DNA-binding behaviors ranging from partial relaxation of specificity to marked shifts in target site recognition are present in variants selected to bind to sites containing mutations at the two base-pairs. Our results illustrate the inherent plasticity of the PI-SceI/DNA interface and demonstrate that selection based on DNA binding is an effective means of altering the DNA cleavage specificity of homing endonucleases. Furthermore, it is apparent that homing endonuclease target specificity derives, in part, from constraints on the flexibility of DNA contacts imposed by hydrogen bonds to proximal residues.     

Catalytic domain structure and hypothesis for function of GIY-YIG intron endonuclease I-TevI

I-TevI, a member of the GIY-YIG family of homing endonucleases, consists of an N-terminal catalytic domain and a C-terminal DNA-binding domain joined by a flexible linker. The GIY-YIG motif is in the N-terminal domain of I-TevI, which corresponds to a phylogenetically widespread catalytic cartridge that is often associated with mobile genetic elements. The crystal structure of the catalytic domain of I-TevI, the first of any GIY-YIG endonuclease, reveals a novel alpha/beta-fold with a central three-stranded antiparallel beta-sheet flanked by three helices. The most conserved and putative catalytic residues are located on a shallow, concave surface and include a metal coordination site. Similarities in the three-dimensional arrangement of the catalytically important residues and the cation-binding site with those of the His-Cys box endonuclease I-PpoI suggest the possibility of mechanistic relationships among these different families of homing endonucleases despite completely different folds.     

Strand-specific contacts and divalent metal ion regulate double-strand break formation by the GIY-YIG homing endonuclease I-BmoI

GIY-YIG homing endonucleases are modular enzymes consisting of a well-defined N-terminal catalytic domain connected to a variable C-terminal DNA-binding domain. Previous studies have revealed that the role of the DNA-binding domain is to recognize and bind intronless DNA substrate, positioning the N-terminal catalytic domain such that it is poised to generate a staggered double-strand break by an unknown mechanism. Interactions of the N-terminal catalytic domain with intronless substrate are therefore a critical step in the reaction pathway but have been difficult to define. Here, we have taken advantage of the reduced activity of I-BmoI, an isoschizomer of the well-studied bacteriophage T4 homing endonuclease I-TevI, to examine double-strand break formation by I-BmoI. We present evidence demonstrating that I-BmoI generates a double-strand break by two sequential but chemically independent nicking reactions where divalent metal ion is a limiting factor in top-strand nicking. We also show by in-gel footprinting that contacts by the I-BmoI catalytic domain induce significant minor groove DNA distortions that occur independently of bottom-strand nicking. Bottom-strand contacts are critical for accurate top-strand nicking, whereas top-strand contacts have little influence on the accuracy of bottom-strand nicking. We discuss our results in the context of current models of GIY-YIG endonuclease function, with emphasis on the role of divalent metal ion and strand-specific contacts in regulating the activity of a single active site to generate a staggered double-strand break.     

Intron-encoded endonuclease I-TevI binds as a monomer to effect sequential cleavage via conformational changes in the td homing site.

I-TevI, the intron-encoded endonuclease from the thymidylate synthase (td) gene of bacteriophage T4, binds its DNA substrate across the minor groove in a sequence-tolerant fashion. We demonstrate here that the 28 kDa I-TevI binds the extensive 37 bp td homing site as a monomer and significantly distorts its substrate. In situ cleavage assays and phasing analyses indicate that upon nicking the bottom strand of the td homing site, I-TevI induces a directed bend of 38 degrees towards the major groove near the cleavage site. Formation of the bent I-TevI-DNA complex is proposed to promote top-strand cleavage of the homing site. Furthermore, reductions in the degree of distortion and in the efficiency of binding base-substitution variants of the td homing site indicate that sequences flanking the cleavage site contribute to the I-TevI-induced conformational change. These results, combined with genetic, physical and computer-modeling studies, form the basis of a model, wherein I-TevI acts as a hinged monomer to induce a distortion that widens the minor groove, facilitating access to the top-strand cleavage site. The model is compatible with both unmodified DNA and glucosylated hydroxymethylcytosine-containing DNA, as exists in the T-even phages.     

102 Genome engineering nucleases derived from GIY-YIG homing endonucleases

Efficient targeted manipulation of complex genomes requires highly specific endonucleases to generate double-strand breaks at defined locations (Bibikova et al., 2003; Bogdanove and Voytas, 2011). The predominantly engineered nucleases, zinc-finger nucleases (ZFNs), and TAL effector nucleases (TALENs) use the catalytic domain of FokI as the nuclease portion. This domain, however, functions as a dimer to nonspecifically cleave DNA meaning that ZFNs and TALENs must be designed in head-to-head pairs to target a desired sequence. To overcome this limitation and expand the toolbox of genome editing reagents, we used the N-terminal catalytic domain and interdomain linker of the monomeric GIY-YIG homing endonuclease I-TevI to create I-TevI-zinc-fingers (Tev-ZFEs), and I-TevI-TAL effectors (Tev-TALs) (Kleinstiver et al. 2012). We also made I-TevI fusions to LAGLIDADGs homing endonucleases (I-Tev-LHEs). All the three fusions showed activity on model substrates on par with ZFNs and TALENs in yeast-based recombination assays. These proof-of-concept experiments demonstrate that the catalytic domain of GIY-YIG homing endonucleases can be targeted to relevant loci by fusing the domain to characterize DNA-binding platforms. Recent efforts have focused on improving the Tev-TAL platform by (1) understanding the spacing requirements between the nuclease cleavage site and the DNA binding site, (2) probing the DNA binding requirements of the I-TevI linker domain, and (3) demonstrating activity in mammalian systems.     

SegG endonuclease promotes marker exclusion and mediates co-conversion from a distant cleavage site

Bacteriophages T2 and T4 are closely related T-even phages. However, T4 genetic markers predominate in the progeny of mixed infections, a phenomenon termed marker exclusion. One region previously mapped where the frequency of T2 markers in the progeny is extremely low is located around gene 32. Here, we describe SegG, a GIY-YIG family endonuclease adjacent to gene 32 of phage T4 that is absent from phage T2. In co-infections with T2 and T4, cleavage in T2 gene 32 by T4-encoded SegG initiates a gene conversion event that results in replacement of T2 gene 32 markers with the corresponding T4 sequence. Interestingly, segG inheritance is limited, apparently because of the physical separation of its cleavage and insertion sites, which are 332 base-pairs apart. This contrasts with efficient inheritance of the phage T4 td group I intron and its endonuclease, I-TevI, for which the distance separating the I-TevI cleavage site and td insertion site is 23 base-pairs. Furthermore, we show that co-conversion tracts generated by repair of SegG and I-TevI double-strand breaks contribute to the localized exclusion of T2 markers. Our results demonstrate that the endonuclease activities of SegG and I-TevI promote the spread of these two endonucleases to progeny phage, consistent with their role as selfish genetic elements, and also provide a mechanism by which the genetic contribution of T2 markers to progeny phage is reduced.     

Amino acid residues in the GIY-YIG endonuclease II of phage T4 affecting sequence recognition and binding as well as catalysis

Phage T4 endonuclease II (EndoII), a GIY-YIG endonuclease lacking a carboxy-terminal DNA-binding domain, was subjected to site-directed mutagenesis to investigate roles of individual amino acids in substrate recognition, binding, and catalysis. The structure of EndoII was modeled on that of UvrC. We found catalytic roles for residues in the putative catalytic surface (G49, R57, E118, and N130) similar to those described for I-TevI and UvrC; in addition, these residues were found to be important for substrate recognition and binding. The conserved glycine (G49) and arginine (R57) were essential for normal sequence recognition. Our results are in agreement with a role for these residues in forming the DNA-binding surface and exposing the substrate scissile bond at the active site. The conserved asparagine (N130) and an adjacent proline (P127) likely contribute to positioning the catalytic domain correctly. Enzymes in the EndoII subfamily of GIY-YIG endonucleases share a strongly conserved middle region (MR, residues 72 to 93, likely helical and possibly substituting for heterologous helices in I-TevI and UvrC) and a less strongly conserved N-terminal region (residues 12 to 24). Most of the conserved residues in these two regions appeared to contribute to binding strength without affecting the mode of substrate binding at the catalytic surface. EndoII K76, part of a conserved NUMOD3 DNA-binding motif of homing endonucleases found to overlap the MR, affected both sequence recognition and catalysis, suggesting a more direct involvement in positioning the substrate. Our data thus suggest roles for the MR and residues conserved in GIY-YIG enzymes in recognizing and binding the substrate.     

DNA binding and cleavage by the HNH homing endonuclease I-HmuI

The structure of I-HmuI, which represents the last family of homing endonucleases without a defining crystallographic structure, has been determined in complex with its DNA target. A series of diverse protein structural domains and motifs, contacting sequential stretches of nucleotide bases, are distributed along the DNA target. I-HmuI contains an N-terminal domain with a DNA-binding surface found in the I-PpoI homing endonuclease and an associated HNH/N active site found in the bacterial colicins, and a C-terminal DNA-binding domain previously observed in the I-TevI homing endonuclease. The combination and exchange of these features between protein families indicates that the genetic mobility associated with homing endonucleases extends to the level of independent structural domains. I-HmuI provides an unambiguous structural connection between the His-Cys box endonucleases and the bacterial colicins, supporting the hypothesis that these enzymes diverged from a common ancestral nuclease.     

Functional characterization of isoschizomeric His-Cys box homing endonucleases from Naegleria.

Several species within the amoeboflagellate genus Naegleria harbor an optional ORF containing group I introns in their nuclear small subunit ribosomal DNA. The different ORFs encode homing endonucleases with 65 to 95% identity at the amino-acid level. I-NjaI, I-NanI and I-NitI, from introns in Naegleria jamiesoni, N. andersoni and N. italica, respectively, were analyzed in more detail and found to be isoschizomeric endonucleases that recognize and cleave an approximal 19-bp partially symmetrical sequence, creating a pentanucleotide 3' overhang upon cleavage. The optimal conditions for cleavage activity with respect to temperature, pH, salt and divalent metal ions were investigated. The optimal cleavage temperature for all three endonucleases was found to be 37 degrees C and the activity was dependent on the concentration of NaCl with an optimum at 200 mM. Divalent metal ions, primarily Mg2+, are essential for Naegleria endonuclease activity. Whereas both Mn2+ and Ca2+ could substitute for Mg2+, but with a slower cleavage rate, Zn2+ was unable to support cleavage. Interestingly, the pH dependence of DNA cleavage was found to vary significantly between the I-NitI and I-NjaI/I-NanI endonucleases with optimal pH values at 6.5 and 9, respectively. Site-directed mutagenesis of conserved I-NjaI residues strongly supports the hypothesis that Naegleria homing endonucleases share a similar zinc-binding structure and active site with the His-Cys box homing endonuclease I-PpoI.     

Cleavage specificity of bacteriophage T4 endonuclease VII and bacteriophage T7 endonuclease I on synthetic branch migratable Holliday junctions

Holliday junctions are intermediate structures that are formed and resolved during the process of genetic recombination. To investigate the interaction of junction-resolving nucleases with synthetic Holliday junctions that contain homologous arm sequences, we constructed substrates in which the junction point was free to branch migrate through 26 base-pairs of homology. In the absence of divalent cations, we found that both phage T4 endonuclease VII and phage T7 endonuclease I bound the synthetic junctions to form specific protein-DNA complexes. Such complexes were not observed in the presence of Mg2+, since the Holliday junctions were resolved by the introduction of symmetrical cuts in strands of like polarity. The major sites of cleavage were identified and found to occur within the boundaries of homology. T4 endonuclease VII showed a cleavage preference for the 3' side of thymine bases, whereas T7 endonuclease I preferentially cut the DNA between two pyrimidine residues. However, cleavage was not observed at all the available sites, indicating that in addition to their structural requirements, the endonucleases show strong site preferences.     

Activity, specificity and structure of I-Bth0305I: a representative of a new homing endonuclease family

Novel family of putative homing endonuclease genes was recently discovered during analyses of metagenomic and genomic sequence data. One such protein is encoded within a group I intron that resides in the recA gene of the Bacillus thuringiensis 03058-36 bacteriophage. Named I-Bth0305I, the endonuclease cleaves a DNA target in the uninterrupted recA gene at a position immediately adjacent to the intron insertion site. The enzyme displays a multidomain, homodimeric architecture and footprints a DNA region of ~60 bp. Its highest specificity corresponds to a 14-bp pseudopalindromic sequence that is directly centered across the DNA cleavage site. Unlike many homing endonucleases, the specificity profile of the enzyme is evenly distributed across much of its target site, such that few single base pair substitutions cause a significant decrease in cleavage activity. A crystal structure of its C-terminal domain confirms a nuclease fold that is homologous to very short patch repair (Vsr) endonucleases. The domain architecture and DNA recognition profile displayed by I-Bth0305I, which is the prototype of a homing lineage that we term the 'EDxHD' family, are distinct from previously characterized homing endonucleases.     

Flexible DNA target site recognition by divergent homing endonuclease isoschizomers I-CreI and I-MsoI

Homing endonucleases are highly specific catalysts of DNA strand breaks that induce the transposition of mobile intervening sequences containing the endonuclease open reading frame. These enzymes recognize long DNA targets while tolerating individual sequence polymorphisms within those sites. Sequences of the homing endonucleases themselves diversify to a great extent after founding intron invasion events, generating highly divergent enzymes that recognize similar target sequences. Here, we visualize the mechanism of flexible DNA recognition and the pattern of structural divergence displayed by two homing endonuclease isoschizomers. We determined structures of I-CreI bound to two DNA target sites that differ at eight of 22 base-pairs, and the structure of an isoschizomer, I-MsoI, bound to a nearly identical DNA target site. This study illustrates several principles governing promiscuous base-pair recognition by DNA-binding proteins, and demonstrates that the isoschizomers display strikingly different protein/DNA contacts. The structures allow us to determine the information content at individual positions in the binding site as a function of the distribution of direct and water-mediated contacts to nucleotide bases, and provide an evolutionary snapshot of endonucleases at an early stage of divergence in their target specificity.     

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.     

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.     

Isolation and characterization of new homing endonuclease specificities at individual target site positions

Homing endonucleases are highly specific DNA endonucleases, encoded within mobile introns or inteins, that induce targeted recombination, double-strand repair and gene conversion of their cognate target sites. Due to their biological function and high level of target specificity, these enzymes are under intense investigation as tools for gene targeting. These studies require that naturally occurring enzymes be redesigned to recognize novel target sites. Here, we report studies in which the homodimeric LAGLIDADG homing endonuclease I-CreI is altered at individual side-chains corresponding to contact points to distinct base-pairs in its target site. The resulting enzyme constructs drive specific elimination of selected DNA targets in vivo and display shifted specificities of DNA binding and cleavage in vitro. Crystal structures of two of these constructs demonstrate that substitution of individual side-chain/DNA contact patterns can occur with almost no structural deformation or rearrangement of the surrounding complex, facilitating an isolated, modular redesign strategy for homing endonuclease activity and specificity.