Photocross-linking of the homing endonuclease PI-SceI to its recognition sequence

PI-SceI is an intein-encoded protein that belongs to the LAGLIDADG family of homing endonucleases. According to the crystal structure and mutational studies, this endonuclease consists of two domains, one responsible for protein splicing, the other for DNA cleavage, and both presumably for DNA binding. To define the DNA binding site of PI-SceI, photocross-linking was used to identify amino acid residues in contact with DNA. Sixty-three double-stranded oligodeoxynucleotides comprising the minimal recognition sequence and containing single 5-iodopyrimidine substitutions in almost all positions of the recognition sequence were synthesized and irradiated in the presence of PI-SceI with a helium/cadmium laser (325 nm). The best cross-linking yield (approximately 30%) was obtained with an oligodeoxynucleotide with a 5-iododeoxyuridine at position +9 in the bottom strand. The subsequent analysis showed that cross-linking had occurred with amino acid His-333, 6 amino acids after the second LAGLIDADG motif. With the H333A variant of PI-SceI or in the presence of excess unmodified oligodeoxynucleotide, no cross-linking was observed, indicating the specificity of the cross-linking reaction. Chemical modification of His residues in PI-SceI by diethylpyrocarbonate leads to a substantial reduction in the binding and cleavage activity of PI-SceI. This inactivation can be suppressed by substrate binding. This result further supports the finding that at least one His residue is in close contact to the DNA. Based on these and published results, conclusions are drawn regarding the DNA binding site of PI-SceI.     

Crystal structure of the intein homing endonuclease PI-SceI bound to its recognition sequence

The first X-ray structures of an intein-DNA complex, that of the two-domain homing endonuclease PI-SceI bound to its 36-base pair DNA substrate, have been determined in the presence and absence of Ca(2+). The DNA shows an asymmetric bending pattern, with a major 50 degree bend in the endonuclease domain and a minor 22 degree bend in the splicing domain region. Distortions of the DNA bound to the endonuclease domain cause the insertion of the two cleavage sites in the catalytic center. DNA binding induces changes in the protein conformation. The two overlapping non-identical active sites in the endonucleolytic center contain two Ca(+2) ions that coordinate to the catalytic Asp residues. Structure analysis indicates that the top strand may be cleaved first.     

DNA recognition by the homing endonuclease PI-SceI involves a divalent metal ion cofactor-induced conformational change

PI-SceI, a homing endonuclease of the LAGLIDADG family, consists of two domains involved in DNA cleavage and protein splicing, respectively. Both domains cooperate in binding the recognition sequence. Comparison of the structures of PI-SceI in the absence and presence of substrate reveals major conformational changes in both the protein and DNA. Notably, in the protein-splicing domain the loop comprising residues 53-70 and adopts a "closed" conformation, thus enabling it to interact with the DNA. We have studied the dynamics of DNA binding and subsequent loop movement by fluorescence techniques. Six amino acids in loop53-70 were individually replaced by cysteine and modified by fluorescein. The interaction of the modified PI-SceI variants with the substrate, unlabeled or labeled with tetramethylrhodamine, was analyzed in equilibrium and stopped-flow experiments. A kinetic scheme was established describing the interaction between PI-SceI and DNA. It is noteworthy that the apparent hinge-flap motion of loop53-70 is only observed in the presence of a divalent metal ion cofactor. Substitution of the major Mg2+-binding ligands in PI-SceI, Asp-218 and Asp-326, by Asn or "nicking" PI-SceI with trypsin at Arg-277, which interferes with formation of an active enzyme.substrate complex, both prevent the conformational change of loop53-70. Deletion of the loop inactivates the enzyme. We conclude that loop53-70 is an important structural element that couples DNA recognition by the splicing domain with DNA cleavage by the catalytic domain and as such "communicates" with the Mg2+ binding sites at the catalytic centers.     

Chemical mechanism of DNA cleavage by the homing endonuclease I-PpoI

Homing endonucleases are distinguished by their ability to catalyze the cleavage of double-stranded DNA with extremely high specificity. I-PpoI endonuclease, a homing endonuclease from the slime mold Physarum polycephalum, is a small enzyme (2 x 20 kDa) of known three-dimensional structure that catalyzes the cleavage of a long target DNA sequence (15 base pairs). Here, a detailed chemical mechanism for catalysis of DNA cleavage by I-PpoI endonuclease is proposed and tested by creating six variants in which active-site residues are replaced with alanine. The side chains of three residues (Arg61, His98, and Asn119) are found to be important for efficient catalysis of DNA cleavage. This finding is consistent with the proposed mechanism in which His98 abstracts a proton from an attacking water molecule bound by an adjacent phosphoryl oxygen, Arg61 and Asn119 stabilize the pentavalent transition state, and Asn119 also binds to the essential divalent metal cation (e.g., Mg(2+) ion), which interacts with the 3'-oxygen leaving group. Because Mg(2+) is required for cleavage of a substrate with a good leaving group (p-nitrophenolate), Mg(2+) likely stabilizes the pentavalent transition state. The pH-dependence of k(cat) for catalysis by I-PpoI reveals a macroscopic pK(a) of 8.4 for titratable groups that modulate product release. I-PpoI appears to be unique among known restriction endonucleases and homing endonucleases in its use of a histidine residue to activate the attacking water molecule for in-line displacement of the 3'-leaving group.     

Metal-dependent DNA cleavage mechanism of the I-CreI LAGLIDADG homing endonuclease

The LAGLIDADG homing endonucleases include free-standing homodimers, pseudosymmetric monomers, and related enzyme domains embedded within inteins. DNA-bound structures of homodimeric I-CreI and monomeric I-SceI indicate that three catalytic divalent metal ions are distributed across a pair of overlapping active sites, with one shared metal participating in both strand cleavage reactions. These structures differ in the precise position and binding interactions of the metals. We have studied the metal dependence for the I-CreI homodimer using site-directed mutagenesis of active site residues and assays of binding affinity and cleavage activity. We have also reassessed the binding of a nonactivating metal ion (calcium) in the wild-type enzyme-substrate complex, and determined the DNA-bound structure of two inactive enzyme mutants. The conclusion of these studies is that the catalytic mechanism of symmetric LAGLIDADG homing endonucleases, and probably many of their monomeric cousins, involves a canonical two-metal mechanism in each of two active sites, which are chemically and structurally tethered to one another by a shared metal ion. Failure to occupy the shared metal site, as observed in the presence of calcium or when the metal-binding side chain from the LAGLIDADG motif (Asp 20) is mutated to asparagine, prevents cleavage by the enzyme.     

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.     

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.     

High resolution crystal structure of domain I of the Saccharomyces cerevisiae homing endonuclease PI-SceI

The homing endonuclease PI-SceI from Saccharo myces cerevisiae consists of two domains. The protein splicing domain I catalyzes the excision of the mature endonuclease (intein) from a precursor protein and the religation of the flanking amino acid sequences (exteins) to a functional protein. Furthermore, domain I is involved in binding and recognition of the specific DNA substrate. Domain II of PI-SceI, the endonuclease domain, which is structurally homologous to other homing endonucleases from the LAGLIDADG family, harbors the endonucleolytic center of PI-SceI, which in vivo initiates the homing process by introducing a double-strand cut in the ~35 bp recognition sequence. At 1.35 Å resolution, the crystal structure of PI-SceI domain I provides a detailed view of the part of the protein that is responsible for tight and specific DNA binding. A geometry-based docking of the 75° bent recognition sequence to the full-length protein implies a conformational change or hinge movement of a subdomain of domain I, the tongs part, that is predicted to reach into the major groove near base pairs +16 to +18.     

Analysis of the LAGLIDADG interface of the monomeric homing endonuclease I-DmoI

The general structural fold of the LAGLIDADG endonuclease family consists of two similar α/β domains (αββαββα) that assemble either as homodimers or monomers with the domains related by pseudo-two-fold symmetry. At the center of this symmetry is the closely packed LAGLIDADG two-helix bundle that forms the main inter- or intra-molecular contact region between the domains of single- or double-motif proteins, respectively. In this work, we further examine the role of the LAGLIDADG residues involved in the helix–helix interaction. The interchangeability of the LAGLIDADG helix interaction was explored by grafting interfacial residues from the homodimeric I-CreI into the corresponding positions in the monomeric I-DmoI. The resulting LAGLIDADG exchange mutant is partially active, preferring to nick dsDNA rather than making the customary double-strand break. A series of partial revertants within the mutated LAGLIDADG region are shown to restore cleavage activity to varying degrees resulting in one I-DmoI mutant that is more active than wild-type I-DmoI. The phenotype of some of these mutants was reconciled on the basis of similarity to the GxxxG helix interaction found in transmembrane proteins. Additionally, a split variant of I-DmoI was created, demonstrating that the LAGLIDADG helices of I-DmoI are capable of forming and maintaining the protein–protein interface in trans to create an active heterodimer.     

Chemical probing shows that the intron-encoded endonuclease I-SceI distorts DNA through binding in monomeric form to its homing site

Despite its small size (27.6 kDa), the group I intron-encoded I-SceI endonuclease initiates intron homing by recognizing and specifically cleaving a large intronless DNA sequence. Here, we used gel shift assays and footprinting experiments to analyze the interaction between I-SceI and its target. I-SceI was found to bind to its substrate in monomeric form. Footprinting using DNase I, hydroxyl radical, phenanthroline copper complexes, UV/DH-MePyPs photosensitizer, and base-modifying reagents revealed the asymmetric nature of the interaction and provided a first glimpse into the architecture of the complex. The protein interacts in the minor and major grooves and distorts DNA at three distinct sites: one at the intron insertion site and the other two, respectively, downstream (-8, -9) and upstream (+9, +10) from this site. The protein appears to stabilize the DNA curved around it by bridging the minor groove on one face of the helix. The scissile phosphates would lie on the outside of the bend, facing in the same direction relative to the DNA helical axis, as expected for an endonuclease that generates 3' overhangs. An internally consistent model is proposed in which the protein would take advantage of the concerted flexibility of the DNA sequence to induce a synergistic binding/kinking process, resulting in the correct positioning of the enzyme active site.     

The C-terminal loop of the homing endonuclease I-CreI is essential for site recognition, DNA binding and cleavage

Meganucleases are sequence-specific endonucleases with large cleavage sites that can be used to induce efficient homologous gene targeting in cultured cells and plants. These enzymes open novel perspectives for genome engineering in a wide range of fields, including gene therapy. A new crystal structure of the I-CreI dimer without DNA has allowed the comparison with the DNA-bound protein. The C-terminal loop displays a different conformation, which suggests its implication in DNA binding. A site-directed mutagenesis study in this region demonstrates that whereas the C-terminal helix is negligible for DNA binding, the final C-terminal loop is essential in DNA binding and cleavage. We have identified two regions that comprise the Ser138–Lys139 and Lys142–Thr143 pairs whose double mutation affect DNA binding in vitro and abolish cleavage in vivo. However, the mutation of only one residue in these sites allows DNA binding in vitro and cleavage in vivo. These findings demonstrate that the C-terminal loop of I-CreI endonuclease plays a fundamental role in its catalytic mechanism and suggest this novel site as a region to take into account for engineering new endonucleases with tailored specificity.     

Mutations altering the cleavage specificity of a homing endonuclease

The homing endonuclease I-CreI recognizes and cleaves a particular 22 bp DNA sequence. The crystal structure of I-CreI bound to homing site DNA has previously been determined, leading to a number of predictions about specific protein–DNA contacts. We test these predictions by analyzing a set of endonuclease mutants and a complementary set of homing site mutants. We find evidence that all structurally predicted I-CreI/DNA contacts contribute to DNA recognition and show that these contacts differ greatly in terms of their relative importance. We also describe the isolation of a collection of altered specificity I-CreI derivatives. The in vitro DNA-binding and cleavage properties of two such endonucleases demonstrate that our genetic approach is effective in identifying homing endonucleases that recognize and cleave novel target sequences.     

Binding, bending and cleavage of DNA substrates by the homing endonuclease Pl-SceI.

To characterize the interaction between the homing endonuclease PI-SceI and DNA, we prepared different DNA substrates containing the natural recognition sequence or parts thereof. Depending on the nature of the substrates, efficient cleavage is observed with a DNA containing approximatel 30 bp of the natural recognition sequence using supercoiled plasmids, approximately 40-50 bp using linearized plasmids and > 50 bp using synthetic double-stranded oligodeoxynucleotides. Cleavage of supercoiled plasmids occurs without accumulation of the nicked intermediate. In the presence of Mn2+, DNA cleavage by PI-SceI is more efficient than with Mg2+ and already occurs with substrates containing a shorter part of the recognition sequence. The requirements for strong binding are less stringent: a 35 bp oligodeoxynucleotide which is not cleaved is bound as firmly as other longer oligodeoxynucleotides. PI-SceI binds with high affinity to one of its cleavage products, a finding which may explain why PI-SceI hardly shows enzymatic turnover in vitro. Upon binding, two complexes are formed, which differ in the degree of bending (45 degrees versus 75 degrees). According to a phasing analysis bending is directed into the major groove. Strong binding, not, however, cleavage is also observed with the genetically engineered enzymatically inactive variant comprising amino acids 1-277. Models for binding and cleavage of DNA by PI-SceI are discussed based on these results.     

The monomeric GIY-YIG homing endonuclease I-BmoI uses a molecular anchor and a flexible tether to sequentially nick DNA

The GIY-YIG nuclease domain is found within protein scaffolds that participate in diverse cellular pathways and contains a single active site that hydrolyzes DNA by a one-metal ion mechanism. GIY-YIG homing endonucleases (GIY-HEs) are two-domain proteins with N-terminal GIY-YIG nuclease domains connected to C-terminal DNA-binding and they are thought to function as monomers. Using I-BmoI as a model GIY-HE, we test mechanisms by which the single active site is used to generate a double-strand break. We show that I-BmoI is partially disordered in the absence of substrate, and that the GIY-YIG domain alone has weak affinity for DNA. Significantly, we show that I-BmoI functions as a monomer at all steps of the reaction pathway and does not transiently dimerize or use sequential transesterification reactions to cleave substrate. Our results are consistent with the I-BmoI DNA-binding domain acting as a molecular anchor to tether the GIY-YIG domain to substrate, permitting rotation of the GIY-YIG domain to sequentially nick each DNA strand. These data highlight the mechanistic differences between monomeric GIY-HEs and dimeric or tetrameric GIY-YIG restriction enzymes, and they have implications for the use of the GIY-YIG domain in genome-editing applications.     

Mechanism of DNA cleavage and substrate recognition by a bovine apurinic endonuclease

The location of the phosphodiester bond cleaved by homogeneous Mg2+-dependent apurinic endodeoxyribonuclease (EC 3.1.25.2; APE) of bovine calf thymus has been determined by using a 21-mer oligonucleotide containing a single central apurinic site as a substrate. A single product of cleavage consistent with cleavage of the oligonucleotide 5' to the apurinic site, and leaving a 3' hydroxyl group, was identified. This enzyme is, therefore, a class II apurinic endonuclease. The substrate specificities of this enzyme have been determined by using a variety of natural and synthetic DNAs or oligonucleotides containing base-free sites. Calf thymus APE has an absolute requirement for a double-stranded DNA and requires an abasic site as a substrate. The presence of a base fragment such as a urea residue, an alkoxyamine group attached to the C'-1 position of the abasic site, or reduction of the C'-1 aldehyde abolishes the APE activity of this enzyme. Synthetic abasic sites containing either ethylene glycol, propanediol, or tetrahydrofuran interphosphate linkages are excellent substrates for bovine APE. These results indicate that APE has no absolute requirement for either ring-opened or ring-closed deoxyribose moieties in its recognition of DNA-cleavage substrates. The enzyme may interact with the pocket in duplex DNA that results from the base loss or with the altered conformations of the phosphodiester backbone that result from the abasic site.     

Comprehensive computational design of mCreI homing endonuclease cleavage specificity for genome engineering

Homing endonucleases (HEs) cleave long (～ 20 bp) DNA target sites with high site specificity to catalyze the lateral transfer of parasitic DNA elements. In order to determine whether comprehensive computational design could be used as a general strategy to engineer new HE target site specificities, we used RosettaDesign (RD) to generate 3200 different variants of the mCreI LAGLIDADG HE towards 16 different base pair positions in the 22 bp mCreI target site. Experimental verification of a range of these designs demonstrated that over 2/3 (24 of 35 designs, 69%) had the intended new site specificity, and that 14 of the 15 attempted specificity shifts (93%) were achieved. These results demonstrate the feasibility of using structure-based computational design to engineer HE variants with novel target site specificities to facilitate genome engineering.     

A "moving metal mechanism" for substrate cleavage by the DNA repair endonuclease APE-1

Apurinic/apyrimidinic endonuclease (APE-1) is essential for base excision repair (BER) of damaged DNA. Here molecular dynamics (MD) simulations of APE1 complexed with cleaved and uncleaved damaged DNA were used to determine the role and position of the metal ion(s) in the active site before and after DNA cleavage. The simulations started from an energy minimized wild-type structure of the metal-free APE1/damaged-DNA complex (1DE8). A grid search with one Mg2+ ion located two low energy clusters of Mg2+ consistent with the experimentally determined metal ion positions. At the start of the longer MD simulations, Mg2+ ions were placed at different positions as seen in the crystal structures and the movement of the ion was followed over the course of the trajectory. Our analysis suggests a "moving metal mechanism" in which one Mg2+ ion moves from the B- (more buried) to the A-site during substrate cleavage. The anticipated inversion of the phosphate oxygens occurs during the in-line cleavage reaction. Experimental results, which show competition between Ca2+ and Mg2+ for catalyzing the reaction, and high concentrations of Mg2+ are inhibitory, indicate that both sites cannot be simultaneously occupied for maximal activity.     

Mapping of a DNA binding region of the PI-sceI homing endonuclease by affinity cleavage and alanine-scanning mutagenesis.

The PI-SceI protein is a member of the LAGLIDADG family of homing endonucleases that is generated by a protein splicing reaction. PI-SceI has a bipartite domain structure, and the protein splicing and endonucleolytic reactions are catalyzed by residues in domains I and II, respectively. Structural and mutational evidence indicates that both domains mediate DNA binding. Treatment of the protein with trypsin breaks a peptide bond within a disordered region of the endonuclease domain situated between residues Val-270 and Leu-280 and interferes with the ability of this domain to bind DNA. To identify specific residues in this region that are involved in DNA binding and/or catalysis, alanine-scanning mutagenesis was used to create a set of PI-SceI mutant proteins that were assayed for activity. One of these mutants, N281A, was >300-fold less active than wild-type PI-SceI, and two other proteins, R277A and N284A, were completely inactive. These decreases in cleavage activity parallel similar decreases in substrate binding by the endonuclease domains of these mutant proteins. We mapped the approximate position of the disordered region to one of the ends of the 31 base pair PI-SceI recognition sequence using mutant proteins that were substituted with cysteine at residues Asn-274 and Glu-283 and tethered to the chemical nuclease FeBABE. These mutational and affinity cleavage data strongly support a model of PI-SceI docked to its DNA substrate that suggests that one or more residues identified here are responsible for contacting base pair A/T(-)(9), which is essential for substrate binding.     

Role of the interdomain linker in distance determination for remote cleavage by homing endonuclease I-TevI

I-TevI is a modular intron-encoded endonuclease, consisting of an N-terminal catalytic domain and a C-terminal DNA-binding domain, joined by a 75 amino acid linker. This linker can be divided into three regions, starting at the N terminus: the deletion-intolerant (DI) region; the deletion-tolerant (DT) region; and a zinc finger, which acts as a distance determinant for cleavage. To further explore linker function, we generated deletion and substitution mutants that were tested for their preference to cleave at a particular distance or at the correct sequence. Our results demonstrate that the I-TevI linker is multi-functional, a property that sets it apart from junction sequences in most other proteins. First, the linker DI region has a role in I-TevI cleavage activity. Second, the DT linker region participates in distance determination, as evident from DT mutants that display a phenotype similar to that of the zinc-finger mutants in their selection of a cleavage site. Finally, NMR analysis of a freestanding 56 residue linker segment showed an unstructured stretch corresponding to the DI region and a portion of the DT region, followed by a β-strand corresponding to the remainder of the DT region and containing a key distance-determining arginine, R129. Mutation of this arginine to alanine abolished distance determination and disrupted the β-strand, indicating that the structure of the DT linker region has a role in cleavage at a fixed distance.