The I-CeuI endonuclease recognizes a sequence of 19 base pairs and preferentially cleaves the coding strand of the Chlamydomonas moewusii chloroplast large subunit rRNA gene.

The I-CeuI endonuclease is a member of the growing family of homing endonucleases that catalyse mobility of group I introns by making a double-strand break at the homing site of these introns in cognate intronless alleles during genetic crosses. In a previous study, we have shown that a short DNA fragment of 26 bp, encompassing the homing site of the fifth intron in the Chlamydomonas eugametos chloroplast large subunit rRNA gene (Ce LSU.5), was sufficient for I-CeuI recognition and cleavage. Here, we report the recognition sequence of the I-CeuI endonuclease, as determined by random mutagenesis of nucleotide positions adjacent to the I-CeuI cleavage site. Single-base substitutions that completely abolish endonuclease activity delimit a 15-bp sequence whereas those that reduce the cleavage rate define a 19-bp sequence that extends from position -7 to position +12 with respect to the Ce LSU.5 intron insertion site. As the other homing endonucleases that have been studied so far, the I-CeuI endonuclease recognizes a non-symmetric degenerate sequence. The top strand of the recognition sequence is preferred for I-CeuI cleavage and the bottom strand most likely determines the rate of double-strand breaks.     

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.     

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.     

Creation of an artificial bifunctional intein by grafting a homing endonuclease into a mini-intein

The majority of inteins are comprised of a protein splicing domain and a homing endonuclease domain. Experimental evidence has demonstrated that the splicing domain and the endonuclease domain in a bifunctional intein are largely independent of each other with respect to both structure and activity. Here, an artificial bifunctional intein has been created through the insertion of an existing homing endonuclease into a mini-intein that is naturally lacking this functionality. The gene for I-CreI, an intron-encoded homing endonuclease, was grafted into the monofunctional Mycobacterium xenopi GyrA intein at the putative site of the missing endonuclease. The resulting fusion protein was found to be capable of protein splicing similar to that of the parent intein. In addition, the protein demonstrated site-specific endonuclease activity that is characteristic of the I-CreI homing endonuclease. The function of each domain therefore remained unaffected by the presence of the other domain. This artificial fusion of the two domains is a potential novel mobile genetic element.     

Homing endonuclease I-CreI derivatives with novel DNA target specificities

Homing endonucleases are highly specific enzymes, capable of recognizing and cleaving unique DNA sequences in complex genomes. Since such DNA cleavage events can result in targeted allele-inactivation and/or allele-replacement in vivo, the ability to engineer homing endonucleases matched to specific DNA sequences of interest would enable powerful and precise genome manipulations. We have taken a step-wise genetic approach in analyzing individual homing endonuclease I-CreI protein/DNA contacts, and describe here novel interactions at four distinct target site positions. Crystal structures of two mutant endonucleases reveal the molecular interactions responsible for their altered DNA target specificities. We also combine novel contacts to create an endonuclease with the predicted target specificity. These studies provide important insights into engineering homing endonucleases with novel target specificities, as well as into the evolution of DNA recognition by this fascinating family of proteins.     

Comprehensive homing endonuclease target site specificity profiling reveals evolutionary constraints and enables genome engineering applications

Homing endonucleases (HEs) promote the evolutionary persistence of selfish DNA elements by catalyzing element lateral transfer into new host organisms. The high site specificity of this lateral transfer reaction, termed homing, reflects both the length (14–40 bp) and the limited tolerance of target or homing sites for base pair changes. In order to better understand molecular determinants of homing, we systematically determined the binding and cleavage properties of all single base pair variant target sites of the canonical LAGLIDADG homing endonucleases I-CreI and I-MsoI. These Chlorophyta algal HEs have very similar three-dimensional folds and recognize nearly identical 22 bp target sites, but use substantially different sets of DNA-protein contacts to mediate site-specific recognition and cleavage. The site specificity differences between I-CreI and I-MsoI suggest different evolutionary strategies for HE persistence. These differences also provide practical guidance in target site finding, and in the generation of HE variants with high site specificity and cleavage activity, to enable genome engineering applications.     

Adaptation of intronic homing endonuclease for successful horizontal transmission

Group I introns are thought to be self-propagating mobile elements, and are distributed over a wide range of organisms through horizontal transmission. Intron invasion is initiated through cleavage of a target DNA by a homing endonuclease encoded in an open reading frame (ORF) found within the intron. The intron is likely of no benefit to the host cell and is not maintained over time, leading to the accumulation of mutations after intron invasion. Therefore, regular invasional transmission of the intron to a new species at least once before its degeneration is likely essential for its evolutionary long-term existence. In many cases, the target is in a protein-coding region which is well conserved among organisms, but contains ambiguity at the third nucleotide position of the codon. Consequently, the homing endonuclease might be adapted to overcome sequence polymorphisms at the target site. To address whether codon degeneracy affects horizontal transmission, we investigated the recognition properties of a homing enzyme, I-CsmI, that is encoded in the intronic ORF of a group I intron located in the mitochondrial COB gene of the unicellular green alga Chlamydomonas smithii. We successfully expressed and purified three types of N-terminally truncated I-CsmI polypeptides, and assayed the efficiency of cleavage for 81 substrates containing single nucleotide substitutions. We found a slight but significant tendency that I-CsmI cleaves substrates containing a silent or tolerated amino acid change more efficiently than nonsilent or nontolerated ones. The published recognition properties of I-SpomI, I-ScaI, and I-SceII were reconsidered from this point of view, and we detected proficient adaptation of I-SpomI, I-ScaI, and I-SceII for target site sequence degeneracy. Based on the results described above, we propose that intronic homing enzymes are adapted to cleave sequences that might appear at the target region in various species, however, such adaptation becomes less prominent in proportion to the time elapsed after intron invasion into a new host.     

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.     

Optimization of in vivo activity of a bifunctional homing endonuclease and maturase reverses evolutionary degradation

The LAGLIDADG homing endonuclease (LHE) I-AniI has adopted an extremely efficient secondary RNA splicing activity that is beneficial to its host, balanced against inefficient DNA cleavage. A selection experiment identified point mutations in the enzyme that act synergistically to improve endonuclease activity. The amino-acid substitutions increase target affinity, alter the thermal cleavage profile and significantly increase targeted recombination in transfected cells. The RNA splicing activity is not affected by these mutations. The improvement in DNA cleavage activity is largely focused on one of the enzyme's two active sites, corresponding to a rearrangement of a lysine residue hypothesized to act as a general base. Most of the constructs isolated in the screen contain one or more mutations that revert an amino-acid identity to a residue found in one or more close homologues of I-AniI. This implies that mutations that have previously reduced the endonuclease activity of I-AniI are identified and reversed, sometimes in combination with additional ‘artificial’ mutations, to optimize its in vivo activity.     

Engineered I-CreI derivatives cleaving sequences from the human XPC gene can induce highly efficient gene correction in mammalian cells

Meganucleases are sequence-specific endonucleases which recognize large (>12 bp) target sites in living cells and can stimulate homologous gene targeting by a 1000-fold factor at the cleaved locus. We have recently described a combinatorial approach to redesign the I-CreI meganuclease DNA-binding interface, in order to target chosen sequences. However, engineering was limited to the protein regions shown to directly interact with DNA in a base-specific manner. Here, we take advantage of I-CreI natural degeneracy, and of additional refinement steps to extend the number of sequences that can be efficiently cleaved. We searched the sequence of the human XPC gene, involved in the disease Xeroderma Pigmentosum (XP), for potential targets, and chose three sequences that differed from the I-CreI cleavage site over their entire length, including the central four base-pairs, whose role in the DNA/protein recognition and cleavage steps remains very elusive. Two out of these targets could be cleaved by engineered I-CreI derivatives, and we could improve the activity of weak novel meganucleases, to eventually match the activity of the parental I-CreI scaffold. The novel proteins maintain a narrow cleavage pattern for cognate targets, showing that the extensive redesign of the I-CreI protein was not made at the expense of its specificity. Finally, we used a chromosomal reporter system in CHO-K1 cells to compare the gene targeting frequencies induced by natural and engineered meganucleases. Tailored I-CreI derivatives cleaving sequences from the XPC gene were found to induce high levels of gene targeting, similar to the I-CreI scaffold or the I-SceI "gold standard". This is the first time an engineered homing endonuclease has been used to modify a chromosomal locus.     

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.     

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.     

DNA substrate specificity and cleavage kinetics of an archaeal homing-type endonuclease from Pyrobaculum organotrophum.

The protein encoded by intron 1 of the single 23S rRNA gene of the archaeal hyperthermophile Pyrobaculum organotrophum was isolated and shown to constitute a homing-type DNA endonuclease, I-PorI. It cleaves the intron- 23S rDNA of the closely related organism Pyrobaculum islandicum near the site of intron insertion in Pb.organotrophum. In contrast, no endonuclease activity was detected for the protein product of intron 2 of the same gene of Pb.organotrophum which, like I-PorI, carries the LAGLI-DADG motif, common to group I intron-encoded homing enzymes. I-PorI cleaves optimally at 80 degrees C, with kcat and Km values of about 2 min-1 and 4 nM, respectively, and generates four nucleotide 3'-overhangs and 5'-phosphates. It can cleave a 25 base pair DNA fragment encompassing the intron insertion site. A mutation-selection study established the base pair specificity of the endonuclease within a 17 bp region, from positions -6 to +11 with respect to the intron-insertion site. Four of the essential base pairs encode the sequence involved in the intron-exon interaction in the pre-rRNA that is required for recognition by the RNA splicing enzymes. Properties of the enzyme are compared and contrasted with those of eucaryotic homing endonucleases.     

The Mitochondrial LSU rRNA Group II Intron of Ustilago maydis Encodes an Active Homing Endonuclease Likely Involved in Intron Mobility

Background

The a2 mating type locus gene lga2 is critical for uniparental mitochondrial DNA inheritance during sexual development of Ustilago maydis. Specifically, the absence of lga2 results in biparental inheritance, along with efficient transfer of intronic regions in the large subunit rRNA gene between parental molecules. However, the underlying role of the predicted LAGLIDADG homing endonuclease gene I-UmaI located within the group II intron LRII1 has remained unresolved.

Methodology/Principal Findings

We have investigated the enzymatic activity of I-UmaI in vitro based on expression of a tagged full-length and a naturally occurring mutant derivative, which harbors only the N-terminal LAGLIDADG domain. This confirmed Mg²⁺-dependent endonuclease activity and cleavage at the LRII1 insertion site to generate four base pair extensions with 3′ overhangs. Specifically, I-UmaI recognizes an asymmetric DNA sequence with a minimum length of 14 base pairs (5′-GACGGGAAGACCCT-3′) and tolerates subtle base pair substitutions within the homing site. Enzymatic analysis of the mutant variant indicated a correlation between the activity in vitro and intron homing. Bioinformatic analyses revealed that putatively functional or former functional I-UmaI homologs are confined to a few members within the Ustilaginales and Agaricales, including the phylogenetically distant species Lentinula edodes, and are linked to group II introns inserted into homologous positions in the LSU rDNA.

Conclusions/Significance

The present data provide strong evidence that intron homing efficiently operates under conditions of biparental inheritance in U. maydis. Conversely, uniparental inheritance may be critical to restrict the transmission of mobile introns. Bioinformatic analyses suggest that I-UmaI-associated introns have been acquired independently in distant taxa and are more widespread than anticipated from available genomic data.     

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.     

Intron 5 alpha of the COXI gene of yeast mitochondrial DNA is a mobile group I intron.

We have found that intron 5 alpha of the COXI gene (al5 alpha) of yeast mtDNA is a mobile group I intron in crosses between strains having or lacking the intron. We have demonstrated the following hallmarks of that process: 1) co-conversion of flanking optional intron markers; 2) mutations that truncate the intron open reading frame block intron mobility; and 3) the intron open reading frame encodes an endonuclease activity that is required for intron movement. The endonuclease activity, termed I-Sce IV, cleaves the COXI allele lacking al5 alpha near the site of intron insertion, making a four-base staggered cut with 3' OH overhangs. Three cloned DNAs derived from different forms of the COXI gene, which differ in primary sequence at up to seven nucleotides around the cleavage site, are all good substrates for in vitro I-Sce IV cleavage activity. Two of the strains from which these substrates were derived were tested in crosses and are comparably efficient as al5 alpha recipients. When compared with omega mobility occurring simultaneously in one cross, al5 alpha is less efficient as a mobile element.     

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.