EC:3.1.30.2 - FACTA Search

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Query: EC:3.1.30.2 (endonuclease)
18,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Homing endonucleases (HEs) cut long DNA target sites with high specificity to initiate and target the lateral transfer of mobile introns or inteins. This high site specificity of HEs makes them attractive reagents for gene targeting to promote DNA modification or repair. We have generated several hundred catalytically active, monomerized versions of the well-characterized homodimeric I-CreI and I-MsoI LAGLIDADG family homing endonuclease (LHE) proteins. Representative monomerized I-CreI and I-MsoI proteins (collectively termed mCreIs or mMsoIs) were characterized in detail by using a combination of biochemical, biophysical and structural approaches. We also demonstrated that both mCreI and mMsoI proteins can promote cleavage-dependent recombination in human cells. The use of single chain LHEs should simplify gene modification and targeting by requiring the expression of a single small protein in cells, rather than the coordinate expression of two separate protein coding genes as is required when using engineered heterodimeric zinc finger or homing endonuclease proteins.
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PMID:Generation of single-chain LAGLIDADG homing endonucleases from native homodimeric precursor proteins. 1915 40

In the cytochrome c oxidase subunit I (cox1) gene of four raphidophycean flagellates Chattonella antiqua, C. marina, C. ovata, and C. minima we found two group II introns described here as Chattonella cox1-i1 and Chattonella cox1-i2 encoding an open reading frame (ORF) comprised of three domains: reverse transcriptase (RT), RNA maturase (Ma) and zinc finger (H-N-H) endonuclease domains. The secondary structures show both Chattonella cox1-i1 and Chattonella cox1-i2 belong to group IIA1, albeit the former possesses a group IIB-like secondary structural character in the epsilon' region of arm I. Our phylogenetic analysis inferred from RT domain sequences of the intronic ORF, comparison of the insertion sites, and the secondary structures of the introns suggests that Chattonella cox1-i1 likely shares an evolutionary origin with the group II introns inserted in cox1 genes of five phylogenetically diverged eukaryotes. In contrast, Chattonella cox1-i2 was suggested to bear a close evolutionary affinity to the group II introns found in diatom cox1 genes. The RT domain-based phylogeny shows a tree topology in which Chattonella cox1-i2 is nested in the diatom sequences suggesting that a diatom-to-Chattonella intron transfer has taken place. Finally, we found no intron in cox1 genes from deeper-branching raphidophyceans. Based on parsimonious discussion, Chattonella cox1-i1 and Chattonella cox1-i2 have invaded into the cox1 gene of an ancestral Chattonella cell after diverging from C. subsalsa.
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PMID:Mitochondrial group II introns in the raphidophycean flagellate Chattonella spp. suggest a diatom-to-Chattonella lateral group II intron transfer. 1934 62

The final cut. Two types of artificial tools (artificial restriction DNA cutter and zinc finger nuclease) that cut double-stranded DNA through hydrolysis of target phosphodiester linkages, have been recently developed. The chemical structures, preparation, properties, and typical applications of these two man-made tools are reviewed.Two types of artificial tools that cut double-stranded DNA through hydrolysis of target phosphodiester linkages have been recently developed. One is the chemistry-based artificial restriction DNA cutter (ARCUT) that is composed of a Ce(IV)-EDTA complex, which catalyses DNA hydrolysis, and a pair of pseudo-complementary peptide nucleic acid fragments for sequence recognition. Another type of DNA cutter, zinc finger nuclease (ZFN), is composed of the nuclease domain of naturally occurring FokI restriction endonuclease and a designed zinc finger DNA-binding domain. For both of these artificial tools, the scission site and specificity can be freely chosen according to our needs, so that even huge genomic DNA sequences can be selectively cut at the target site. In this article, the chemical structures, preparation, properties, and typical applications of these two man-made tools are described.
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PMID:Artificial restriction DNA cutters as new tools for gene manipulation. 1939 51

Cytotoxicity of cisplatin and mitomycin C (MMC) is ascribed largely to their ability to generate interstrand crosslinks (ICLs) in DNA, which block the progression of replication forks. The processing of ICLs requires the Fanconi anemia (FA) pathway, excision repair, and translesion DNA synthesis (TLS). It also requires homologous recombination (HR), which repairs double-strand breaks (DSBs) generated by cleavage of the blocked replication forks. Here we describe KIAA1018, an evolutionarily conserved protein that has an N-terminal ubiquitin-binding zinc finger (UBZ) and a C-terminal nuclease domain. KIAA1018 is a 5'-->3' exonuclease and a structure-specific endonuclease that preferentially incises 5' flaps. Like cells from FA patients, human cells depleted of KIAA1018 are sensitized to ICL-inducing agents and display chromosomal instability. The link of KIAA1018 to the FA pathway is further strengthened by its recruitment to DNA damage through interaction of its UBZ domain with monoubiquitylated FANCD2. We therefore propose to name KIAA1018 FANCD2-associated nuclease, FAN1.
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PMID:Deficiency of FANCD2-associated nuclease KIAA1018/FAN1 sensitizes cells to interstrand crosslinking agents. 2070 Jan 43

While the experimental tools developed for zebrafish have continued to advance the organism as a laboratory model, techniques for reverse genetics remain somewhat limited in scope. Zinc finger nucleases (ZFNs), chimeric fusions between DNA-binding zinc finger proteins and the non-specific cleavage domain of the FokI endonuclease, hold great promise for targeted mutagenesis in zebrafish, as demonstrated by two recent publications (Doyon et al., 2008, Nat Biotechnol. 26, 702-708; Meng et al., 2008, Nat Biotechnol. 26, 695-701). Because ZFNs can be designed to recognize a unique sequence in the genome, they can specifically bind and cleave a target locus, creating a double-strand break (DSB) that is repaired by one of two major DNA repair pathways. Repair by one of these pathways, non-homologous end joining, is often mutagenic, allowing one to screen for induced mutations in the target locus. By injecting into zebrafish embryos RNA encoding ZFNs that target three different loci, two groups have shown that ZFNs work efficiently to induce somatic and germline mutations (reviewed in (3)). We review here protocols for injection of ZFN-encoding mRNA into zebrafish embryos, screening of injected fish for induced mutations, and subsequent recovery of the induced mutations.
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PMID:Using zinc finger nucleases for efficient and heritable gene disruption in zebrafish. 2068 Aug 42

Genome maintenance pathways correct aberrations in DNA that would be deleterious to the organism. A crucial element of many genome maintenance processes is the ability to degrade DNA that either contains errors or obscures useful substrates for recombination and/or repair by means of nucleases. We have examined a putative nuclease that has heretofore been unreported, KIAA1018/FAN1. This protein contains a predicted ubiquitin-binding zinc finger domain (UBZ) near its N-terminus and an endonuclease-like fold near its C-terminus. Here we describe that FAN1 is a nuclear protein and forms DNA-damage-induced foci, which appear to be at stalled replication forks as denoted by RPA colocalization. Localization of FAN1 to sites of damage is dependent upon its UBZ domain. In addition, knockdown of FAN1 by RNA interference leads to increased sensitivity to interstrand crosslinking agents and accumulation of abnormal chromosomes. FAN1 may be an important new player in the maintenance of genome stability.
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PMID:Human KIAA1018/FAN1 localizes to stalled replication forks via its ubiquitin-binding domain. 2105 4

It is well understood how mobile introns home to allelic sites, but how they are stimulated to transpose to ectopic locations on an evolutionary timescale is unclear. Here we show that a group I intron can move to degenerate sites under oxidizing conditions. The phage T4 td intron endonuclease, I-TevI, is responsible for this infidelity. We demonstrate that I-TevI, which promotes mobility and is subject to autorepression and translational control, is also regulated posttranslationally by a redox mechanism. Redox regulation is exercised by a zinc finger (ZF) in a linker that connects the catalytic domain of I-TevI to the DNA binding domain. Four cysteines coordinate Zn(2+) in the ZF, which ensures that I-TevI cleaves its DNA substrate at a fixed distance, 23-25 nucleotides upstream of the intron insertion site. We show that the fidelity of I-TevI cleavage is controlled by redox-responsive Zn(2+) cycling. When the ZF is mutated, or after exposure of the wild-type I-TevI to H(2)O(2), intron homing to degenerate sites is increased, likely because of indiscriminate DNA cleavage. These results suggest a mechanism for rapid intron dispersal, joining recent descriptions of the activation of biomolecular processes by oxidative stress through cysteine chemistry.
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PMID:Redox-responsive zinc finger fidelity switch in homing endonuclease and intron promiscuity in oxidative stress. 2125 16

The FokI endonuclease is a monomeric protein with discrete DNA-recognition and catalytic domains. The latter has only one active site so, to cut both strands, the catalytic domains from two monomers associate to form a dimer. The dimer involving a monomer at the recognition site and another from free solution is less stable than that from two proteins tethered to the same DNA. FokI thus cleaves DNA with two sites better than one-site DNA. The two sites can be immediately adjacent, but they can alternatively be many hundreds of base pairs apart, in either inverted or repeated orientations. The catalytic domain of FokI is often a component of zinc finger nucleases. Typically, the zinc finger domains of two such nucleases are designed to recognize two neighbouring DNA sequences, with the objective of cutting the DNA exclusively between the target sequences. However, this strategy fails to take account of the fact that the catalytic domains of FokI can dimerize across distant sites or even at a solitary site. Additional copies of either target sequence elsewhere in the chromosome must elicit off-target cleavages.
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PMID:The reaction mechanism of FokI excludes the possibility of targeting zinc finger nucleases to unique DNA sites. 2142 44

Endonuclease-mediated induction of genomic double-strand breaks has enabled genome editing in living cells. However, deploying this technology for the induction of gene disruption in plant cells often relies on direct gene transfer of endonuclease (i.e. zinc finger nuclease or homing endonuclease) expression constructs into the targeted cell, followed by regeneration of a mutated plant. Such mutants, even when they have no detectable traces of foreign DNA, might still be classified as transgenic because of the transgenic nature of the endonuclease delivery method. Indirect delivery of endonucleases into target cells by viral vectors provides a unique non-transgenic approach to the production of mutated plants. Furthermore, viral vectors can spread into the growing and developing tissues of infected plants, which could provide a unique opportunity to bypass the regeneration step that is often required in direct gene-transfer methods.
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PMID:Permanent genome modifications in plant cells by transient viral vectors. 2153 37

ZIF268, a member of the classical zinc finger protein family, contains three Cys(2)His(2) zinc binding domains that together recognize the DNA sequence 5'-AGCGTGGGCGT-3'. These domains can be fused to an endonuclease to make a chimeric protein to target and cleave specific DNA sequences. A peptide corresponding to these domains, named ZIF268-3D, has been prepared to determine if the zinc finger domain itself can promote DNA cleavage when a redox active metal ion, Fe(II), is coordinated. The UV-vis absorption spectrum of Fe(II)-ZIF268-3D is indicative of Fe(II) coordination. Using fluorescence anisotropy, we demonstrate that Fe(II)-ZIF268-3D binds selectively to its target DNA in the same manner as Zn(II)-ZIF268-3D. In the presence of added oxidant, H(2)O(2) or O(2), DNA cleavage is not observed by Fe(II)-ZIF268-3D. Instead, the peptide itself is rapidly oxidized. Similarly, Zn(II)-ZIF268-3D and apo-ZIF268-3D are rapidly oxidized by H(2)O(2) or O(2), and we propose that ZIF268-3D is highly susceptible to oxidation.
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PMID:Classical Cys2His2 zinc finger peptides are rapidly oxidized by either H2O2 or O2 irrespective of metal coordination. 2157 51

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