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)

The major mammalian apurinic/apyrimidinic (AP) endonuclease (APE1) plays a central role in the DNA base excision repair pathway (BER) in two distinct ways. As an AP endonuclease, it initiates repair of AP sites in DNA produced either spontaneously or after removal of uracil and alkylated bases in DNA by monofunctional DNA glycosylases. Alternatively, by acting as a 3'-phosphoesterase, it initiates repair of DNA strand breaks with 3'-blocking damage, which are produced either directly by reactive oxygen species (ROS) or indirectly through the AP lyase reaction of damage-specific DNA glycosylases. The endonuclease activity of APE1, however, is much more efficient than its DNA 3'-phosphoesterase activity. Using whole extracts from human HeLa and lymphoblastoid TK6 cells, we have investigated whether these two activities differentially affect BER efficiency. The repair of ROS-induced DNA strand breaks was significantly stimulated by supplementing the reaction with purified APE1. This enhancement was linearly dependent on the amount of APE1 added, while addition of other BER enzymes, such as DNA ligase I and FEN1, had no effect. Moreover, depletion of endogenous APE1 from the extract significantly reduced the repair activity, suggesting that APE1 is essential for repairing such DNA damage and is limiting in extracts of human cells. In contrast, when uracil-containing DNA was used as the substrate, the efficiency of repair was not affected by exogenous APE1, presumably because the AP endonuclease activity was not limiting. These results indicate that the cellular level of APE1 may differentially affect repair efficiency for DNA strand breaks but not for uracil and AP sites in DNA.
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PMID:Requirement for human AP endonuclease 1 for repair of 3'-blocking damage at DNA single-strand breaks induced by reactive oxygen species. 1087 10

The products of proliferating cell nuclear antigen (PCNA) and flap endonuclease (FEN1) genes are multifunctional proteins that are involved in DNA replication and damage repair. Yeast models suggest association of mutant forms of PCNA and FEN1 with genomic instability. In our study, we have determined the single nucleotide polymorphisms in human PCNA and FEN1 genes. We sequenced the coding region and adjacent noncoding region of both the PCNA and FEN1 genes in 120 alleles (60 individuals). In the PCNA gene, we detected 9 sequence variants with Hardy-Weinberg allele frequency ranging from 0.008 to 0.088. No polymorphism was detected in the FEN1 gene. The sequence variants in the PCNA gene included 7 intronic single nucleotide polymorphisms (SNP) and 2 synonymous exonic SNPs. All the intronic SNPs were located in introns 1 and 4, which contain several regulatory elements involved in the control of PCNA gene expression. Six of the 7 intronic SNPs showed complete linkage disequilibrium. We confirmed this allelic linkage disequilibrium by allele-specific PCR sequencing. We genotyped 117 additional individuals belonging to 3 population subgroups using the PCR-RFLP method. Finally, to see if the detected polymorphisms are associated with any cancer type, we genotyped cases with melanomas (37 cases), breast cancers (118 cases) and lung cancers (100 cases). We did not find statistical difference in frequency of polymorphism in any cancer type compared with healthy controls, although in breast cancer the frequency was low. Our results suggest that the coding regions of the PCNA and FEN1 genes are highly conserved when compared with other DNA repair genes. The potential of some of the detected intronic polymorphisms to effect regulation of the PCNA gene expression remains to be determined.
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PMID:Single nucleotide polymorphism analyses of the human proliferating cell nuclear antigen (pCNA) and flap endonuclease (FEN1) genes. 1109 18

Saccharomyces cerevisiae mutants lacking the structure-specific nuclease Rad27 display an enhancement in recombination that increases as sequence length decreases, suggesting that Rad27 preferentially restricts recombination between short sequences. Since wild-type alleles of both RAD27 and its human homologue FEN1 complement the elevated short-sequence recombination (SSR) phenotype of a rad27-null mutant, this function may be conserved from yeast to humans. Furthermore, mutant Rad27 and FEN-1 enzymes with partial flap endonuclease activity but without nick-specific exonuclease activity partially complement the SSR phenotype of the rad27-null mutant. This suggests that the endonuclease activity of Rad27 (FEN-1) plays a role in limiting recombination between short sequences in eukaryotic cells.
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PMID:Novel function of Rad27 (FEN-1) in restricting short-sequence recombination. 1125 84

At least 12 disorders including Huntington disease (HD) are associated with expansion of a trinucleotide repeat (TNR). Factors contributing to the risk of expansion of TNRs and the mechanism of expansion have not been elucidated. Data from Saccharomyces cerevisiae suggest that the flap endonuclease FEN1 plays a role in expansion of repetitive DNA tracts. It has been hypothesized that insufficiency of FEN1 or a mutant FEN1 might contribute to the occurrence of expansion events of long repetitive DNA tracts after polymerase slippage events during lagging strand synthesis. The expression pattern of FEN1 was determined, and ubiquitous tissue expression, including germ cells, suggested that FEN1 has the potential to be involved in HD. Fifteen HD parent/child pairs that demonstrated intergenerational increases in CAG length of greater than 10 repeats were examined for possible mutations or polymorphisms within the FEN1 gene that could underlie the saltatory repeat expansions seen in these individuals. No alterations were observed compared to 50 controls, excluding FEN1 as a trans-acting factor underlying TNR expansion. The identification of a candidate gene(s) in HD or other CAG-expansion disorders implicated in TNR instability will elucidate the mechanism of expansion for this growing family of neurological disorders.
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PMID:The "flap" endonuclease gene FEN1 is excluded as a candidate gene implicated in the CAG repeat expansion underlying Huntington disease. 1126 Feb 14

Nucleases are involved in the processing of various intermediates generated during crucial DNA metabolic processes such as replication, repair, and recombination and also during maturation of RNA precursors. An endonuclease, degrading specifically single-stranded circular DNA, was identified earlier in rat testis nuclear extract while purifying a strand-transfer activity. We are now reporting the purification of this endonuclease, which is a monomeric 42 kDa protein, from rat testis to near-homogeneity. In addition to degrading single-stranded circular DNA, it nicks supercoiled plasmid DNA to generate relaxed DNA and does not act on linear single-stranded or double-stranded DNA. It also makes specific incisions at the single-strand/duplex junction of pseudo-Y, 3'- and 5'-overhangs and 3'- and 5'-flap structures. Other structures such as mismatch, insertion loop, and Holliday junction are not substrates for the testis endonuclease. In contrast to FEN1, the testis endonuclease makes asymmetric incisions on both strands of the branched structures, and free single-stranded ends are not necessary for the structure-specific incisions. Neither 5'-3' nor 3'-5' exonuclease activity is associated with the testis endonuclease. The amino acid sequences of tryptic peptides of the 42 kDa endonuclease show near-identity to polypyrimidine-tract binding protein (PTB) that is involved in the regulation of splicing of eukaryotic mRNA. The significance of the results on the association of structure-specific endonucleae activities with PTB-related protein is discussed.
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PMID:A novel structure-specific endonuclease activity associated with polypyrimidine-tract binding (PTB) related protein from rat testis. 1226 5

The conserved, structure-specific flap endonuclease FEN1 cleaves 5' DNA flaps that arise during replication or repair. To address in vivo mechanisms of flap cleavage, we developed a screen for human FEN1 mutants that are toxic when expressed in yeast. Two targets were revealed: the flexible loop domain and the catalytic site. Toxic mutants caused G(2) arrest and cell death and were unable to repair methyl methanesulfonate lesions. All the mutant proteins retained flap binding. Unlike the catalytic site mutants, which lacked cleavage of any 5' flaps, the loop mutants exhibited partial ability to cut 5' flaps when an adjacent single nucleotide 3' flap was present. We suggest that the flexible loop is important for efficient cleavage through positioning the 5' flap and the catalytic site.
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PMID:The flexible loop of human FEN1 endonuclease is required for flap cleavage during DNA replication and repair. 1241 10

In the presence of proliferating cell nuclear antigen, yeast DNA polymerase delta (Pol delta) replicated DNA at a rate of 40-60 nt/s. When downstream double-stranded DNA was encountered, Pol delta paused, but most replication complexes proceeded to carry out strand-displacement synthesis at a rate of 1.5 nt/s. In the presence of the flap endonuclease FEN1 (Rad27), the complex carried out nick translation (1.7 nt/s). The Dna2 nuclease/helicase alone did not efficiently promote nick translation, nor did it affect nick translation with FEN1. Maturation in the presence of DNA ligase was studied with various downstream primers. Downstream DNA primers, RNA primers, and small 5'-flaps were efficiently matured by Pol delta and FEN1, and Dna2 did not stimulate maturation. However, maturation of long 5'-flaps to which replication protein A can bind required both DNA2 and FEN1. The maturation kinetics were optimal with a slight molar excess over DNA of Pol delta, FEN1, and proliferating cell nuclear antigen. A large molar excess of DNA ligase substantially enhanced the rate of maturation and shortened the nick-translation patch (nucleotides excised past the RNA/DNA junction before ligation) to 4-6 nt from 8-12 nt with equimolar ligase. These results suggest that FEN1, but not DNA ligase, is a stable component of the maturation complex.
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PMID:Okazaki fragment maturation in yeast. I. Distribution of functions between FEN1 AND DNA2. 1242 38

The sliding clamp, PCNA, of the archaeon Sulfolobus solfataricus P2 is a heterotrimer of three distinct subunits (PCNA1, 2, and 3) that assembles in a defined manner. The PCNA heterotrimer, but not individual subunits, stimulates the activities of the DNA polymerase, DNA ligase I, and the flap endonuclease (FEN1) of S. solfataricus. Distinct PCNA subunits contact DNA polymerase, DNA ligase, or FEN1, imposing a defined architecture at the lagging strand fork and suggesting the existence of a preformed scanning complex at the fork. This provides a mechanism to tightly couple DNA synthesis and Okazaki fragment maturation. Additionally, unique subunit-specific interactions between components of the clamp loader, RFC, suggest a model for clamp loading of PCNA.
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PMID:A heterotrimeric PCNA in the hyperthermophilic archaeon Sulfolobus solfataricus. 1253 40

Genome sequencing projects have focused attention on the problem of discovering the functions of protein domains that are widely distributed throughout living species but which are, as yet, largely uncharacterized. One such example is the PIN domain, found in eukaryotes, bacteria, and Archaea, and with suggested roles in signaling, RNase editing, and/or nucleotide binding. The first reported crystal structure of a PIN domain (open reading frame PAE2754, derived from the crenarchaeon, Pyrobaculum aerophilum) has been determined to 2.5 A resolution and is presented here. Mapping conserved residues from a multiple sequence alignment onto the structure identifies a putative active site. The discovery of distant structural homology with several exonucleases, including T4 phage RNase H and flap endonuclease (FEN1), further suggests a likely function for PIN domains as Mg2+-dependent exonucleases, a hypothesis that we have confirmed in vitro. The tetrameric structure of PAE2754, with the active sites inside a tunnel, suggests a mechanism for selective cleavage of single-stranded overhangs or flap structures. These results indicate likely DNA or RNA editing roles for prokaryotic PIN domains, which are strikingly numerous in thermophiles, and in organisms such as Mycobacterium tuberculosis. They also support previous hypotheses that eukaryotic PIN domains participate in RNAi and nonsense-mediated RNA degradation.
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PMID:Distant structural homology leads to the functional characterization of an archaeal PIN domain as an exonuclease. 1473 48

During each yeast cell cycle, approximately 100,000 nicks are generated during lagging-strand DNA replication. Efficient nick processing during Okazaki fragment maturation requires the coordinated action of DNA polymerase delta (Pol delta) and the FLAP endonuclease FEN1. Misregulation of this process leads to the accumulation of double-stranded breaks and cell lethality. Our studies highlight a remarkably efficient mechanism for Okazaki fragment maturation in which Pol delta by default displaces 2-3 nt of any downstream RNA or DNA it encounters. In the presence of FEN1, efficient nick translation ensues, whereby a mixture of mono- and small oligonucleotides are released. If FEN1 is absent or not optimally functional, the ability of Pol delta to back up via its 3'-5'-exonuclease activity, a process called idling, maintains the polymerase at a position that is ideal either for ligation (in case of a DNA-DNA nick) or for subsequent engagement by FEN1 (in case of a DNA-RNA nick). Consistent with the hypothesis that DNA polymerase epsilon is the leading-strand enzyme, we observed no idling by this enzyme and no cooperation with FEN1 for creating a ligatable nick.
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PMID:Idling by DNA polymerase delta maintains a ligatable nick during lagging-strand DNA replication. 1552 Feb 75

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