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)

We recently purified and cloned the gene for a DNA structure-specific endonuclease, FEN-1, from murine cells. The murine protein recognizes 5' DNA flap structures that have been proposed in DNA replication, repair, and recombination. Here, we report the sequence of the human FEN1 gene. The translated sequence is identical to peptide sequence obtained from maturation factor-1, which is 1 of the 10 essential proteins for cell-free DNA replication. The human protein has the same structure-specific DNA endonuclease activity as the murine protein. Two human chromosomal hybridization signals, 11q12 and 1p22.2, were observed by FISH analysis using human genomic clones homologous to the mouse Fen-1 gene. The localization on human 11q12 was confirmed using radiation-reduced hybrids. The mouse Fen-1 gene is assigned to chromosome 19 based on somatic cell hybrids. The significance of these FEN1 gene localizations in human and mouse is discussed.
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PMID:Sequence of human FEN-1, a structure-specific endonuclease, and chromosomal localization of the gene (FEN1) in mouse and human. 777 22

One, two or four copies of the 'helix-hairpin-helix' (HhH) DNA-binding motif are predicted to occur in 14 homologous families of proteins. The predicted DNA-binding function of this motif is shown to be consistent with the crystallographic structure of rat polymerase beta, complexed with DNA template-primer [Pelletier, H., Sawaya, M.R., Kumar, A., Wilson, S.H. and Kraut, J. (1994) Science 264, 1891-1903] and with biochemical data. Five crystal structures of predicted HhH motifs are currently known: two from rat pol beta and one each in endonuclease III, AlkA and the 5' nuclease domain of Taq pol I. These motifs are more structurally similar to each other than to any other structure in current databases, including helix-turn-helix motifs. The clustering of the five HhH structures separately from other bi-helical structures in searches indicates that all members of the 14 families of proteins described herein possess similar HhH structures. By analogy with the rat pol beta structure, it is suggested that each of these HhH motifs bind DNA in a non-sequence-specific manner, via the formation of hydrogen bonds between protein backbone nitrogens and DNA phosphate groups. This type of interaction contrasts with the sequence-specific interactions of other motifs, including helix-turn-helix structures. Additional evidence is provided that alphaherpesvirus virion host shutoff proteins are members of the polymerase I 5'-nuclease and FEN1-like endonuclease gene family, and that a novel HhH-containing DNA-binding domain occurs in the kinesin-like molecule nod, and in other proteins such as cnjB, emb-5 and SPT6.
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PMID:The helix-hairpin-helix DNA-binding motif: a structural basis for non-sequence-specific recognition of DNA. 869 86

Deoxyinosine 3'-endonuclease, an Escherichia coli repair enzyme that recognizes and cleaves DNA containing deoxyinosine and base mismatches, can cleave heteroduplexes containing a hairpin or unpaired loop. These DNA structures, referred to as insertion/deletion mismatches (IDM), are abnormal intermediate structures generated during replication of repetitive DNA sequences. In addition, the enzyme also cleaved the 5'-single-stranded tails of flap and pseudo-Y DNA structures, suggesting that deoxyinosine 3'-endonuclease is a bacterial functional homologue of human FEN1 and yeast RTH1 nucleases. These biochemical properties suggest that deoxyinosine 3'-endonuclease might be important in the repair of IDM structures generated in lagging strand during DNA replication.
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PMID:Cleavage of insertion/deletion mismatches, flap and pseudo-Y DNA structures by deoxyinosine 3'-endonuclease from Escherichia coli. 894 43

Two forms of DNA base excision-repair (BER) have been observed: a 'short-patch' BER pathway involving replacement of one nucleotide and a 'long-patch' BER pathway with gap-filling of several nucleotides. The latter mode of repair has been investigated using human cell-free extracts or purified proteins. Correction of a regular abasic site in DNA mainly involves incorporation of a single nucleotide, whereas repair patches of two to six nucleotides in length were found after repair of a reduced or oxidized abasic site. Human AP endonuclease, DNA polymerase beta and a DNA ligase (either III or I) were sufficient for the repair of a regular AP site. In contrast, the structure-specific nuclease DNase IV (FEN1) was essential for repair of a reduced AP site, which occurred through the long-patch BER pathway. DNase IV was required for cleavage of a reaction intermediate generated by template strand displacement during gap-filling. XPG, a related nuclease, could not substitute for DNase IV. The long-patch BER pathway was largely dependent on DNA polymerase beta in cell extracts, but the reaction could be reconstituted with either DNA polymerase beta or delta. Efficient repair of gamma-ray-induced oxidized AP sites in plasmid DNA also required DNase IV. PCNA could promote the Pol beta-dependent long-patch pathway by stimulation of DNase IV.
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PMID:Second pathway for completion of human DNA base excision-repair: reconstitution with purified proteins and requirement for DNase IV (FEN1). 921 49

The initiator RNAs of mammalian Okazaki fragments are thought to be removed by RNase HI and the 5'-3' flap endonuclease (FEN1). Earlier evidence indicated that the cleavage site of RNase HI is 5' of the last ribonucleotide at the RNA-DNA junction on an Okazaki substrate. In current work, highly purified calf RNase HI makes this exact cleavage in Okazaki fragments containing mismatches that distort the hybrid structure of the heteroduplex. Furthermore, even fully unannealed Okazaki fragments were cleaved. Clearly, the enzyme recognizes the transition from RNA to DNA on a single-stranded substrate and not the RNA/DNA heteroduplex structure. We have named this junction RNase activity. This activity exactly comigrates with RNase HI activity during purification strongly suggesting that both activities reside in the same enzyme. After junction cleavage, FEN1 removes the remaining ribonucleotide. Because FEN1 prefers a substrate with a single-stranded 5'-flap structure, the single-stranded activity of junction RNase suggests that Okazaki fragments are displaced to form a 5'-tail prior to cleavage by both nucleases.
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PMID:Junction ribonuclease: an activity in Okazaki fragment processing. 948 70

Base excision repair (BER) pathway is the major cellular process for removal of endogenous base lesions and apurinic/apyrimidinic (AP) sites in DNA. There are two base excision repair subpathways in mammalian cells, characterized by the number of nucleotides synthesized into the excision patch. They are the "single-nucleotide" (one nucleotide incorporated) and the "long-patch" (several nucleotides incorporated) BER pathways. Proliferating cell nuclear antigen (PCNA) is known to be an essential factor in long-patch base excision repair. We have studied the role of replication protein A (RPA) in PCNA-dependent, long-patch BER of AP sites in human cell extracts. PCNA and RPA were separated from the other BER proteins by fractionation of human whole-cell extract on a phosphocellulose column. The protein fraction PC-FII (phosphocellulose fraction II), which does not contain RPA and PCNA but otherwise contains all core BER proteins required for PCNA-dependent BER (AP endonuclease, DNA polymerases delta, beta and DNA ligase, and FEN1 endonuclease), had reduced ability to repair plasmid DNA containing AP sites. Purified PCNA or RPA, when added separately, could only partially restore the PC-FII repair activity of AP sites. However, additions of both proteins together greatly stimulated AP site repair by PC-FII. These results demonstrate a role for RPA in PCNA-dependent BER of AP sites.
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PMID:Replication protein A stimulates proliferating cell nuclear antigen-dependent repair of abasic sites in DNA by human cell extracts. 1046 Jan 57

The flap endonuclease, FEN1, plays a critical role in DNA replication and repair. Human FEN1 exhibits both a 5' to 3' exonucleolytic and a structure-specific endonucleolytic activity. On primer-template substrates containing an unannealed 5'-tail, or flap structure, FEN1 employs a unique mechanism to cleave at the point of annealing, releasing the 5'-tail intact. FEN1 appears to track along the full length of the flap from the 5'-end to the point of cleavage. Substrates containing structural modifications to the flap have been used to explore the mechanism of tracking. To determine whether the nuclease must recognize a succession of nucleotides on the flap, chemical linkers were used to replace an interior nucleotide. The nuclease could readily traverse this site. The footprint of the nuclease at the time of cleavage does not extend beyond 25 nucleotides on the flap. Eleven-nucleotide branches attached to the flap beyond the footprinted region do not prevent cleavage. Single- or double-thymine dimers also allow cleavage. cis-Platinum adducts outside the protected region are moderately inhibitory. Platinum-modified branch structures are completely inert to cleavage. These results show that some flap modifications can prevent or inhibit tracking, but the tracking mechanism tolerates a variety of flap modifications. FEN1 has a flexible loop structure through which the flap has been proposed to thread. However, efficient cleavage of branched structures is inconsistent with threading the flap through a hole in the protein.
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PMID:Effect of flap modifications on human FEN1 cleavage. 1052 10

The flap endonuclease, FEN1, is an evolutionarily conserved component of DNA replication from archaebacteria to humans. Based on in vitro results, it processes Okazaki fragments during replication and is involved in base excision repair. FEN1 removes the last primer ribonucleotide on the lagging strand and it cleaves a 5' flap that may result from strand displacement during replication or during base excision repair. Its biological importance has been revealed largely through studies in the yeast Saccharomyces cerevisiae where deletion of the homologous gene RAD27 results in genome instability and mutagen sensitivity. While the in vivo function of Rad27 has been well characterized through genetic and biochemical approaches, little is understood about the in vivo functions of human FEN1. Guided by our recent results with yeast RAD27, we explored the function of human FEN1 in yeast. We found that the human FEN1 protein complements a yeast rad27 null mutant for a variety of defects including mutagen sensitivity, genetic instability and the synthetic lethal interactions of a rad27 rad51 and a rad27 pol3-01 mutant. Furthermore, a mutant form of FEN1 lacking nuclease function exhibits dominant-negative effects on cell growth and genome instability similar to those seen with the homologous yeast rad27 mutation. This genetic impact is stronger when the human and yeast PCNA-binding domains are exchanged. These data indicate that the human FEN1 and yeast Rad27 proteins act on the same substrate in vivo. Our study defines a sensitive yeast system for the identification and characterization of mutations in FEN1.
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PMID:Functional analysis of human FEN1 in Saccharomyces cerevisiae and its role in genome stability. 1054 7

The RAD2 family of nucleases includes human XPG (Class I), FEN1 (Class II), and HEX1/hEXO1 (Class III) products gene. These proteins exhibit a blend of substrate specific exo- and endonuclease activities and contribute to repair, recombination, and/or replication. To date, the substrate preferences of the EXO1-like Class III proteins have not been thoroughly defined. We report here that the RAD2 domain of human exonuclease 1 (HEX1-N2) exhibits both a robust 5' to 3' exonuclease activity on single- and double-stranded DNA substrates as well as a flap structure-specific endonuclease activity but does not show specific endonuclease activity at 10-base pair bubble-like structures, G:T mismatches, or uracil residues. Both the 5' to 3' exonuclease and flap endonuclease activities require a divalent metal cofactor, with Mg(2+) being the preferred metal ion. HEX1-N2 is approximately 3-fold less active in Mn(2+)-containing buffers and exhibits <5% activity in the presence of Co(2+), Zn(2+), or Ca(2+). The optimal pH range for the nuclease activities of HEX1-N2 is 7.2-8.2. The specific activity of its 5' to 3' exonuclease function is 2.5-7-fold higher on blunt end and 5'-recessed double-stranded DNA substrates compared with duplex 5'-overhang or single-stranded DNAs. The flap endonuclease activity of HEX1-N2 is similar to that of human flap endonuclease-1, both in terms of turnover efficiency (k(cat)) and site of incision, and is as efficient (k(cat)/K(m)) as its exonuclease function. The nuclease activities of HEX1-N2 described here indicate functions for the EXO1-like proteins in replication, repair, and/or recombination that may overlap with human flap endonuclease-1.
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PMID:The RAD2 domain of human exonuclease 1 exhibits 5' to 3' exonuclease and flap structure-specific endonuclease activities. 1060 37

Recent genetic evidence indicates that null mutants of the 5'-flap endonuclease (FEN1) result in an expansion of repetitive sequences. The substrate for FEN1 is a flap formed by natural 5'-end displacement of the short intermediates of lagging strand replication. FEN1 binds the 5'-end of the flap, tracks to the point of annealing at the base of the flap, and then cleaves. Here we examine mechanisms by which foldback structures within the flap could contribute to repeat expansions. Cleavage by FEN1 was reduced with increased length of the foldback. However, even the longest foldbacks were cleaved at a low rate. Substrates containing the repetitive sequence CTG also were cleaved at a reduced rate. Bubble substrates, likely intermediates in repeat expansions, were inhibitory. Neither replication protein A nor proliferating cell nuclear antigen were able to assist in the removal of secondary structure within a flap. We propose that FEN1 cleaves natural foldbacks at a reduced rate. However, although the cleavage delay is not likely to influence the overall process of chromosomal replication, specific foldbacks could inhibit cleavage sufficiently to result in duplication of the foldback sequence.
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PMID:Inhibition of flap endonuclease 1 by flap secondary structure and relevance to repeat sequence expansion. 1074 45

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