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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)
To avoid genome instability, DNA repair nucleases must precisely target the correct damaged substrate before they are licensed to incise. Damage identification is a challenge for all DNA damage response proteins, but especially for nucleases that cut the DNA and necessarily create a cleaved DNA repair intermediate, likely more toxic than the initial damage. How do these enzymes achieve exquisite specificity without specific sequence recognition or, in some cases, without a non-canonical DNA nucleotide? Combined structural, biochemical, and biological analyses of repair nucleases are revealing their molecular tools for damage verification and safeguarding against inadvertent incision. Surprisingly, these enzymes also often act on RNA, which deserves more attention. Here, we review protein-DNA structures for nucleases involved in replication, base excision repair, mismatch repair, double strand break repair (DSBR), and telomere maintenance: apurinic/apyrimidinic endonuclease 1 (APE1), Endonuclease IV (Nfo), tyrosyl DNA phosphodiesterase (TDP2), UV Damage
endonuclease
(UVDE), very short patch repair
endonuclease
(Vsr), Endonuclease V (Nfi),
Flap endonuclease 1
(
FEN1
), exonuclease 1 (Exo1), RNase T and Meiotic recombination 11 (Mre11). DNA and RNA structure-sensing nucleases are essential to life with roles in DNA replication, repair, and transcription. Increasingly these enzymes are employed as advanced tools for synthetic biology and as targets for cancer prognosis and interventions. Currently their structural biology is most fully illuminated for DNA repair, which is also essential to life. How DNA repair enzymes maintain genome fidelity is one of the DNA double helix secrets missed by James Watson and Francis Crick, that is only now being illuminated though structural biology and mutational analyses. Structures reveal motifs for repair nucleases and mechanisms whereby these enzymes follow the old carpenter adage: measure twice, cut once. Furthermore, to measure twice these nucleases act as molecular level transformers that typically reshape the DNA and sometimes themselves to achieve extraordinary specificity and efficiency.
...
PMID:The cutting edges in DNA repair, licensing, and fidelity: DNA and RNA repair nucleases sculpt DNA to measure twice, cut once. 2475 99
Gene 6 protein of bacteriophage T7 has 5'-3'-exonuclease activity specific for duplex DNA. We have found that gene 6 protein also has flap
endonuclease
activity. The flap
endonuclease
activity is considerably weaker than the exonuclease activity. Unlike the human homolog of gene 6 protein, the flap
endonuclease
activity of gene 6 protein is dependent on the length of the 5'-flap. This dependency of activity on the length of the 5'-flap may result from the structured helical gateway region of gene 6 protein which differs from that of human
flap endonuclease 1
. The flap
endonuclease
activity provides a mechanism by which RNA-terminated Okazaki fragments, displaced by the lagging strand DNA polymerase, are processed. 3'-extensions generated during degradation of duplex DNA by the exonuclease activity of gene 6 protein are inhibitory to further degradation of the 5'-terminus by the exonuclease activity of gene 6 protein. The single-stranded DNA binding protein of T7 overcomes this inhibition.
...
PMID:Flap endonuclease of bacteriophage T7: Possible roles in RNA primer removal, recombination and host DNA breakdown. 2510 57
Topoisomerase 1 (Top1) is the intercellular target of camptothecins (CPTs). CPT blocks DNA religation in the Top1-DNA complex and induces Top1-attached nick DNA lesions. In this study, we demonstrate that excision repair cross complementing 1 protein-xeroderma pigmentosum group F (ERCC1-XPF)
endonuclease
and replication protein A (RPA) participate in the repair of Top1-attached nick DNA lesions together with other nucleotide excision repair (NER) factors. ERCC1-XPF shows nuclease activity in the presence of RPA on a 3'-phosphotyrosyl bond nick-containing DNA (Tyr-nick DNA) substrate, which mimics a Top1-attached nick DNA lesion. In addition, ERCC1-XPF and RPA form a DNA/protein complex on the nick DNA substrate in vitro, and co-localize in CPT-treated cells in vivo. Moreover, the DNA repair synthesis of Tyr-nick DNA lesions occurred in the presence of NER factors, including ERCC1-XPF, RPA, DNA polymerase delta,
flap endonuclease 1
and DNA ligase 1. Therefore, some of the NER repair machinery might be an alternative repair pathway for Top1-attached nick DNA lesions. Clinically, these data provide insights into the potential of ERCC1 as a biomarker during CPT regimens.
...
PMID:Repair synthesis step involving ERCC1-XPF participates in DNA repair of the Top1-DNA damage complex. 2602 8
Replication forks are vulnerable to wayward nuclease activities. We report here our discovery of a new member in guarding genome stability at replication forks. We previously isolated a Drosophila mutation, wuho (wh, no progeny), characterized by a severe fertility defect and affecting expression of a protein (WH) in a family of conserved proteins with multiple WD40 repeats. Knockdown of WH by siRNA in Drosophila, mouse, and human cultured cells results in DNA damage with strand breaks and apoptosis through ATM/Chk2/p53 signaling pathway. Mice with mWh knockout are early embryonic lethal and display DNA damage. We identify that the
flap endonuclease 1
(
FEN1
) is one of the interacting proteins. Fluorescence microscopy showed the localization of WH at the site of nascent DNA synthesis along with other replication proteins, including
FEN1
and PCNA. We show that WH is able to modulate
FEN1
's endonucleolytic activities depending on the substrate DNA structure. The stimulatory or inhibitory effects of WH on
FEN1
's flap versus gap
endonuclease
activities are consistent with the proposed WH's functions in protecting the integrity of replication fork. These results suggest that wh is a new member of the guardians of genome stability because it regulates
FEN1
's potential DNA cleavage threat near the site of replication.
...
PMID:Wuho Is a New Member in Maintaining Genome Stability through its Interaction with Flap Endonuclease 1. 2675 Oct 69
Engineered endonucleases are a powerful tool for editing DNA. However, sequence preferences may limit their application. We engineer a structure-guided
endonuclease
(SGN) composed of
flap endonuclease-1
(
FEN-1
), which recognizes the 3' flap structure, and the cleavage domain of Fok I (Fn1), which cleaves DNA strands. The SGN recognizes the target DNA on the basis of the 3' flap structure formed between the target and the guide DNA (gDNA) and cut the target through its Fn1 dimerization. Our results show that the SGN, guided by a pair of gDNAs, cleaves transgenic reporter gene and endogenous genes in zebrafish embryonic genome.
...
PMID:An alternative novel tool for DNA editing without target sequence limitation: the structure-guided nuclease. 2764 Aug 75
The search for novel ways to target and alter the genomes of living organisms accelerated rapidly this decade with the discovery of CRISPR/Cas9. Since the initial discovery, efforts to find alternative methods for altering the genome have expanded. A new study presenting an alternative approach has been demonstrated that utilizes
flap endonuclease 1
(
FEN-1
) fused to the Fok1
endonuclease
, which shows potential for DNA-guided genome targeting in vivo.
...
PMID:DNA-guided genome editing using structure-guided endonucleases. 2763 79
Protein-protein interaction (PPI) plays a key role in cellular communication, Protein-protein interaction connected with each other with hubs and nods involved in signaling pathways. These interactions used to develop network based biomarkers for early diagnosis of cancer. FEN1(
Flap endonuclease 1
) is a central component in cellular metabolism, over expression and decrease of FEN1 levels may cause cancer, these regulation changes of Flap
endonuclease
1reported in many cancer cells, to consider this data may needs to develop a network based biomarker. The current review focused on types of PPI, based on nature, detection methods and its role in cancer. Interacting partners of
Flap endonuclease 1
role in DNA replication repair and development of anticancer therapeutics based on Protein-protein interaction data.
...
PMID:Interacting partners of FEN1 and its role in the development of anticancer therapeutics. 2818 40
Structure-specific endonucleases (SSEs) have key roles in DNA replication, recombination and repair, and emerging roles in transcription. These enzymes have specificity for DNA secondary structure rather than for sequence, and therefore their activity must be precisely controlled to ensure genome stability. In this Review, we discuss how SSEs are controlled as part of genome maintenance pathways in eukaryotes, with an emphasis on the elaborate mechanisms that regulate the members of the major SSE families - including the xeroderma pigmentosum group F-complementing protein (XPF) and MMS and UV-sensitive protein 81 (MUS81)-dependent nucleases, and the
flap endonuclease 1
(
FEN1
), XPG and XPG-like
endonuclease
1 (GEN1) enzymes - during processes such as DNA adduct repair, Holliday junction processing and replication stress. We also discuss newly characterized connections between SSEs and other classes of DNA-remodelling enzymes and cell cycle control machineries, which reveal the importance of SSE scaffolds such as the synthetic lethal of unknown function 4 (SLX4) tumour suppressor for the maintenance of genome stability.
...
PMID:Control of structure-specific endonucleases to maintain genome stability. 2832 56
Flap endonuclease 1
(
FEN1
) is a structure selective
endonuclease
required for proficient DNA replication and the repair of DNA damage. Cellularly active inhibitors of this enzyme have previously been shown to induce a DNA damage response and, ultimately, cell death. High-throughput screens of human cancer cell-lines identify colorectal and gastric cell-lines with microsatellite instability (MSI) as enriched for cellular sensitivity to N-hydroxyurea series inhibitors of
FEN1
, but not the PARP inhibitor olaparib or other inhibitors of the DNA damage response. This sensitivity is due to a synthetic lethal interaction between
FEN1
and MRE11A, which is often mutated in MSI cancers through instabilities at a poly(T) microsatellite repeat. Disruption of ATM is similarly synthetic lethal with
FEN1
inhibition, suggesting that disruption of
FEN1
function leads to the accumulation of DNA double-strand breaks. These are likely a result of the accumulation of aberrant replication forks, that accumulate as a consequence of a failure in Okazaki fragment maturation, as inhibition of
FEN1
is toxic in cells disrupted for the Fanconi anemia pathway and post-replication repair. Furthermore, RAD51 foci accumulate as a consequence of
FEN1
inhibition and the toxicity of
FEN1
inhibitors increases in cells disrupted for the homologous recombination pathway, suggesting a role for homologous recombination in the resolution of damage induced by
FEN1
inhibition. Finally,
FEN1
appears to be required for the repair of damage induced by olaparib and cisplatin within the Fanconi anemia pathway, and may play a role in the repair of damage associated with its own disruption.
...
PMID:Small molecule inhibitors uncover synthetic genetic interactions of human flap endonuclease 1 (FEN1) with DNA damage response genes. 2862 39
Human exonuclease 1 (hEXO1) is a member of the 5'-nuclease superfamily and plays important roles in DNA repair. Along with acting as a 5'-exonuclease on blunt, gapped, nicked, and 3'-overhang DNAs, hEXO1 can also act as an
endonuclease
removing protruding 5'-single-stranded flaps from duplex ends. How hEXO1 and related 5'-nuclease human
flap endonuclease 1
(hFEN1) are specific for discontinuous DNA substrates like 5'-flaps has been controversial. Here we report the first functional data that imply that hEXO1 threads the 5'-flap through a hole in the protein known as the helical arch, thereby excluding reactions of continuous single strands. Conjugation of bulky 5'-streptavidin that would "block" threading through the arch drastically slowed the hEXO1 reaction. In contrast, addition of streptavidin to a preformed hEXO1 5'-biotin flap DNA complex trapped a portion of the substrate in a highly reactive threaded conformation. However, another fraction behaves as if it were "blocked" and decayed very slowly, implying there were both threaded and unthreaded forms of the substrate present. The reaction of an unmodified hEXO1-flap DNA complex did not exhibit marked biphasic kinetics, suggesting a fast re-equilibration occurs that produces more threaded substrate when some decays. The finding that a threading mechanism like that used by hFEN1 is also used by hEXO1 unifies the mode of operation for members of the 5'-nuclease superfamily that act on discontinuous substrates. As with hFEN1, intrinsic disorder of the arch region of the protein may explain how flaps can be threaded without a need for a coupled energy source.
...
PMID:Human Exonuclease 1 Threads 5'-Flap Substrates through Its Helical Arch. 2868 61
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