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Query: EC:3.1.4.1 (
phosphodiesterase
)
18,767
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
In eukaryotic cells, a 5'-flap DNA endonuclease and a double-stranded DNA
5'-exonuclease
activity reside within a 42-kDa enzyme called FEN-1 (
flap endonuclease-1
and 5(five)'-exonuclease). This endo/exonuclease has been shown to be highly homologous to human XP-G, Saccharomyces cerevisiae RAD2, and S. cerevisiae YKL510. Like FEN-1, these related structure-specific nucleases recognize and cleave a branched DNA structure called a DNA flap and its derivative, called a pseudo Y-structure. To dissect the important structural components of the DNA flap structure, we have developed a mobility shift assay. We find that the Fadj strand (located adjacent to the displaced flap strand) is necessary for efficient binding and cleavage of flap structures by FEN-1. When this strand is absent or when it is present, but recessed from the elbow of the flap strand, binding efficiency drops. Further investigation of the role of the Fadj strand using double flap structures reveals that the Fadj strand is necessary to provide a double-stranded template upon which FEN-1 can bind near the elbow of the flap strand. These results provide a basis for understanding how this structure-specific nuclease recognizes a variety of DNA substrates.
...
PMID:DNA structural elements required for FEN-1 binding. 787 18
Oxidative DNA damage has been attributed to increased cancer incidence and premature aging phenotypes. Reactive oxygen species (ROS) are unavoidable byproducts of oxidative phosphorylation and are the major contributors of endogenous oxidative damage. To prevent the negative effects of ROS, cells have developed DNA repair mechanisms designed to specifically combat endogenous DNA modifications. The base excision repair (BER) pathway is primarily responsible for the repair of small non-helix distorting lesions and DNA single strand breaks. This repair pathway is found in all organisms, and in mammalian cells, consists of three related sub-pathways: short patch (SP-BER), long patch (LP-BER) and single strand break repair (SSBR). While much is known about nuclear BER, comparatively little is known about this pathway in the mitochondria, particularly the LP-BER and SSBR sub-pathways. There are a number of proteins that have recently been found to be involved in mitochondrial BER, including Cockayne syndrome proteins A and B (CSA and CSB), aprataxin (APTX), tryosyl-DNA
phosphodiesterase
1 (TDP1),
flap endonuclease 1
(
FEN-1
) and exonuclease G (EXOG). These significant advances in mitochondrial DNA repair may open new avenues in the management and treatment of a number of neurological disorders associated with mitochondrial dysfunction, and will be reviewed in further detail herein.
...
PMID:Repair of persistent strand breaks in the mitochondrial genome. 2213 76
The structure- and strand-specific
phosphodiesterase
flap endonuclease-1
(
FEN1
), the prototypical 5'-nuclease, catalyzes the essential removal of 5'-single-stranded flaps during replication and repair.
FEN1
achieves this by selectively catalyzing hydrolysis one nucleotide into the duplex region of substrates, always targeting the 5'-strand. This specificity is proposed to arise by unpairing the 5'-end of duplex to permit the scissile phosphate diester to contact catalytic divalent metal ions. Providing the first direct evidence for this, we detected changes induced by human
FEN1
(hFEN1) in the low-energy CD spectra and fluorescence lifetimes of 2-aminopurine in substrates and products that were indicative of unpairing. Divalent metal ions were essential for unpairing. However, although 5'-nuclease superfamily-conserved active-site residues K93 and R100 were required to produce unpaired product, they were not necessary to unpair substrates. Nevertheless, a unique arrangement of protein residues around the unpaired DNA was detected only with wild-type protein, suggesting a cooperative assembly of active-site residues that may be triggered by unpaired DNA. The general principles of
FEN1
strand and reaction-site selection, which depend on the ability of juxtaposed divalent metal ions to unpair the end of duplex DNA, may also apply more widely to other structure- and strand-specific nucleases.
...
PMID:Observation of unpaired substrate DNA in the flap endonuclease-1 active site. 2397 98
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
Etoposide is a widely used anticancer drug and a DNA topoisomerase II (Top2) inhibitor. Etoposide produces Top2-attached single-strand breaks (Top2-SSB complex) and double-strand breaks (Top2-DSB complex) that are thought to induce cell death in tumor cells. The Top2-SSB complex is more abundant than the Top2-DSB complex. Human tyrosyl-DNA
phosphodiesterase
2 (TDP2) is required for efficient repair of Top2-DSB complexes. However, the identities of the proteins involved in the repair of Top2-SSB complexes are unknown, although yeast genetic data indicate that 5' to 3' structure-specific DNA endonuclease activity is required for alternative repair of Top2 DNA damage. In this study, we purified a
flap endonuclease 1
(
FEN1
) and xeroderma pigmentosum group G protein (XPG) in the 5' to 3' structure-specific DNA endonuclease family and synthesized single-strand break DNA substrates containing a 5'-phoshotyrosyl bond, mimicking the Top2-SSB complex. We found that
FEN1
and XPG did not remove the 5'-phoshotyrosyl bond-containing DSB substrates but removed the 5'-phoshotyrosyl bond-containing SSB substrates. Under DNA repair conditions,
FEN1
efficiently repaired the 5'-phoshotyrosyl bond-containing SSB substrates in the presence of DNA ligase and DNA polymerase. Therefore,
FEN1
may play an important role in the repair of Top2-SSB complexes in etoposide-treated cells.
...
PMID:FEN1 participates in repair of the 5'-phosphotyrosyl terminus of DNA single-strand breaks. 2658 Dec 12
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
