about
Frequent and efficient use of the sister chromatid for DNA double-strand break repair during budding yeast meiosisNucleotide excision repair is associated with the replisome and its efficiency depends on a direct interaction between XPA and PCNAOut of balance: R-loops in human diseaseCdk1 targets Srs2 to complete synthesis-dependent strand annealing and to promote recombinational repairThe mechanism of double-strand DNA break repair by the nonhomologous DNA end-joining pathwayCRISPR/Cas9-mediated gene editing in human tripronuclear zygotesInhibition of homologous recombination by the PCNA-interacting protein PARIA PP4 phosphatase complex dephosphorylates RPA2 to facilitate DNA repair via homologous recombinationEnhancement of RAD51 recombinase activity by the tumor suppressor PALB2.A novel role of human holliday junction resolvase GEN1 in the maintenance of centrosome integrityMenin stimulates homology-directed DNA repairDNA-PK-dependent RPA2 hyperphosphorylation facilitates DNA repair and suppresses sister chromatid exchangeHuman RNF169 is a negative regulator of the ubiquitin-dependent response to DNA double-strand breaksHuman Fbh1 helicase contributes to genome maintenance via pro- and anti-recombinase activitiesDNA polymerase POLN participates in cross-link repair and homologous recombinationAn alternative form of replication protein a expressed in normal human tissues supports DNA repairScaffolding protein SPIDR/KIAA0146 connects the Bloom syndrome helicase with homologous recombination repairRad17 recruits the MRE11-RAD50-NBS1 complex to regulate the cellular response to DNA double-strand breaksRAD51-associated protein 1 (RAD51AP1) interacts with the meiotic recombinase DMC1 through a conserved motifMus81 nuclease and Sgs1 helicase are essential for meiotic recombination in a protist lacking a synaptonemal complexThe DNA-damage response in human biology and diseaseDynamics of DNA damage response proteins at DNA breaks: a focus on protein modificationsMolecular mechanisms of the whole DNA repair system: a comparison of bacterial and eukaryotic systemsFanconi anemia complementation group A (FANCA) protein has intrinsic affinity for nucleic acids with preference for single-stranded formsMRE11 and RAD50, but not NBS1, are essential for gene targeting in the moss Physcomitrella patensNucleophosmin: from structure and function to disease developmentGenome-edited human stem cell-derived beta cells: a powerful tool for drilling down on type 2 diabetes GWAS biologyDNA End Resection: Facts and MechanismsRing of Change: CDC48/p97 Drives Protein Dynamics at ChromatinDNA repair targeted therapy: The past or future of cancer treatment?DNA Damage Signalling and Repair Inhibitors: The Long-Sought-After Achilles' Heel of CancerDissecting diabetes/metabolic disease mechanisms using pluripotent stem cells and genome editing toolsPhysiology of the read-write genomeNucleases in homologous recombination as targets for cancer therapyTargeting ATM-deficient CLL through interference with DNA repair pathwaysBeyond DNA repair: DNA-PK function in cancerWhat goes on must come off: phosphatases gate-crash the DNA damage responseDouble-strand break repair on sex chromosomes: challenges during male meiotic prophaseFOXM1: an emerging master regulator of DNA damage response and genotoxic agent resistanceDNA Damage and Pulmonary Hypertension
P2860
Q21092719-3430B10B-A5C7-426D-9A7C-33F35A069752Q21133901-A2F1ACDC-2939-4CFC-8062-C2D47F23EF62Q21144865-1D2A71F7-0DD6-4E7C-BAC3-BB9845DFEC31Q21144986-7A33F6DB-5CF2-4EE0-91DA-5FB4B80C0EE1Q22065419-BCEA500A-A7E8-44E9-A405-F3CA389B692FQ22337358-020E2C3F-162E-4536-AAE2-B7E14036C931Q24299258-9BC22A67-1F42-480C-8140-849A8733A95AQ24299264-D6364CB2-1601-4698-96DB-A23ED8D953BFQ24301052-563028C9-A03C-4EEC-9598-7B468EB2ECAFQ24304112-A1D1D4F8-A2B0-49A8-A536-C1FC86B94578Q24304240-BC3DD55D-4073-4F40-ACCC-670F08BEC995Q24311527-7AE2C37D-1EA5-432A-AC55-A54A876C1BD1Q24312250-5086FD13-17B0-42B0-AAE7-918CF0D8DADCQ24314262-6D5F7D45-211D-424A-BBFF-E8C59818927FQ24336826-127C856A-7CB9-4318-99A1-AC7E8FDDD3EBQ24336962-1E8AD625-CF05-48AA-A950-58D3ED47FC5CQ24336963-E3B4CA4B-6A1D-494D-B00B-823E30278ABEQ24337442-1444247D-0083-4ADC-B8BC-0C774F09E3EDQ24337502-E4DE854D-FF83-4A32-BB97-457815C2418BQ24603667-A4CF44E2-F17D-4466-B3B7-F9FB761C1BA9Q24606586-41399C1E-B1EF-403E-8F98-78F290ACBF19Q24608343-BE51F767-7CD6-4F98-B2E9-A1FD5CF4062EQ24630140-BC77A9F1-950B-444C-ADFF-6E9A5682A32EQ24631719-E64EB731-15C3-4D81-9EEB-D6E20768C75DQ24633971-3EFB6EE5-91E0-4722-B7CC-841B0454EBE9Q26739704-06549FB4-13D0-402A-A3DA-C850F96B4540Q26742051-E18EA07C-BB50-49BA-900F-08DADC091093Q26744798-B9865AC5-E9AA-4089-94F1-D65DBDFEE19CQ26747328-3AC38C95-D0E2-42F8-93D5-460A8BD995EEQ26768679-BD3DF046-C459-4F85-B345-63F70783305EQ26776513-A367C757-D379-4ED3-B4FA-C23471AA9557Q26785684-74555D2E-50AC-4166-AAD1-3CA47C9C3FB9Q26822420-431297DA-217D-4186-B564-3AC3F8672325Q26822478-704E38AD-324A-4795-826F-8189172EA9EDQ26822592-74BD67E7-4D11-4EDA-B47A-BC956717CD33Q26827232-51594083-FF99-478B-BF2B-B554C4404EB8Q26827821-8708F2D6-0399-4DFE-A7F3-E50E0FFE55BAQ26830517-98BCD908-8E75-4ADB-AAD0-F3C8D8CA33A2Q26864654-09057034-468D-4C5C-8A3D-1BAF07D98E53Q27005594-D616A955-CBF1-4FDA-A576-A146EB307FE9
P2860
description
2008 nî lūn-bûn
@nan
2008 թուականին հրատարակուած գիտական յօդուած
@hyw
2008 թվականին հրատարակված գիտական հոդված
@hy
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
name
Mechanism of eukaryotic homologous recombination
@ast
Mechanism of eukaryotic homologous recombination
@en
type
label
Mechanism of eukaryotic homologous recombination
@ast
Mechanism of eukaryotic homologous recombination
@en
prefLabel
Mechanism of eukaryotic homologous recombination
@ast
Mechanism of eukaryotic homologous recombination
@en
P3181
P1476
Mechanism of eukaryotic homologous recombination
@en
P2093
Joseph San Filippo
Patrick Sung
P304
P3181
P356
10.1146/ANNUREV.BIOCHEM.77.061306.125255
P407
P577
2008-01-01T00:00:00Z