34 research outputs found
Senataxin, defective in ataxia oculomotor apraxia type 2, is involved in the defense against oxidative DNA damage.
A defective response to DNA damage is observed in several human autosomal
recessive ataxias with oculomotor apraxia, including ataxia-telangiectasia. We
report that senataxin, defective in ataxia oculomotor apraxia (AOA) type 2, is a
nuclear protein involved in the DNA damage response. AOA2 cells are sensitive to
H2O2, camptothecin, and mitomycin C, but not to ionizing radiation, and
sensitivity was rescued with full-length SETX cDNA. AOA2 cells exhibited
constitutive oxidative DNA damage and enhanced chromosomal instability in
response to H2O2. Rejoining of H2O2-induced DNA double-strand breaks (DSBs) was
significantly reduced in AOA2 cells compared to controls, and there was no
evidence for a defect in DNA single-strand break repair. This defect in DSB
repair was corrected by full-length SETX cDNA. These results provide evidence
that an additional member of the autosomal recessive AOA is also characterized by
a defective response to DNA damage, which may contribute to the neurodegeneration
seen in this syndrome
An Active Site Aromatic Triad in Escherichia coli DNA Pol IV Coordinates Cell Survival and Mutagenesis in Different DNA Damaging Agents
DinB (DNA Pol IV) is a translesion (TLS) DNA polymerase, which inserts a
nucleotide opposite an otherwise replication-stalling
N2-dG lesion in vitro, and
confers resistance to nitrofurazone (NFZ), a compound that forms these lesions
in vivo. DinB is also known to be part of the cellular
response to alkylation DNA damage. Yet it is not known if DinB active site
residues, in addition to aminoacids involved in DNA synthesis, are critical in
alkylation lesion bypass. It is also unclear which active site aminoacids, if
any, might modulate DinB's bypass fidelity of distinct lesions. Here we
report that along with the classical catalytic residues, an active site
“aromatic triad”, namely residues F12, F13, and Y79, is critical for
cell survival in the presence of the alkylating agent methyl methanesulfonate
(MMS). Strains expressing dinB alleles with single point
mutations in the aromatic triad survive poorly in MMS. Remarkably, these strains
show fewer MMS- than NFZ-induced mutants, suggesting that the aromatic triad, in
addition to its role in TLS, modulates DinB's accuracy in bypassing
distinct lesions. The high bypass fidelity of prevalent alkylation lesions is
evident even when the DinB active site performs error-prone NFZ-induced lesion
bypass. The analyses carried out with the active site aromatic triad suggest
that the DinB active site residues are poised to proficiently bypass distinctive
DNA lesions, yet they are also malleable so that the accuracy of the bypass is
lesion-dependent
XRN2 Links Transcription Termination to DNA Damage and Replication Stress
We thank the Proteomics Core Facility. We thank Dr. Robert J. Crouch for providing us with GFP- and GFP-RNase H expression plasmids. We also thank Dr. Stephen H. Leppla for providing us with antibodies directed against RNA:DNA hybrids (R loops) (S9.6). We thank Novus Biologicals for generously providing XRN2 and Rrp45 antibodies. We also thank the members of the Boothman lab for critical reading of this manuscript.Author Summary Genomic instability is one of the primary causes of disease states, in particular cancer. One major cause of genomic instability is the formation of DNA double strand breaks (DSBs), which are one of the most dangerous types of DNA lesions the cell can encounter. If not repaired in a timely manner, one DSB can lead not only to cell death. If misrepaired, one DSB can lead to a hazardous chromosomal aberration, such as a translocation, that can eventually lead to cancer. The cell encounters and repairs DSBs that arise from naturally occurring cellular processes on a daily basis. A number of studies have demonstrated that aberrant structures that form during transcription under certain circumstances, in particular RNA:DNA hybrids (R loops), can lead to DSB formation and genomic instability, especially during DNA synthesis. Thus, it is important to understand how the cell responds and repairs transcription-mediated DNA damage in general and R loop-related DNA damage in particular. This paper both demonstrates that the XRN transcription termination factor links transcription and DNA damage, but also provides a better understanding of how the cell prevents transcription-related DNA damage.Yeshttp://www.plosgenetics.org/static/editorial#pee
Reprogramming triggers endogenous L1 and Alu retrotransposition in human induced pluripotent stem cells
Human induced pluripotent stem cells (hiPSCs) are capable of unlimited proliferation and can differentiate in vitro to generate derivatives of the three primary germ layers. Genetic and epigenetic abnormalities have been reported by Wissing and colleagues to occur during hiPSC derivation, including mobilization of engineered LINE-1 (L1) retrotransposons. However, incidence and functional impact of endogenous retrotransposition in hiPSCs are yet to be established. Here we apply retrotransposon capture sequencing to eight hiPSC lines and three human embryonic stem cell (hESC) lines, revealing endogenous L1, Alu and SINE-VNTR-Alu (SVA) mobilization during reprogramming and pluripotent stem cell cultivation. Surprisingly, 4/7 de novo L1 insertions are full length and 6/11 retrotransposition events occurred in protein-coding genes expressed in pluripotent stem cells. We further demonstrate that an intronic L1 insertion in the CADPS2 gene is acquired during hiPSC cultivation and disrupts CADPS2 expression. These experiments elucidate endogenous retrotransposition, and its potential consequences, in hiPSCs and hESCs
Aprataxin, poly-ADP ribose polymerase 1 (PARP-1) and apurinic endonuclease 1 (APE1) function together to protect the genome against oxidative damage.
Aprataxin, defective in the neurodegenerative disorder ataxia oculomotor apraxia type 1 (AOA1), is a DNA repair protein that processes the product of abortive ligations, 5' adenylated DNA. In addition to its interaction with the single-strand break repair protein XRCC1, aprataxin also interacts with poly-ADP ribose polymerase 1 (PARP-1), a key player in the detection of DNA single-strand breaks. Here, we reveal reduced expression of PARP-1, apurinic endonuclease 1 (APE1) and OGG1 in AOA1 cells and demonstrate a requirement for PARP-1 in the recruitment of aprataxin to sites of DNA breaks. While inhibition of PARP activity did not affect aprataxin activity in vitro, it retarded its recruitment to sites of DNA damage in vivo. We also demonstrate the presence of elevated levels of oxidative DNA damage in AOA1 cells coupled with reduced base excision and gap filling repair efficiencies indicative of a synergy between aprataxin, PARP-1, APE-1 and OGG1 in the DNA damage response. These data support both direct and indirect modulating functions for aprataxin on base excision repair