iment by knocking down PARP1 CAL-101 andor Ku80 making use of siRNA. Like ABT888, PARP1 depletion decreased theclonogenic survival of PEO1 cells but not PEO4 cells, and Ku80knockdown reversed the effect of the PARP1 siRNA. Comparable toKu80 knockdown, siRNA depletion of Artemis also reversed thelethality of ABT888 in PEO1 cells. Likewise, coadministrationof the DNAPK inhibitor AZ12594248 diminishedthe effects of ABT888and a different PARP inhibitor, AZD2281. Similarresults had been observed in BRCA2mutant CAPAN1 cells, whereDNAPK inhibition once more mitigated the toxicity of PARP inhibition. In short, inhibition or downregulation of multiplecomponents of the NHEJ pathway diminished the toxicityof PARP inhibition in BRCA2deficient cells, indicating that thetoxicity of PARP inhibition depends on NHEJ in this context.
NHEJ Is also Responsible CAL-101 for PARP Inhibitor Lethality in Other HRDeficientContexts. In addition to BRCA2, previous studies havedocumented synthetic lethality among PARP inhibition and lossof other HR components, for instance BRCA1and ATM. InHCC1937 cells, which lackBRCA1, addition ofthe DNAPK inhibitor diminished ABT888 sensitivity,just because it did in PEO1 cells. In addition, in HCC1937 cells,inhibition of DNAPK also diminished formation of H2AX fociand inhibited ABT888induced colocalization ofphosphoThr2609DNAPK and phosphoSer139H2AX in foci. Likewise, BRCA1 knockdown sensitized DNAPKcsreconstituted M059J cells to ABT888. Importantly, parental M059J cells lackingDNAPKcs were not sensitizedby BRCA1 knockdown, delivering independentgenetic evidence for the crucial role Gefitinib of DNAPKcs within the syntheticlethality of HR deficiency and PARP inhibition.
To extend these results to ATM deficiency, we examinedGM16666 and GM16667 cells, an ATMdeficient line and itsATMreconstituted counterpart. Comparable toBRCA1and BRCA2deficient cells, GM16666 cells exhibitedheightened sensitivity to ABT888, and inhibition of DNAPKreversed this effect. HSP Collectively, results presented inFig. 6 not only demonstrate that the effect of DNAPK inhibitionon cellular sensitivity to PARP inhibition extends to other HRdeficientbackgrounds but also provide genetic evidence thatNHEJ plays a vital role in hypersensitivity of HRdeficient cellsto PARP inhibitors.DiscussionThe idea of synthetic lethality centers on the combination oftwo genetic lesions, each of which is nonlethal, that neverthelessinduce lethality with each other.
This approach has been extended topharmacologic agents that target certain pathways to exploitexisting genetic alterations in cancer cells. Most notably, twogroups demonstrated Gefitinib the striking sensitivity of BRCAdeficientcells to PARP inhibitors, which has since been extended toother HRdeficient backgrounds. In addition to the clinicalpotential of these findings, they provide an opportunity to morefully realize the biology of HR as well as the interplay betweenHR along with other modalities of repair. In this study, weevaluated the contribution of NHEJ towards the effects of PARP inhibitionin HRdeficient cells. Our results strongly support adifferent modelfor the mechanism of PARP inhibitorsynthetic lethality in these cells.The original explanation for the antitumor effects of PARPinhibitors in HRdeficient cells invoked the welldefined role ofPARP1 in BER.
This model postulated that catalytic inhibitionof CAL-101 PARP1 disabled the capacity of the cell to respond to endogenousDNA damage through BER, resulting in accumulatedSSBs. Even so, the inability to demonstrate increasedSSBs after PARP inhibitionraised queries about thismodel, and our failure to discover synthetic lethality when XRCC1 isdownregulated in BRCA2deficient cells raised the possibilitythat the effects of PARP inhibitors may be mediated througha mechanism distinct from BER.As a corollary towards the original model, if accumulated DNAdamage had been responsible for the toxicity of PARP inhibitors, onewould expect HRdeficient cells to depend on alternate DSBrepair pathways for instance NHEJ for survival.
In direct contradictionto this prediction, we found that disabling NHEJ diminishedthe genomic instability and lethality of PARP inhibition in HRdeficientcells rather than exacerbating it. Our results extend thegrowing body of literature that has connected NHEJ to genomicinstability after exposure to chemotherapeutic agents. Inside a recentstudy, disabling NHEJ was shown to reverse Gefitinib the DNArepairdefects and chromosomal instability of FANCD2 mutants exposedto platinum crosslinking agents. In addition, ablationof 53BP1, a molecule lately demonstrated to facilitate NHEJmediatedDSB repairin addition to its other roles, alsorescued the genotoxicity of DNAdamaging agents inside a BRCA1background. These earlier studies provide support fora model in which unrestricted NHEJ could induce genomic instabilityand eventual lethality in HRdeficient cells.Due to the errorprone nature of NHEJ, the interplaybetween HR and NHEJ has crucial implications for genomicstability. Our findings are consistent with all the observation thatcompetition among these two DS
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