Mechanistic Modelling of Slow and Fast NHEJ DNA Repair Pathways Following Radiation for G0/G1 Normal Tissue Cells

Qi, Yaping; Warmenhoven, John-William; Henthorn, Nicholas; Ingram, Samuel; Xu, X. George; Kirkby, K.J.; Merchant, Michael J

doi:10.3390/cancers13092202

Cited by 9 publications

(9 citation statements)

References 75 publications

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“…Once bound, KU70/80 not only facilitates synapsis but also protects DNA ends from resection, thereby promoting cNHEJ. Emerging data supports a division of cNHEJ into two distinct biphasic pathways, termed fast-kinetic and slow-kinetic cNHEJ (Figures 1B, 2B,E, and Jakob et al, 2011;Biehs et al, 2017;Chang et al, 2017;Löbrich and Jeggo, 2017;Shibata et al, 2018;Frit et al, 2019;Setiaputra and Durocher, 2019;Shibata and Jeggo, 2020a;Shibata and Jeggo, 2020b;Qi et al, 2021). The fastkinetic cNHEJ is also termed 53BP1-, Artemis-, or resectionindependent cNHEJ, with Artemis clearly function downstream of ATM (Riballo et al, 2004;Woodbine et al, 2011).…”

Section: The Role Of Ku70/80 and Mrn In The Immediate-early Double Strand Break Responsementioning

confidence: 54%

“…In addition to the complex competition and recruitment interactions between KU70/80 and PARP, KU70/80 and MRN also share what has been termed 'entwined' loading, meaning they are not loaded in defined sequential order or competitively, but rather with more complex dynamics that include multiple points of crosstalk (see below and Rupnik et al, 2008;Shibata et al, 2018;Ingram et al, 2019). In addition, the common model where KU70/80 solely promotes NHEJ by recruiting DNA-PK, and MRN promotes HR by recruiting ATM, is clearly an oversimplification, as both complexes can be loaded to the same DSB (Britton et al, 2013;Ingram et al, 2019;Qi et al, 2021).…”

Section: The Role Of Ku70/80 and Mrn In The Immediate-early Double Strand Break Responsementioning

confidence: 99%

“…Whereas the core cNHEJ proteins are required by both fast-and slow-kinetic cNHEJ, 53BP1, RIF1, and Shieldin are antiresection factors and CST-Polα primase balances resection with de novo DNA synthesis, likely improving fidelity (Mirman et al, 2018). However, fast-and slow-kinetic cNHEJ differ in their ability to repair simple versus complex DSBs, have different recruitment pathways, and are used to different extents throughout the cell cycle (Setiaputra and Durocher, 2019;Shibata and Jeggo, 2020a;Shibata and Jeggo, 2020b;Qi et al, 2021). Intriguingly, emerging data suggests that slow-kinetic cNHEJ can avoid mutagenic deletions by using RNA molecules as homology templates for retrieving sequence information that can be lost during resection (Storici et al, 2007;Chakraborty et al, 2016;Meers et al, 2016;Mazina et al, 2017).…”

Section: Downstream Double Strand Break Repair Pathwaysmentioning

confidence: 99%

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Immediate-Early, Early, and Late Responses to DNA Double Stranded Breaks

Kieffer

Lowndes

2022

Front. Genet.

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Loss or rearrangement of genetic information can result from incorrect responses to DNA double strand breaks (DSBs). The cellular responses to DSBs encompass a range of highly coordinated events designed to detect and respond appropriately to the damage, thereby preserving genomic integrity. In analogy with events occurring during viral infection, we appropriate the terms Immediate-Early, Early, and Late to describe the pre-repair responses to DSBs. A distinguishing feature of the Immediate-Early response is that the large protein condensates that form during the Early and Late response and are resolved upon repair, termed foci, are not visible. The Immediate-Early response encompasses initial lesion sensing, involving poly (ADP-ribose) polymerases (PARPs), KU70/80, and MRN, as well as rapid repair by so-called ‘fast-kinetic’ canonical non-homologous end joining (cNHEJ). Initial binding of PARPs and the KU70/80 complex to breaks appears to be mutually exclusive at easily ligatable DSBs that are repaired efficiently by fast-kinetic cNHEJ; a process that is PARP-, ATM-, 53BP1-, Artemis-, and resection-independent. However, at more complex breaks requiring processing, the Immediate-Early response involving PARPs and the ensuing highly dynamic PARylation (polyADP ribosylation) of many substrates may aid recruitment of both KU70/80 and MRN to DSBs. Complex DSBs rely upon the Early response, largely defined by ATM-dependent focal recruitment of many signalling molecules into large condensates, and regulated by complex chromatin dynamics. Finally, the Late response integrates information from cell cycle phase, chromatin context, and type of DSB to determine appropriate pathway choice. Critical to pathway choice is the recruitment of p53 binding protein 1 (53BP1) and breast cancer associated 1 (BRCA1). However, additional factors recruited throughout the DSB response also impact upon pathway choice, although these remain to be fully characterised. The Late response somehow channels DSBs into the appropriate high-fidelity repair pathway, typically either ‘slow-kinetic’ cNHEJ or homologous recombination (HR). Loss of specific components of the DSB repair machinery results in cells utilising remaining factors to effect repair, but often at the cost of increased mutagenesis. Here we discuss the complex regulation of the Immediate-Early, Early, and Late responses to DSBs proceeding repair itself.

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Section: The Role Of Ku70/80 and Mrn In The Immediate-early Double Strand Break Responsementioning

confidence: 54%

Section: The Role Of Ku70/80 and Mrn In The Immediate-early Double Strand Break Responsementioning

confidence: 99%

Section: Downstream Double Strand Break Repair Pathwaysmentioning

confidence: 99%

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Immediate-Early, Early, and Late Responses to DNA Double Stranded Breaks

Kieffer

Lowndes

2022

Front. Genet.

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“…These findings suggest that the cells did not undergo cell cycle arrest after exposure to 1 and 2 Gy of X-rays in the G0 phase, as this would have resulted in a decreased proportion of dividing cells due to arrest at the cell cycle checkpoints 34 . This indicates that most of the DNA damage induced by irradiation was repaired before continuing their cell cycle progression, which is not unexpected as it is known that the main repair pathway active in the G0 phase, namely the non-homologous end joining (NHEJ) pathway, ensures repair of DNA damage within 24 h 35 , 36 . It is important to note that in these experiments, the cells were exposed to moderate doses of X-rays and that higher doses (> 7.5 Gy) have been reported to inhibit the proliferative response of lymphocytes, as shown by multiple studies 37 , 38 .…”

Section: Discussionmentioning

confidence: 71%

An updated view into the cell cycle kinetics of human T lymphocytes and the impact of irradiation

Vral

Baeyens

2022

Sci Rep

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Even though a detailed understanding of the proliferative characteristics of T lymphocytes is imperative in many research fields, prior studies have never reached a consensus on these characteristics, and on the corresponding cell cycle kinetics specifically. In this study, the general proliferative response of human T lymphocytes to phytohaemagglutinin (PHA) stimulation was characterized using a carboxyfluorescein succinimidyl ester-based flow cytometric assay. We were able to determine when PHA-stimulated T lymphocytes complete their first division, the proportion of cells that initiate proliferation, the subsequent division rate of the cells, and the impact of irradiation on these proliferative properties. Next, we accurately visualized the cell cycle progression of dividing T lymphocytes cultured in whole blood using an adapted 5-ethynyl-2’-deoxyuridine pulse-chase method. Furthermore, through multiple downstream analysis methods, we were able to make an estimation of the corresponding cell cycle kinetics. We also visualized the impact of X-rays on the progression of the cells through the cell cycle. Our results showed dose-dependent G2 arrest after exposure to irradiation, and a corresponding delay in G1 phase-entry of the cells. In conclusion, utilizing various flow cytometric assays, we provided valuable information on T lymphocyte proliferation characteristics starting from first division to fully dividing cells.

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“…The process of DNA repair can be simulated mechanically according to the information of lesions. Stochastic methods [ 21 , 22 ] and deterministic methods [ 1 , 4 , 23 , 24 ] are used in the simulation of DNA repair. Several models consider the resection-independent and resection-dependent NHEJ [ 22 , 25 ].…”

Section: Introductionmentioning

confidence: 99%

Modeling of DNA Damage Repair and Cell Response in Relation to p53 System Exposed to Ionizing Radiation

Zhou

et al. 2022

IJMS

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Repair of DNA damage induced by ionizing radiation plays an important role in the cell response to ionizing radiation. Radiation-induced DNA damage also activates the p53 system, which determines the fate of cells. The kinetics of repair, which is affected by the cell itself and the complexity of DNA damage, influences the cell response and fate via affecting the p53 system. To mechanistically study the influences of the cell response to different LET radiations, we introduce a new repair module and a p53 system model with NASIC, a Monte Carlo track structure code. The factors determining the kinetics of the double-strand break (DSB) repair are modeled, including the chromosome environment and complexity of DSB. The kinetics of DSB repair is modeled considering the resection-dependent and resection-independent compartments. The p53 system is modeled by simulating the interactions among genes and proteins. With this model, the cell responses to low- and high-LET irradiation are simulated, respectively. It is found that the kinetics of DSB repair greatly affects the cell fate and later biological effects. A large number of DSBs and a slow repair process lead to severe biological consequences. High-LET radiation induces more complex DSBs, which can be repaired by slow processes, subsequently resulting in a longer cycle arrest and, furthermore, apoptosis and more secreting of TGFβ. The Monte Carlo track structure simulation with a more realistic repair module and the p53 system model developed in this study can expand the functions of the NASIC code in simulating mechanical radiobiological effects.

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Mechanistic Modelling of Slow and Fast NHEJ DNA Repair Pathways Following Radiation for G0/G1 Normal Tissue Cells

Cited by 9 publications

References 75 publications

Immediate-Early, Early, and Late Responses to DNA Double Stranded Breaks

Immediate-Early, Early, and Late Responses to DNA Double Stranded Breaks

An updated view into the cell cycle kinetics of human T lymphocytes and the impact of irradiation

Modeling of DNA Damage Repair and Cell Response in Relation to p53 System Exposed to Ionizing Radiation

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