Coordination of DNA single strand break repair

Abbotts, Rachel; Wilson, David M.

doi:10.1016/j.freeradbiomed.2016.11.039

Cited by 181 publications

(147 citation statements)

References 311 publications

(360 reference statements)

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“…In quiescent type B NSCs, repair of double‐strand break defaults to the nonhomologous end joining pathway (NHEJ) . Ionizing radiation also generates large numbers of single‐strand breaks and these are repaired by a base excision repair subpathway . As stated above, Achanta et al reported the loss of type B cells following a single fraction of 10 Gy .…”

Section: Introductionmentioning

confidence: 99%

Bcl2-Expressing Quiescent Type B Neural Stem Cells in the Ventricular–Subventricular Zone Are Resistant to Concurrent Temozolomide/X-Irradiation

et al. 2019

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The ventricular–subventricular zone (V‐SVZ) of the mammalian brain is a site of adult neurogenesis. Within the V‐SVZ reside type B neural stem cells (NSCs) and type A neuroblasts. The V‐SVZ is also a primary site for very aggressive glioblastoma (GBM). Standard‐of‐care therapy for GBM consists of safe maximum resection, concurrent temozolomide (TMZ), and X‐irradiation (XRT), followed by adjuvant TMZ therapy. The question of how this therapy impacts neurogenesis is not well understood and is of fundamental importance as normal tissue tolerance is a limiting factor. Here, we studied the effects of concurrent TMZ/XRT followed by adjuvant TMZ on type B stem cells and type A neuroblasts of the V‐SVZ in C57BL/6 mice. We found that chemoradiation induced an apoptotic response in type A neuroblasts, as marked by cleavage of caspase 3, but not in NSCs, and that A cells within the V‐SVZ were repopulated given sufficient recovery time. 53BP1 foci formation and resolution was used to assess the repair of DNA double‐strand breaks. Remarkably, the repair was the same in type B and type A cells. While Bax expression was the same for type A or B cells, antiapoptotic Bcl2 and Mcl1 expression was significantly greater in NSCs. Thus, the resistance of type B NSCs to TMZ/XRT appears to be due, in part, to high basal expression of antiapoptotic proteins compared with type A cells. This preclinical research, demonstrating that murine NSCs residing in the V‐SVZ are tolerant of standard chemoradiation therapy, supports a dose escalation strategy for treatment of GBM. stem cells 2019;37:1629–1639

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Section: Introductionmentioning

confidence: 99%

Bcl2-Expressing Quiescent Type B Neural Stem Cells in the Ventricular–Subventricular Zone Are Resistant to Concurrent Temozolomide/X-Irradiation

et al. 2019

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“…The DNA breaks are detected primarily by poly(ADP-ribose) polymerase 1 (PARP1); the unblocking of 3′-and 5′-ends in breaks is catalyzed by specific activities of APE1, PNKP, aprataxin (APTX), and tyrosyl-DNA phosphodiesterase 1 (TDP1); gap filling and ligation are catalyzed by the same set of enzymes that participate in the respective steps of the short-patch repair of the damaged DNA bases (Polβ and LigIIIα). PARP1 is activated via the interaction with the damaged DNA; it catalyzes the synthesis of poly(ADP-ribose) (PAR) and covalent attachment of the PAR polymer to PARP1 itself and other proteins involved in the DNA repair [4,5]. The XRCC1 protein is considered to be a main target of PARP1 catalyzed poly(ADP-ribosyl)ation.…”

Section: Main Steps Of Ber and Proteins Involvedmentioning

confidence: 99%

“…The XRCC1 protein is considered to be a main target of PARP1 catalyzed poly(ADP-ribosyl)ation. PARP1 has been suggested to play the main role in recruitment of the XRCC1 protein to the damages of chromosomal DNA [4,5]. XRCC1 displays no enzymatic activity and is proposed to function as a scaffold protein of the BER process.…”

Section: Main Steps Of Ber and Proteins Involvedmentioning

confidence: 99%

“…Base excision repair (BER), which ensures correction of the most abundant damages-modified nitrogenous bases and apurinic/apyrimidinic (AP) sites-is critically important for survival of human cells [1][2][3]. Enzyme and protein factors of BER also participate in the repair of DNA single-strand breaks (SSBs) considered as a separate pathway of the BER system [4,5]. The other repair systems (Figure 1) deal with bulky nucleobase lesions (NER), DNA double-strand breaks (HR; NHEJ), and mismatched bases (MMR).…”

Section: Introductionmentioning

confidence: 99%

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Coordination of DNA Base Excision Repair by Protein-Protein Interactions

Moor¹,

Lavrik²

2019

DNA Repair- An Update

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The system of base excision repair (BER) evolved to correct the most abundant DNA damages in mammalian cells is the most essential for maintaining the genome integrity. The multistep BER process involves several enzymes and protein factors functioning in a coordinated fashion that ensures the repair efficiency. The coordination is facilitated by the formation of protein complexes stabilized via either direct or indirect DNA-mediated interactions. This review focuses on direct interactions of proteins participating in BER with each other and with noncanonical factors found recently to modulate the efficiency of BER. All the known partners of main BER participants, the sites responsible for their interaction, and the characteristics of protein-protein affinity are summarized. Well-documented evidences of how DNA intermediates and posttranslational modifications of proteins modulate protein-protein interactions are presented. The available data allow to suggest that the multiprotein complexes are assembled with the involvement of a scaffold protein XRCC1 and poly(ADP-ribose) polymerase 1, a key regulator of the BER process, irrespective of the DNA damage; the composition and the structure of the complexes are dynamically changed depending on the DNA damage, its chromatin environment, and the step of BER process.

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“…Эксцизионная репарация оснований (BER) обеспечивает коррекцию самых многочисленных повреждений ДНК -модифицированных оснований, апуриновых/апиримидиновых (АР) сайтов и одноцепочечных разрывов [1], возникающих под воздействием различных факторов, включая активные формы кислорода. Активность ферментов, катализирующих отдельные стадии многоступенчатого процесса BER, координируется с участием поли(АДФ-рибоза) полимераз (PARP1 и PARP2) и белка XRCC1 (X-ray repair cross-complementing protein 1), опосредующих сборку мультибелковых ансамблей (репарасом).…”

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Role of oxidation of XRCC1 protein in regulation of mammalian DNA repair process

Васильева

Moor

Lavrik

2019

Доклады Академии наук

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Influence of XRCC1 protein oxidation on the modification of proteins catalyzed by poly(ADP‑ribose)polyme-rases (PARP1 and PARP2) has been studied for the first time. XRCC1, PARP1 and PARP2 are responsible for coordination of multistep repair of most abundant DNA lesions, functioning as scaffold proteins. We have shown that the XRCC1 oxidation reduces the efficiency of its ADP‑ribosylation and the protein affinity for poly(ADP‑ribose). The ADP‑ribose modification of various XRCC1 forms is enhanced in the presence of DNA polymerase b (Polb) capable to form a stable complex with XRCC1. The oxidation suppresses the inhibiting activity of XRCC1 and its complex with Polb towards the automodification of PARP1 and PARP2 that may enhance the efficiency of repair. The results of this study indicate that the oxidation of XRCC1 play a role in fine regulation of poly(ADP‑ribosyl)ation levels of proteins and their coordinating functions in the DNA repair.

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Coordination of DNA single strand break repair

Cited by 181 publications

References 311 publications

Bcl2-Expressing Quiescent Type B Neural Stem Cells in the Ventricular–Subventricular Zone Are Resistant to Concurrent Temozolomide/X-Irradiation

Bcl2-Expressing Quiescent Type B Neural Stem Cells in the Ventricular–Subventricular Zone Are Resistant to Concurrent Temozolomide/X-Irradiation

Coordination of DNA Base Excision Repair by Protein-Protein Interactions

Role of oxidation of XRCC1 protein in regulation of mammalian DNA repair process

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