Radiosensitization in Pediatric High-Grade Glioma: Targets, Resistance and Developments

Metselaar, Dennis S.; Chatinier, Aimée du; Stuiver, Iris; Kaspers, Gertjan J. L.; Hulleman, Esther

doi:10.3389/fonc.2021.662209

Cited by 14 publications

(8 citation statements)

References 92 publications

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“…Several clinical phase I-II trials of checkpoint kinase inhibitors in combination with RT and CT in solid tumors or leukemia have been published or are ongoing, but a comprehensive review included only two ongoing trials on brain tumors [124]. A recent review discussed molecular targets in the treatment of high-grade pediatric glioma, but no clinical studies on cell cycle checkpoint kinase inhibitors were listed [125].…”

Section: Clinical Studiesmentioning

confidence: 99%

Targeting Cell Cycle Checkpoint Kinases to Overcome Intrinsic Radioresistance in Brain Tumor Cells

Vlatkovic

Veldwijk

Giordano

et al. 2022

Cancers

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Radiation therapy is an important part of the standard of care treatment of brain tumors. However, the efficacy of radiation therapy is limited by the radioresistance of tumor cells, a phenomenon held responsible for the dismal prognosis of the most aggressive brain tumor types. A promising approach to radiosensitization of tumors is the inhibition of cell cycle checkpoint control responsible for cell cycle progression and the maintenance of genomic integrity. Inhibition of the kinases involved in these control mechanisms can abolish cell cycle checkpoints and DNA damage repair and thus increase the sensitivity of tumor cells to radiation and chemotherapy. Here, we discuss preclinical progress in molecular targeting of ATM, ATR, CHK1, CHK2, and WEE1, checkpoint kinases in the treatment of brain tumors, and review current clinical phase I-II trials.

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Section: Clinical Studiesmentioning

confidence: 99%

Targeting Cell Cycle Checkpoint Kinases to Overcome Intrinsic Radioresistance in Brain Tumor Cells

Vlatkovic

Veldwijk

Giordano

et al. 2022

Cancers

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“…Finally, it is noteworthy that the H3.3 and H3.1 mutant histones can be found associated with genetic alterations/mutations expected to perturb DNA repair (reviewed by Pedersen et al [ 22 ] and Metselaar et al [ 21 ]). For instance, Mackay et al [ 3 ] reported that 60% of the 1000 pHGGs characterized in their integrative genomic analysis contained genetic alterations in DNA repair genes, including HR genes and Fanconi anemia genes involved in the protection/restart of replication forks and DNA crosslink repair [ 186 ].…”

Section: Impact Of Mutations In H33/ Atrx /Daxx On Dna Repair and Telomere Dynamicsmentioning

confidence: 99%

“…Targeting DNA repair pathway addictions, through inhibition of components of the DDR, including modulation of cell cycle and mitotic progression, and genetic stability, has emerged as an important therapeutic approach against many cancers [ 221 , 222 , 223 , 224 ]. At the same time, our catalogue of small molecule inhibitors targeting DNA repair is expanding rapidly [ 225 , 226 , 227 , 228 ] while novel targets are being discovered for the sensitization of glioma cells to radio- and chemotherapy [ 21 , 22 ]. These include RAD52 whose depletion led to TMZ hypersensitivity in GBM cells [ 64 ].…”

Section: Strategies Targeting Chromatin Dynamics and Dna Repair In Phggsmentioning

confidence: 99%

“…For pHGG patients with sus-tentorial locations, radiotherapy follows surgical resection, which tends to be extensive, and is associated at least with DNA alkylating agents like temozolomide (TMZ) [ 16 ]. In thalamic pHGGs and DIPGs, targeted therapies are nowadays proposed concomitantly to irradiation and prolonged until progression [ 17 , 18 , 19 , 20 , 21 ]. However, contrasting with our understanding of their molecular biology, there has been little improvement in the treatment of pHGGs where the development of tumor resistance driven by complex DNA repair pathways severely limits the efficiency of genotoxic chemotherapy and ionizing radiation (IR) [ 21 , 22 ].…”

Section: Introductionmentioning

confidence: 99%

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Impact of Chromatin Dynamics and DNA Repair on Genomic Stability and Treatment Resistance in Pediatric High-Grade Gliomas

Pinto

Baidarjad

Entz‐Werlé³

et al. 2021

Cancers

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Despite their low incidence, pediatric high-grade gliomas (pHGGs), including diffuse intrinsic pontine gliomas (DIPGs), are the leading cause of mortality in pediatric neuro-oncology. Recurrent, mutually exclusive mutations affecting K27 (K27M) and G34 (G34R/V) in the N-terminal tail of histones H3.3 and H3.1 act as key biological drivers of pHGGs. Notably, mutations in H3.3 are frequently associated with mutations affecting ATRX and DAXX, which encode a chaperone complex that deposits H3.3 into heterochromatic regions, including telomeres. The K27M and G34R/V mutations lead to distinct epigenetic reprogramming, telomere maintenance mechanisms, and oncogenesis scenarios, resulting in distinct subgroups of patients characterized by differences in tumor localization, clinical outcome, as well as concurrent epigenetic and genetic alterations. Contrasting with our understanding of the molecular biology of pHGGs, there has been little improvement in the treatment of pHGGs, with the current mainstays of therapy—genotoxic chemotherapy and ionizing radiation (IR)—facing the development of tumor resistance driven by complex DNA repair pathways. Chromatin and nucleosome dynamics constitute important modulators of the DNA damage response (DDR). Here, we summarize the major DNA repair pathways that contribute to resistance to current DNA damaging agent-based therapeutic strategies and describe the telomere maintenance mechanisms encountered in pHGGs. We then review the functions of H3.3 and its chaperones in chromatin dynamics and DNA repair, as well as examining the impact of their mutation/alteration on these processes. Finally, we discuss potential strategies targeting DNA repair and epigenetic mechanisms as well as telomere maintenance mechanisms, to improve the treatment of pHGGs.

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“…Tremendous progress has been made over time to limit both dose and field of radiation exposure in order to minimize damage to healthy cells, which can lead to growth impairment, cognitive deficits, and secondary malignancies. 11 Despite these strides in RT technique, some degree of inherent risk remains, especially when a larger tumor or larger portion of the brain requires irradiation.…”

Section: Introductionmentioning

confidence: 99%

Population-based analysis of radiation-induced gliomas after cranial radiotherapy for childhood cancers

Leary

Anderson-Mellies

Green

2022

Preprint

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Background: Cranial radiotherapy (RT) is used to treat pediatric central nervous system (CNS) cancers and leukemias. RT carries a risk of secondary CNS malignancies, including radiation-induced gliomas, the epidemiology of which is poorly understood. Methods: This retrospective study using SEER registry data (1975-2016) included two cohorts. Cohort 1 included patients diagnosed with Grade III/IV or ungraded glioma as a second malignancy at least 2 years after receiving beam radiation and/or chemotherapy for a first malignancy diagnosed at ages 0-19 years, either a primary CNS tumor treated with RT (1a, n=57) or leukemia with unknown RT treatment (1b, n=20). Cohort 2 included patients with possible missed RIG who received RT for a primary CNS tumor diagnosed at 0-19 and then died of presumed progressive disease more than 5 years after diagnosis, since previous studies have documented many missed RIGs in this group (n=296). Controls (n=10,687) included all other patients ages 0-19 who received RT for a first CNS tumor or leukemia who did not fit inclusion criteria above. Results: For Cohort 1 (likely/definite RIGs), 0.97% of patients receiving cranial RT went on to develop RIG. 3.39% of patients receiving cranial RT for primary CNS tumors fell in Cohort 2 (potential RIGs). Median latency to RIG diagnosis was 11.1 years; latency was significantly shorter for Cohort 1b (median 10.0, range 5.0-16.1) vs. 1a (12.0, 3.6-34.4, p=0.018). Median OS for Cohort 1 was 9.0 months. Receiving surgery, radiation, or chemotherapy were all associated with a non-statistically significant improvement in OS (p 0.1-0.2). 1.8% of brain tumor deaths in the cohort fell in Cohort 1, with an additional 7.9% in Cohort 2. Conclusion: Within the limitations of a population-based study, 1-4% of patients undergoing cranial RT for pediatric cancers later develop RIG, which is incurable and can occur anywhere from 3-35 years later. 2-10% of pediatric brain tumor deaths are attributable to RIG. Effective treatment of RIG remains unclear and is thus deserving of increased attention in preclinical and clinical studies.

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Radiosensitization in Pediatric High-Grade Glioma: Targets, Resistance and Developments

Cited by 14 publications

References 92 publications

Targeting Cell Cycle Checkpoint Kinases to Overcome Intrinsic Radioresistance in Brain Tumor Cells

Targeting Cell Cycle Checkpoint Kinases to Overcome Intrinsic Radioresistance in Brain Tumor Cells

Impact of Chromatin Dynamics and DNA Repair on Genomic Stability and Treatment Resistance in Pediatric High-Grade Gliomas

Population-based analysis of radiation-induced gliomas after cranial radiotherapy for childhood cancers

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