The Fanconi Anaemia (FA) pathway and glioblastoma: a new foundation for DNA damage response targeted combinations

Ola  Rominiyi; Katie  Myers; Natividad Gomez-Roman; Nikita  Lad; Dawoud Dar; David  Jellinek; Anthony  Chalmers; Thomas  Carroll; Beining Chen; Yahia  Al-Tamimi; Spencer Collis

doi:10.1093/neuonc/noz175.871

Abstract

Treatment resistance in glioblastoma is underpinned by highly interconnected DNA damage response (DDR) processes. The FA-pathway is a fundamental DDR process required for the resolution of replication fork impeding lesions, and we have previously shown that it is inactive in normal brain, but is re-activated in glioblastoma, providing a cancer-specific target for combination DDR therapies. Here, we find that elevated FA-pathway gene expression in gliomas is associated with poor survival (-17.1% 5-year OS, p< 0.0001, n=329–REMBRANT). Furthermore, patient-derived glioblastoma stem cell (GSC) populations, which drive therapeutic resistance, display high FA-pathway expression relative to paired bulk tumour cell populations (mean 2.3-fold higher across genes, p=0.0073). We further show that inhibition of a single DDR process (FA-pathway, PARP, ATR or ATM) increases the susceptibility of glioblastoma cell lines and patient-derived GSCs to current adjuvant therapy. Importantly, clinically approved PARP inhibitor (PARPi) monotherapy stimulates robust FANCD2 mono-ubiquitination, supporting a role of FA-pathway activation in response to current DDR-targeted therapy. In clinically-relevant 3D GSC models, simultaneous inhibition of the FA-pathway (FAPi) and PARP or ATR enhanced temozolomide sensitisation compared to a single DDR inhibitor (DDRi). Furthermore, combined FAPi+PARPi consistently conferred radiosensitisation whilst combined FAPi+ATRi led to a profoundly radiosensitising effect; e.g. sensitizer enhancement ratio (SER0.37) of 3.23 (3.03–3.49, 95% CI). Furthermore, comparison of α/β ratio enhancement suggests dual-DDRi strategies fundamentally alter the response of GSCs, whilst single cell gel electrophoresis & immunofluorescence studies suggest FA-pathway based DDRi combinations profoundly delay the resolution of IR-induced DNA strand breaks at 6 hours post-treatment, with increased persistent DNA double strand breaks at 24 hours. In conclusion, simultaneously targeting the FA-pathway and interconnected DDR processes represents an appealing therapeutic strategy. Additionally, constitutive lack of FA pathway function in some tumours, could serve as a novel predictive biomarker for patient response to PARPi and ATRi currently in clinical trials.

Original language	English
Pages (from-to)	vi209
Number of pages	1
Journal	Neuro-Oncology
Volume	21
Issue number	Suppl.6
DOIs	https://doi.org/10.1093/neuonc/noz175.871
Publication status	Published - 11 Nov 2019
Event	British Neuro-Oncology Society Annual Meeting - Wincester, United Kingdom Duration: 4 Jul 2018 → 8 Jul 2018

Keywords

glioblastoma
fanconi anemia
gene expression
cancer
stem cells
biological markers
DNA
DNA damage
recombinant DNA
fluorescent antibody technique
infectious mononucleosis
poly(adp-ribose) polymerases
neoplasms
tumor cells
adjuvant therapy

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1093/neuonc/noz175.871

Cite this

@article{b55a53ab8d624d9d9a9d7c4ab91da789,

title = "The Fanconi Anaemia (FA) pathway and glioblastoma: a new foundation for DNA damage response targeted combinations",

abstract = "Treatment resistance in glioblastoma is underpinned by highly interconnected DNA damage response (DDR) processes. The FA-pathway is a fundamental DDR process required for the resolution of replication fork impeding lesions, and we have previously shown that it is inactive in normal brain, but is re-activated in glioblastoma, providing a cancer-specific target for combination DDR therapies. Here, we find that elevated FA-pathway gene expression in gliomas is associated with poor survival (-17.1% 5-year OS, p< 0.0001, n=329–REMBRANT). Furthermore, patient-derived glioblastoma stem cell (GSC) populations, which drive therapeutic resistance, display high FA-pathway expression relative to paired bulk tumour cell populations (mean 2.3-fold higher across genes, p=0.0073). We further show that inhibition of a single DDR process (FA-pathway, PARP, ATR or ATM) increases the susceptibility of glioblastoma cell lines and patient-derived GSCs to current adjuvant therapy. Importantly, clinically approved PARP inhibitor (PARPi) monotherapy stimulates robust FANCD2 mono-ubiquitination, supporting a role of FA-pathway activation in response to current DDR-targeted therapy. In clinically-relevant 3D GSC models, simultaneous inhibition of the FA-pathway (FAPi) and PARP or ATR enhanced temozolomide sensitisation compared to a single DDR inhibitor (DDRi). Furthermore, combined FAPi+PARPi consistently conferred radiosensitisation whilst combined FAPi+ATRi led to a profoundly radiosensitising effect; e.g. sensitizer enhancement ratio (SER0.37) of 3.23 (3.03–3.49, 95% CI). Furthermore, comparison of α/β ratio enhancement suggests dual-DDRi strategies fundamentally alter the response of GSCs, whilst single cell gel electrophoresis & immunofluorescence studies suggest FA-pathway based DDRi combinations profoundly delay the resolution of IR-induced DNA strand breaks at 6 hours post-treatment, with increased persistent DNA double strand breaks at 24 hours. In conclusion, simultaneously targeting the FA-pathway and interconnected DDR processes represents an appealing therapeutic strategy. Additionally, constitutive lack of FA pathway function in some tumours, could serve as a novel predictive biomarker for patient response to PARPi and ATRi currently in clinical trials.",

keywords = "glioblastoma, fanconi anemia, gene expression, cancer, stem cells, biological markers, DNA, DNA damage, recombinant DNA, fluorescent antibody technique, infectious mononucleosis, poly(adp-ribose) polymerases, neoplasms, tumor cells, adjuvant therapy",

author = "Ola Rominiyi and Katie Myers and Natividad Gomez-Roman and Nikita Lad and Dawoud Dar and David Jellinek and Anthony Chalmers and Thomas Carroll and Beining Chen and Yahia Al-Tamimi and Spencer Collis",

note = "{\textcopyright} The Author(s) 2019. Published by Oxford University Press on behalf of the Society for Neuro-Oncology. All rights reserved. Ola Rominiyi and others, RDNA-12. THE FANCONI ANAEMIA (FA) PATHWAY AND GLIOBLASTOMA: A NEW FOUNDATION FOR DNA DAMAGE RESPONSE TARGETED COMBINATIONS, Neuro-Oncology, Volume 21, Issue Supplement_6, November 2019, Page vi209, https://doi.org/10.1093/neuonc/noz175.871 ; British Neuro-Oncology Society Annual Meeting ; Conference date: 04-07-2018 Through 08-07-2018",

year = "2019",

month = nov,

day = "11",

doi = "10.1093/neuonc/noz175.871",

language = "English",

volume = "21",

pages = "vi209",

journal = "Neuro-Oncology",

issn = "1522-8517",

publisher = "Oxford University Press",

number = "Suppl.6",

}

TY - JOUR

T1 - The Fanconi Anaemia (FA) pathway and glioblastoma

T2 - British Neuro-Oncology Society Annual Meeting

AU - Rominiyi, Ola

AU - Myers, Katie

AU - Gomez-Roman, Natividad

AU - Lad, Nikita

AU - Dar, Dawoud

AU - Jellinek, David

AU - Chalmers, Anthony

AU - Carroll, Thomas

AU - Chen, Beining

AU - Al-Tamimi, Yahia

AU - Collis, Spencer

N1 - © The Author(s) 2019. Published by Oxford University Press on behalf of the Society for Neuro-Oncology. All rights reserved. Ola Rominiyi and others, RDNA-12. THE FANCONI ANAEMIA (FA) PATHWAY AND GLIOBLASTOMA: A NEW FOUNDATION FOR DNA DAMAGE RESPONSE TARGETED COMBINATIONS, Neuro-Oncology, Volume 21, Issue Supplement_6, November 2019, Page vi209, https://doi.org/10.1093/neuonc/noz175.871

PY - 2019/11/11

Y1 - 2019/11/11

N2 - Treatment resistance in glioblastoma is underpinned by highly interconnected DNA damage response (DDR) processes. The FA-pathway is a fundamental DDR process required for the resolution of replication fork impeding lesions, and we have previously shown that it is inactive in normal brain, but is re-activated in glioblastoma, providing a cancer-specific target for combination DDR therapies. Here, we find that elevated FA-pathway gene expression in gliomas is associated with poor survival (-17.1% 5-year OS, p< 0.0001, n=329–REMBRANT). Furthermore, patient-derived glioblastoma stem cell (GSC) populations, which drive therapeutic resistance, display high FA-pathway expression relative to paired bulk tumour cell populations (mean 2.3-fold higher across genes, p=0.0073). We further show that inhibition of a single DDR process (FA-pathway, PARP, ATR or ATM) increases the susceptibility of glioblastoma cell lines and patient-derived GSCs to current adjuvant therapy. Importantly, clinically approved PARP inhibitor (PARPi) monotherapy stimulates robust FANCD2 mono-ubiquitination, supporting a role of FA-pathway activation in response to current DDR-targeted therapy. In clinically-relevant 3D GSC models, simultaneous inhibition of the FA-pathway (FAPi) and PARP or ATR enhanced temozolomide sensitisation compared to a single DDR inhibitor (DDRi). Furthermore, combined FAPi+PARPi consistently conferred radiosensitisation whilst combined FAPi+ATRi led to a profoundly radiosensitising effect; e.g. sensitizer enhancement ratio (SER0.37) of 3.23 (3.03–3.49, 95% CI). Furthermore, comparison of α/β ratio enhancement suggests dual-DDRi strategies fundamentally alter the response of GSCs, whilst single cell gel electrophoresis & immunofluorescence studies suggest FA-pathway based DDRi combinations profoundly delay the resolution of IR-induced DNA strand breaks at 6 hours post-treatment, with increased persistent DNA double strand breaks at 24 hours. In conclusion, simultaneously targeting the FA-pathway and interconnected DDR processes represents an appealing therapeutic strategy. Additionally, constitutive lack of FA pathway function in some tumours, could serve as a novel predictive biomarker for patient response to PARPi and ATRi currently in clinical trials.

AB - Treatment resistance in glioblastoma is underpinned by highly interconnected DNA damage response (DDR) processes. The FA-pathway is a fundamental DDR process required for the resolution of replication fork impeding lesions, and we have previously shown that it is inactive in normal brain, but is re-activated in glioblastoma, providing a cancer-specific target for combination DDR therapies. Here, we find that elevated FA-pathway gene expression in gliomas is associated with poor survival (-17.1% 5-year OS, p< 0.0001, n=329–REMBRANT). Furthermore, patient-derived glioblastoma stem cell (GSC) populations, which drive therapeutic resistance, display high FA-pathway expression relative to paired bulk tumour cell populations (mean 2.3-fold higher across genes, p=0.0073). We further show that inhibition of a single DDR process (FA-pathway, PARP, ATR or ATM) increases the susceptibility of glioblastoma cell lines and patient-derived GSCs to current adjuvant therapy. Importantly, clinically approved PARP inhibitor (PARPi) monotherapy stimulates robust FANCD2 mono-ubiquitination, supporting a role of FA-pathway activation in response to current DDR-targeted therapy. In clinically-relevant 3D GSC models, simultaneous inhibition of the FA-pathway (FAPi) and PARP or ATR enhanced temozolomide sensitisation compared to a single DDR inhibitor (DDRi). Furthermore, combined FAPi+PARPi consistently conferred radiosensitisation whilst combined FAPi+ATRi led to a profoundly radiosensitising effect; e.g. sensitizer enhancement ratio (SER0.37) of 3.23 (3.03–3.49, 95% CI). Furthermore, comparison of α/β ratio enhancement suggests dual-DDRi strategies fundamentally alter the response of GSCs, whilst single cell gel electrophoresis & immunofluorescence studies suggest FA-pathway based DDRi combinations profoundly delay the resolution of IR-induced DNA strand breaks at 6 hours post-treatment, with increased persistent DNA double strand breaks at 24 hours. In conclusion, simultaneously targeting the FA-pathway and interconnected DDR processes represents an appealing therapeutic strategy. Additionally, constitutive lack of FA pathway function in some tumours, could serve as a novel predictive biomarker for patient response to PARPi and ATRi currently in clinical trials.

KW - glioblastoma

KW - fanconi anemia

KW - gene expression

KW - cancer

KW - stem cells

KW - biological markers

KW - DNA

KW - DNA damage

KW - recombinant DNA

KW - fluorescent antibody technique

KW - infectious mononucleosis

KW - poly(adp-ribose) polymerases

KW - neoplasms

KW - tumor cells

KW - adjuvant therapy

U2 - 10.1093/neuonc/noz175.871

DO - 10.1093/neuonc/noz175.871

M3 - Conference abstract

SN - 1522-8517

VL - 21

SP - vi209

JO - Neuro-Oncology

JF - Neuro-Oncology

IS - Suppl.6

Y2 - 4 July 2018 through 8 July 2018

ER -