New insights into the cellular response to complex DNA damage induced by proton beam therapy
Lead Research Organisation:
University of Liverpool
Department Name: Institute of Translational Medicine
Abstract
Radiotherapy is still the most effective treatment for a number of human cancers, and the emergence of proton beam therapy (PBT) facilities in the UK, particularly in Manchester and London (operational from late 2018 and 2021, respectively), is likely to signal a new era for cancer treatment. This is due to the fact that PBT is a precision technique able to deliver the majority of the radiation dose directly to the cancer, thus sparing the surrounding normal tissues of any unwanted dose of radiation and reducing the adverse side-effects that are commonly observed with conventional radiotherapy. However whilst radiotherapy, including PBT, is known to act by causing damage to the DNA of cancer cells causing them to die, there is still not a complete understanding of the mechanisms which the cells use to repair certain types of DNA damage and that can cause significant resistance to treatment.
This proposal therefore aims to reveal new knowledge into the basic biological mechanisms that cancer cells use to repair DNA damage caused by PBT, with the future goal of providing leads to the development of new strategies in combination with PBT for effective cancer treatment. Indeed, this study will largely employ cells derived from patients with head and neck cancer, which is a priority tumour research area within the University of Liverpool due to the high local incidence, but also a tumour which is increasingly being treated with PBT worldwide. Therefore, this proposal has the significant potential to devise future optimal treatments using PBT for head and neck cancer patients, leading to reductions in adverse side-effects and improvement in quality of life, but more importantly to increases in overall survival rates.
This proposal therefore aims to reveal new knowledge into the basic biological mechanisms that cancer cells use to repair DNA damage caused by PBT, with the future goal of providing leads to the development of new strategies in combination with PBT for effective cancer treatment. Indeed, this study will largely employ cells derived from patients with head and neck cancer, which is a priority tumour research area within the University of Liverpool due to the high local incidence, but also a tumour which is increasingly being treated with PBT worldwide. Therefore, this proposal has the significant potential to devise future optimal treatments using PBT for head and neck cancer patients, leading to reductions in adverse side-effects and improvement in quality of life, but more importantly to increases in overall survival rates.
Technical Summary
Proton beam therapy (PBT) is a cutting-edge precision technique for cancer treatment that specifically targets the tumour and spares the surrounding normal tissues. The therapeutic effect of PBT is largely attributable to DNA damage, particularly complex DNA damage (CDD) where several DNA lesions are generated in close proximity by a single radiation track. Since PBT is not monoenergetic and energy is deposited via the Bragg peak, the amount and complexity of CDD can vary which can have a significant impact on the biological response to PBT. However little is known of the molecular and cellular mechanisms that recognise and process CDD in cells.
Recent evidence published by the Principal Investigator has demonstrated that a specific cellular DNA damage response is triggered in response to CDD induced by PBT, and that specific enzymes (e.g. USP6 and PARP-1) control cell survival under these conditions. Utilising PBT at different energies (and thus linear energy transfer; LET) which creates CDD in different proportions, in combination with various biochemical, molecular and cellular biology techniques, this proposal aims to expand on this knowledge by focusing on the specific DNA repair pathways and enzymes, particularly of the base excision/single strand break repair pathways, that are critical for resolving of PBT-induced CDD sites. Furthermore, data provided from recent comprehensive siRNA screening has identified proteins in the cellular DNA damage response (e.g. OGG1 and PARG), and ultimately utilised novel inhibitors against these enzymes (TH5487 and PDD00017273) that can enhance cellular radiosensitivity in response to CDD-induced by PBT, which require further detailed investigation. The overall goal is to improve our understanding of the radiobiology of PBT linked to CDD and repair, and ultimately in the identification of novel strategies using targeted drugs/small molecule inhibitors that may enhance the efficacy of PBT in cancer treatment.
Recent evidence published by the Principal Investigator has demonstrated that a specific cellular DNA damage response is triggered in response to CDD induced by PBT, and that specific enzymes (e.g. USP6 and PARP-1) control cell survival under these conditions. Utilising PBT at different energies (and thus linear energy transfer; LET) which creates CDD in different proportions, in combination with various biochemical, molecular and cellular biology techniques, this proposal aims to expand on this knowledge by focusing on the specific DNA repair pathways and enzymes, particularly of the base excision/single strand break repair pathways, that are critical for resolving of PBT-induced CDD sites. Furthermore, data provided from recent comprehensive siRNA screening has identified proteins in the cellular DNA damage response (e.g. OGG1 and PARG), and ultimately utilised novel inhibitors against these enzymes (TH5487 and PDD00017273) that can enhance cellular radiosensitivity in response to CDD-induced by PBT, which require further detailed investigation. The overall goal is to improve our understanding of the radiobiology of PBT linked to CDD and repair, and ultimately in the identification of novel strategies using targeted drugs/small molecule inhibitors that may enhance the efficacy of PBT in cancer treatment.
Organisations
- University of Liverpool (Lead Research Organisation)
- AstraZeneca (United Kingdom) (Collaboration)
- The Clatterbridge Cancer Centre NHS Foundation Trust (Collaboration)
- UNIVERSITY OF OXFORD (Collaboration)
- University of Sheffield (Collaboration)
- Karolinska Institute (Collaboration)
- UNIVERSITY OF BIRMINGHAM (Collaboration)
People |
ORCID iD |
| Jason Luke Parsons (Principal Investigator) |
Publications
Fabbrizi M
(2022)
Cell death mechanisms in head and neck cancer cells in response to low and high-LET radiation
in Expert Reviews in Molecular Medicine
Melia E
(2023)
DNA Damage and Repair Dependencies of Ionising Radiation Modalities.
in Bioscience reports
Wilkinson B
(2023)
The Cellular Response to Complex DNA Damage Induced by Ionising Radiation
in International Journal of Molecular Sciences
| Description | Member of ITRF Advisory Committee |
| Geographic Reach | National |
| Policy Influence Type | Participation in a guidance/advisory committee |
| Title | Method for quantifying levels of complex DNA damage in cells following irradiation |
| Description | We have established a specific method, entitled the Enzyme-Modified Neutral Comet (EMNC) assay, for quantitatively examining the levels of complex DNA damage (CDD) induced by ionising radiation. This is now a commonly used technique by Dr Jason Parsons and his Team to further our understanding of radiobiology within cultured cell lines. Specifically, the EMNC allows an assessment of CDD induced by ionising radiation of increasing linear energy transfer (LET), and have proven this can capture such sites in cultured cells following proton beam therapy. This will enable further investigations into the molecular and cellular biology of radiation-induced CDD, with the future goal of developing optimal strategies for the effective use of protons and other high-LET radiation in cancer treatment. |
| Type Of Material | Technology assay or reagent |
| Year Produced | 2021 |
| Provided To Others? | Yes |
| Impact | The EMNC assay has only been reported this year, although we have previously used this methodology to further our understanding of the radiobiology of protons, as evidenced here (PMID: 30851349; 29413288). Further impact will no doubt be developed more in the future. |
| URL | https://www.mdpi.com/2409-9279/4/1/14 |
| Title | Research Laboratory Examining Proton Irradiation |
| Description | In association with our collaborators at the Clatterbridge Cancer Centre, we have established a research laboratory at the Centre (with generous funding of ~£40k) dedicated for examining the molecular and cellular effects of proton beam therapy. This is now heavily used by Dr Jason Parsons and his Team to further an understanding of the radiobiology of proton irradiation on cancer cells, although is open and indeed being utilised for collaborative radiobiology research particularly with other UK Centres (e.g. University of Birmingham, University of Oxford, University College London, and Imperial College London). The future goal is the development of optimal strategies for the effective use of protons in cancer treatment. This research is vital given that the Clatterbridge Cancer Centre currently houses the only accessible proton beam therapy facility, and now the only research laboratory, in the UK but that new proton facilities are now active in Manchester and London (from 2021). Therefore this facility is currently at the forefront of radiobiology research into proton beam therapy. |
| Type Of Material | Improvements to research infrastructure |
| Year Produced | 2016 |
| Provided To Others? | Yes |
| Impact | The establishment of the new research laboratory at the Clatterbridge Cancer Centre is crucial in furthering our understanding of the radiobiology of proton beam therapy in cancer cells, and since this is currently the only such accessible and collaborative facility in the UK, we are at the forefront of research in this area. |
| Title | Cellular sensitivity to ionising radiation |
| Description | My Postdoctoral Research Scientist (Dr Rachel Carter) funded by the MRC Award (MR/M000354/1) has completed both a plasmid overexpression, and an siRNA knockdown screen in cells and analysed the cellular response to different sources of ionising radiation. This has examined the effect of (~90) deubiquitylation enzymes on the survival of cells following either low-LET x-ray irradiation or high-LET alpha particle irradiation (collaboration with the CRUK/MRC Oxford Institute for Radiation Oncology). Work has also been extended to examining the cellular response of these enzymes following proton beam therapy, at both high and low-LET (collaboration with the Clatterbridge Cancer Centre). This is aimed at improving our understanding and knowledge of radiobiology. |
| Type Of Material | Database/Collection of data |
| Year Produced | 2019 |
| Provided To Others? | Yes |
| Impact | This collection of data has given us valuable insights into the roles of deubiquitylation enzymes in the cellular response to different sources of ionising radiation, with a particular focus on those enzymes playing a role in the identification and/or processing of complex DNA damage induced by high-LET alpha particle and proton irradiation. We are in the continual process of validating candidate enzymes, leading to the identification of cellular enzymes and their novel roles in radiation biology. Our future goal is to examine validated enzymes as novel targets for drugs and/or small molecule inhibitors for improving the efficacy of radiotherapy in cancer treatment. |
| Description | Collaboration with AstraZeneca |
| Organisation | AstraZeneca |
| Country | United Kingdom |
| Sector | Private |
| PI Contribution | A collaboration has been established with AstraZeneca regarding collaborative research into the impact of DNA repair inhibitors in combination with different forms of radiotherapy on cell models of head and neck cancers, glioblastoma and uveal melanoma. We have had regular contact with the appropriate leads at AstraZeneca (Dr Stephen Durant and Dr Alan Lau) to develop research using the appropriate 2D and 3D tumour cell models and their sensitisation with inhibitors of DNA double strand break repair pathways in combination with ionising radiation (photons and protons). |
| Collaborator Contribution | Our direct partners, Dr Stephen Durant and Dr Alan Lau, have provided their expertise into specific inhibitors of DNA damage and repair for translational research. The collaborative agreement has allowed us access to AstraZeneca's specific and potent DNA repair inhibitors for our radiobiology research, and ongoing intellectual support and advice is provided into our studies to identify novel and optimal radiosensitisation strategies using different radiotherapy sources on 2D and 3D tumour cell models. |
| Impact | No outputs or outcomes have yet resulted. |
| Start Year | 2020 |
| Description | Collaboration with Clatterbridge Cancer Centre |
| Organisation | The Clatterbridge Cancer Centre NHS Foundation Trust |
| Country | United Kingdom |
| Sector | Public |
| PI Contribution | My research team and I have regular visits to Dr Andrzej Kacperek and the Eye Proton Therapy Team at the Clatterbridge Cancer Centre, Bebington, UK in order to perform cell irradiation experiments using the 60 MeV proton beam. We also have regular contact and discussion with our collaborators on experimental design, results and evaluation in order for the research to proceed effectively. |
| Collaborator Contribution | Our partners at the Clatterbridge Cancer Centre, including Dr Andrez Kacperek, assist in the dosimetry and delivery of proton beam irradiation of cells. They also advise on experimental design, and interpretation of results. |
| Impact | As a consequence of this collaboration, we have now established a radiobiology research laboratory at the Clatterbridge Cancer Centre (funded by the Centre to a cost of ~£40k) which is dedicated for further examining the cellular response to proton beam therapy, and majorly used by Dr Jason Parsons and his research team. This research laboratory, and indeed the proton beam facility itself, are currently the only facilities available in the UK for studying the effects of protons on cancer cells and crucial for the increased future use of proton beam therapy for cancer treatment. Also published research in three peer-reviewed manuscripts (PMID: 29413288; PMID: 30851349, PMID: 34277417). |
| Start Year | 2014 |
| Description | Collaboration with Karolinska Institute |
| Organisation | Karolinska Institute |
| Department | Department of Oncology-Pathology |
| Country | Sweden |
| Sector | Academic/University |
| PI Contribution | A collaboration has been established with Prof Thomas Helleday at the Karolinska Institute, Sweden regarding the role of the 8-oxoguanine DNA glycosylase (OGG1) in controlling the radiosensitivity of tumour cells. We've have had regular contact with Prof Helleday to develop research investigating OGG1 inhibitors as novel sensitizers of 2D and 3D models of head and neck cancers and glioblastoma following different radiotherapy types (photons, protons and high linear energy transfer radiation). |
| Collaborator Contribution | Our partner, Prof Helleday, is an expert in developing novel inhibitors, particularly those targeting DNA damage and repair, for translational research. He has provided us with specific OGG1 inhibitors/activators for our radiobiology research, and given intellectual support into our studies investigating OGG1 inhibition in combination with different radiotherapy sources on 2D and 3D tumour cell models. |
| Impact | No outputs or outcomes have yet resulted. |
| Start Year | 2020 |
| Description | Collaboration with University of Birmingham |
| Organisation | University of Birmingham |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | My postdoctoral research scientist (Dr Jonathan Hughes) employed on the STFC grant had regular visits to the University of Birmingham, UK in order to discuss with colleagues there about establishment of radiobiology facilities in association with the Birmingham cyclotron. These were to be specifically designed to enable the progress of ultra-high dose rate (FLASH) proton radiobiology research. Myself and Dr Hughes also had regular contact and discussions with our collaborators, including Prof Stuart Green, Prof Tzany Kokalova-Wheldon, Dr Tony Price and Dr Ben Phoenix, to discuss the effective development of the facilities and of the associated research. |
| Collaborator Contribution | Our partners, led by Prof Stuart Green, Prof Tzany Kokalova-Wheldon, Dr Tony Price and Dr Ben Phoenix, assisted in access to the Birmingham cyclotron for FLASH proton irradiation, but also providing space for us to build and establish radiobiology facilities on site. Our collaborators have also been actively involved in the discussion of experimental setup for proton irradiations, and to plan the future direction of the work.. |
| Impact | No outputs or outcomes have resulted as yet. |
| Start Year | 2019 |
| Description | Collaboration with University of Oxford |
| Organisation | University of Oxford |
| Department | Department of Oncology |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | My postdoctoral research scientist (Dr Rachel Carter) employed on the MRC Award had regular visits to the CRUK/MRC Oxford Institute for Radiation Oncology, University of Oxford, UK in order to perform irradiation experiments (using high-LET alpha particles) in collaboration with Dr Mark Hill. Myself and Dr Carter also had regular contact and discussions with our collaborators, including both Dr Mark Hill and Prof Peter O'Neill, which also involved Institute visits every 6 months to discuss the effective progress of the research. |
| Collaborator Contribution | Our partners, led by Dr Mark Hill and his Postdoctoral Research Scientist Dr Jamie Thompson, assist in the dosimetry and delivery of alpha particle irradiation to cells using their laboratory facilities. Prof Peter O'Neill has been advising on design of irradiation studies, as well as on in vitro biochemical experiments using mononucleosome substrates. Both were also actively involved in the evaluation and discussion of results, and to plan the future direction of the work.. |
| Impact | Published research in three peer-reviewed manuscripts (PMID: 29413288; PMID: 30851349, PMID: 34277417). Also published one expert review (PMID: 36902352). |
| Start Year | 2014 |
| Description | Collaboration with University of Sheffield |
| Organisation | University of Sheffield |
| Department | Sheffield Medical School |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | A collaboration has been established with Dr Helen Bryant at the University of Sheffield, UK regarding collaborative research into poly(ADP-ribose) glycohydrolase (PARG) as a therapeutic target in cancer cells. We've have had regular contact and discussions with Dr Bryant to examine the combination of PARG inhibitors with ionising radiation (photons and protons) in the effective treatment of head and neck and glioblastoma cell models. We've also established work examining the impact of different ionising radiation sources on the efficiency of DNA replication. |
| Collaborator Contribution | Our partner, Dr Bryant, is head of the DNA replication and repair research group in Sheffield, and has significant experience in examining DNA replication and in the development of potent PARG inhibitors. She has provided us with PARG inhibitors for our radiobiology research, and given significant intellectual support into PARG inhibition and studies to investigate DNA replication rates post-ionising radiation in tumour cell models. |
| Impact | No outputs or outcomes have yet resulted. |
| Start Year | 2019 |
| Description | Invited seminar speaker |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | Local |
| Primary Audience | Other audiences |
| Results and Impact | Invited seminar speaker at the Institute of Cancer and Genomic Sciences, University of Birmingham, Birmingham, UK. The seminar covered the radiobiology of proton beam therapy in head and neck cancer models, but also strategies to optimise radiation-induced tumour cell killing through targeting the DNA damage response that can be translated clinically. |
| Year(s) Of Engagement Activity | 2022 |
| Description | Invited seminar speaker |
| Form Of Engagement Activity | Participation in an activity, workshop or similar |
| Part Of Official Scheme? | No |
| Geographic Reach | National |
| Primary Audience | Other audiences |
| Results and Impact | Invited seminar speaker at the British Institute for Radiology-Practical Radiobiology for modern everyday radiotherapy (virtual). The seminar covered the radiobiology of photons and protons in head and neck tumour cell models, but also our experiences of optimising the radiotherapy response through targeting DNA damage and repair which can be translated for cancer treatment. |
| Year(s) Of Engagement Activity | 2021 |
| URL | https://www.mybir.org.uk/CPBase__event_detail?id=a173Y00000Fol3pQAB&site=a0N2000000COvFsEAL |
| Description | Invited seminar speaker |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | Local |
| Primary Audience | Other audiences |
| Results and Impact | Invited seminar speaker at the Liverpool Cancer Research Institute Scientific Symposium, Liverpool, UK. The seminar covered the radiobiology of proton beam therapy versus photon radiotherapy in head and neck cancer models, but also strategies to optimise radiation-induced tumour cell killing through targeting the DNA damage response that can be translated clinically. |
| Year(s) Of Engagement Activity | 2021 |
| Description | Invited seminar speaker |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | International |
| Primary Audience | Other audiences |
| Results and Impact | Invited seminar speaker at the 68th Annual Meeting of the Radiation Research Society (RRS), Hawaii, USA. The seminar covered the radiobiology of protons and high-LET radiation in head and neck cancer and glioblastoma cell models, but also our ongoing strategies to optimise radiation-induced tumour cell killing through targeting the DNA damage response that can be translated clinically. |
| Year(s) Of Engagement Activity | 2022 |
| URL | https://na.eventscloud.com/website/37917/ |
| Description | Invited seminar speaker |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | Local |
| Primary Audience | Other audiences |
| Results and Impact | Invited seminar speaker at the University of Lancaster, Lancaster, UK. The seminar covered the radiobiology of proton beam therapy in head and neck cancer models, but also strategies to optimise radiation-induced tumour cell killing through targeting the DNA damage response that can be translated clinically. |
| Year(s) Of Engagement Activity | 2022 |
| Description | Invited seminar speaker |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | Regional |
| Primary Audience | Other audiences |
| Results and Impact | Invited seminar speaker at the Institute of Physics-Ultra-high dose rate: Transforming Radiotherapy in a FLASH, London, UK. The seminar covered our research on the the radiobiology of protons versus photons in head and neck tumour cell models and how to optimise the radiotherapy response through targeting DNA damage and repair. This also covered our very preliminary research examining the radiobiology of protons delivered at ultra-high dose rates (FLASH). |
| Year(s) Of Engagement Activity | 2022 |
| URL | https://iop.eventsair.com/udr2022 |