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1. Supplementary Figures 1 - 6 from BRCA1 Deficiency Exacerbates Estrogen-Induced DNA Damage and Genomic Instability

Author

D. Paul Harkin, Christopher T. Elliott, Derek J. Richard, Manuel Salto-Tellez, Stuart A. McIntosh, Kevin M. Prise, Ben Ho Park, Simon S. McDade, Lorenzo Manti, Alexander Powell, Angelina F. Madden, Joy N. Kavanagh, Jekaterina Vohhodina, Katy S. Orr, Julia J. Gorski, Gareth W. Irwin, Kevin M. Cooper, Eliana M. Barros, Kyle B. Matchett, and Kienan I. Savage

Abstract

PDF file - 2823K, Supplementary Figure 1. Estrogen metabolites cause DNA double strand breaks in S- phase cells. Supplementary Figure 2. BRCA1 supresses estrogen metabolite mediated DSBs and is required for their repair. Supplementary Figure 3. Estrogen and its metabolites induce DNA DSBs in a dose and time dependent manner. Supplementary Figure 4. BRCA1 suppresses estrogen metabolites induced DNA damage in BRCA1 mutant breast cancer cells. Supplementary Figure 5. BRCA1 and BRCA2 are required for repair of estrogen metabolite induced DSBs in MCF10A and MCF7 breast cells. Supplementary Figure 6. BRCA1, but not BRCA2, suppresses estrogen metabolite mediated DNA damage by repressing CYP1A1 expression in breast cells.

Published
2023

2. Supplementary Methods from BRCA1 Deficiency Exacerbates Estrogen-Induced DNA Damage and Genomic Instability

Author

D. Paul Harkin, Christopher T. Elliott, Derek J. Richard, Manuel Salto-Tellez, Stuart A. McIntosh, Kevin M. Prise, Ben Ho Park, Simon S. McDade, Lorenzo Manti, Alexander Powell, Angelina F. Madden, Joy N. Kavanagh, Jekaterina Vohhodina, Katy S. Orr, Julia J. Gorski, Gareth W. Irwin, Kevin M. Cooper, Eliana M. Barros, Kyle B. Matchett, and Kienan I. Savage

Abstract

PDF file - 124K

Published
2023

3. Data from BRCA1 Deficiency Exacerbates Estrogen-Induced DNA Damage and Genomic Instability

Author

D. Paul Harkin, Christopher T. Elliott, Derek J. Richard, Manuel Salto-Tellez, Stuart A. McIntosh, Kevin M. Prise, Ben Ho Park, Simon S. McDade, Lorenzo Manti, Alexander Powell, Angelina F. Madden, Joy N. Kavanagh, Jekaterina Vohhodina, Katy S. Orr, Julia J. Gorski, Gareth W. Irwin, Kevin M. Cooper, Eliana M. Barros, Kyle B. Matchett, and Kienan I. Savage

Abstract

Germline mutations in BRCA1 predispose carriers to a high incidence of breast and ovarian cancers. BRCA1 functions to maintain genomic stability through critical roles in DNA repair, cell-cycle arrest, and transcriptional control. A major question has been why BRCA1 loss or mutation leads to tumors mainly in estrogen-regulated tissues, given that BRCA1 has essential functions in all cell types. Here, we report that estrogen and estrogen metabolites can cause DNA double-strand breaks (DSB) in estrogen receptor-α–negative breast cells and that BRCA1 is required to repair these DSBs to prevent metabolite-induced genomic instability. We found that BRCA1 also regulates estrogen metabolism and metabolite-mediated DNA damage by repressing the transcription of estrogen-metabolizing enzymes, such as CYP1A1, in breast cells. Finally, we used a knock-in human cell model with a heterozygous BRCA1 pathogenic mutation to show how BRCA1 haploinsufficiency affects these processes. Our findings provide pivotal new insights into why BRCA1 mutation drives the formation of tumors in estrogen-regulated tissues, despite the general role of BRCA1 in DNA repair in all cell types. Cancer Res; 74(10); 2773–84. ©2014 AACR.

Published
2023

4. Supplementary Figure Legends from BRCA1 Deficiency Exacerbates Estrogen-Induced DNA Damage and Genomic Instability

Author

D. Paul Harkin, Christopher T. Elliott, Derek J. Richard, Manuel Salto-Tellez, Stuart A. McIntosh, Kevin M. Prise, Ben Ho Park, Simon S. McDade, Lorenzo Manti, Alexander Powell, Angelina F. Madden, Joy N. Kavanagh, Jekaterina Vohhodina, Katy S. Orr, Julia J. Gorski, Gareth W. Irwin, Kevin M. Cooper, Eliana M. Barros, Kyle B. Matchett, and Kienan I. Savage

Abstract

PDF file - 75K

Published
2023

5. Radiation responses of stem cells: targeted and not-targeted effects

Author

Joy N. Kavanagh, Kevin M. Prise, and E. J. Waring

Subjects
Genome instability, Radiation, Radiological and Ultrasound Technology, medicine.medical_treatment, Stem Cells, Public Health, Environmental and Occupational Health, General Medicine, Bystander Effect, Biology, medicine.disease_cause, Phenotype, Radiation Tolerance, Genomic Instability, Cell biology, Radiation therapy, Haematopoiesis, Cell Transformation, Neoplastic, Cancer stem cell, medicine, Bystander effect, Humans, Radiology, Nuclear Medicine and imaging, Stem cell, Carcinogenesis, DNA Damage
Abstract

Stem cells are fundamental to the development of any tissue or organism via their ability to self-renew, which is aided by their unlimited proliferative capacity and their ability to produce fully differentiated offspring, often from multiple lineages. Stems cells are long lived and have the potential to accumulate mutations, including in response to radiation exposure. It is thought that stem cells have the potential to be induced into a cancer stem cell phenotype and that these may play an important role in resistance to radiotherapy. For radiation-induced carcinogenesis, the role of targeted and non-targeted effects is unclear with tissue or origin being important. Studies of genomic instability and bystander responses have shown consistent effects in haematopoietic models. Several models of radiation have predicted that stem cells play an important role in tumour initiation and that bystander responses could play a role in proliferation and self-renewal.

Published
2015

6. Low dose effects of ionizing radiation on normal tissue stem cells

Author

Kevin M. Prise, Katrin Manda, Dajana Buttler, Guido Hildebrandt, and Joy N. Kavanagh

Subjects
Senescence, INDUCED GENOMIC INSTABILITY, Carcinogenesis, Health, Toxicology and Mutagenesis, Cellular differentiation, Biology, medicine.disease_cause, DOUBLE-STRAND BREAKS, HOMOLOGOUS RECOMBINATION, Ionizing radiation, BONE-MARROW INJURY, SDG 3 - Good Health and Well-being, HUMAN FIBROBLASTS, Genetics, medicine, Normal stem cells, MESENCHYMAL TRANSITION, NITRIC-OXIDE, CANCER PROGRESSION, Cancer, IN-VITRO, Cell cycle, medicine.disease, In vitro, Low dose, HEMATOPOIETIC STEM, Immunology, Cancer research, Irradiation, Stem cell
Abstract

In recent years, there has been growing evidence for the involvement of stem cells in cancer initiation. As a result of their long life span, stem cells may have an increased propensity to accumulate genetic damage relative to differentiated cells. Therefore, stem cells of normal tissues may be important targets for radiation-induced carcinogenesis.Knowledge of the effects of ionizing radiation (IR) on normal stem cells and on the processes involved in carcinogenesis is very limited. The influence of high doses of IR (>5 Gy) on proliferation, cell cycle and induction of senescence has been demonstrated in stem cells. There have been limited studies of the effects of moderate (0.5–5 Gy) and low doses (This review will provide an overview of the current knowledge of radiation-induced effects on normal stem cells, with particular focus on low and moderate doses of IR.

Published
2014

7. Relative biological effectiveness variation along monoenergetic and modulated Bragg peaks of a 62-MeV therapeutic proton beam: A preclinical assessment

Author

Francesco Romano, Joy N. Kavanagh, Frederick Currell, Lorenzo Manti, Kevin M. Prise, Pankaj Chaudhary, F. Hanton, G.A.P. Cirrone, F. M. Perozziello, Giuseppe Schettino, Thomas I. Marshall, Stephen J. McMahon, Chaudhary, P, Marshall, Ti, Perozziello, Francesca Margaret, Manti, Lorenzo, Currell, Fj, Hanton, F, Mcmahon, Sj, Kavanagh, Jn, Cirrone, Gap, Romano, F, Prise, Km, and Schettino, G.

Subjects
Cancer Research, Cell Survival, Physics::Medical Physics, Sobp, Linear energy transfer, Particle therapy, Bragg peak, Radiation Tolerance, Ionizing radiation, Cell Line, Tumor, Relative biological effectiveness, Proton Therapy, Dosimetry, Medicine, Humans, Radiology, Nuclear Medicine and imaging, Linear Energy Transfer, Proton therapy, Radiation, business.industry, Glioma, Cyclotrons, Fibroblasts, Computational physics, CARBON-ION-BEAMS, Cell killing, Oncology, adverse effects, Relative Biological Effectiveness, Protons, Nuclear medicine, business, Relative Biological Effectiveness
Abstract

Purpose The biological optimization of proton therapy can be achieved only through a detailed evaluation of relative biological effectiveness (RBE) variations along the full range of the Bragg curve. The clinically used RBE value of 1.1 represents a broad average, which disregards the steep rise of linear energy transfer (LET) at the distal end of the spread-out Bragg peak (SOBP). With particular attention to the key endpoint of cell survival, our work presents a comparative investigation of cell killing RBE variations along monoenergetic (pristine) and modulated (SOBP) beams using human normal and radioresistant cells with the aim to investigate the RBE dependence on LET and intrinsic radiosensitvity. Methods and Materials Human fibroblasts (AG01522) and glioma (U87) cells were irradiated at 6 depth positions along pristine and modulated 62-MeV proton beams at the INFN-LNS (Catania, Italy). Cell killing RBE variations were measured using standard clonogenic assays and were further validated using Monte Carlo simulations and the local effect model (LEM). Results We observed significant cell killing RBE variations along the proton beam path, particularly in the distal region showing strong dose dependence. Experimental RBE values were in excellent agreement with the LEM predicted values, indicating dose-averaged LET as a suitable predictor of proton biological effectiveness. Data were also used to validate a parameterized RBE model. Conclusions The predicted biological dose delivered to a tumor region, based on the variable RBE inferred from the data, varies significantly with respect to the clinically used constant RBE of 1.1. The significant RBE increase at the distal end suggests also a potential to enhance optimization of treatment modalities such as LET painting of hypoxic tumors. The study highlights the limitation of adoption of a constant RBE for proton therapy and suggests approaches for fast implementation of RBE models in treatment planning.

Published
2014

8. Radiobiology at ultra-high dose rates employing laser-driven ions

Author

Marco Borghesi, K. F. Kakolee, Satyabrata Kar, Karen J. Kirkby, F. Hanton, D. Kirby, Michael J. Merchant, Joy N. Kavanagh, Kevin M. Prise, Giuseppe Schettino, Rajendra Prasad, M. Zpef, F. Fiorini, S. K. Litt, Ciaran Lewis, Hamad Ahmed, Stuart Green, Domenico Doria, J. C. G. Jeynes, and Gagik Nersisyan

Subjects
Range (particle radiation), Materials science, Proton, law, Relative biological effectiveness, Particle accelerator, Irradiation, Atomic physics, Laser, Proton therapy, Ion, law.invention
Abstract

The potential that laser based particle accelerators offer to solve sizing and cost issues arising with conventional proton therapy has generated great interest in the understanding and development of laser ion acceleration, and in investigating the radiobiological effects induced by laser accelerated ions. Laser-driven ions are produced in bursts of ultra-short duration resulting in ultra-high dose rates, and an investigation at Queen's University Belfast was carried out to investigate this virtually unexplored regime of cell rdaiobiology. This employed the TARANIS terawatt laser producing protons in the MeV range for proton irradiation, with dose rates exceeding 109 Gys-1 on a single exposure. A clonogenic assay was implemented to analyse the biological effect of proton irradiation on V79 cells, which, when compared to data obtained with the same cell line irradiated with conventionally accelerated protons, was found to show no significant difference. A Relative Biological effectiveness of 1.4±0.2 at 10 % Survival Fraction was estimated from a comparison with a 225 kVp X-ray source. © 2013 SPIE.

Published
2013

9. Antiproton induced DNA damage: proton like in flight, carbon-ion like near rest

Author

Frederick Currell, Michael H. Holzscheiter, Kienan I. Savage, Kevin M. Prise, Fabrizio Romano, G.A.P. Cirrone, Derek J. Richard, Giuseppe Schettino, David J. Timson, Oliver Hartley, Joy N. Kavanagh, Niels Bassler, and Stephen J. McMahon

Subjects
Proton, Cell Survival, Physics::Medical Physics, Sobp, Bragg peak, ddc:616.07, Article, 030218 nuclear medicine & medical imaging, Ion, Nuclear physics, 03 medical and health sciences, 0302 clinical medicine, SDG 3 - Good Health and Well-being, Relative biological effectiveness, Humans, Irradiation, Nuclear Experiment, General, Cells, Cultured, Ions, Carbon/chemistry/pharmacology, Physics, Multidisciplinary, Annihilation, Radiotherapy, business.industry, X-Rays, Ions/pharmacology, Cell Survival/radiation effects, Radiotherapy Dosage, Carbon, Radiotherapy/methods, Antiproton, 030220 oncology & carcinogenesis, ddc:000, Physics::Accelerator Physics, Protons, Nuclear medicine, business, Relative Biological Effectiveness, DNA Damage
Abstract

Biological validation of new radiotherapy modalities is essential to understand their therapeutic potential. Antiprotons have been proposed for cancer therapy due to enhanced dose deposition provided by antiproton-nucleon annihilation. We assessed cellular DNA damage and relative biological effectiveness (RBE) of a clinically relevant antiproton beam. Despite a modest LET (~19 keV/μm), antiproton spread out Bragg peak (SOBP) irradiation caused significant residual γ-H2AX foci compared to X-ray, proton and antiproton plateau irradiation. RBE of ~1.48 in the SOBP and ~1 in the plateau were measured and used for a qualitative effective dose curve comparison with proton and carbon-ions. Foci in the antiproton SOBP were larger and more structured compared to X-rays, protons and carbon-ions. This is likely due to overlapping particle tracks near the annihilation vertex, creating spatially correlated DNA lesions. No biological effects were observed at 28–42 mm away from the primary beam suggesting minimal risk from long-range secondary particles.

Published
2013

10. DNA double strand break repair: a radiation perspective

Author

Kevin M. Prise, Kelly M. Redmond, Giuseppe Schettino, and Joy N. Kavanagh

Subjects
DNA Replication, DNA Repair, Physiology, DNA damage, DNA repair, Clinical Biochemistry, Biology, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, SDG 3 - Good Health and Well-being, Neoplasms, Animals, Humans, DNA Breaks, Double-Stranded, Spatiotemporal correlation, Radiation Injuries, Molecular Biology, 030304 developmental biology, General Environmental Science, Genetics, 0303 health sciences, Radiation, DNA replication, Cell Biology, Bystander Effect, Double Strand Break Repair, Cell biology, Oxidative Stress, chemistry, 030220 oncology & carcinogenesis, General Earth and Planetary Sciences, DNA mismatch repair, Homologous recombination, DNA
Abstract

SIGNIFICANCE:Ionizing radiation (IR) can induce a wide range of unique deoxyribonucleic acid (DNA) lesions due to the spatiotemporal correlation of the ionization produced. Of these, DNA double strand breaks (DSBs) play a key role. Complex mechanisms and sophisticated pathways are available within cells to restore the integrity and sequence of the damaged DNA molecules.RECENT ADVANCES:Here we review the main aspects of the DNA DSB repair mechanisms with emphasis on the molecular pathways, radiation-induced lesions, and their significance for cellular processes.CRITICAL ISSUES:Although the main characteristics and proteins involved in the two DNA DSB repair processes present in eukaryotic cells (homologous recombination and nonhomologous end-joining) are reasonably well established, there are still uncertainties regarding the primary sensing event and their dependency on the complexity, location, and time of the damage. Interactions and overlaps between the different pathways play a critical role in defining the repair efficiency and determining the cellular functional behavior due to unrepaired/miss-repaired DNA lesions. The repair pathways involved in repairing lesions induced by soluble factors released from directly irradiated cells may also differ from the established response mechanisms.FUTURE DIRECTIONS:An improved understanding of the molecular pathways involved in sensing and repairing damaged DNA molecules and the role of DSBs is crucial for the development of novel classes of drugs to treat human diseases and to exploit characteristics of IR and alterations in tumor cells for successful radiotherapy applications.

Published
2013

11. Abstract 404: Development of a RSPO3 CLIA-validated assay as a predictive biomarker for response to anti-RSPO3 antibody treatment in patients with solid tumors

Author

Edwina Dobbin, Leonardo Faoro, Marcus Fischer, Belinda Cancilla, Pete Yeung, Ann M. Kapoun, Fiore Cattaruzza, Cheryl McFarlane, John Lewicki, Min Wang, Wan-Ching Yen, Joy N. Kavanagh, Chun Zhang, Tim Hoey, Gilbert O'Young, Michelle McCarthy, Yu-Wang Liu, Jennifer Cain, and Austin L. Gurney

Subjects
Cancer Research, RSPO3, Microarray, biology, business.industry, Colorectal cancer, Cancer, medicine.disease, Oncology, Immunology, Cancer research, FOLFIRI, biology.protein, Medicine, In patient, Antibody, business, Predictive biomarker
Abstract

R-Spondin (RSPO) proteins bind to LGR receptors and potentiate Wnt/β-catenin signaling. We have identified a therapeutic anti-RSPO3 antibody targeting the RSPO-LGR pathway. In preclinical studies, RSPO3 gene expression has shown correlation with anti-RSPO3 antibody efficacy in multiple solid tumor types. A qPCR-based RSPO3 assay has been developed as a predictive biomarker for response to the anti-RSPO3 antibody. In addition, RSPO gene fusions may play a role in the activation of Wnt signaling. A gene fusion detection workflow consisting of a RSPO3 CLIA assay, a RSPO3 RUO assay and next generation sequencing (NGS) has also been developed. We designed 6 qPCR-based assays for the RSPO3 CLIA assay development and 2 assays for the RUO assay. These assays were designed to span exon-exon junctions or target microarray probe set sequences. Amplification sensitivity and specificity were assessed for assay selection. The analytic performance of the candidate RSPO3 CLIA assay and quality control measures were established in a validation study. The validation study included: 1) performance specifications of the RSPO3 assay including analytical sensitivity, linearity, and precision, 2) determination of a reportable range, 3) establishment of a cut-off for the RSPO3 CLIA assay for patient selection, and 4) establishment of quality control procedures. 104 human cancer tissues and 24 independent patient-derived tumor xenografts (PDX) were used in these studies. To evaluate the fusion detection workflow, the RUO assay was performed on samples that tested above the CLIA assay cut-off. The delta Ct difference between the CLIA and RUO assays was calculated to identify potential fusions. The limit of quantification was established for the RSPO3 CLIA assay. The 95% reference interval was estimated to be (-2.44, 16.02) with 90% confidence interval for the lower bound (-3.45, -2.12) and upper bound (15.26, 16.57). The delta Ct cut-off for the RSPO3 CLIA assay was set based on sensitivity, specificity and prevalence. No statistically significant difference in the total variance across the tested samples was observed. A549 and OV56 were identified to be cell line controls with established acceptable delta Ct limits. Using NGS, RSPO3 fusions were identified in 6 PDX tumors with delta Ct RUO - delta Ct CLIA>7, including a novel fusion. This cut-off was further refined with NGS of 9 clinical samples. Prevalence of the RSPO3 expression and fusions will be presented. A qPCR based RSPO3 assay was developed and CLIA-validated for use as a potential predictive biomarker for response to anti-RSPO3 therapy. This RSPO3 CLIA assay, together with the fusion detection workflow, will be evaluated in a Phase 1a/b dose escalation study of anti-RSPO3 (OMP-131R10) in advanced solid tumors and in combination with FOLFIRI in metastatic colorectal cancer (NCT02482441). Citation Format: Chun Zhang, Yuwang Liu, Min Wang, Gilbert OYoung, Joy Kavanagh, Cheryl McFarlane, Fiore Cattaruzza, Pete Yeung, Jennifer Cain, Wan-Ching Yen, Marcus Fischer, Belinda Cancilla, Edwina Dobbin, Michelle McCarthy, Austin Gurney, Leonardo Faoro, John Lewicki, Tim Hoey, Ann M. Kapoun. Development of a RSPO3 CLIA-validated assay as a predictive biomarker for response to anti-RSPO3 antibody treatment in patients with solid tumors. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 404.

Published
2016

12. Biological cell irradiation at ultrahigh dose rate employing laser driven protons

Author

Gagik Nersisyan, Kevin M. Prise, Joy N. Kavanagh, S. K. Litt, Jc. G. Jeynes, Marco Borghesi, Hamad Ahmed, K. F. Kakolee, Karen J. Kirkby, D. Kirby, Ciaran Lewis, R. Prasad, F. Fiorini, Michael J. Merchant, Matthew Zepf, Stuart Green, Satyabrata Kar, Giuseppe Schettino, and Domenico Doria

Subjects
Radiobiology, Proton, law, Chemistry, Radiochemistry, Relative biological effectiveness, Dosimetry, Irradiation, Clonogenic assay, Laser, Ion, law.invention
Abstract

The ultrashort duration of laser-driven multi-MeV ion bursts offers the possibility of radiobiological studies at extremely high dose rates. Employing the TARANIS Terawatt laser at Queen's University, the effect of proton irradiation at MeV-range energies on live cells has been investigated at dose rates exceeding 109Gy/s as a single exposure. A clonogenic assay showed consistent lethal effects on V-79 live cells, which, even at these dose rates, appear to be in line with previously published results employing conventional sources. A Relative Biological Effectiveness (RBE) of 1.4±0.2 at 10% survival is estimated from a comparison with a 225 kVp X-ray source.

Published
2012

14. 161: RBE and DNA damage variation along monoenergetic and modulated Bragg peaks of a 62 MeV therapeutic protons beam

Author

Giuseppe Schettino, G.A.P. Cirrone, Stephen J. McMahon, Kevin M. Prise, Lorenzo Manti, Frederick Currell, Thomas I. Marshall, Pankaj Chaudhary, Joy N. Kavanagh, Fabrizio Romano, and F. M. Perozziello

Subjects
Materials science, Oncology, DNA damage, Radiology, Nuclear Medicine and imaging, Hematology, Atomic physics, Variation (astronomy), Beam (structure)
Published
2014

15. Abstract P5-03-14: Low dose ionising radiation effects in normal breast progenitor sub-populations

Author

Kevin M. Prise, Joy N. Kavanagh, Gareth Irwin, and A Kissenpfennig

Subjects
Cancer Research, Pathology, medicine.medical_specialty, Cluster of differentiation, DNA repair, Cellular differentiation, Biology, Cell sorting, Stem cell marker, medicine.disease_cause, Oncology, Cell culture, Cancer research, medicine, Progenitor cell, skin and connective tissue diseases, Carcinogenesis
Abstract

The human breast is a radiosensitive tissue and radiation exposure is proposed to contribute to mammary gland carcinogenesis through changes to stem and progenitor cells that result in aberrant proliferation, differentiation and genome instability. However, little is known about the low dose radiation response (LD IR) under conditions of relevance to environmental and occupational and medical imaging exposures. This study utilises 2-D and 3-D breast models derived from two normal breast cell lines (MCF10A and HME1) and primary human mammary epithelial cells from reduction mammoplasty surgery, to investigate the mechanisms underpinning sensitivity of normal breast to LD IR and elucidate its role in breast cancer initiation and progression. We have shown that DNA damage can be detected in both cell lines after doses Using antibodies to cell surface markers suggested to be putative breast stem cell markers, we have performed Fluoresence Activated Cell Sorting (FACS) to isolate subpopulations from the MCF10A cell line. CD49fhi, EpCAM-, MUC1- cells thought to be progenitor like cells were found to be more resistant to LD IR than the EpCAM+, MUC1+ population. As the pathways that govern survival/proliferation of stem and progenitor cells versus differentiation are interconnected, we have investigated if radiation resistance is also correlated with changes to breast cell differentiation. It was observed that LD IR modulated breast cell lineage markers in 2D cultures of both cell lines. We subsequently found that radiation induces a decrease in MUC1 mRNA expression levels which coincides with increased Lef1 expression. Lef1 has been shown to promote Mre11 expression thereby conferring elevated DNA repair and radiation resistance in tumour cells. Based on our findings, we hypothesize that progenitor cell populations within normal breast cell lines may be more efficient at detecting DNA DSBs resulting from LD IR leading to a pro-survival response. We are currently investigating these effects in primary mammary epithelial cell samples, using FACS to isolate progenitor subpopulations. Citation Information: Cancer Res 2013;73(24 Suppl): Abstract nr P5-03-14.

Published
2013

16. Development of a low-energy particle irradiation facility for the study of the biological effectiveness of the ion track end

Author

L. Campajola, Giuseppe Schettino, Lorenzo Manti, Joy N. Kavanagh, F. M. Perozziello, Manti, Lorenzo, Campajola, Luigi, Perozziello, Francesca Margaret, Kavanagh, Jn, and Schettino, G.

Subjects
Physics, History, Low-energy particle, Physics::Medical Physics, Sobp, Linear energy transfer, Bragg peak, Normal tissue long-term effects, Radiation, Charged particle, Computer Science Applications, Education, Ion track, Nuclear physics, Hadron therapy, Relative biological effectiveness, Physics::Accelerator Physics, Irradiation, Atomic physics, Particle radiation
Abstract

Uncertainties surround the radiobiological consequences of exposure to charged particles, despite the increasing use of accelerated ion beams for cancer treatment (hadrontherapy). In particular, little is known about the long-term effects on normal tissue at the beam entrance or in the distal part of the Spread-Out Bragg Peak (SOBP). Moreover, although the relative biological effectiveness (RBE) of particle radiation has been traditionally related to the radiation linear energy transfer (LET), it has become increasingly evident that radiation-induced cell death, as well as long term radiation effects, is not adequately described by this parameter. Hence, exploring the effectiveness of various ion beams at or around the Bragg peak of monoenergetic ion beams can prove useful to gain insights into the role played by parameters other than the particle LET in determining the outcome of particle radiation exposures. In this context, the upgrade of the Tandem irradiation facility at Naples University here described, has allowed us to perform a series of preliminary radiobiological measurements using proton and carbon ion beams. The facility is currently used to irradiate normal and cancer cell lines with ion beams such as oxygen and fluorine.

Published
2012

17. Remarkable stability of ionic gold supported on sulfated lanthanum oxide

Author

Christopher Hardacre, Youssef Saih, Jacinto Sá, Alexandre Goguet, Joy N. Kavanagh, and Matthew Ace

Subjects
Chemistry, Inorganic chemistry, Metals and Alloys, Cationic polymerization, Ionic bonding, General Chemistry, Catalysis, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, Sulfation, Lanthanum oxide, Materials Chemistry, Ceramics and Composites
Abstract

Isolated cationic gold deposited on sulfated lanthanum oxide has been shown to exhibit remarkable stability opening a promising way of stabilising ionic gold for catalytic reactions.

Published
2009

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