Searching for Radiosensitizers: Development of a Novel Assay and High-throughput Screening

Katz, David

24 February 2009

The colony formation assay (CFA) is the gold standard for measuring cytotoxic effects on cells. To increase efficiency, the CFA was converted to a 96-well format using an automated colony counting algorithm. The 96-well CFA was validated using ionizing radiation (IR) on the FaDu and A549 cancer cell lines. Its ability to evaluate combination therapies was investigated using cisplatin and IR. The 96-well CFA was transferred to a robotic platform for evaluation as a high-throughput screen (HTS) readout for the discovery of novel anti-cancer compounds, and radiosensitizers. Screening yielded eight putative anti-cancer hits, and five putative radiosensitizing hits. Secondary screening confirmed 6/8 anti-cancer compounds, and 0/5 radiosensitizing compounds. Thus, the 96-well CFA can be adopted as an alternative assay to the 6-well CFA in the evaluation of cytotoxicity in vitro, providing a possible readout to be utilized in HTS for discovering anti-cancer compounds, but with limited applicability in discovering radiosensitizers.

Radiosensitizer

High-Throughput Screening

Colony Formation Assay

0307

0992

Searching for Radiosensitizers: Development of a Novel Assay and High-throughput Screening

Katz, David

24 February 2009

The colony formation assay (CFA) is the gold standard for measuring cytotoxic effects on cells. To increase efficiency, the CFA was converted to a 96-well format using an automated colony counting algorithm. The 96-well CFA was validated using ionizing radiation (IR) on the FaDu and A549 cancer cell lines. Its ability to evaluate combination therapies was investigated using cisplatin and IR. The 96-well CFA was transferred to a robotic platform for evaluation as a high-throughput screen (HTS) readout for the discovery of novel anti-cancer compounds, and radiosensitizers. Screening yielded eight putative anti-cancer hits, and five putative radiosensitizing hits. Secondary screening confirmed 6/8 anti-cancer compounds, and 0/5 radiosensitizing compounds. Thus, the 96-well CFA can be adopted as an alternative assay to the 6-well CFA in the evaluation of cytotoxicity in vitro, providing a possible readout to be utilized in HTS for discovering anti-cancer compounds, but with limited applicability in discovering radiosensitizers.

Radiosensitizer

High-Throughput Screening

Colony Formation Assay

0307

0992

The Synthesis and Biological Characterization of a Potential Hypoxic Cell Sensitizer

Beickelman, Amy C.

January 2007

No description available.

Health Sciences, Pharmacology

Radiosensitizer

Hypoxia

Radiation

Cancer

AB2

Nitroimidazole

Radiosensitizing glioblastoma in a rat model using l-buthionine-sr-sulfoximine (BSO)

Ataelmannan, Khalid Ali

21 April 2008

Glioblastoma multiforme (GBM) is the most aggressive and most common primary brain tumor in adults accounting for 50-60% of primary brain tumors. The prognosis for patients with GBM remains poor and treatment is mainly palliative with a mean survival time of less than one year. Radiotherapy is used extensively in the management of glioblastoma either alone or in combination with surgery and/or chemotherapy. However, this tumor is one of the most resistant tumors to radiotherapy thus limiting the benefit of this form of treatment. <p>Studies have shown that malignant tumors have a high content of glutathione an antioxidant responsible for protecting the cells against damage from free radicals (mainly superoxide, hydroxyl and hydrogen peroxide). It is well established that glutathione, by neutralizing these free radicals plays a major role in radioresistance. Glioblastoma has relatively high levels of glutathione. In this study, by reducing the glutathione content of glioblastoma in a rat model, we were able to investigate the effect of this reduction in enhancing the effect of radiotherapy as a form of treatment for glioblastoma multiforme in a rat model. <p>By injecting L-Buthionine-SR-Sulfoximine (BSO) in to the tumor tissue, the glutathione content of the tumor was reduced by about 70% of its initial value. When administered into the tumors 2 hours prior to radiotherapy the animals so treated had a significantly longer median survival time compared with animals that received radiotherapy alone.

l-buthionine-sr-sulfoximine

rat

glioblastoma

radiosensitizer

radiotherapy

glutathione

C6 glioma cell line

bso

The MET Receptor Tyrosine Kinase Is a Potential Therapeutic Target in Combination with Radiation in Head and Neck Squamous Cell Carcinoma

Wu, Ronald

23 July 2012

Radioresistance is a major cause of treatment failure and relapse in head and neck squamous cell carcinoma (HNSCC). Novel molecular targets need to be identified to increase cure rates and radiosensitivity in HNSCC. The MET receptor tyrosine kinase is highly dysregulated in cancer and plays a role in tumourigenesis, chemoresistance, and radioresistance. However, the role of MET in HNSCC radioresistance has not yet been investigated and may potentially be a radiosensitizing target. We discovered MET expression and intact ligand-induced signalling in HNSCC cell lines. Small molecule MET kinase inhibitors inhibited ligand-induced MET activation and downstream signalling. These inhibitors decreased HNSCC cell proliferation and clonogenic survival. Similarly, short-interfering RNAs targeting MET also decreased cell proliferation. The combination of radiation with the MET kinase inhibitors decreased clonogenic survival in an additive manner. Cell cycle analyses demonstrated that MET inhibitors alone or in combination with radiation induced small increases in sub-G1 cell populations.

Radiosensitizer

Receptor Tyrosine Kinase

Radiation

MET

Radioresistance

Clonogenic Survival

0992

0760

0307

The MET Receptor Tyrosine Kinase Is a Potential Therapeutic Target in Combination with Radiation in Head and Neck Squamous Cell Carcinoma

Wu, Ronald

23 July 2012

Radioresistance is a major cause of treatment failure and relapse in head and neck squamous cell carcinoma (HNSCC). Novel molecular targets need to be identified to increase cure rates and radiosensitivity in HNSCC. The MET receptor tyrosine kinase is highly dysregulated in cancer and plays a role in tumourigenesis, chemoresistance, and radioresistance. However, the role of MET in HNSCC radioresistance has not yet been investigated and may potentially be a radiosensitizing target. We discovered MET expression and intact ligand-induced signalling in HNSCC cell lines. Small molecule MET kinase inhibitors inhibited ligand-induced MET activation and downstream signalling. These inhibitors decreased HNSCC cell proliferation and clonogenic survival. Similarly, short-interfering RNAs targeting MET also decreased cell proliferation. The combination of radiation with the MET kinase inhibitors decreased clonogenic survival in an additive manner. Cell cycle analyses demonstrated that MET inhibitors alone or in combination with radiation induced small increases in sub-G1 cell populations.

Radiosensitizer

Receptor Tyrosine Kinase

Radiation

MET

Radioresistance

Clonogenic Survival

0992

0760

0307

Radiosensitizing glioblastoma in a rat model using l-buthionine-sr-sulfoximine (BSO)

Ataelmannan, Khalid Ali

21 April 2008

Glioblastoma multiforme (GBM) is the most aggressive and most common primary brain tumor in adults accounting for 50-60% of primary brain tumors. The prognosis for patients with GBM remains poor and treatment is mainly palliative with a mean survival time of less than one year. Radiotherapy is used extensively in the management of glioblastoma either alone or in combination with surgery and/or chemotherapy. However, this tumor is one of the most resistant tumors to radiotherapy thus limiting the benefit of this form of treatment. <p>Studies have shown that malignant tumors have a high content of glutathione an antioxidant responsible for protecting the cells against damage from free radicals (mainly superoxide, hydroxyl and hydrogen peroxide). It is well established that glutathione, by neutralizing these free radicals plays a major role in radioresistance. Glioblastoma has relatively high levels of glutathione. In this study, by reducing the glutathione content of glioblastoma in a rat model, we were able to investigate the effect of this reduction in enhancing the effect of radiotherapy as a form of treatment for glioblastoma multiforme in a rat model. <p>By injecting L-Buthionine-SR-Sulfoximine (BSO) in to the tumor tissue, the glutathione content of the tumor was reduced by about 70% of its initial value. When administered into the tumors 2 hours prior to radiotherapy the animals so treated had a significantly longer median survival time compared with animals that received radiotherapy alone.

l-buthionine-sr-sulfoximine

rat

glioblastoma

radiosensitizer

radiotherapy

glutathione

C6 glioma cell line

bso

New preclinical strategies for characterization and development of anticancer drugs

Karlsson, Henning

January 2017

Increased understanding of the molecular mechanisms underlying cancer development has shifted drug discovery towards target driven drug development the last decades, but the development of effective cancer drugs has been hampered by the lack of predictive preclinical models. 3-D cultures, considered to more accurately reflect solid tumors in vivo, have been proposed as one way to increase the predictability of clinical efficacy in cancer drug discovery and development. The aims of this thesis were to improve preclinical models for cancer drug development, with focus on colorectal cancer (CRC) and use of multicellular tumor spheroids (MCTS), and also to mechanistically characterize some potentially new anticancer drugs (papers I – IV). The most important technical improvement was the development of direct measurement of green fluorescent protein (GFP) marked cells in spheroids, simplifying live collection of viability data and enabling high-throughput screening (HTS) in the MCTS model (paper I). In paper III and IV, the 3-D model was adapted to enable studies on the interaction between drugs and radiation. Two potentially new anticancer drugs, VLX50 and VLX60, were mechanistically characterized. VLX60, a novel copper containing thiosemicarbazone, induced reactive oxygen species (ROS) formation, was selectively active against BRAF mutated colon cancer cells and exhibited anticancer activity in vivo (paper II). Furthermore, two potentially new anticancer drugs were found suitable for further development for use in combination with radiation (papers III and IV). In paper III, synergy with radiation in spheroids compared to monolayer cultured colon cancer cells was shown with the novel iron-chelating inhibitor of oxidative phosphorylation, VLX600. In paper IV, the antiprotozoal drug nitazoxanide was shown to sensitize quiescent clonogenic colon cancer cells to radiation. In conclusion, introduction of measurement of fluorescence of GFP marked cells in spheroids makes clinically relevant 3-D models feasible for HTS experiments and characterization of candidate drugs and radiosensitizers in early cancer drug discovery and development. VLX60 has several characteristics suitable for further development into a cancer drug, notably against BRAF mutated colorectal cancer cells. VLX600 and nitazoxanide show radiosensitizing properties making them promising for further development for use as cancer drugs in combination with radiation.

colorectal cancer

spheroids

green fluorescent protein

VLX50

VLX60

VLX600

nitazoxanide

radiation

radiosensitizer

Cancer and Oncology

Cancer och onkologi

Suramin as a chemo- and radio-sensitizer: preclinical translational studies

Xin, Yan

14 July 2006

No description available.

suramin

chemosensitizer

radiosensitizer

mitomycin C

survivin

paclitaxel

bladder cancer

pancreatic cancer

prostate cancer

head and neck cancer

MOLECULAR RESPONSES OF LUNG CANCER TO IONIZING RADIATION: INVESTIGATION OF THE BIGUANIDE METFORMIN IN COMBINATION WITH IONIZING RADIATION

Storozhuk, Yaryna

10 1900

<p><strong><em>Purpose</em></strong></p> <p>To examine the potential of the anti-diabetic agent Metformin (MET) to enhance responses of NSCLC to ionizing radiation (IR).</p> <p><strong><em>Experimental Design</em></strong></p> <p>Human NSCLC A549, H1299 and SK-MES cells were treated with IR, MET or the mTOR inhibitor rapamycin and subjected to proliferation, clonogenic, immunoblotting, cell cycle and apoptosis assays. A549 and H1299 cells were grafted into flanks of immunosuppressed mice and treated with MET and/or IR. Tumours were analyzed by immunoblotting and immunohistochemistry.</p> <p><strong><em>Results</em></strong></p> <p>MET(2.5uM-5mM) caused dose-dependent inhibition of proliferation (10-70%)in all lines, inibited clonogenic survival and sensitized cells to IR. In A549 cellsMET caused inhibition of proliferation comparable to rapamycin, stimulated expression and activation of the ATM and AMPK-p53-p21^cip1and inhibited the Akt-mTOR-4-EBP1 pathway.MET caused G1 arrest of cell cycle, enhanced apoptosis and induced sustained DNA repair foci of gH2AX. MET and IR alone inhibited xenograft growth and combined treatment enhanced that further. IR and MET induced sustained enhancement of expression and activity of ATM-AMPK-p53-p21^cip1and inhibitionof Akt-mTOR-4-EBP1 pathways in tumours also. MET reduced expression of angiogenesis and enhanced expression of apoptosis markers in both control and radiated tumours.</p> <p><strong><em>Conclusions</em></strong></p> <p>Clinically achievable(uM) doses ofMET inhibit human NSCLC cell and tumour growth and sensitize them to IR.This is accompanied by desirable modulation of molecular signals, inhibition of angiogenesis and induction of apoptosis. Our results suggest that MET could be a clinically useful adjunct to radiotherapy in NSCLC and support clinical investigation of MET in combination with radiotherapy.</p> / Master of Science (MSc)

AMPK

cancer

ionizing radiation

radiosensitizer

metformin

lung cancer

Medical Molecular Biology

Medical Molecular Biology