Does tirapazamine (SR-4233) have any cytotoxic or sensitizing effect on three human tumour cell lines at clinically relevant partial oxygen pressure?

Targeting Hypoxia: Revival of Old Remedies

Tumour hypoxia is significantly correlated with patient survival and treatment outcomes. At the molecular level, hypoxia is a major driving factor for tumour progression and aggressiveness. Despite the accumulative scientific and clinical efforts to target hypoxia, there is still a need to find specific treatments for tumour hypoxia. In this review, we discuss a variety of approaches to alter the low oxygen tumour microenvironment or hypoxia pathways including carbogen breathing, hyperthermia, hypoxia-activated prodrugs, tumour metabolism and hypoxia-inducible factor (HIF) inhibitors. The recent advances in technology and biological understanding reveal the importance of revisiting old therapeutic regimens and repurposing their uses clinically.

Clinical Advances of Hypoxia-Activated Prodrugs in Combination With Radiation Therapy

With the increasing incidence of cancer worldwide, the need for specific, effective therapies is ever more urgent. One example of targeted cancer therapeutics is hypoxia-activated prodrugs (HAPs), also known as bioreductive prodrugs. These prodrugs are inactive in cells with normal oxygen levels but in hypoxic cells (with low oxygen levels) undergo chemical reduction to the active compound. Hypoxia is a common feature of solid tumors and is associated with a more aggressive phenotype and resistance to all modes of therapy. Therefore, the combination of radiation therapy and bioreductive drugs presents an attractive opportunity for synergistic effects, because the HAP targets the radiation-resistant hypoxic cells. Hypoxia-activated prodrugs have typically been precursors of DNA-damaging agents, but a new generation of molecularly targeted HAPs is emerging. By targeting proteins associated with tumorigenesis and survival, these compounds may result in greater selectivity over healthy tissue. We review the clinical progress of HAPs as adjuncts to radiation therapy and conclude that the use of HAPs alongside radiation is vastly underexplored at the clinical level.

A hybrid cellular automaton model of solid tumor growth and bioreductive drug transport

Bioreductive drugs are a class of hypoxia selective drugs that are designed to eradicate the hypoxic fraction of solid tumors. Their activity depends upon a number of biological and pharmacological factors and we used a mathematical modeling approach to explore the dynamics of tumor growth, infusion, and penetration of the bioreductive drug Tirapazamine (TPZ). An in-silico model is implemented to calculate the tumor mass considering oxygen and glucose as key microenvironmental parameters. The next stage of the model integrated extra cellular matrix (ECM), cell-cell adhesion, and cell movement parameters as growth constraints. The tumor microenvironments strongly influenced tumor morphology and growth rates. Once the growth model was established, a hybrid model was developed to study drug dynamics inside the hypoxic regions of tumors. The model used 10, 50 and 100 \mu {\rm M} as TPZ initial concentrations and determined TPZ pharmacokinetic (PK) (transport) and pharmacodynamics (cytotoxicity) properties inside hypoxic regions of solid tumor. The model results showed that diminished drug transport is a reason for TPZ failure and recommend the optimization of the drug transport properties in the emerging TPZ generations. The modeling approach used in this study is novel and can be a step to explore the behavioral dynamics of TPZ.

Avascular tumour growth dynamics and the constraints of protein binding for drug transportation

The potential for the use of in-silico models of disease in progression monitoring is becoming increasingly recognised, as well as its contribution to the development of complete curative processes. In this paper we report the development of a hybrid cellular automaton model to mimic the growth of avascular tumours, including the infusion of a bioreductive drug to study the effects of protein binding on drug transportation. The growth model is operated within an extracellular tumour microenvironment. An artificial Neural Network based scheme was implemented that modelled the behaviours of each cell (proliferation, quiescence, apoptosis and/or movement) based on the complex heterogeneous microenvironment; consisting of oxygen, glucose, hydrogen ions, inhibitory factors and growth factors. To validate the growth model results, we conducted experiments with multicellular tumour spheroids. These results showed good agreement with the predicted growth dynamics. The outcome of the avascular tumour growth model suggested that tumour microenvironments have a strong impact on cell behaviour. To address the problem of cellular proteins acting as resistive factors preventing efficient drug penetration, a bioreactive drug (tirapazamine) was added to the system. This allowed us to study the drug penetration through multicellular layers of tissue after its binding to cellular proteins. The results of the in vitro model suggested that the proteins reduce the toxicity of the drug, reducing its efficacy for the most severely hypoxic fractions furthest from a functional blood vessel. Finally this research provides a unique comparison of in vitro tumour growth with an intelligent in silico model to measure bioreductive drug availability inside tumour tissue through a set of experiments.

Hypoxia-targeting by tirapazamine (TPZ) induces preferential growth inhibition of nasopharyngeal carcinoma cells with Chk1/2 activation

Hypoxia is commonly developed in solid tumors, which contributes to metastasis as well as radio- and chemo-resistance. Nasopharyngeal carcinoma (NPC) is a highly invasive and metastatic head and neck cancer prevalent in Southeast Asia with a high incidence rate of 15-30/100,000 persons/year (comparable to that of pancreatic cancer in the US). Previous clinical studies in NPC showed that hypoxia is detected in almost 100% of primary tumors and overexpression of hypoxia markers correlated with poor clinical outcome. Tirapazamine (TPZ) is a synthetic hypoxia-activated prodrug, which preferentially forms cytotoxic and DNA-damaging free radicals under hypoxia, thus selectively eradicate hypoxic cells. Here, we hypothesized that specific hypoxia-targeting by this clinical trial agent may be therapeutic for NPC. Our findings demonstrated that under hypoxia, TPZ was able to induce preferential growth inhibition of NPC cells, which was associated with marked cell cycle arrest at S-phase and PARP cleavage (a hallmark of apoptosis). Examination of S-phase checkpoint regulators revealed that Chk1 and Chk2 were selectively activated by TPZ in NPC cells under hypoxia. Hypoxia-selectivity of TPZ was also demonstrated by preferential downregulation of several important hypoxia-induced markers (HIF-1α, CA IX and VEGF) under hypoxia. Furthermore, we demonstrated that TPZ was equally effective and hypoxia-selective even in the presence of the EBV oncoprotein, LMP1 or the EBV genome. In summary, encouraging results from this proof-of-concept study implicate the therapeutic potential of hypoxia-targeting approaches for the treatment of NPC.

The concurrent chemoradiation paradigm—general principles

During the past 20 years, the advent of neoadjuvant, primary, and adjuvant concurrent chemoradiotherapy has improved cancer care dramatically. Significant contributions have been made by technological improvements in radiotherapy, as well as by the introduction of novel chemotherapy agents and dosing schedules. This article will review the rationale for the use of concurrent chemoradiotherapy for treating malignancies. The molecular basis and mechanisms of action of combining classic cytotoxic agents (e.g. platinum-containing drugs, taxanes, etc.) and novel agents (e.g. tirapazamine, EGFR inhibitors and other targeted agents) with radiotherapy will be examined. This article is part one of two articles. In the subsequent article, the general principles outlined here will be applied to head and neck cancer, in which the impact of concurrent chemoradiotherapy is particularly evident.

Tumor-activated prodrugs--a new approach to cancer therapy

Systemic cytotoxic (antiproliferative) anticancer drugs rely primarily for their therapeutic effect on cytokinetic differences between cancer and normal cells. One approach aimed at improving the selectivity of tumor cell killing by such compounds is the use of less toxic prodrug forms that can be selectively activated in tumor tissue (tumor-activated prodrugs; TAP). There are several mechanisms potentially exploitable for the selective activation of TAP. Some utilize unique aspects of tumor physiology such as selective enzyme expression or hypoxia. Others are based on tumor-specific delivery techniques, including activation of prodrugs by exogenous enzymes delivered to tumor cells via monoclonal antibodies (ADEPT) or generated in tumor cells from DNA constructs containing the corresponding gene (GDEPT). Whichever activating mechanism is used, only a small proportion of the tumor cells are likely to be competent to activate the prodrug. Therefore, TAP need to fully exploit these "activator" cells by being capable of killing activation-incompetent cells as well via a "bystander effect." A wide variety of chemistries have been explored for the selective activation of TAP. Examples are given of the most important-the reduction of quinones, N-oxides, and nitroaromatics by endogenous enzymes or radiation; the cleavage of amides by endogenous peptidases; and hydrolytic metabolism by a variety of exogenous enzymes, including phosphatases, kinases, amidases, and glycosidases.

Hypoxia targeted gene therapy to increase the efficacy of tirapazamine as an adjuvant to radiotherapy: reversing tumor radioresistance and effecting cure

Solid tumors are characterized by regions of hypoxia that are inherently resistant to both radiotherapy and some chemotherapy. To target this resistant population, bioreductive drugs that are preferentially toxic to tumor cells in a hypoxic environment are being evaluated in clinical trials; the lead compound, tirapazamine (TPZ), is being used in combination with cisplatin and/or with radiotherapy. Crucially, tumor response to TPZ is also dependent on the cellular complement of reductases. In particular, NADPH:cytochrome P450 reductase (P450R) plays a major role in the metabolic activation of TPZ. In a gene-directed enzyme prodrug therapy (GDEPT) approach using adenoviral delivery, we have overexpressed human P450R specifically within hypoxic cells in tumors, with the aim of harnessing hypoxia as a trigger for both enzyme expression and drug metabolism. The adenovirus used incorporates the hypoxia-responsive element (HRE) from the lactate dehydrogenase gene in a minimal SV40 promoter context upstream of the cDNA for P450R. In a human tumor model in which TPZ alone does not potentiate radiotherapeutic outcome (HT1080 fibrosarcoma), we witnessed complete tumor regression when tumors were virally transduced before treatment.

Tirapazamine: a bioreductive anticancer drug that exploits tumour hypoxia

Tirapazamine is the second clinical anticancer drug (after porfiromycin) that functions primarily as a hypoxia-selective cytotoxin. Hypoxic cells in tumours are relatively resistant to radiotherapy and to some forms of chemotherapy and are also biologically aggressive, thus representing an important target population in oncology. Tirapazamine undergoes metabolism by reductases to form a transient oxidising radical that can be efficiently scavenged by molecular oxygen in normal tissues to re-form the parent compound. In the absence of oxygen, the oxidising radical abstracts a proton from DNA to form DNA radicals, largely at C4' on the ribose ring. Tirapazamine can also oxidise such DNA radicals to cytotoxic DNA strand breaks. It therefore shows substantial selective cytotoxicity for anoxic cells in culture (typically approximately 100-fold more potent than under oxic conditions) and for the hypoxic subfraction of cells in tumours. Preclinical studies showed enhanced activity of combinations of tirapazamine with radiation (to kill oxygenated cells) and with conventional cytotoxics, especially cisplatin (probably through inhibition of repair of cisplatin DNA cross-links in hypoxic cells). Phase II and III clinical studies of tirapazamine and cisplatin in malignant melanoma and non-small cell lung cancer suggest that the combination is more active than cisplatin alone and preliminary results with advanced squamous cell carcinomas of the head and neck indicate that tirapazamine may enhance the activity of cisplatin with fractionated radiotherapy.

[In vitro oxygen-dependent survival of 2 human cell lines after radiation combined with tirapazamine (SR-4233) and cisplatin]

Recent data have shown that the in vitro and in vivo cytotoxicity of bioreductive drugs could be significantly increased by combination with ionising radiation or chemotherapy. Various parameters such as oxygen tension and timing of administration of the drugs could play a crucial role in the efficacy of combined treatment modalities. The aim of this study was to define the oxygen dependency of cell survival after in vitro irradiation and incubation with tirapazamine, a bioreductive drug, and cisplatin given alone or simultaneously. Two human cell lines were studied: one cell line sensitive to tirapazamine, Na11+, a pigmented melanoma with a high percentage of hypoxic cells, and a less sensitive cell line to tirapazamine, HRT18, a rectal adenocarcinoma. Gas changes were made to study cell survival at four different oxygen concentrations (pO2): air (20.9% O2), 10.2 and 0.2% O2. Cells were incubated with tirapazamine and cisplatin alone or combined for one hour at 37 degrees C, then irradiated and cultured. For Na11+, cell survival after irradiation was comparable in air and at 10% oxygen with the two drugs given alone or combined. At 2 and 0.2% oxygen, cell killing was largely increased by tirapazamine and was not modified by the addition of cisplatin. For HRT18, cell survival was not modified when cisplatin was added to radiation, whatever the oxygen partial pressure. At low pO2 (2 and 0.2%) the cytotoxic effect of tirapazamine was not significantly decreased by the addition of cisplatin. When cytotoxic and bioreductive drugs are combined to radiation, the magnitude of the observed effect is highly dependent on the partial oxygen pressure and on the sensitivity of the cell line to the individual drugs. This has very important implications for clinical strategies based on combined chemo-radiotherapy.

[Radiation sensitizing agents for hypoxic cells: past, present and future]

Hypoxic cells are present in rodent and xenografted human tumours and it has been known for a long time that the absence of oxygen in tumours is a factor of resistance against ionising radiation. The dose modifying role of oxygen (oxygen enhancement ratio) has been largely studied in experimental models. For pO2 values of 2 mmHg, the relative radiosensitivity of tumour cells is intermediate between the maximum sensitivity observed in air and the minimal one observed in hypoxia. The measurement of tumour pO2 in patients (polarographic technique) has demonstrated the presence of low values (< 10 mmHg) in many different tumour sites (ENT, uterine cervix, breast, melanoma, etc). In order to sensitise hypoxic tumours, imidazole have been used in patients, but most of the results were negative. New methods have been developed in the combination of bioreductive drugs of cytotoxic cells to radiotherapy. In this article, we will describe the clinical results obtained in patients with radiosensitising chemical agents.

Variations in tumour oxygen tension (pO2) during accelerated radiotherapy of head and neck carcinoma

The study was performed to assess the effect of accelerated radiotherapy on oxygenation of primary tumours and metastatic nodes in patients with advanced head and neck tumours. In 14 patients with head and neck tumour, oxygen tension (pO2) was evaluated in normal tissues and tumours (primary tumour or metastatic neck node) before (0 Gy) and after 2 weeks (32 Gy) of accelerated radiotherapy (70 Gy in 3.5 weeks, with three daily fractions). Radiotherapy was combined with carbogen breathing in 5 patients. pO2 was measured using a polarographic technique. For pooled normal tissues, median pO2 was 38 mmHg before treatment and 46 mmHg after 2 weeks. For tumours, very low values (< 2 mmHg) represented 20% of the recorded values before treatment and 10% after 2 weeks. The relative increase in tumour oxygenation was more pronounced for primary tumours (median pO2 12 mmHg before treatment versus 26 mmHg after 2 weeks, P < 0.05) than for metastatic nodes (respectively, 20 and 27 mmHg P = 0.1). For the 5 patients who breathed carbogen during accelerated radiotherapy, the median pO2 was 44 mmHg at 2 weeks, compared with 13.5 mmHg before treatment (P = 0.05). Very low pO2 values, corresponding to tumour hypoxia, were found in the tumours (primary and metastatic neck nodes) prior to accelerated treatment. During the first 2 weeks of accelerated treatment, an increase in median pO2 was found in nine of the 14 tumours, together with a decrease in the frequency of very low values.

The effect of tirapazamine (SR-4233) alone or combined with chemotherapeutic agents on xenografted human tumours

Recent data have shown that the in vitro and in vivo cytotoxicity of bioreductive drugs could be significantly increased when combined with chemotherapy drugs such as cisplatinum, depending on the timing of administration. The aim of this study was to define the toxicity (animal lethality) and the activity (growth delay assay, excision assay) of a bioreductive drug, tirapazamine, alone and combined with chemotherapy agents (5-FU, VP16, bleo, DTIC and c-DDP) on nude mice bearing xenografted human tumours: a rectal carcinoma (HRT18) and a melanoma (Na11+). Animal lethality was markedly increased when tirapazamine at the lethal dose 10% was combined with the other drugs. For the HRT18 tumour the combination of tirapazamine and bleomycin significantly increased the delay of regrowth compared with bleomycin alone (P = 0.04) and was more cytotoxic than tirapazamine alone (P = 0.04). For the Na11+ tumours the combination of tirapazamine with VP16 significantly increased tumour doubling time compared with the controls (P = 0.001) or VP16 alone. The combination of tirapazamine and VP16 was more cytotoxic than VP16 alone (P = 0.0001). When compared with c-DDP or tirapazamine alone, there was a significant decrease in plating efficiency when tirapazamine and c-DDP were given at the same time (P = 0.04), but not when tirapazamine was given 3 h before c-DDP. In conclusion, tirapazamine was shown to be cytotoxic against clonogenic human tumour cells. Its efficacy in vivo may depend on its combination with already active chemotherapy drugs on the tumour model used. The timing of administration may be less important than previously thought.