Alexandra M. Mowday

Molecular and cellular pharmacology of the hypoxia-activated prodrug TH-302

TH-302 is a 2-nitroimidazole triggered hypoxia-activated prodrug (HAP) of bromo-isophosphoramide mustard currently undergoing clinical evaluation. Here, we describe broad-spectrum activity, hypoxia-selective activation, and mechanism of action of TH-302. The concentration and time dependence of TH-302 activation was examined as a function of oxygen concentration, with reference to the prototypic HAP tirapazamine, and showed superior oxygen inhibition of cytotoxicity and much improved dose potency relative to tirapazamine. Enhanced TH-302 cytotoxicity under hypoxia was observed across 32 human cancer cell lines. One-electron reductive enzyme dependence was confirmed using cells overexpressing human NADPH:cytochrome P450 oxidoreductase and radiolytic reduction established the single-electron stoichiometry of TH-302 fragmentation (activation). Examining downstream effects of TH-302 activity, we observed hypoxia-dependent induction of γH2AX phosphorylation, DNA cross-linking, and cell-cycle arrest. We used Chinese hamster ovary cell–based DNA repair mutant cell lines and established that lines deficient in homology-dependent repair, but not lines deficient in base excision, nucleotide excision, or nonhomologous end-joining repair, exhibited marked sensitivity to TH-302 under hypoxia. Consistent with this finding, enhanced sensitivity to TH-302 was also observed in lines deficient in BRCA1, BRCA2, and FANCA. Finally, we characterized TH-302 activity in the three-dimensional tumor spheroid and multicellular layer models. TH-302 showed much enhanced potency in H460 spheroids compared with H460 monolayer cells under normoxia. Multicellular layers composed of mixtures of parental HCT116 cells and HCT116 cells engineered to express an oxygen-insensitive bacterial nitroreductase showed that TH-302 exhibits a significant bystander effect. Mol Cancer Ther; 11(3); 740–51. ©2011 AACR.

Bioreductive prodrugs as cancer therapeutics: targeting tumor hypoxia

Hypoxia, a state of low oxygen, is a common feature of solid tumors and is associated with disease progression as well as resistance to radiotherapy and certain chemotherapeutic drugs. Hypoxic regions in tumors, therefore, represent attractive targets for cancer therapy. To date, five distinct classes of bioreactive prodrugs have been developed to target hypoxic cells in solid tumors. These hypoxia-activated prodrugs, including nitro compounds, N-oxides, quinones, and metal complexes, generally share a common mechanism of activation whereby they are reduced by intracellular oxidoreductases in an oxygen-sensitive manner to form cytotoxins. Several examples including PR-104, TH-302, and EO9 are currently undergoing phase II and phase III clinical evaluation. In this review, we discuss the nature of tumor hypoxia as a therapeutic target, focusing on the development of bioreductive prodrugs. We also describe the current knowledge of how each prodrug class is activated and detail the clinical progress of leading examples.

Targeted mutagenesis of the Vibrio fischeri flavin reductase FRase I to improve activation of the anticancer prodrug CB1954

Phase I/II cancer gene therapy trials of the Escherichia coli nitroreductase NfsB in partnership with the prodrug CB1954 [5-(aziridin-1-yl)-2,4-dinitrobenzamide] have indicated that CB1954 toxicity is dose-limiting at concentrations far below the enzyme K(M). Here we report that the flavin reductase FRase I from Vibrio fischeri is also a CB1954 nitroreductase, which has a substantially lower apparent K(M) than E. coli NfsB. To enhance the activity of FRase I with CB1954 we used targeted mutagenesis and an E. coli SOS reporter strain to engineer single- and multi-residue variants that possess a substantially reduced apparent K(M) and an increased k(cat)/K(M) relative to the wild type enzyme. In a bacteria-delivered model for enzyme prodrug therapy, the engineered FRase I variants were able to kill human colon carcinoma (HCT-116) cells at significantly lower CB1954 concentrations than wild type FRase I or E. coli NfsB.

Creation and screening of a multi-family bacterial oxidoreductase library to discover novel nitroreductases that efficiently activate the bioreductive prodrugs CB1954 and PR-104A

Two potentially complementary approaches to improve the anti-cancer strategy gene-directed enzyme prodrug therapy (GDEPT) are discovery of more efficient prodrug-activating enzymes, and development of more effective prodrugs. Here we demonstrate the utility of a flexible screening system based on the Escherichia coli SOS response to evaluate novel nitroreductase enzymes and prodrugs in concert. To achieve this, a library of 47 candidate genes representing 11 different oxidoreductase families was created and screened to identify the most efficient activators of two different nitroaromatic prodrugs, CB1954 and PR-104A. The most catalytically efficient nitroreductases were found in the NfsA and NfsB enzyme families, with NfsA homologues generally more active than NfsB. Some members of the AzoR, NemA and MdaB families also exhibited low-level activity with one or both prodrugs. The results of SOS screening in our optimised E. coli reporter strain SOS-R2 were generally predictive of the ability of nitroreductase candidates to sensitise E. coli to CB1954, and of the kcat/Km for each prodrug substrate at a purified protein level. However, we also found that not all nitroreductases express stably in human (HCT-116 colon carcinoma) cells, and that activity at a purified protein level did not necessarily predict activity in stably transfected HCT-116. These results highlight a need for all enzyme-prodrug partners for GDEPT to be assessed in the specific context of the vector and cell line that they are intended to target. Nonetheless, our oxidoreductase library and optimised screens provide valuable tools to identify preferred nitroreductase-prodrug combinations to advance to preclinical evaluation.

Pseudomonas aeruginosa NfsB and nitro-CBI-DEI – a promising enzyme/prodrug combination for gene directed enzyme prodrug therapy

BackgroundThe nitro-chloromethylbenzindoline prodrug nitro-CBI-DEI appears a promising candidate for the anti-cancer strategy gene-directed enzyme prodrug therapy, based on its ability to be converted to a highly cytotoxic cell-permeable derivative by the nitroreductase NfsB from Escherichia coli. However, relative to some other nitroaromatic prodrugs, nitro-CBI-DEI is a poor substrate for E. coli NfsB. To address this limitation we evaluated other nitroreductase candidates from E. coli and Pseudomonas aeruginosa.FindingsInitial screens of candidate genes in the E. coli reporter strain SOS-R2 identified two additional nitroreductases, E. coli NfsA and P. aeruginosa NfsB, as being more effective activators of nitro-CBI-DEI than E. coli NfsB. In monolayer cytotoxicity assays, human colon carcinoma (HCT-116) cells transfected with P. aeruginosa NfsB were >4.5-fold more sensitive to nitro-CBI-DEI than cells expressing either E. coli enzyme, and 23.5-fold more sensitive than untransfected HCT-116. In three dimensional mixed cell cultures, not only were the P. aeruginosa NfsB expressing cells 540-fold more sensitive to nitro-CBI-DEI than pure cultures of untransfected HCT-116, the activated drug that they generated also displayed an unprecedented local bystander effect.ConclusionWe posit that the discrepancy in the fold-sensitivity to nitro-CBI-DEI between the two and three dimensional cytotoxicity assays stems from loss of activated drug into the media in the monolayer cultures. This emphasises the importance of evaluating high-bystander GDEPT prodrugs in three dimensional models. The high cytotoxicity and bystander effect exhibited by the NfsB_Pa/nitro-CBI-DEI combination suggest that further preclinical development of this GDEPT pairing is warranted.

Advancing Clostridia to Clinical Trial: Past Lessons and Recent Progress

Most solid cancers contain regions of necrotic tissue. The extent of necrosis is associated with poor survival, most likely because it reflects aggressive tumour outgrowth and inflammation. Intravenously injected spores of anaerobic bacteria from the genus Clostridium infiltrate and selectively germinate in these necrotic regions, providing cancer-specific colonisation. The specificity of this system was first demonstrated over 60 years ago and evidence of colonisation has been confirmed in multiple tumour models. The use of “armed” clostridia, such as in Clostridium Directed Enzyme Prodrug Therapy (CDEPT), may help to overcome some of the described deficiencies of using wild-type clostridia for treatment of cancer, such as tumour regrowth from a well-vascularised outer rim of viable cells. Successful preclinical evaluation of a transferable gene that metabolises both clinical stage positron emission tomography (PET) imaging agents (for whole body vector visualisation) as well as chemotherapy prodrugs (for conditional enhancement of efficacy) would be a valuable early step towards the prospect of “armed” clostridia entering clinical evaluation. The ability to target the immunosuppressive hypoxic tumour microenvironment using CDEPT may offer potential for synergy with recently developed immunotherapy strategies. Ultimately, clostridia may be most efficacious when combined with conventional therapies, such as radiotherapy, that sterilise viable aerobic tumour cells.

Abstract B88: Discovery, characterization, and engineering of bacterial nitroreductases for gene-directed enzyme prodrug therapy.

Tumor-targeting viruses and bacteria hold great promise as anti-cancer agents. They kill cells by entirely different mechanisms to radio- and chemotherapies, and have potential to synergize with these treatments without overlapping toxicities. Furthermore, these agents can be ‘armed’ with genes that encode enzymes that activate prodrugs - compounds that are deactivated in their administered form, but become highly toxic upon metabolic activation. This not only improves killing of infected cells, but also neighboring non-infected cells, as the prodrug metabolites can diffuse locally and exert a bystander effect. A highly efficient activating enzyme in partnership with a prodrug that has a strong bystander effect can address some of the historical limitations of cancer gene therapy including the inability of biological vectors to reach every target cell. Phase I/II trials of the first-generation nitroaromatic prodrug CB1954 in conjunction with the prototype gene therapy nitroreductase, Escherichia coli NfsB, have been conducted in prostate and liver cancer. These trials provided some evidence of anti-tumor activity but, due to dose-limiting hepatotoxicity, the highest achievable plasma concentration of CB1954 was less than 1% of NfsB9s K m . As well as highlighting a need for more efficient nitroreductase enzymes, this has fuelled a search for superior nitroaromatic prodrugs. The next-generation dinitrobenzamide mustard prodrug PR-104A is not only 5–50 fold more dose-potent upon activation, but also better tolerated in humans (MTD 1100 mg/m 2 vs 24 mg/m 2 ; q3w, iv). However, E. coli NfsB also has relatively poor (millimolar) affinity for this substrate. To discover more efficient nitroreductases we developed screens for genotoxic prodrug activation, based on their ability to induce reporter genes linked to the E. coli SOS (DNA damage repair) response. We used these to screen a large library of candidate enzymes for DNBM activity, and selected E. coli NfsA as a top candidate for further improvement by random and targeted mutagenesis. High throughput screening of large error prone PCR libraries coupled with medium throughput screening of targeted mutagenesis libraries revealed 10 individual mutations that significantly increased NfsA activity. These mutations were then combined in a synthetic “smart” library, from which eight poly-mutant enzymes were selected for kinetic analysis. Relative to wild type the engineered variants display an 18–40 fold improvement in PR-104A K m with respect to E. coli NfsA, and are 860–1700 fold better than NfsB. Importantly they also retain, or are improved in, their ability to co-metabolize preferred 2-nitroimidazole probes with PET-imaging capabilities (see abstract: Patterson et al, “Molecular imaging using bacterial nitroreductase reporter genes by repurposing the clinical stage hypoxia PET probe EF5”). The enhanced prodrug activation and in vivo imaging potential of these enzymes is now being evaluated in human gene therapy models. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the AACR-NCI-EORTC International Conference: Molecular Targets and Cancer Therapeutics; 2011 Nov 12-16; San Francisco, CA. Philadelphia (PA): AACR; Mol Cancer Ther 2011;10(11 Suppl):Abstract nr B88.