This review examines the vast catalytic and therapeutic potential offered by type I (i.e. oxygen-insensitive) nitroreductase enzymes in partnership with nitroaromatic prodrugs, with particular focus on gene-directed enzyme prodrug therapy (GDEPT; a form of cancer gene therapy). Important first indications of this potential were demonstrated over 20 years ago, for the enzyme-prodrug pairing of Escherichia coli NfsB and CB1954 [5-(aziridin-1-yl)-2,4-dinitrobenzamide]. However, it has become apparent that both the enzyme and the prodrug in this prototypical pairing have limitations that have impeded their clinical progression. Recently, substantial advances have been made in the biodiscovery and engineering of superior nitroreductase variants, in particular development of elegant high-throughput screening capabilities to enable optimization of desirable activities via directed evolution. These advances in enzymology have been paralleled by advances in medicinal chemistry, leading to the development of second- and third-generation nitroaromatic prodrugs that offer substantial advantages over CB1954 for nitroreductase GDEPT, including greater dose-potency and enhanced ability of the activated metabolite(s) to exhibit a local bystander effect. In addition to forging substantial progress towards future clinical trials, this research is supporting other fields, most notably the development and improvement of targeted cellular ablation capabilities in small animal models, such as zebrafish, to enable cell-specific physiology or regeneration studies.
Evaluating the abilities of diverse nitroaromatic prodrug metabolites to exit a model Gram negative vector for bacterial-directed enzyme-prodrug therapy
Gene-directed enzyme-prodrug therapy (GDEPT) employs tumour-tropic vectors including viruses and bacteria to deliver a genetically-encoded prodrug-converting enzyme to the tumour environment, thereby sensitising the tumour to the prodrug. Nitroreductases, able to activate a range of promising nitroaromatic prodrugs to genotoxic metabolites, are of great interest for GDEPT. The bystander effect (cell-to-cell transfer of activated prodrug metabolites) has been quantified for some nitroaromatic prodrugs in mixed multilayer human cell cultures, however while these provide a good model for viral DEPT (VDEPT) they do not inform on the ability of these prodrug metabolites to exit bacterial vectors (relevant to bacterial-DEPT (BDEPT)). To investigate this we grew two Escherichia coli strains in co-culture; an activator strain expressing the nitroreductase E. coli NfsA and a recipient strain containing an SOS-GFP DNA damage responsive gene construct. In this system, induction of GFP by reduced prodrug metabolites can only occur following their transfer from the activator to the recipient cells. We used this to investigate five clinically relevant prodrugs: metronidazole, CB1954, nitro-CBI-DEI, and two dinitrobenzamide mustard prodrug analogues, PR-104A and SN27686. Consistent with the bystander efficiencies previously measured in human cell multilayers, reduced metronidazole exhibited little bacterial cell-to-cell transfer, whereas nitro-CBI-DEI was passed very efficiently from activator to recipient cells post-reduction. However, in contrast with observations in human cell multilayers, the nitrogen mustard prodrug metabolites were not effectively passed between the two bacterial strains, whereas reduced CB1954 was transferred efficiently. Using nitroreductase enzymes that exhibit different biases for the 2-versus 4-nitro substituents of CB1954, we further showed that the 2-nitro reduction products exhibit substantially higher levels of bacterial cell-to-cell transfer than the 4-nitro reduction products, consistent with their relative bystander efficiencies in human cell culture. Overall, our data suggest that prodrugs may differ in their suitability for VDEPT versus BDEPT applications and emphasise the importance of evaluating an enzyme-prodrug partnership in an appropriate context for the intended vector.
Use of an optimised enzyme/prodrug combination for Clostridia directed enzyme prodrug therapy induces a significant growth delay in necrotic tumours. Cancer Gene Therapy.
Enterovirus 74 (EV74) is a rarely detected viral infection of children. In 2010, EV74 was identified in New Zealand in a 2 year old child with acute flaccid paralysis (AFP) through routine polio AFP surveillance. A further three cases of EV74 were identified in children within six months. These cases are the first report of EV74 in New Zealand. In this study we describe the near complete genome sequence of four EV74 isolates from New Zealand, which shows only limited sequence identity in the non-structural proteins when compared to the other two known EV74 sequences. As is typical of enteroviruses multiple recombination events were evident, particularly in the P2 region and P3 regions. This is the first complete EV74 genome sequenced from a patient with acute flaccid paralysis.
<p>Gene-directed enzyme-prodrug therapy (GDEPT) employs tumour-tropic vectors including viruses (VDEPT) and bacteria (BDEPT) to deliver a genetically-encoded prodrug-converting enzyme to the tumour environment, thereby sensitising the tumour to a prodrug. Bacterial nitroreductases, which are able to activate a range of anti-cancer nitroaromatic prodrugs to genotoxic metabolites, are of particular interest for GDEPT. The bystander effect is crucial to the success of GDEPT. The bystander effect is a measure of how efficiently activated prodrug metabolites are transferred from gene-expressing cells to neighbouring tissues. This promotes more extensive tumour cell killing. The bystander effect has been quantified for multiple nitroaromatic prodrugs in mixed multilayer human cell cultures. Although this is a good model for VDEPT it cannot simulate the ability of these prodrug metabolites to exit the bacterial vectors relevant to BDEPT. Prior to this work there was an unmet need for an in vitro method of quantifying the bystander effect as it occurs in BDEPT, i.e. a bacterial model of cell-to-cell transfer of activated prodrug metabolites. This thesis presents a method for measuring the bacterial bystander effect in vitro in a microplate based assay that was validated by flow cytometry. In this assay two Escherichia coli strains are grown in co-culture; an activator strain expressing the nitroreductase E. coli nfsA and a recipient strain containing an SOS-GFP DNA damage responsive gene construct. In this system, induction of GFP by reduced prodrug metabolites can only occur following their transfer from the activators to the recipients. Using this method, the bacterial bystander effect of the clinically relevant prodrugs, metronidazole, CB1954, nitro-CBI-DEI, PR-104A and SN27686, was assessed. Consistent with the bystander efficiencies in human cell multilayers, reduced metronidazole exhibited little bacterial cell-to-cell transfer, whereas nitro-CBI-DEI was passed very efficiently from activator to recipient cells post-reduction. In contrast with observations in human cell multilayers, the PR-104A and SN27686 metabolites were not effectively passed between the two bacterial strains, whereas reduced CB1954 was transferred efficiently. Using nitroreductase enzymes that exhibit different biases for the 2- versus 4-nitro substituents of CB1954, I further showed that the 2-nitro reduction products exhibit substantially higher levels of bacterial cell-to-cell transfer than the 4-nitro reduction products. The outcomes of this investigation highlighted the importance of evaluating enzyme-prodrug combinations in models relevant to the intended GDEPT vector, as there can evidently be profound differences in efficacy in different settings. These findings motivated an investigation into the influence of the bystander effect on certain screening strategies used for directed evolution of nitroreductases. It was observed that the bacterial bystander effect can occur during fluorescence activated cell sorting (FACS) of a nitroreductase variant library and negatively impact the recovery of more active variants. Significantly fewer nfsA-expressing cells were recovered from FACS when using CB1954 and nitro-CBI-DEI, when the bystander effect was given time to occur, as compared to controls in which the bystander effect was given no time to occur. In contrast, at the preferred challenge concentrations the mustard prodrugs PR-104A and SN27686 did not yield significantly lower proportions of nfsA-expressing cells under bystander condition. A subsequent investigation compared the evolutionary outcomes arising from screening a nitroreductase variant library using FACS, in which the bystander effect can occur, in parallel to a manual pre-selection method of individual clones for detoxification of structurally divergent nitroaromatic antibiotics. Overall the results of this investigation were inconclusive after just a single round of selection, but there is some evidence that the FACS strategy was more effective than niclosamide/chloramphenicol pre-selection in enriching for superior CB1954-reducing variants. Finally, a panel of nitroreductase candidates was evaluated with the next generation prodrugs PR-104A and SN36506 for possible Clostridia-DEPT development. It was found that the Vibrio vulnificus NfsB F70A/F108Y variant displayed the highest catalytic efficiency with PR-104A reported thus far compared to any other nitroreductase, and was the only NfsB family nitroreductase to exhibit any activity with SN36506 at the purified protein level. At the time this research was performed only NfsB family nitroreductases had been successfully expressed in C. sporogenes by our collaborators, hence the V. vulnificus NfsB F70A/F108Y variant was selected as a promising lead enzyme for further development.</p>
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