Protocol for evaluating the abilities of diverse nitroaromatic prodrug metabolites to exit a model Gram negative bacterial vector

Protocol for evaluating the abilities of diverse nitroaromatic prodrug metabolites to exit a model Gram negative bacterial vector

Bacterial-directed enzyme-prodrug therapy (BDEPT) uses tumour-tropic bacteria armed with a genetically-encoded prodrug-converting enzyme to sensitise tumours to a systemically-administered prodrug. A strong bystander effect (i.e., efficient bacteria-to-tumour transfer of activated prodrug metabolite...

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Bibliographic Details
Main Authors: Jasmine V.E. Chan-Hyams, David F. Ackerley
Format: Article
Language:English
Published: Elsevier 2020-01-01
Series:MethodsX
Subjects:
BDEPT
GDEPT
Cancer gene therapy
Nitroreductase
Bystander effect
CB1954
Online Access:http://www.sciencedirect.com/science/article/pii/S2215016120300170
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spelling doaj-d0b861d02e9f41b2a93bb7a84d0de1ad2021-01-02T05:10:04ZengElsevierMethodsX2215-01612020-01-017100797Protocol for evaluating the abilities of diverse nitroaromatic prodrug metabolites to exit a model Gram negative bacterial vectorJasmine V.E. Chan-Hyams0David F. Ackerley1School of Biological Sciences, Victoria University of Wellington, Wellington, 6012, New Zealand; Centre for Biodiscovery, Victoria University of Wellington, Wellington, 6012, New ZealandSchool of Biological Sciences, Victoria University of Wellington, Wellington, 6012, New Zealand; Centre for Biodiscovery, Victoria University of Wellington, Wellington, 6012, New Zealand; Corresponding author at: School of Biological Sciences, Victoria University of Wellington, Wellington, 6012, New Zealand.Bacterial-directed enzyme-prodrug therapy (BDEPT) uses tumour-tropic bacteria armed with a genetically-encoded prodrug-converting enzyme to sensitise tumours to a systemically-administered prodrug. A strong bystander effect (i.e., efficient bacteria-to-tumour transfer of activated prodrug metabolites) is critical to maximise tumour cell killing and avoid bacterial self-sterilisation. To investigate the bystander effect in bacteria we developed a sensitive screen that utilised two Escherichia coli strains grown in co-culture. The first of these was an activator strain that overexpressed the E. coli nitroreductase NfsA, and the second was a nitroreductase null recipient strain bearing an SOS-GFP DNA damage responsive gene construct. In this system, induction of GFP by genotoxic prodrug metabolites can only occur following their transfer from the activator to the recipient cells. This can be monitored both in fluorescence based microtitre plate assays and by flow-cytometry, enabling modelling of the abilities of diverse nitroaromatic prodrug metabolites to exit a Gram negative vector.http://www.sciencedirect.com/science/article/pii/S2215016120300170BDEPTGDEPTCancer gene therapyNitroreductaseBystander effectCB1954
collection DOAJ
language English
format Article
sources DOAJ
author Jasmine V.E. Chan-Hyams
David F. Ackerley
spellingShingle Jasmine V.E. Chan-Hyams
David F. Ackerley
Protocol for evaluating the abilities of diverse nitroaromatic prodrug metabolites to exit a model Gram negative bacterial vector
MethodsX
BDEPT
GDEPT
Cancer gene therapy
Nitroreductase
Bystander effect
CB1954
author_facet Jasmine V.E. Chan-Hyams
David F. Ackerley
author_sort Jasmine V.E. Chan-Hyams
title Protocol for evaluating the abilities of diverse nitroaromatic prodrug metabolites to exit a model Gram negative bacterial vector
title_short Protocol for evaluating the abilities of diverse nitroaromatic prodrug metabolites to exit a model Gram negative bacterial vector
title_full Protocol for evaluating the abilities of diverse nitroaromatic prodrug metabolites to exit a model Gram negative bacterial vector
title_fullStr Protocol for evaluating the abilities of diverse nitroaromatic prodrug metabolites to exit a model Gram negative bacterial vector
title_full_unstemmed Protocol for evaluating the abilities of diverse nitroaromatic prodrug metabolites to exit a model Gram negative bacterial vector
title_sort protocol for evaluating the abilities of diverse nitroaromatic prodrug metabolites to exit a model gram negative bacterial vector
publisher Elsevier
series MethodsX
issn 2215-0161
publishDate 2020-01-01
description Bacterial-directed enzyme-prodrug therapy (BDEPT) uses tumour-tropic bacteria armed with a genetically-encoded prodrug-converting enzyme to sensitise tumours to a systemically-administered prodrug. A strong bystander effect (i.e., efficient bacteria-to-tumour transfer of activated prodrug metabolites) is critical to maximise tumour cell killing and avoid bacterial self-sterilisation. To investigate the bystander effect in bacteria we developed a sensitive screen that utilised two Escherichia coli strains grown in co-culture. The first of these was an activator strain that overexpressed the E. coli nitroreductase NfsA, and the second was a nitroreductase null recipient strain bearing an SOS-GFP DNA damage responsive gene construct. In this system, induction of GFP by genotoxic prodrug metabolites can only occur following their transfer from the activator to the recipient cells. This can be monitored both in fluorescence based microtitre plate assays and by flow-cytometry, enabling modelling of the abilities of diverse nitroaromatic prodrug metabolites to exit a Gram negative vector.
topic BDEPT
GDEPT
Cancer gene therapy
Nitroreductase
Bystander effect
CB1954
url http://www.sciencedirect.com/science/article/pii/S2215016120300170
work_keys_str_mv AT jasminevechanhyams protocolforevaluatingtheabilitiesofdiversenitroaromaticprodrugmetabolitestoexitamodelgramnegativebacterialvector
AT davidfackerley protocolforevaluatingtheabilitiesofdiversenitroaromaticprodrugmetabolitestoexitamodelgramnegativebacterialvector
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