Work Package 1: Identify the enzyme responsible for epimerisation of C-1 of the DHCCA moiety.
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At the start of the project, it was believed that C-1 of the DHCCA moiety in enacyloxin undergoes epimerisation after the Bamb_5915-catalysed esterification reaction. However, this hypothesis was refuted by in vitro biochemical assays which showed that, contrary to initial observations, the Bamb_5915 protein can utilise (1S, 3R, 4S)-DHCCA as a substrate. This finding led us to conclude that there is no epimerase involved in enacyloxin biosynthesis.
Work package 2: Explore the ability of the Bamb_5915 chain release enzyme to catalyse the acylation of diverse DHCCA analogues
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To probe its substrate specificity, purified 5915 protein was incubated with acetyl-ACP and a range of commercially-available and chemically-synthesized DHCCA analogues. These experiments revealed that the chain release enzyme has a relaxed substrate specificity and is able to utilise a wide range of DHCCA analogues in vitro.
Work package 3: Create a Burkholderia ambifaria mutant blocked in DHCCA biosynthesis
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A mutant of B. ambifaria blocked in DHCCA biosynthesis was constructed by simultaneously deleting three DHCCA biosynthetic genes in the enacyloxin biosynthetic gene cluster. LC-MS analysis of extracts from agar cultures confirmed that enacyloxin IIa production is abolished in this mutant and showed that it is possible to restore enacyloxin biosynthesis by feeding chemically-synthesised (1S,3R,4S)-DHCCA.
Work Package 4: Produce novel enacyloxin IIa derivatives via a mutasynthesis approach involving feeding of DHCCA analogues to a B. ambifaria mutant blocked in DHCCA biosynthesis.
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Over a dozen enacyloxin derivatives with altered DHCCA moieties were produced by feeding the DHCCA analogues identified as substrates of the Bamb_5915 protein to the mutant of B. ambifaria blocked in DHCCA biosynthesis. By studying the activity of the purified analogues against A. baumannii, insight was obtained into the structure-activity relationship for the DHCCA moiety of the antibiotic.
The novel analogues are currently being protected through patent applications (1 filed, 1 in preparation) to facilitate exploitation and commercial development. Collaborations with two industrial partners have been established under the protection of a confidentiality agreement, focused on carrying out preclinical evaluation of the analogues generated. Once IP rights are secured, the results of this project will also be disseminated to the scientific community through publication in international peer-reviewed journals.