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Abstract
The bacterial Lux system is used as a gene expression reporter. It is fast, sensitive and non-destructive, enabling high frequency measurements. Originally developed for bacterial cells, it has also been adapted for eukaryotic cells, and can be used for whole cell biosensors, or in real time with live animals without the need for euthanasia. However, correct interpretation of bioluminescent data is limited: the bioluminescence is different from gene expression because of nonlinear molecular and enzyme dynamics of the Lux system. We have developed a computational approach that, for the first time, allows users of Lux assays to infer gene transcription levels from the light output. This approach is based upon a new mathematical model for Lux activity, that includes the actions of LuxAB, LuxEC and Fre, with improved mechanisms for all reactions, as well as synthesis and turn-over of Lux proteins. The model is calibrated with new experimental data for the LuxAB and Fre reactions from Photorhabdus luminescens—the source of modern Lux reporters—while literature data has been used for LuxEC. Importantly, the data show clear evidence for previously unreported product inhibition for the LuxAB reaction. Model simulations show that predicted bioluminescent profiles can be very different from changes in gene expression, with transient peaks of light output, very similar to light output seen in some experimental data sets. By incorporating the calibrated model into a Bayesian inference scheme, we can reverse engineer promoter activity from the bioluminescence. We show examples where a decrease in bioluminescence would be better interpreted as a switching off of the promoter, or where an increase in bioluminescence would be better interpreted as a longer period of gene expression. This approach could benefit all users of Lux technology.
Highlights
The lux operon contains genes for the bacterial bioluminescent reaction [1, 2]: luxA and luxB encode the α and β subunits of the heterodimeric bacterial luciferase; luxC encodes a 54kDa fatty acid reductase; luxD encodes a 33kDa acyl transferase; and luxE encodes a 42kDa acylprotein synthetase
In this paper we show that detailed mathematical models for bioluminescence can be used to relate bioluminescence to promoter activity
We have developed a new mathematical model to relate gene expression to light output in Lux promoter assays, that includes newly discovered experimental evidence for product inhibition of the LuxAB reaction by FMNH2
Summary
The lux operon contains genes for the bacterial bioluminescent reaction [1, 2]: luxA and luxB encode the α and β subunits of the heterodimeric bacterial luciferase; luxC encodes a 54kDa fatty acid reductase; luxD encodes a 33kDa acyl transferase; and luxE encodes a 42kDa acylprotein synthetase. These genes, including their order (luxCDABE), are conserved in all lux systems of bioluminescent bacteria. In E. coli and other species, Fre has been shown to be the enzyme responsible for flavin reduction back to FMNH2
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