A step towards animal models with self-sustained fungal bioluminescence

Engineering animal models with self-sustained luminescence could enable non-invasive longitudinal monitoring of molecular events in living animals. To create animal models that report physiology with autoluminescence, both luciferin biosynthesis enzymes and the luciferase need to be optimised. Previous work on engineering the autoluminescence pathway from fungi resulted in the development of nnLuz_v3, a version of Neonothopanus nambi luciferase with enhanced thermal stability. Here, we generated an nnLuz_v3 reporter of endogenous Cyp1a1 expression as a measure of aryl hydrocarbon receptor (AHR) activation, assessing the performance of nnLuz_v3 in vivo at physiologically relevant expression levels. As AHR dynamically responds to metabolic, environmental and dietary changes it provides a validated platform to assess novel luminescence approaches. In Cyp1a1-nnLuz mice bioluminescence signal was stable, allowing the generation of well-resolved luminescence images both on standard in vivo imaging equipment and consumer-grade cameras. Using mice and nematode models, we demonstrated limited oral availability of the fungal luciferin, potentially compatible with delivering the substrate via food or the microbiome. Our results are an encouraging first step in the generation of an autoluminescent mammalian model of a molecular event and encourage optimisation of other enzymes of the fungal luciferase pathway.