posted on 2020-08-04, 18:15authored byZi Yao, Brendan S. Zhang, Rachel C. Steinhardt, Jeremy H. Mills, Jennifer A. Prescher
Bioluminescence
imaging with luciferase-luciferin pairs is commonly
used for monitoring biological processes in cells and whole organisms.
Traditional bioluminescent probes are limited in scope, though, as
they cannot be easily distinguished in biological environments, precluding
efforts to visualize multicellular processes. Additionally, many luciferase-luciferin
pairs emit light that is poorly tissue penetrant, hindering efforts
to visualize targets in deep tissues. To address these issues, we
synthesized a set of π-extended luciferins that were predicted
to be red-shifted luminophores. The scaffolds were designed to be
rotationally labile such that they produced light only when paired
with luciferases capable of enforcing planarity. A luciferin comprising
an intramolecular “lock” was identified as a viable
light-emitting probe. Native luciferases were unable to efficiently
process the analog, but a complementary luciferase was identified
via Rosetta-guided enzyme design. The unique enzyme–substrate
pair is red-shifted compared to well-known bioluminescent tools. The
probe set is also orthogonal to other luciferase-luciferin probes
and can be used for multicomponent imaging. Four substrate-resolved
luciferases were imaged in a single session. Collectively, this work
provides the first example of Rosetta-guided design in engineering
bioluminescent tools and expands the scope of orthogonal imaging probes.