An improved monomeric infrared fluorescent protein for neuronal and tumour brain imaging.

Abstract

Infrared fluorescent proteins (IFPs) are ideal for in vivo imaging and monomeric versions of these proteins can be advantageous as protein tags or for sensor development. In contrast to GFP, which requires only molecular oxygen for chromophore maturation, phytochrome-derived IFPs incorporate biliverdin (BV) as the chromophore. However, BV varies in concentration in different cells and organisms. Here we engineered cells to express the heme oxygenase responsible for BV biosynthesys and a brighter monomeric IFP mutant (IFP2.0). Together, these tools improve the imaging capabilities of IFP2.0 compared to monomeric IFP1.4 and dimeric iRFP. By targeting IFP2.0 to the plasma membrane, we demonstrate robust labeling of neuronal processes in Drosophila larvae. We also show that this strategy improves the sensitivity when imaging brain tumors in whole mice. Our work shows promise in the application of IFPs for protein labeling and in vivo imaging.