Abstract
Fish are ideally suited for in vivo-imaging due to their transparency at early stages combined with a large genetic toolbox. Key challenges to further advance imaging are fluorophore selection, immobilization of the specimen and approaches to eliminate pigmentation. We addressed all three and identified the fluorophores and anaesthesia of choice by high throughput time-lapse imaging. Our results indicate that eGFP and mCherry are the best conservative choices for in vivo-fluorescence experiments, when availability of well-established antibodies and nanobodies matters. Still, mVenusNB and mGFPmut2 delivered highest absolute fluorescence intensities in vivo. Immobilization is of key importance during extended in vivo imaging. Here, traditional approaches are outperformed by mRNA injection of α-Bungarotoxin which allows a complete and reversible, transient immobilization. In combination with fully transparent juvenile and adult fish established by the targeted inactivation of both, oca2 and pnp4a via CRISPR/Cas9-mediated gene editing in medaka we could dramatically improve the state-of-the art imaging conditions in post-embryonic fish, now enabling light-sheet microscopy of the growing retina, brain, gills and inner organs in the absence of side effects caused by anaesthetic drugs or pigmentation.
Highlights
IntroductionFish (Zebrafish, Danio rerio [1,2]; Medaka, Oryzias latipes, [3,4]) have become popular model systems for in vivo imaging due to their transparent embryos and their extended genetic toolbox [5,6]
Fish (Zebrafish, Danio rerio [1,2]; Medaka, Oryzias latipes, [3,4]) have become popular model systems for in vivo imaging due to their transparent embryos and their extended genetic toolbox [5,6].In contrast to the first hours of development, imaging of subsequent stages of development and adult life is obscured by increasing pigmentation and active movements of the growing animals
In order to assess the fluorescence intensity of different, commonly used fluorescent protein (FP) (CFP, Clover, eGFP, eGFPvar, eGFPvarA206K, Venus, YFP, mGFPmut2, mVenusNB, exact fluorophore mutations are listed in S1 Table), we performed a transient ratiometric approach over extended periods of time
Summary
Fish (Zebrafish, Danio rerio [1,2]; Medaka, Oryzias latipes, [3,4]) have become popular model systems for in vivo imaging due to their transparent embryos and their extended genetic toolbox [5,6]. In contrast to the first hours of development, imaging of subsequent stages of development and adult life is obscured by increasing pigmentation and active movements of the growing animals. The biggest challenge does not reside on the level of instrumentation, but rather within the specimen itself. They need to be tackled to fully exploit the excellent genetic toolbox. Long term lineaging approaches in both species [7,8] will only deliver dynamic data on fate decisions, once these challenges have been addressed.
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