Abstract
Larval Drosophila are used as a genetically accessible study case in many areas of biological research. Here we report a fast, robust and user-friendly procedure for the whole-body multi-fluorescence imaging of Drosophila larvae; the protocol has been optimized specifically for larvae by systematically tackling the pitfalls associated with clearing this small but cuticularized organism. Tests on various fluorescent proteins reveal that the recently introduced monomeric infrared fluorescent protein (mIFP) is particularly suitable for our approach. This approach comprises an effective, low-cost clearing protocol with minimal handling time and reduced toxicity in the reagents employed. It combines a success rate high enough to allow for small-scale screening approaches and a resolution sufficient for cellular-level analyses with light sheet and confocal microscopy. Given that publications and database documentations typically specify expression patterns of transgenic driver lines only within a given organ system of interest, the present procedure should be versatile enough to extend such documentation systematically to the whole body. As examples, the expression patterns of transgenic driver lines covering the majority of neurons, or subsets of chemosensory, central brain or motor neurons, are documented in the context of whole larval body volumes (using nsyb-Gal4, IR76b-Gal4, APL-Gal4 and mushroom body Kenyon cells, or OK371-Gal4, respectively). Notably, the presented protocol allows for triple-color fluorescence imaging with near-infrared, red and yellow fluorescent proteins.
Highlights
Our understanding of the principles of animal form and function has considerably advanced in recent years
The following stocks were obtained from the Bloomington Drosophila Stock Center (BDSC): y1 wÃ; nsybGal4; w1118; vGlutOK371-Gal4 (#26160; Mahr & Aberle, 2006) ( OK371-Gal4); wà dlg1YC0005 (#50859; Quinones-Coello et al, 2007); wÃ; UAS-mCherryCAAX (#59021; Sens et al, 2010) ( UAS-mCherry-CAAX); wÃ;; UASmIFP-T2A-HO1 (#64181; Yu et al, 2015) ( UASmIFP-T2A-HO1); wÃ; IR76b-Gal4/CyO; TM2/TM6b
Pioneered by Werner Spalteholz a century ago, tissue clearing proved to be a groundbreaking technique in microscopic anatomy (Eisenstein, 2018; Spalteholz, 1911) once optimized protocols were combined with state-of-the-art cell labeling, microscopy, and image data processing (Ueda et al, 2020)
Summary
Our understanding of the principles of animal form and function has considerably advanced in recent years. What is missing are techniques for the convenient, routine contextualization of such data within the whole body. We report such a technique for larval Drosophila. Drosophila larvae are used to study processes as diverse as chromatin organization and remodeling (Schwartz & Cavalli, 2017), tissue morphogenesis and regeneration Larval Drosophila serve as a model system in both the neural and the behavioral sciences. Studies on the thirdinstar larval neuromuscular junction (NMJ), for instance, have uncovered evolutionarily conserved mechanisms of synaptogenesis, synaptic function, and synaptic plasticity (Frank, James, & Muller, 2020; Ghelani & Sigrist, 2018; Harris & Littleton, 2015). Focusing on larval food search strategies, Supplemental data for this article can be accessed here
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