Feasibility of commonly used fluorescent dyes and viral tracers in aqueous and solvent-based tissue clearing.

OBJECTIVE: To study the compatibility of traditional tracers and viral tracers with tissue clearing technology and to provide guidance in choosing suitable tracing methods for a specific tissue clearing technique. METHOD: Experiment 1: In this study, two different types of representative tracers, namely fluorescent dye tracers (Fluoro-Gold and Fluoro-Ruby) and viral tracers carrying fluorescent proteins (rAAV9-hSyn-mCherry-WPRE-pA and rAAV9-hSyn-EGFP-WPRE-pA), were selected to trace the cerebrospinal tract of the animals by microinjection. Furthermore, we presented the signal changes after using the three representative transparentizing methods, which included FRUIT (aqueous tissue clearing), 3DISCO (solvent-based tissue clearing), and uDISCO (solvent-based tissue clearing), were compared after slicing. Experiment 2: Based on the research mentioned above, Fluoro-Ruby was microinjected unilaterally into the primary motor cortex of rats, directly tracing the pyramidal tract to the spinal cord. Then, the entire brain and spinal cord were collected for tissue transparency using the 3DISCO method, after which three-dimensional imaging was performed using optical microscopic imaging equipment. RESULTS: Experiment 1 indicated that Fluoro-Gold and Fluoro-Ruby displayed better compatibility with the three transparent methods. The viral tracer exhibited higher compatibility with the FRUIT method, while its compatibility with 3DISCO and uDISCO was low. Furthermore, GFP was quenched more quickly and seriously than cherry protein under the same experimental conditions. Experiment 2: The Fluoro-Ruby tag displayed the presence of long-distance axons. For microscopic imaging, light sheet microscopy and two-photon microscopy were both used to identify the signals of tracers in transparent tissue. RESULTS: Both Fluoro-Gold and Fluoro-Ruby displayed excellent compatibility with tissue clearing technology, which, with dehydration and delipidation at its core, lead to quenching of fluorescence proteins, while exhibiting poor compatibility with viral tracers. In combination with tissue clearing technology and optical microscopy, the anterograde tracer Fluoro-Ruby could stereoscopically display the complete neural conduction pathway.

Spatial Distribution of Motor Endplates and its Adaptive Change in Skeletal Muscle.

Motor endplates (MEPs) are the important interfaces between peripheral nerves and muscle fibers. Investigation of the spatial distribution of MEPs could help us better understand neuromuscular functional activities and improve the diagnosis and therapy of related diseases. Methods: Fluorescent α-bungarotoxin was injected to label the motor endplates in whole-mount skeletal muscles, and tissue optical clearing combined with light-sheet microscopy was used to investigate the spatial distribution of MEPs and in-muscle nerve branches in different skeletal muscles in wild-type and transgenic fluorescent mice. Electrophysiology was used to determine the relationship between the spatial distribution of MEPs and muscle function. Results: The exact three-dimensional distribution of MEPs in whole skeletal muscles was first obtained. We found that the MEPs in the muscle were distributed in an organized pattern of lamella clusters, with no MEPs outside the lamella zone. Each MEP lamella was innervated by one independent in-muscle nerve branch and mediated an independent muscle subgroup contraction. Additionally, the MEPs changed along the lamella clusters after denervation and regained the initial pattern after reinnervation. The integrity and spatial distribution of MEPs could reflect the functional state of muscles. The signal absence of a certain MEP lamella could suggest a problem in certain part of the muscle. Conclusions: The MEP lamella clusters might be the basis of neuromuscular function, and the spatial distribution of MEPs could serve as a testbed for evaluating the functional status of muscle and the therapeutic targeting map related to MEPs.

In vivo injection of α-bungarotoxin to improve the efficiency of motor endplate labeling.

INTRODUCTION: Motor endplates are composed of a motor neuron terminal and muscle fiber and are distributed in skeletal muscle, causing muscle contraction. However, traditional motor endplate staining methods are limited to the observation of partial skeletal muscle. The procedure was time-consuming due to strict incubation conditions, and usually provided unsatisfactory results. We explored a novel method to label motor endplate rapidly by in vivo injection of fluorescent α-bungarotoxin. METHODS: Fifty-two mice were randomly divided into two groups, an experiment group (n = 50), and a contrast group (n = 2). In experiment group, α-bungarotoxin was injected via the caudal vein. The injection dosages were designated as 0.1, 0.2, 0.3, 0.4, and 0.5 µg/g. The experimental mice were divided into five subgroups of ten mice per group. The contrast group was only injected with 200 µL normal saline solution. Bilateral gastrocnemius were acquired for microscope analysis and optical clearing to seek specific fluorescent signal. RESULTS: A dose of 0.3 µg/g of α-bungarotoxin with 1 h conjugation time could display the number and structure of motor endplate in plane view. Compared with the traditional procedure, this method was rapid, convenient, and time-saving. Combined with the optical clearing technique, spatial distribution could also be seen, helping to better understand the stereoscopic view of motor endplate position in skeletal muscle. CONCLUSIONS: In vivo injection of α-bungarotoxin proved effective for studying motor endplate in skeletal muscle.