Dextran Amine-Conjugated Neural Tracing in Mosquitoes.
Meg A YoungerPublished in: Cold Spring Harbor protocols (2023)
To understand the circuitry of the brain, it is often advantageous to visualize the processes of a single neuron or population of neurons. Identifying sites where a neuron, or neurons, originates and where it projects can allow a researcher to begin to map the circuitry underlying various processes, including sensory-guided behaviors. Furthermore, neural tracing allows one to map locations where processes terminate onto regions of the brain that may have known functions and sometimes to identify candidate upstream or downstream connections, based on proximity. Many methods of neural tracing are available; here, we focus on loading fluorescent dyes into a neuron (fluorescent dye filling). Different options for dyes exist to label neurites. Among the most versatile and easy to use are dextran amine-conjugated dyes. They fill neurons bidirectionally, not discriminating between anterograde or retrograde loading direction. Dye filling must be done in unfixed tissue, as the dye needs to move through the neurons; however, dextran amine conjugates are aldehyde-fixable and once cells have been fully loaded with dye the tissue can be fixed and subjected to immunostaining. Coupling neural tracing with immunofluorescence is a useful way to determine specific brain or ventral nerve cord (VNC) regions where a neuron projects. This protocol describes methods for loading dextran amine conjugated dyes into a sensory tissue in the mosquito to visualize sites of sensory neuron innervation in the central nervous system, as well as efferent projections to these structures. This protocol is described for Aedes aegypti , for which it was optimized, but it also works across a variety of insects.
Keyphrases
- aedes aegypti
- aqueous solution
- spinal cord
- dengue virus
- resting state
- zika virus
- white matter
- photodynamic therapy
- highly efficient
- quantum dots
- randomized controlled trial
- induced apoptosis
- functional connectivity
- quality improvement
- cerebral ischemia
- drug delivery
- cancer therapy
- spinal cord injury
- high resolution
- cerebrospinal fluid
- cell death
- visible light
- cell proliferation
- cell cycle arrest
- ionic liquid
- fluorescent probe