Hypocretin1/OrexinA axon targeting of laterodorsal tegmental nucleus neurons projecting to the rat medial prefrontal cortex.

Cortical activation and goal-directed behaviors characterize wakefulness. One cortical region especially involved in these phenomena is the medial prefrontal cortex (mPFC), which receives many inputs from cholinergic-containing neurons in brain stem structures implicated in arousal and wakefulness, such as the laterodorsal tegmental nucleus (LDT). Hypocretins/orexins (Hcrt/Ox), whose dysfunction is linked to narcolepsy, maintains arousal and stabilizes sleep-wakefulness states. We aim to determine if Hcrt1/OxA axons (1) innervate LDT neurons projecting to the mPFC, a target that would allow them to sustain arousal and wakefulness, and (2) target preferentially cholinergic versus noncholinergic LDT neurons. The retrograde tracer Fluorogold (FG) was injected in the rat mPFC, and dual immunolabeling of anti-FG and either anti-choline acetyltransferase (ChAT) or anti-Hcrt1/OxA antisera was determined in LDT. Also, actual Hcrt1/OxA targeting of cholinergic LDT neurons was ascertained by dual anti-Hcrt1/OxA and anti-ChAT detection in additional noninjected animals. Many LDT FG-labeled neurons were cholinergic (52.05 ± 3.72%). Hcrt1/OxA immunoprecipitate was observed in cytoplasm and granular vesicles within axons. Some Hcrt1/OxA-containing axons established asymmetric excitatory-type synapses with either unlabeled (46/438) or FG-labeled (7/438) dendrites. One-third of the target neurons were ChAT labeled. Hcrt1/OxA excitatory input to LDT neurons projecting to mPFC probably contributes to the wakefulness-enhancing actions of Hcrt/Ox impaired in narcoleptics.

Quantitative expansion microscopy for the characterization of the spectrin periodic skeleton of axons using fluorescence microscopy.

Fluorescent nanoscopy approaches have been used to characterize the periodic organization of actin, spectrin and associated proteins in neuronal axons and dendrites. This membrane-associated periodic skeleton (MPS) is conserved across animals, suggesting it is a fundamental component of neuronal extensions. The nanoscale architecture of the arrangement (190 nm) is below the resolution limit of conventional fluorescent microscopy. Fluorescent nanoscopy, on the other hand, requires costly equipment and special analysis routines, which remain inaccessible to most research groups. This report aims to resolve this issue by using protein-retention expansion microscopy (pro-ExM) to reveal the MPS of axons. ExM uses reagents and equipment that are readily accessible in most neurobiology laboratories. We first explore means to accurately estimate the expansion factors of protein structures within cells. We then describe the protocol that produces an expanded specimen that can be examined with any fluorescent microscopy allowing quantitative nanoscale characterization of the MPS. We validate ExM results by direct comparison to stimulated emission depletion (STED) nanoscopy. We conclude that ExM facilitates three-dimensional, multicolor and quantitative characterization of the MPS using accessible reagents and conventional fluorescent microscopes.