Abstract
The dorsal root ganglia (DRG) house the primary afferent neurons responsible for somatosensation, including pain. We previously identified Jedi-1 (PEAR1/MEGF12) as a phagocytic receptor expressed by satellite glia in the DRG involved in clearing apoptotic neurons during development. Here, we further investigated the function of this receptor in vivo using Jedi-1 null mice. In addition to satellite glia, we found Jedi-1 expression in perineurial glia and endothelial cells, but not in sensory neurons. We did not detect any morphological or functional changes in the glial cells or vasculature of Jedi-1 knockout mice. Surprisingly, we did observe changes in DRG neuron activity. In neurons from Jedi-1 knockout (KO) mice, there was an increase in the fraction of capsaicin-sensitive cells relative to wild type (WT) controls. Patch-clamp electrophysiology revealed an increase in excitability, with a shift from phasic to tonic action potential firing patterns in KO neurons. We also found alterations in the properties of voltage-gated sodium channel currents in Jedi-1 null neurons. These results provide new insight into the expression pattern of Jedi-1 in the peripheral nervous system and indicate that loss of Jedi-1 alters DRG neuron activity indirectly through an intercellular interaction between non-neuronal cells and sensory neurons.
Highlights
The dorsal root ganglia (DRG) house the primary afferent neurons responsible for somatosensation, including pain
We demonstrate that loss of the phagocytic receptor Jedi-1 increases DRG neuronal excitability; Jedi-1 was not detected in the neurons, but was expressed by endothelial cells, satellite glia and perineurial cells
We found that satellite glial cells (SGCs) express low levels of Jedi-1, similar to previous results[3]
Summary
The dorsal root ganglia (DRG) house the primary afferent neurons responsible for somatosensation, including pain. The cellular corpses are efficiently removed through phagocytosis, which we previously demonstrated is carried out in the DRG by satellite glia, a specialized type of peripheral glial cell that enshrouds the sensory neuron somas[3]. This clearance process involved the phagocytic receptors MEGF10 and Jedi-1 (MEGF12/PEAR1), homologs of the well-characterized engulfment receptors Draper in Drosophila melanogaster and CED1 in Caenorhabditis elegans[3,4,5]. These data indicate that Jedi-1 acts in a non-cell autonomous manner to modulate sensory neuron function
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