Abstract
BackgroundRag1 (Recombination activation gene-1) mediates genomic rearrangement and is essential for adaptive immunity in vertebrates. This gene is also expressed in the olfactory epithelium, but its function there is unknown.ResultsUsing a transgenic zebrafish line and immunofluorescence, we show that Rag1 is expressed and translated in a subset of olfactory sensory neurons (OSNs). Neurons expressing GFP under the Rag1 promoter project their axons to the lateral region of the olfactory bulb only, and axons with the highest levels of GFP terminate in a single glomerular structure. A subset of GFP-expressing neurons contain Gαo, a marker for microvillous neurons. None of the GFP-positive neurons express Gαolf, Gαq or the olfactory marker protein OMP. Depletion of RAG1, by morpholino-mediated knockdown or mutation, did not affect axon targeting. Calcium imaging indicates that amino acids evoke chemotopically organized glomerular activity patterns in a Rag1 mutant.ConclusionRag1 expression is restricted to a subpopulation of zebrafish olfactory neurons projecting to the lateral olfactory bulb. RAG1 catalytic activity is not essential for axon targeting, nor is it likely to be required for regulation of odorant receptor expression or the response of OSNs to amino acids.
Highlights
Rag1 (Recombination activation gene-1) mediates genomic rearrangement and is essential for adaptive immunity in vertebrates
Each olfactory sensory neurons (OSNs) expresses a single allele of one odorant receptor [1] on a dendrite that is exposed to the external world, and on an axon terminal that extends into the brain [2]
Rag1 expression in the zebrafish olfactory system Using a transgenic zebrafish line in which the coding sequence of Rag1 within a PAC was replaced with GFP, Shuo Lin and colleagues have reported the expression of Rag1 in olfactory sensory neurons [15]
Summary
Rag (Recombination activation gene-1) mediates genomic rearrangement and is essential for adaptive immunity in vertebrates This gene is expressed in the olfactory epithelium, but its function there is unknown. Animals possess a number of chemosensory systems that enable them to perceive diverse stimuli in the environment. One such system is the olfactory system, which detects chemicals by a large number of olfactory sensory neurons (OSNs) in the nose. The projection of OSNs is highly ordered: all neurons expressing a given receptor converge to the same region in the ipsilateral olfactory bulb [3,4,5], terminating in a single glomerulus, i. As a result of this well-ordered projection, chemical information is presented to the brain as spatial activity patterns across the array of glomeruli in the olfactory bulb [8,9]
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