The origin of dopaminergic systems in chordate brains: insights from amphioxus

• Elisabeth Zieger ^[1] ; Thurston C. Lacalli ^[2] ; Mario Pestarino ^[3] ; Michael Schubert ^[1] ; Simona Candiani ^[3]
  1. [1] Sorbonne Universités

     Sorbonne Universités

     París, Francia

     
  2. [2] University of Victoria

     University of Victoria

     Canadá

     
  3. [3] University of Genova, Italy

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• Localización: International journal of developmental biology, ISSN 0214-6282, Vol. 61, Nº. Extra 10-12, 2017 (Ejemplar dedicado a: The Amphioxus Model System / coord. por Zbynek Kozmik), págs. 749-761
• Idioma: inglés
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• Resumen

  • The basic anatomy of the central nervous system (CNS) is well conserved within the vertebrates and differs in significant ways from that of non-vertebrate chordates. Of the latter, amphioxus is of special interest, being the best available stand-in for the basal chordate condition. Immunohistochemical and gene expression studies on the developing CNS of amphioxus embryos and larvae are now sufficiently advanced that we can begin to assign specific neurotransmitter phenotypes to neurons identified by transmission electron microscopy (TEM), and then compare the distribution of cell types to that in vertebrate brains. Here, by monitoring tyrosine hydroxylase (TH) transcripts and protein, along with serial TEM, we identify a population of catecholamine-containing neurons in the anterior nerve cord of amphioxus larvae and describe their pattern of synaptic inputs and outputs. Inputs parallel those to the large paired neurons that control the larval escape response, suggesting that the TH+ system functions as an accessory excitatory and perhaps modulatory pathway in larval locomotion, with the added feature of recruiting an assortment of additional interneurons to the circuitry. The TH+ cells probably contain either L-DOPA or dopamine, and correspond closely with a cell population known from previous work on adult amphioxus to be dopaminergic. This population lies in a CNS domain now thought to comprise a combined vertebrate diencephalon plus mesencephalon, the implication being that dopaminergic nuclei in both of these brain regions could derive from a single dien-mese