Tc. Lacalli et Sj. Kelly, The infundibular balance organ in amphioxus larvae and related aspects of cerebral vesicle organization, ACT ZOOL, 81(1), 2000, pp. 37-47
Serial EM reconstructions were used to examine the organization and constit
uent cell types of the infundibular region of the cerebral vesicle (c.v.) i
n a 12.5-day larva of Branchiostoma floridae. The balance organ lies just i
n front of the infundibular cells and consists of 10 electron-dense cells w
ith long, bulbous cilia, each surrounded by a ring of accessory cells. The
ciliary bulb cells have axons that terminate in vesicle-filled swellings th
at lack identifiable synapses. The accessory cells have short basal process
es that are minor contributors to the adjacent neuropile. Based on morpholo
gy, we suggest a mechanosensory function for the ciliary bulb cells, possib
ly related to balance or motion detection. Scattered cells of similar type
are found elsewhere in the cerebral vesicle, along with a variety of other
neurones with caudally projecting axons and varicosities, but few synapses.
Instead, nonsynaptic, paracrine secretion appears to be the predominant mo
de of transmitter release in the neuropile and ventral tracts of the cerebr
al vesicle. The closest vertebrate homologue of this part of the amphioxus
brain is arguably the limbic core of the caudal diencephalon and mesencepha
lon, including the homeostatic control centres of the hypothalamus. We post
ulate that this limbic core is an ancient structure traceable at least as f
ar back in evolution as the common ancestor of amphioxus and vertebrates.