a1 Department of Psychology, Dalhousie University, Life Sciences Center, Halifax, Nova Scotia, Canada
The cellular mechanisms by which nervous systems evolve to match evolutionary changes occurring in the rest of the body remain largely unexplored. In a distal visual neuropil of a previously unexamined ancient dipteran family, Stratiomyidae, homologues of all of the periodic neurons known already from more recent Diptera can be recognized, occupying the same locations within the unit structure. This points to extreme developmental stasis for more than 200 million years, conserving both cell identity and position. The arborizations that some neurons make also have remained conservative, but others show marked differences between families in both size and branching patterns. At the electron-microscopical level, extensive differences in synaptic connectivity are found, some sufficient to radically redefine the systems roles of particular neurons. The findings bear out an earlier prediction that changes in the connectivity matrix linking conserved neurons may have been a major factor in implementing evolutionary change in the nervous system.
(Received May 12 1989)
(Accepted July 19 1989)
c1 D. Moore&s current address is Department of Biological Sciences, East Tennessee State University, Johnson City, TN.
Reprint requests to: S.R. Shaw, Department of Psychology, Dalhousie University, Life Sciences Center, Halifax, Nova Scotia, Canada B3H 4Jl.