Are neuronal precursor cells committed to coexpress different neuroactive substances in early amphibian neurulae?

Considering the initial expression of neurotransmitters and neuropeptides immediately after neural induction in amphibian embryos, we previously pointed out that a neuronal cell population emerges from neural plate (NP) and neural fold (NF) expressing very early specific cholinergic, catecholaminergic, GABAergic and peptidergic traits. The purpose of the present work was to investigate the extent to which the neuroblasts that are present in the neurectoderm immediately after gastrulation are committed to give rise to multiple subsets of neurons containing various combinations of neuroactive transmitters rather than to different subpopulations of neurochemically homogeneous neurons. By means of double immunocytochemical localization with a monoclonal TOH-antibody and polyclonal antibodies against GABA or somatostatin, no coexistence of neurotransmitters and neuropeptide was ever found in neuronal subpopulations arising in vitro from NP or NF.

From presumptive ectoderm to neural cells in an amphibian.

As an immediate consequence of neural induction during gastrulation, some neuroectodermal cells acquire the ability to develop a number of specific neuronal and astroglial features, without requiring subsequent chordamesodermal cues. Thus, cholinergic, dopaminergic, noradrenergic, gabaergic, somatostatinergic, enkephalinergic, etc. traits are expressed in cultures of neural plate and neural fold isolated from amphibian late gastrulae immediately after induction and cultured in a defined medium.

Neural induction.

The molecular mechanism of neural induction of embryonic cells is an important but poorly understood problem in neuroembryology. Glycoconjugates in the target cell plasma membrane and/or its structural organization play a key role in the reception of the inductive signal. It is the competent target tissue itself which probably contains the capacity and specificity for neuralization.