%0 Journal Article %A SD Meriney %A G Pilar %A M Ogawa %A R Nunez %T Differential neuronal survival in the avian ciliary ganglion after chronic acetylcholine receptor blockade %D 1987 %R 10.1523/JNEUROSCI.07-12-03840.1987 %J The Journal of Neuroscience %P 3840-3849 %V 7 %N 12 %X We have described in the preceding 2 papers the development of the pharmacological and contractile properties of all targets of the ciliary ganglion: the iris and ciliary body (Pilar et al., 1987), and the choroidal coat (Meriney and Pilar, 1987). In this paper, we examine the chronic effects of ACh receptor (AChR) blockade on ciliary ganglion neuron survival. Nicotinic or muscarinic AChR blockers were administered daily to developing chicken embryos during the normal neuronal death period in the ciliary ganglion. The effects of the blockers on ganglionic and neuromuscular transmission were assessed, and neuronal survival was assayed by counting both the total number of ganglion neurons and the selectively HRP-labeled ciliary neurons after the normal neuronal death period. Blockade of ganglionic transmission decreases survival in both populations of neurons. Blockade of neuromuscular muscular transmission increases survival in the ciliary population, which innervates the striated iris and ciliary body muscle. In contrast, blockade of synaptic activity has various influences on the survival of the choroid population, which innervates the smooth muscle of the choroid coat. Smooth muscle muscarinic receptor blockade with atropine does not influence survival. At higher doses (which block ganglionic transmission), atropine decreases choroid survival. Survival of the choroid population is increased by nicotinic blockade with 75 micrograms alpha bungarotoxin (alpha BTX), but decreased by 12.5 micrograms alpha BTX. Two main conclusions arise from these studies. Activation of postsynaptic AChRs in both the ganglion and the periphery are important in the regulation of neuronal survival. These effects usually occur in opposite directions: Blockade of ganglionic transmission decreases neuronal survival, while paralysis of neuromuscular transmission increases neuronal survival. This embodies the “balance” hypothesis (Cunningham, 1982) for neuronal survival, which states that motoneurons must balance afferent and target interactions during a critical period after synapses are formed in both regions. The present observations support this hypothesis. However, although both ciliary and choroid neurons have been shown to depend on the presence of the periphery for survival, target muscle paralysis via AChR blockade rescues the ciliary neurons but does not influence survival in the choroid population. Target-dependent regulation of choroid neuron survival during the normal neuronal death period is clearly different from the regulation of ciliary neuron survival. %U https://www.jneurosci.org/content/jneuro/7/12/3840.full.pdf