Within the developing chick hindbrain, motor neurons differentiate in columns on either side of the ventral midline floor plate. Along the rostrocaudal axis, populations of motor neurons are organized segmentally with the trigeminal (V) and facial (VII) nuclei occupying successive pairs of rhombomeres. To reach their targets, motor axons follow stereotyped pathways. Branchiomotor and visceral motor axons of the Vth and VIIth nerves first project in a dorsal (lateral) direction away from the floor plate and towards the nerve exit point located in the alar plate of the even-numbered rhombomere of the pair. Having exited the hindbrain, axons grow in association with the cranial sensory ganglia before branchiomotor axons enter the branchial arches. We have investigated some of the factors that might guide cranial motor axons using a three-dimensional collagen gel culture system. When explants of hindbrain basal plate containing trigeminal or facial motor neurons were co-cultured with floor plate explants, axon outgrowth from the side facing the floor plate was inhibited in a manner consistent with chemorepulsion. When basal plate explants that contained an exit point were cultured alone, motor axons grew to the exit point and then stopped. When basal plate explants were co-cultured with trigeminal ganglia, motor outgrowth was increased in comparison with that in control cultures, suggesting a trophic influence. The findings presented here indicate that motor pathways are elaborated due to a progression of signals to which the growth cones respond in sequence.
Near the floor plate of the embryonic neural tube there is a group of neuroepithelial precursor cells that are specialized for production of the oligodendrocyte lineage. We performed experiments to test whether specification of these neuroepithelial oligodendrocyte precursors, like other ventral neural cell types, depends on signals from the notochord and/or floor plate. We analyzed heterozygous Danforth's short tail (Sd/+) mutant mice, which lack a notochord and floor plate in caudal regions of the neural tube, and found that oligodendrocyte precursors did not appear at the ventricular surface where there was no floor plate. Moreover, oligodendrocytes did not develop in explant cultures ofSd/+ spinal cord in the absence of a floor plate. When a second notochord was grafted into an ectopic position dorsolateral to the endogenous notochord of a chicken embryo, an additional floor plate was induced along with an ectopic focus of oligodendrocyte precursors at the ventricular surface. Oligodendrocytes developed in explants of intermediate neural tube only when they were cocultured with fragments of notochord or in the presence of purified Sonic hedgehog (Shh) protein. Thus, signals from the notochord/floor plate, possibly involving Shh, are necessary and sufficient to induce the development of ventrally derived oligodendroglia. These signals appear to act by specifying the future fate(s) of neuroepithelial cells at the ventricular surface rather than by influencing the proliferation or differentiation of prespecified progenitor cells in the parenchyma of the cord.
Of paramount importance for hindbrain patterning is positional information that is laid down along the rostrocaudal axis. Recent findings suggest that retinoic acid may establish rostrocaudal domains of gene expression that confer on rhombomeres their specific identities; these domains display different responses to dorsoventral signals that further refine the repertoire of cellular fates therein. After rhombomere boundaries form, a high degree of segmental autonomy is balanced by a continuing capacity for interaction along the rostrocaudal axis, exemplified by the generation of the neural crest.
Expression of beta-tectorin mRNA in the inner ear of the embryonic and early posthatch (PH) chick was studied by in situ hybridisation. In the PH chick, beta-tectorin mRNA is expressed in the basilar papilla, in the clear and the cuboidal cells that lie either side of the papilla, in the striolar regions of the maculae, and in two small groups of cells lying adjacent to the midline in the cristae of the anterior and posterior ampullae. Expression of beta-tectorin is not observed in the lateral ampulla. In the sensory epithelia of the PH chick in which beta-tectorin mRNA is detected, expression is restricted to the supporting cell population. During development of the cochlear duct, beta-tectorin expression begins between embryonic (E) days 5 and 6. At E6, expression is observed throughout the length of the duct but is highest at the distal end. By E7, the pattern of expression is reversed and is highest at the proximal end of the cochlea, suggesting that a wave of high beta-tectorin expression passes disto-proximally along the papilla during E6 and E7. Expression of beta-tectorin mRNA is not detected in the homogene cells at any stage during the development of the cochlear duct, indicating that these cells do not synthesise one of the two major proteins of the avian tectorial membrane. The distribution of supporting cells expressing beta-tectorin mRNA in the different epithelia was compared with the distribution of sensory cells that have type B hair bundles, those with shaft links restricted to basal regions of their stereocilia, and sensory cells that have type A bundles, those with shaft links all over the entire surface of their stereocilia. Hair cells with type A hair bundles are never found in association with supporting cells expressing beta-tectorin. Although there is a correspondence in the basilar papilla and the maculae of the utriculus and lagena between the distribution of supporting cells expressing beta-tectorin mRNA and hair cells with type B bundles, this correlation does not generalise to the other sensory epithelia.
The enzyme nitric oxide synthase can be localised by NADPH-diaphorase histochemistry. Here we have applied this technique to the optic lobe of the locust Schistocerca gregaria and revealed new features of the insect visual system. Extensive but locally intense staining is associated with identified tracts, distinct neuropiles and cell body groups, and a detailed analysis of stained elements is provided here. The must striking staining occurs in the anterior lobe of the lobula complex and its connection with the medulla by means of the dorsal uncrossed bundle. Eleven groups of cell bodies are identified and their contribution to fibre tracts and neuropile areas is described. Diaphorase-positive fibre tracts pass between all major subdivisions of the optic lobe, but there are no conspicuous fibre connections from the optic lobe to the brain. The widespread distribution of NADPH-diaphorase staining in the optic lobe suggests that nitric oxide is likely to play an important role in information processing in insect vision.