Quantitative and topographical study of retinal ganglion cells in the chameleon (Chameleo chameleon).

Chameleons display a number of well-described physiological peculiarities of their visual system, but there is no information on the topography of the retinal ganglion cell layer. In the present study, ganglion cell density of the chameleon retina was constructed from whole mounts of the retina stained with cresyl violet. For the identification of ganglion cells, these latter cells were labelled retrogradely with horseradish peroxidase applied to the optic nerve. Using this criterion, the proportion of ganglion cells was estimated to represent 80% of retinal cells, while glial cells and amacrine cells represented 14 and 6%, respectively, of the total cell population of the retina. As for the main features of the retinal map, first, ganglion cells were distributed inhomogeneously within the ganglion cell layer, and revealed the existence of a putative area centralis. Second, a horizontal visual streak, which showed two peak density areas, was identified. These features point out the degree of specialisation of the chameleon retina and the complexity of its visual system.

Localization of motoneurons innervating the extraocular muscles in the chameleon (Chamaeleo chameleon).

The topography and localization of motoneurons innervating the six extraocular muscles in the chameleon (Chamaeleo chameleon) was studied following HRP injection in each of these individual muscles. Four muscles were innervated ipsilaterally: medial rectus, inferior rectus, inferior oblique and lateral rectus. The medial rectus muscle was innervated by the dorsomedial part of the oculomotor nucleus. The innervation to the inferior rectus muscle arose from the lateral part of the intermediate oculomotor subnucleus, which extended to the lateral part of the dorsal subdivision. The lateral rectus muscle was innervated by the abducens nucleus, which was composed by two subgroups of labeled cells, respectively observed in the principal and accessory abducens subnuclei, whereas efferents to the inferior oblique muscle originated from both the ventral and intermediate oculomotor subnuclei. The contralateral pattern consisted of motoneurons innervating the superior rectus and the superior oblique that were located respectively in the caudal portion of the ventral oculomotor nucleus and in the trochlear nucleus. These results confirmed data reported in most vertebrate species, and were discussed from a comparative and functional point of view.

The retinopetal visual system in the chameleon (Chameleo chameleon).

Intraocular injections of rhodamine and horseradish peroxidase in chameleon, labelled retrogradely neurons in the ventromedial tegmental region of the mesencephalon and the ventrolateral thalamus of the diencephalon. In both areas, staining was observed contralaterally to the injected eye. Labelling was occasionally observed in some rhombencephalic motor nuclei. These results indicate that chameleons, unlike other reptilian species, have two retinopetal nuclei.

A quantitative ultrastructural study of the optic nerve of the chameleon.

The optic nerve of adult chameleons was investigated with an electron microscope. The total number of retinal ganglion cell axons, the proportion of myelinated axons, the frequency distributions of myelinated and unmyelinated axon diameters were estimated, together with the volume occupied by glial processes. These were distinguished from unmyelinated axons using an antibody directed against glial fibrillary acidic protein, in a post-embedding procedure. The total number of fibers was estimated to be 405,235 +/- 60,000 axons. The proportion of myelinated fibers varied with position between the eyeball and the chiasma; being 22-27% close to the eyeball, rising to 42-47% halfway along the optic nerve and to 56-62% close to the chiasma. Myelinated and unmyelinated fiber diameter distributions were unimodal and positively skewed, with modes of 0.7 microm and 0.2 microm, respectively. There was a significant regional variation in the size of optic nerve axons. Large myelinated axons were observed in the dorsal and ventral periphery, whereas smaller myelinated fibers and a high proportion of unmyelinated fibers were found in the center of the nerve.