Tectum

Abstract: Retinal fibers in both the pigeon and owl terminate in a multi-nucleate complex of the dorsal thalamus, including the nuclei lateralis anterior, dorsolateralis-anterior, dorsolateralis anterior, pars lateralis et pars magnocellularis, and collectively designated the nucleus opticus principalis thalami (OPT). Efferent projections of OPT were traced with the Fink-Heimer method into the ipsilateral lateral forebrain bundle, and via the dorsal supraoptic decussation, into the contralateral lateral forebrain bundle. OPT projections terminate within an elevation, or “Wulst” on the dorsum of the telencephalon. The Wulst is a multilaminate structure containing a deep lying layer of large cells the hyper-striatum dorsale (HD), a dispersed cell layer — the hyperstriatum intercalatus suprema (HISm), a granule cell layer or nucleus intercalatus hyperstriatum accessorium (IHA), an overlying hyperstriatum accessorium (HA) consisting of a broad layer of medium sized neurons, and an overlying fibro-molecular layer. Each of these laminae are particularly well developed in the owl, where the granule cell layer is divisible into inner and outer bands (IHAex and IHAint). The projections of OPT terminate in the HD, HISm and IHA. A homotopic projection was also found in the contralateral Wulst. The pattern of termination was similar in both the pigeon and the owl, though the pattern of distribution was more apparent in the owl with its massive OPT and Wulst. Medial, nonvisual, thalamic cell groups in the pigeon (nuclei dorsolateralis pars medialis and dorso-medialis anterior) also project bilaterally upon the Wulst, but terminate in a more medial, nonvisual and cytologically different, portion of HD. The projections of the medial thalamic nuclei did not overlap with those of OPT and appear to be a separate functional system of still undetermined nature. Efferent axons of the “visual Wulst” of the pigeon and owl project upon the ipsilateral lateral hyperstriatum ventrale, neostriatum and upon the peri-ectostriatal belt (Karten and Hodos, '70). Extratelencephalic projections via the septomesencephalic tract (TSM) terminate in OPT, the internal lamina of the ventral lateral geniculate nucleus (LGv), pretectal nuclei and optic tectum. A small contingent of fibers of the TSM cross to the opposite side in the dorsal supraoptic decussation, to terminate in LGv, and, in the owl, in the contralateral ventromedial tectum. Dense terminal degeneration has also been observed in the deeper layers of the ipsilateral optic tectum of pigeon whereas in the owl the projection of the Wulst also extends to the more superficial layers of the tectum, and appears to be topographically arranged. The numerous similarities between the system described above and the geniculostriate visual pathways of mammals seems apparent. These findings clearly indicate that the geniculo-striate type of system may attain elaborate degrees of development in nonmammalian as well as mammalian brains.

Abstract: The receptive field properties and functional organization of visual and auditory responses were studied in the optic tectum of the barn owl (Tyto alba). Most units throughout the depth of the tectum responded to both visual and auditory stimuli. The entire visual field of each eye was represented topographically in the contralateral tectum. In the portion of the tectal map representing the zone of binocular vision, 50% of the superficial layer units and 100% of the deep; layer units were driven binocularly. The representation of the frontal binocular region of space was greatly expanded in the map; the average magnification factor was 3 times greater for the frontal binocular zone than for the monocular zone. The responses of the superficial and deep tectal units to auditory stimuli were space specific; they responded only when a sound source was located in a particular region of space, or receptive field, regardless of the intensity or type of sound used. Most auditory receptive fields contained a distinct "best area" where a sound source was most effective in driving the unit. Auditory space, as defined by receptive fields and best areas, was represented topographically in the tectum. The auditory and visual maps of space had the same orientations, positions, magnification factors, and termination coordinates at the anterior and dorsal edges of the tectum. Yet the maps lost their registry near the posterior and ventral margins where the most peripheral regions of space were represented. These characteristics suggest that the spatiotopic organization in the tectum is a compromise between a tendency for the space representations of different modalities to align and for the representation of each modality to fill the entire tectum.

Abstract: The optic tecta of surgically produced three-eyed tadpoles were chronically exposed to the N-methyl-D-aspartate (NMDA) receptor antagonist aminophosphonovaleric acid (APV), or to NMDA itself, to assess the influence of NMDA receptor/channels on the eye-specific segregation of retinal ganglion cell (RGC) terminals that occurs whenever two retinas innervate one tectal lobe. Exposure of the tectum to the active isomer of APV produces desegregation of the RGC terminals without blocking electrical activity in the afferents or altering their terminal arbor morphology. Exposure to the inactive isomer of APV causes no perturbation of the normal stripe pattern. APV-induced desegregation is completely reversible within 2 weeks of removal of the APV. In addition, exposure of the optic tectum to NMDA results in stripes with sharper borders and fewer forks and fusions than untreated animals. These results suggest that the NMDA receptor/channel plays a role in eye-specific segregation in the three-eyed tadpole.