Morphology, axonal projection pattern, and response types of tectal neurons in plethodontid salamanders. II: Intracellular recording and labeling experiments

In the plethodontid salamanders Plethodon jordani and P. glutinosus , the morphology and axonal projections of 140 tectal neurons and their responses to electrical optic nerve stimulation were determined by intracellular recording and biocytin labeling. Six types of neurons are distinguished morphologically. TO1 neurons have wide dendritic trees that arborize mainly in tectal layers 1 and 3; they project bilaterally to the tegmentum and contralaterally to the medulla oblongata. TO2 neurons have very wide dendritic trees that arborize mainly in layers 2 and 3; axons project bilaterally or unilaterally to the pretectum and thalamus and ipsilaterally to the medulla oblongata. TO3 neurons have very wide and flat dendritic trees confined to layers 3–5; some have the same axonal projection as TO2 neurons, whereas others have descending axons that reach only the level of the cerebellum. TO4 neurons have narrower dendritic trees that arborize in layers 2 and 3; they project to the ipsilateral pretectum, thalamus, and medulla oblongata. TO5 neurons have dendritic trees that arborize in layers 1 and 2 or 1–3 and project bilaterally or unilaterally to the pretectum and thalamus. TO‐IN are interneurons, with a number of subtypes with respect to variations in dendritic arborization pattern. TO1–TO5 neurons generally have short latencies of 2–16 ms (average = 8.4 ms) at electrical optic nerve stimulation; first responses are always excitatory, often followed by inhibition. They are likely to be mono‐ or oligosynaptically driven by retinal afferents. TO‐IN interneurons have long latencies of 20–80 ms (average = 38.6 ms) and appear to receive no direct retinal input. With their specific dendritic arborization, consequent dominant retinal input, specific axonal projections, the different types of tectal projection neurons constitute separate ascending and descending visual pathways. Hypotheses are presented regarding the nature of the information processed by these pathways. J. Comp. Neurol. 404:489–504, 1999. © 1999 Wiley‐Liss, Inc.