We labeled axonal projections using carbocyanine dyes in the developing rat brain to study cellular interactions that might underlie the establishment of thalamocortical connectivity. By embryonic day 14 (E14), groups of neurons in the ventral diencephalon and the primitive internal capsule have established projections to the dorsal thalamus, and thalamic fibers pass in topographic order among them. Simultaneously, axons from the early-born cells in both subplate and marginal zone (i.e., the original cortical preplate) establish an ordered array that fills the intermediate zone. Thalamic axons and preplate fibers meet in the lateral part of the internal capsule (at E15 for occipital cortex and dorsolateral thalamus). Subsequently, selective labeling of corresponding thalamic and early corticofugal projections reveals thalamic fibers growing in association with early corticofugal axons, right up to the cortical subplate. A small carbocyanine crystal implanted at any point in the cortex shortly after the arrival of thalamic axons (E16 for the occipital cortex) labels a single, tight bundle containing both descending and ascending fibers, rather than two separate tracts, providing further evidence for intimate topographic association of the two axon systems. Crystals placed in a row, parasagittally or coronally along the hemisphere, reveal separate, topographically distributed, discrete fiber bundles throughout the pathway, leading to spatially ordered groups of back-labeled thalamic cells. These results indicate that the topography of thalamic axons is maintained throughout the pathway and that they reach the cortex by associating with the projections of a number of preexisting cells, including the preplate scaffold.Key words: cortex; thalamus; rat; pioneer axons; development; subplate; perireticular nucleus; preplate; "handshake" hypothesis; internal capsule; thalamic reticular nucleus; axon guidanceThe adult mammalian neocortex consists of numerous areas, differing in connectivity and f unctional properties (Peters and Jones, 1985), many of which have a distinctive cytoarchitectural appearance (Brodmann, 1909). Thalamic axons, the carriers of most afferent information to the cortex, arrive before the majority of cortical neurons are born (L und and Mustari, 1977;Rakic, 1977;Wise and Jones, 1978;Shatz and L uskin, 1986). These early afferent projections, if they are topographically distributed and distinctive for each particular area, could play a part in initiating regional differentiation (O'Leary, 1989). In that case, unraveling the mechanisms by which thalamic axons are directed toward their target regions is important in understanding how cortical organization is determined.The representation of the thalamus on the cortex and the topographic distribution of thalamic axons have been studied extensively in postnatal and adult rodents (C aviness and Frost, 1980; Frost and C aviness, 1980; Crandall and C aviness, 1984;Bernardo and Woolsey, 1987; C aviness, 1988;Agmon and Connors, 1991;Agmon et al., 1993Agmon et...
