Abstract
The mammalian brain is characterized by orderly spatial distribution of its cellular components, commonly referred to as topographical organization. The topography of cortical and subcortical maps is thought to represent functional or computational properties. In the present investigation, we have studied map transformations and organizing principles in the projections from the cerebral cortex to the pontine nuclei, with emphasis on the mapping of the cortex as a whole onto the pontine nuclei. Following single or multiple axonal tracer injections into different cortical regions, three-dimensional (3-D) distributions of anterogradely labeled axons in the pontine nuclei were mapped. All 3-D reconstructed data sets were normalized to a standardized local coordinate system for the pontine nuclei and uploaded in a database application (FACCS, Functional Anatomy of the Cerebro-Cerebellar System, available via The Rodent Brain Workbench, http://www.rbwb.org). The database application allowed flexible use of the data in novel combinations, and use of a previously published data sets. Visualization of different combinations of data was used to explore alternative principles of organization. As a result of these analyses, a principal map of the topography of corticopontine projections was developed. This map followed the organization of early spatiotemporal gradients present in the cerebral cortex and the pontine nuclei. With the principal map for corticopontine projections, a fairly accurate prediction of pontine target area can be made for any site of origin in the cerebral cortex. The map and the underlying shared data sets represent a basis for modeling of topographical organization and structure–function relationships in this system.
Highlights
Classical recording studies have revealed discrete localization of body part representations in motor and somatosensory cortical areas and represent the basis for maps of somatotopical organization, featuring a homunculus cartoon superimposed on the brain surface
The present report is based on findings from 13 not previously published single and multiple tracing experiments, combined with data from 6 previously published experiments downloaded from the FACCS database application available via The Rodent Brain Workbench
All data on distribution of corticopontine axons were normalized to a standardized, local coordinate system for the pontine nuclei (Bjaalie et al, 2005; Bjaalie and Leergaard, 2006; Brevik et al, 2001; Leergaard et al, 2000a, b, 2004), according to procedures detailed in Bjaalie and Leergaard (2006) and on the FACCS web pages
Summary
Classical recording studies have revealed discrete localization of body part representations in motor and somatosensory cortical areas (see, e.g., Foerster, 1936; Penfield and Boldrey, 1937; Woolsey et al, 1942) and represent the basis for maps of somatotopical organization, featuring a homunculus cartoon superimposed on the brain surface. At higher levels of processing in cortical and subcortical networks, more complicated patterns of organization occur (see, e.g., Felleman and Van Essen, 1991; Gerfen, 1992; Joel and Weiner, 2000). Such more complicated maps are viewed as important in the context of understanding brain function (see, e.g., Sporns et al, 2004; Strogatz, 2001; Thivierge and Marcus, 2007). Based on findings in newborn rats, we have earlier proposed that the overall topographical layout of corticopontine projections is determined by interaction of temporal and spatial gradients operative within the source (cerebral cortex) and target region
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