Classically, mossy fiber and climbing fiber terminals are regarded as having very different spatial distributions in the cerebellar cortex. However, previous anatomical studies have not studied these two major cerebellar inputs with sufficient resolution to confirm this assumption. Here, we examine the detailed pattern of collateralization of both types of cerebellar afferent using small injections of the bidirectional tracer cholera toxin b subunit into the posterior cerebellum. The cortical and zonal location of these injections was characterized by mapping climbing fiber field potentials, the distribution of retrogradely labeled olivary neurons, and the intrinsic zebrin pattern of Purkinje cells.Labeled climbing fiber collaterals were distributed as longitudinal strips and were always accompanied by clusters of labeled mossy fiber rosettes in the subjacent granular layer. Two-and three-dimensional reconstructions and quantitative analysis showed that mossy fibers also collateralized to other stripe-like regions usually below Purkinje cells with the same zebrin-positive or zebrin-negative characteristics as that of the injection site and associated climbing fiber collaterals. The distribution of retrogradely labeled neurons in two major sources of mossy fibers, the lateral reticular and basilar pontine nuclei, revealed interlobular and some interzonal differences.These data indicate that nonadjacent cerebellar zones, sharing the same climbing fiber input and zebrin identity, also share a common mossy fiber input. Other cerebellar cortical regions that receive collaterals from the same mossy fibers usually also have the same zebrin signature. Together with the distribution of neurons in precerebellar centers, the findings suggest a revision of the modular hypothesis for information processing in the cerebellar cortex.
This study provides a detailed anatomical description of the relation between olivo-cortico-nuclear modules of the intermediate cerebellum of the rat and the intrinsic zebrin pattern of the Purkinje cells. Strips of climbing fibers were labeled using small injections of biotinylated dextran amine into either the medial or dorsal accessory olives, while, in some cases, simultaneous retrograde labeling of Purkinje cells was obtained using gold-lectin injections into selected parts of the interposed nuclei. Our data are represented in a new, highly detailed, cortical surface reconstruction of the zebrin pattern and in relation to the collateral labeling of the climbing fibers to the cerebellar nuclei. We show that the somatotopic regions of the dorsal accessory olive behave differently in their projections to essentially zebrin-negative regions that represent the C1 and C3 zones of the anterior and posterior parts of the cortex. The rostral part of the medial accessory olive projects to zebrin-positive areas, in particular to the P4+ band of the anterior lobe and lobule VI and to the P5+ band of the posterior lobe, indicating that C2 has two noncontiguous representations in the SL and crus 1. By relating the areas of overlap that resulted from the injections in the accessory olives, i.e., labeling of climbing fiber strips and patches of climbing fiber nuclear collaterals, with the results from the injections in the interposed nuclei, i.e., retrograde labeling of Purkinje cells and of inferior olivary neurons, direct verification of the concept of modular cerebellar connections was obtained.
To identify cerebellar regions that are involved in the control of limb muscles, rabies virus was injected into the tibialis anterior (TA), the gastrocnemius (GC) or, for comparison, into the flexor digitorum (FD) muscles of the rat. Progression of retrograde transneuronal infection at supraspinal levels was assessed after variable time spans and was divided into three groups. Initially, infected neurons were observed in the reticular formation, lateral vestibular nucleus, red nucleus and motor cortex (group 1). Group 2 was characterized by labelling within the cerebellar nuclei as well as of two vermal strips of Purkinje cells (PCs). Double-labelling with zebrin enabled identification of these strips as the lateral part of the A1- and B-zone. For TA both zones were ipsilateral, whereas for GC the A1 strip predominated contralaterally. Group 3 infections showed additional labelling of multiple, in part bilateral, identifiable strips of PCs in vermis, paravermis and hemisphere. FD injections resulted in less robust labelling of vermal strips and more pronounced labelling within paravermal and hemispheral zonal regions. Only sporadic labelling in corresponding regions of the inferior olive and no labelling of cortical interneurons or granule cells was observed. Prolonged infection was seen to result in degeneration of PCs and possibly of motoneurons. We conclude that vermal, paravermal as well as hemispheral zones of the cerebellar cortex converge upon motoneurons that innervate a particular muscle. In addition, individual zones may control motorpools of different muscles and thus contribute to muscle synergies.
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