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Notes: This paper examines the organization of host afferents within cerebellar grafts implanted into kainic acid lesioned cerebellum. Our selection of a cerebellum, a prime example of a ‘point-to-point’ system, permits precise determination of the degree and the specificity of host-graft interactions.One month after a cerebellar injection of kainic acid, the lesion produced can be divided into two concentric regions: (i) a central necrotic zone, totally depleted of neurons (zone 1), and (ii) a peripheral zone which lacks all Purkinje cells but preserves its cortical lamination (zone 2). Two months after the implantation of solid pieces of embryonic cerebellum, the graft has evolved into a minicerebellar structure, occupying most of zone 1. The grafted minicerebellum consists of a highly convoluted trilaminated cortex with a core containing deep nuclear neurons. Purkinje cells are positioned between the molecular and granular layer with their short and irregular dendrites branching within the former. Donor foetal Purkinje cells migrate into the contiguous portion of the molecular layer of the host zone 2. These embryonic neurons set up within the upper three-quarters of the host molecular layer, and develop monoplanar dendritic trees that span the whole width of the layer.The organization of host-graft interactions was studied by autoradiography of anterogradely transported tritiated leucine, injected in the host bulbar region containing the caudal half of the inferior olivary complex (origin of all vermal climbing fibres) and the dorsally adjacent paramedian reticular nucleus (origin of a few mossy fibres). Numerous labelled fibres cross the host-graft interface from the white matter of the host cerebellum, and provide innervation to the minicerebellar structure. The vast majority of these labelled axons terminate in the molecular layer, forming axonal arborizations that follow the shape of the Purkinje cell dendrites. The labelled climbing fibres are organized into uneven sagittally aligned strips, which mimic that of olivocerebellar projections in control rats. Only a small proportion of host labelled fibres end in the donor granular layer, forming typical mossy fibre rosettes. The latter are present in the region of the graft close to the host-graft interface. In addition, labelled axons are observed climbing over the dendritic trees of grafted Purkinje cells that have invaded a portion of the host molecular layer of zone 2. In all regions containing grafted Purkinje cells and labelled climbing fibres, the density of the innervation is close to normal with practically all Purkinje cells receiving a climbing fibre.The extensive integration of the grafted cells into the deficient neuronal networks of the host clearly illustrates the positive neurotropic effect exerted by immature cerebellar neurons on adult extracerebellar afferent fibres. The hodological integration, allowing a possible restoration of the impaired cerebellar circuitry, takes place respecting the specificity and topographic distribution which characterize the ‘point-to-point’ arrangement of normal cerebellar circuitry.

Notes: Homotopic and isochronic transplantations of the right dorsal half of the mesencephalic vesicle have been performed between chick and quail embryos at the stage of 10–14 somites. Analysis of the extension of the graft, by means of the quail nucleolar marker, combined with cytoarchitectonic analysis has disclosed that the transplanted neuroepithelium gives rise to isthmic nuclei and to a portion of rostral cerebellum, in addition to the optic tectum and mesencephalic dorsal grisea. These results show that the rostral portion of the cerebellar primordium is located in the so-called ‘mesencephalic’ alar plate, thus considerably more rostrally than previously supposed. This has been confirmed by two other types of chimeric embryos resulting from homotopic transplantation of either: (i) the quail right alar plate of the first rhombencephalic vesicle, which gives rise to caudal but not rostral cerebellum in the operated side, or (ii) the right alar portion of a segment of the quail neural tube including both the caudal third of the mesencephalic vesicle and the rostral half of the first rhombencephalic vesicle, which gives rise to the whole hemicerebellum in the operated side. Moreover, in chimeric embryos with transplants restricted to the mesencephalic alar plate, the grafted portion of the cerebellar primordium gives rise both to deep cerebellar neurons and to all types of cortical neurons. Among the quail cortical neurons, the Purkinje cells, although intermingled with host Purkinje cells, are organized, at E18, in a characteristic longitudinal band which is strongly reminiscent of the longitudinal functional and morphological organization of the cerebellum. Other types of quail cortical neurons, that is, Golgi cells, granule cells, and molecular layer interneurons, are also observed within this sagittal band. In addition, quail granule cells and molecular layer interneurons as well as quail glial cells, extend over a larger territory on both sides of the longitudinal band containing quail Purkinje cells and even cross the midline and invade the contralateral hemicerebellum. In all types of chimeric embryos, the proliferation, migration, and differentiation of quail transplanted neurons, both in the isthmic region and in the cerebellum, evolve asynchronously from the host homologous ones, following a more precocious and faster developmental schedule. This asynchrony in the development of grafted and host isthmic and cerebellar homologous areas confirms and extends previous findings concerning the proliferation and migration of quail tectal cells in chick quail chimeric embryos (Senut and Alvarado-Mallart, 1987).

Notes: The expression of the homeobox-containing gene En-2 was analysed with the monoclonal antibody 4D9 in the chick central nervous system throughout embryogenesis. Confirming previous studies, early expression of the En-2 protein [beginning at stage 9 of Hamburger and Hamilton (HH9)] is restricted to a portion of the neural tube containing the primordia of the cerebellum, the isthmic region and the mesencephalic grisea, and forms a double gradient decreasing both caudally and rostrally from a high point located around the midbrain-hindbrain constriction. This mes-isthmo-cerebellar region contains all the En-2-positive germinative cells and the great majority of the En-2-positive postmitotic neurons throughout embryogenesis. Nevertheless, as the postmitotic neurons appear, En-2 expression also occurs outside this region: in two columns of non-motoneuron cells in rhombomeres two to four (between HH20 and HH30) and, from HH24 onwards, throughout the grey matter of the lumbar and thoracic spinal cord, with the exception of the ventral motoneuron columns. Here, a detailed description of En-2 expression is provided for the mes-isthmo-cerebellar region at stages HH30–32 [embryonic day (E) 71, HH37 (E11) and HH46 (E21, hatching). This allows the visualization of cellular groups with heterogeneous patterns of En-2 expression, which are specific for each group in the intensity of En-2 expression, the distribution of the labelled cells and the temporal regulation of the gene. The use of tyrosine hydroxylase antiserum shows coexpression of the tyrosine hydroxylase enzyme and En-2 protein in the caudal part of the nuclei tegmenti pedunculo-pontinus, the area ventralis of Tsai and the substantia grisea centralis, but not in the locus coeruleus. In the cerebellum, the first expression, which is located in the deep nuclei and parasagittal bands of Purkinje cells, is down-regulated when the molecular layer interneurons and the granular cells begin to express the gene, at the end of embryogenesis. Finally, at hatching, En-2 expression permits the visualization in the cerebellum of a population of small En-2-negative cells located around the Purkinje cells that may correspond to those described in chick/quail chimaeras as having an origin different from that of the bulk of granular neurons.

Notes: [Auszug] Purkinje cell degeneration (pcd) is a recessive mutation which arose spontaneously in the C57BL/cdJ mouse strain2. The mutant pcd allele intrinsically leads to the death of cerebellar Purkinje cells5, a process which is almost complete two months after birth2'6. For our grafting experiments, we ...