Neuron specific α-adrenergic receptor expression in human cerebellum: Implications for emerging cerebellar roles in neurologic disease
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Deep cerebellar nuclei
The study of the clinical anatomy and functional features of the cortex, subcortical and conductive pathways of the cerebellum is necessary for clinicians for elaboration rational surgical approaches to these formations, for determination the localization of pathological processes associated with these formations. Cerebellar nucleus neurons are crucial to the olivo-cerebellar circuit as they provide the sole output of the entire cerebellum. The relationship between mobility and cognition in aging is well established, but the relationship between mobility and the structure and function of the aging brain is relatively unknown. In connection with the above, the purpose of our study was detection of the morphological characteristics of the cerebellum nuclei in aged persons. Study was performed on 48 specimens of the cerebellum from people (24 male and 24 female), who died at the age from 75 to 99 years due to diseases, which were not related to the central nervous system damaging. Formalin-fixed human hemispheres were dissected with the Ludwig and Klingler fiber dissection technique under x6 to x40 magnifications of binocular microscope Olympus BX41 (Japan). The morphological features of the human cerebellar nuclei were established. Namely, on the series of sections of the cerebellum in the horizontal, frontal and sagittal planes, as well as on the macro-microscopic preparations of the cerebellar nuclei location, their relative position, shape, linear dimensions, weight and volume were described. The features of macro-microscopic and histological structure of the nuclei of the cerebellum were made own classification of the gyri and teeth of the dentate nucleus of the cerebellum was offered. Macro-microscopic dissection of persons died after 75 years old show no significant variability of linear dimensions of cerebellar nuclei with their specific location and options. Simultaneously, reliable reducing of cellular density was detected for Purkinje, granule and basket neurons more pronounced in male for Purkinje cells.
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Abstract A myeloarchitectonic atlas of the longitudinal (or mediolateral) subdivision of the cerebellum of the chicken (white Leghorn) was prepared from serial Häggqvist or toluidine‐blue‐stained sections of five animals. This myeloarchitectonic subdivision is based on the alternate occurrence of large fiber accumulations (LFAs) and small fiber areas (SFAs) in the cerebellar white matter and allows the distinction of a number of parasagittal fiber compartments, each of which consists of a medial LFA and a lateral SFA. The compartmental subdivision of the cerebellar white matter in mammals and birds derives its importance from the fact that essentially it corresponds to the organization of the afferent and efferent connections of the cerebellar cortex. The simple structure of the avian cerebellum makes it ideally suited for a complete description of its compartmental subdivision and may serve as a natural system of coordinates in future anatomical and physiological studies. The number of fiber compartments that can be counted in the chicken cerebellum on either side of the midline varies from six (in the narrowest folium I) to nine (in the widest folia IX and X) and is approximately the same as in mammals, in which a maximum of eight or ten compartments can be recognized. On the basis of the organization of its myeloarchitecture and the otherwise relatively scarce data on the organization of the connecitons of its cortex, it can, therefore, be postulated that the avian cerebellum is the homologue of the entire mammalian cerebellum. In addition, the present knowledge of the connections of the cerebellar cortex in birds indicates that the avian compartments 1—3 may correspond to the mammalian compartments A1, A2, and A3 (or X), whereas the avian compartment 4 or 5 (or both) may represent the mammalian B compartment. Lack of further anatomical data so far precludes conclusions on a possible homology between the avian compartments 6–9 and the mammalian C and D compartments.
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Inferior olivary nucleus
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This current review is focused on the generation and settled patterns of mouse Purkinje cells (PCs) and deep cerebellar nuclei (DCN) neurons. By mean of progressively delayed comprehensive labeling procedure, I will show, with the technique of [3H] thymidine autoradiography, the quantitative determination of PCs and DCN neurons production along the mediolateral and rostrocaudal axes of the cerebellum. The procedure consists of injecting groups of pregnant mice, on specific embryonic (E) days, with two doses of [3H] thymidine in an overlapping series with 24 h delays between groups (E11-12, E12-13, E13-14, E14-15). The analysis of the autoradiograms revealed that PCs and DCN neurons are sequentially generated following precise neurogenetic timetables. PCs are born somewhat later than the DCN neurons. Both macroneurons are produced following two gradients. The first of these is mediolateral and the second is rostrocaudal. On the other hand, it will be also shown that PCs and DCN neurons were settled in the cerebellum following accurate neurogenetic gradients. These data have suggested that the chronological sequence of neuron production is a key factor in facilitating, in the adulthood, the cytoarchitecture of the cerebellum, and the establishment of patterns of orderly connections between PCs and DCN neurons.
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Deep cerebellar nuclei
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Deep cerebellar nuclei
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Reeler
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Deep cerebellar nuclei
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The cerebellum is composed of a diverse array of neuronal subtypes. Here we have used a candidate approach to identify Zac1, a tumor suppressor gene encoding a zinc finger transcription factor, as a new player in the transcriptional network required for the development of a specific subset of cerebellar nuclei and a population of Golgi cells in the cerebellar cortex.We found that Zac1 has a complex expression profile in the developing cerebellum, including in two proliferating progenitor populations; the cerebellar ventricular zone and the external granular layer overlying posterior cerebellar lobules IX and X. Zac1 is also expressed in some postmitotic cerebellar neurons, including a subset of GABAergic interneurons in the medial cerebellar nuclei. Notably, GABAergic interneurons in the cerebellar nuclei are derived from the cerebellar ventricular zone, where Zac1 is also expressed, consistent with a lineage relationship between these two Zac1+ populations. Zac1 is also expressed in a small subset of cells in the posterior vermis, including some neurogranin-immunoreactive (NG+) Golgi cells, which, based on short-term birthdating, are derived from the EGL, where Zac1 is also expressed. However, Zac1+ cells and NG+ Golgi cells in the cerebellar cortex also display unique properties, as they are generated within different, albeit overlapping, time windows. Finally, consistent with the expression profile of Zac1, two conspicuous abnormalities were found in the cerebellum of Zac1 null mice: the medial cerebellar nuclei, and not the others, were significantly reduced in size; and the number of Golgi cells in cerebellar lobule IX was reduced by approximately 60% compared to wild-type littermates.The data presented here indicate that the tumor suppressor gene Zac1 is expressed in a complex fashion in the developing cerebellum, including in two dividing progenitor populations and in specific subsets of postmitotic neurons, including Golgi cells and GABAergic neurons in the medial nuclei, which require Zac1 for their differentiation. We thus conclude that Zac1 is a critical regulator of normal cerebellar development, adding a new transcriptional regulator to the growing list of factors involved in generating neuronal diversity in the developing cerebellum.
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