Summary
Pieces of the developing cerebellar anlage were prepared from 13–15 day old rat embryos and transplanted to the cerebellar region of 5–7 and 13–14 day old rat pups. Approximately two months later, sections showed most grafts to consist of both cerebellar cortex, with a typical trilaminar organization, and white matter areas containing large neuronal perikarya.
The astrocytic populations were studied using immunohistochemistry with antisera raised against the intermediate filaments, glial fibrillary acidic protein (GFA), and vimentin. The GFA-antiserum revealed a glial interface along most of the border between host brain and graft. Both antisera stained long, slender, although slightly distorted Bergmann fibers spanning the molecular layer. Using GF-Aantiserum, star-shaped fluorescent astrocytes were seen in the granular layer and in the white matter. Only in the white matter did the amount of GFA-like immunoreactivity suggest an astrocytic gliosis. With vimentin antiserum fluorescent astrocytes in the white matter were seen. There were no signs of increased amounts of vimentin-like immunoreactivity. Taken together, the amount and distribution of GFA-and vimentin-like immunoreactivity suggests a rather normal astrocytic development in the cerebellar grafts.
Using an antiserum against the neurofilament (NF) triplet, delicate immunoreactive fibres were seen in both the molecular and the granular layer. No positive cell bodies could be visualized in the cortical areas. Although the Purkinje cells themselves were negative, fibre baskets around them were intensely stained. In the white matter a high density of NF-positive fibres and some positive perikarya were visualized. Thus the distribution of NF-like immunoreactivity in the grafts corresponded well to the normal NF distribution.
The functional maturation of the cerebellar grafts was studied electrophysiologically. A spontaneous mean discharge rate of 19.3 + 1.7 Hz was recorded from the Purkinje cells. This compares with a discharge rate of 26.8 + 1.0 Hz for Purkinje neurons in situ. The difference was at least partly ascribable to the absence of climbing fibre bursts in the grafts. Local stimulation of the graft surface caused both decreased and increased Purkinje cell discharge. In conclusion, these experiments suggest that grafts of fetal cerebellar buds to the young cerebellum develop into cerebellar tissue having both morphological and electrophysiological characteristics quite similar to the normal cerebellum.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Addison WHF (1911) The development of the Purkinje cells and of their cortical layers in the cerebellum of the albino rat. J Comp Neurol 21: 459–487
Altman J (1972a) Postnatal developmental of the cerebellar cortex in the rat. I. The external germinal layer and the transitional molecular layer. J Comp Neurol 145: 353–398
Altman J (1972b) Postnatal development of the cerebellar cortex in the rat. II. Phases in the maturation of Purkinje cells and of the molecular layer. J Comp Neurol 145: 399–464
Altman J (1972c) Postnatal development of the cerebellar cortex in the rat. III. Maturation of the components of the granular layer. J Comp Neurol 145: 465–514
Altman J, Bayer SA (1978) Prenatal development of the cerebellar system in the rat. I. Cytogenesis and histogenesis of the deep nuclei and the cortex of the cerebellum. J Comp Neurol 179: 23–48
Alvarado-Mallart RM, Sotelo C (1982) Differentiation of cerebellar anlage heterotopically transplanted to adult rat brain: A light and electron microscopic study. J Comp Neurol 212: 247–267
Bignami A, Dahl D (1973) Differentiation of astrocytes in the cerebellar cortex and the pyramidal tracts of the newborn rat. An immunofluorescence study with antibodies to a protein specific to astrocytes. Brain Res 49: 393–402
Bignami A, Dahl D (1976) The astroglial response to stabbing. Immunofluorescence studies with antibodies to astrocytespecific protein (GFA) in mammalian and submammalian vertebrates. Neuropathol Appl Neurobiol 2: 99–111
Bignami A, Dahl D (1982) Ten-nanometer filament proteins in neural development and aging. In: Giacobini E et al. (eds) The aging brain cellular and molecular mechanisms of aging in the nervous system. Raven Press, New York, pp 99–105
Bignami A, Dahl D, Rueger C (1980) Glial fibrillary acidic (GFA) protein in normal neural cells and in pathological conditions. In: Fedoroff S, Hertz L (eds) Advances in cellular neurobiology, Vol 1. Academic Press, New York London, pp 285–319
Björklund A, Stenevi U, Svendgaard N-Aa (1976) Growth of transplanted monoaminergic neurones into the adult hippocampus along the perforant path. Nature 262: 787–790
Björklund A, Stenevi U (1979) Reconstruction of the nigrostriatal dopamine pathway in intracerebral transplants. Brain Res 177: 555–560
Björklund H, Dahl D (1982) Glial disturbances in isolated neocortex: Evidence from immunohistochemistry of intraocular grafts. Dev Neurosci 5: 424–436
Björklund H, Dahl D, Haglid K, Rosengren L, Olson L (1983) Astrocytic development in fetal parietal cortex grafted to cerebral and cerebellar cortex of immature rats. Dev Brain Res 9: 171–180
Björklund H, Dahl D, Olson L (1984) Morphometry of GFA and vimentin positive astrocytes in grafted and lesioned cortex cerebri. Int J Dev Neurosci 2: 181–192
Chiu F-C, Norton WT, Fields KL (1981) The cytoskeleton of primary astrocytes in culture contains actin, glial fibrillary acidic protein, and the fibroblast-type filament protein, vimentin. J Neurochem 37: 147–155
Coons AH (1958) Fluorescent antibody methods. In: Danielli JF (ed) General Cytochemical Methods. Academic Press, New York, pp 399–422
Dahl D, Bich NT, Bignami A (1982a) Ultrastructural localization of neurofilament proteins in aluminium-induced neurofibrillary tangles and rat cerebellum by immunoperoxidase labelling. Dev Neurosci 5: 54–63
Dahl D, Bignami A (1976) Immunogenic properties of the glial fibrillary acidic protein. Brain Res 116: 150–157
Dahl D, Bignami A (1977) Preparation of antisera to neurofilament protein from chicken brain and human sciatic nerve. J Comp Neurol 176: 645–658
Dahl D, Bignami A, Weber K, Osborn M (1981a) Filament proteins in rat optic nerve undergoing Wallerian degeneration. Localization of vimentin, the fibroblastic 100 Å filament protein, in normal and reactive astrocytes. Exp Neurol 73: 496–506
Dahl D, Crosby CF, Bignami A (1981b) Filament proteins in rat optic nerves undergoing Wallerian degeneration. Exp Neurol 71: 421–430
Dahl D, Rueger DC, Bignami A, Weber K, Osborn M (1981c) Vimentin, the 57,000 dalton protein of fibroblast filaments, is the major cytoskeletal component in immature glia. Eur J Cell Biol 124: 191–196
Dahl D, Selkoe DJ, Pero RT, Bignami A (1982b) Immunostaining of neurofibrillary tangles in Alzheimer's senile dementia with a neurofilament antiserum. J Neurosci 2: 113–119
Das GD, Altman J (1971) Transplanted precursors of nerve cells: Their fate in the cerebellums of young rats. Science 173: 637–638
Das GD, Hallas BH, Das KG (1980) Transplantation of brain tissue in the brain of rat. I. Growth characteristics of neocortical transplants from embryos of different ages. Am J Anat 158: 135–145
Das GD, Nornes HO (1972) Neurogenesis in the cerebellum of the rat: an autoradiographic study. Z Anat Entwickl-Gesch 138: 155–165
Dunnett SB, Björklund A, Stenevi U, Iversen SD (1981) Grafts of embryonic substantia nigra reinnervating the ventrolateral striatum ameliorate sensorimotor impairments and akinesia in rats with 6-OHDA lesions of the nigrostriatal pathway. Brain Res 229: 209–217
Eccles JC, Ito M, Szentágothai J (1967) The Cerebellum as a Neuronal Machine. Springer, Berlin Heidelberg New York
Fedoroff S, White R, Neal J, Subrahmanyan L, Kalnins VI (1983) Astrocyte cell lineage. II. Mouse fibrous astrocytes and reactive astrocytes in cultures have vimentin-and GFAP-containing intermediate filaments. Dev Brain Res 7: 303–315
Franke WW, Schmid E, Osborn M, Weber K (1978) Differentintermediate-sized filaments distinguished by immunofluorescence microscopy. Proc Natl Acad Sci 75: 5034–5038
Fray PJ, Dunnett SB, Iversen SD, Björklund A, Stenevi U (1983) Nigral transplants reinnervating the dopamine depleted neostriatum can sustain intracranial self-stimulation. Science 219: 416–419
Gambetti P, Velasco ME, Dahl D, Bignami A, Roessmann U, Sindeley SD (1980) In: Amaducci L, Davison AN, Antuono P (eds) Aging of the Brain and Dementia. Raven Press, New York, pp 55–63
Hallas BH, Das GD, Das KG (1980a) Transplantation of brain tissue in the brain of rat. II. Growth characteristics of neocortical transplants in host of different ages. Am J Anat 158: 147–159
Hallas BH, Oblinger MM, Das GD (1980b) Heterotopic transplants in the cerebellum of the rat: their afferents. Brain Res 196: 242–246
Hoffer BJ, Olson L, Seiger Å, Bloom FE (1975) Formation of a functional adrenergic input to intraocular cerebellar grafts: Ingrowth of sympathetic fibers and inhibition of Purkinje cell activity by adrenergic input. J Neurobiol 6: 565–586
Hoffer BJ, Seiger Å, Ljungberg T, Olson L (1974) Electrophysiological studies of brain homografts in the anterior chamber of the eye: Maturation of cerebellar cortex in oculo. Brain Res 79: 165–184
Hoffer BJ, Siggins GR, Woodward DJ, Bloom FE (1971) Spontaneous discharge of Purkinje neurons after destruction of catecholamine-containing afferents by 6-hydroxydopamine. Brain Res 30: 425–430
Jaeger CB, Lund RD (1980) Transplantation of embryonic occipital cortex to the brain of newborn rats. An autoradiographic study of transplant histogenesis. Exp Brain Res 40: 265–272
Jaeger CB, Lund RD (1982) Influence of grafted glia cells and host mossy fibers on anomalously migrated host granule cells surviving in cortical transplants. Neuroscience 7: 3069–3076
Kromer LF, Björklund A, Stenevi U (1979) Intracephalic implants: a technique for studying neuronal interactions. Science 204: 1117–1119
Kromer LF, Björklund A, Stenevi U (1983) Intracephalic embryonic neural implants in the adult rat brain. I. Growth and mature organization of brainstem, cerebellar, and hippocampal implants. J Comp Neurol 218: 433–459
Lazarides E (1980) Intermediate filaments as mechanical integrators of cellular space. Nature 283: 249–256
Lund RD, Hauschka SD (1976) Transplanted neural tissue develops connections with host rat brain. Science 193: 582–584
Oblinger MM, Das GD (1982) Connectivity of neural transplants in adult rats: analysis of afferents and efferents of neocortical transplants in the cerebellar hemisphere. Brain Res 249: 31–49
Oblinger MM, Hallas BH, Das GD (1980) Neocortical transplants in the cerebellum of the rat: their afferents and efferents. Brain Res 189: 228–232
Olson L, Seiger Å, Strömberg I (1983) Intraocular transplantation in rodents. A detailed account of the procedure and examples of its use in neurobiology with special reference to brain tissue grafting. In: Fedoroff S, Hertz L (eds) Advances in Cellular Biology, Vol 4. Academic Press, New York, pp 407–422
Osborn M, Weber K (1982) Intermediate filaments: cell-type-specific markers in differentiation and pathology. Cell 31: 303–306
Paetau A, Virtanen I, Stenman S, Kurki P, Linder E, Vaheri A, Westermark B, Dahl D, Haltia M (1979) Glial fibrillary acidic protein and intermediate filaments in human glioma cells. Acta Neuropathol 47: 71–74
Perlow M, Freed W, Hoffer B, Seiger Å, Olson L, Wyatt R (1979) Brain grafts reduce motor abnormalities produced by destruction of nigrostriatal dopamine system. Science 204: 643–647
Rakic P (1971) Neuro-glia relationship during granule cell migration in developing cerebellar cortex. A golgi and electron microscopic study in Macacus rhesus. J Comp Neurol 141: 283–312
Rakic P (1972) Mode of cell migration to the superficial layers of fetal monkey neocortex. J Comp Neurol 145: 61–84
Rakic P, Sidman RL (1973a) Weaver mutant mouse cerebellum, defective neuronal migration secondary to abnormality of Bergmann glia. Proc Natl Acad Sci, USA 70: 240–244
Rakic P, Sidman RL (1973b) Sequence of developmental abnormalities leding to granule cell deficit in cerebellar cortex of weaver mutant mice. J Comp Neurol 152: 103–132
Schlaepfer WW, Lynch RG (1977) Immunofluorescence studies of neurofilaments in the rat and human peripheral and central nervous system. J Cell Biol 74: 241–250
Schlaepfer WA, Mamoon A, Tobias C (1972) Spontaneous bioelectric activity of neurons in cerebellar cultures: Evidence for synaptic interaction. Brain Res 45: 345–363
Schnitzer I, Franke WW, Schachner M (1981) Immunocytochemical demonstration of vimentin in astrocytes and ependymal cells of developing and adult mouse nervous system. J Cell Biol 90: 435–447
Shaw G, Osborn M, Weber K (1981) An immunofluorescence microscopical study of the neurofilament triplet proteins, vimentin and glial fibrillary acidic protein within the adult rat brain. Eur J Cell Biol 26: 68–82
Stenevi U, Björklund A, Svengaard, N-Aa (1976) Transplantation of central and peripheral monoamine neurons to the adult rat brain: techniques and conditions for survival. Brain Res 114: 1–20
Wells J, McAllister JP (1982) The development of cerebellar primordia transplanted to the neocortex of the rat. Dev Brain Res 4: 167–179
Wille W, Goldowitz D, Seiger Å, Olson L (1983) The neurological mutation staggerer is expressed in embryonic cerebellar transplants matured in the anterior eye chamber. Neurosci Lett 42: 1–6
Woodward DJ, Hoffer BJ, Altman J (1974) Electrophysiological and pharmacological properties of Purkinje cells in rat cerebellum degranulated by postnatal X-irradiation. J Neurobiol 5: 283–304
Yen SH, Fields KL (1981) Antibodies to neurofilament, glial filament and fibroblast intermediate filament proteins bind to different cell types of the nervous system. J Cell Biol 88: 115–126
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Björklund, H., Bickford, P., Dahl, D. et al. Intracranial cerebellar grafts: Intermediate filament immunohistochemistry and electrophysiology. Exp Brain Res 55, 372–385 (1984). https://doi.org/10.1007/BF00237288
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF00237288