Summary
This study shows that mouse mature chromaffin cells can elaborate neurite-like fibers and became integrated with the host brain. A piece of adrenal medulla, with or without attached adrenal cortical tissue, was implanted into the subarachnoid space or the hippocampal formation and examined using the electron microscopy. One week after transplantation, chromaffin cells could be observed surrounded by a basal lamina, containing many densecored vesicles 100–280 nm in diameter, including synaptic-like vesicles, which tended to gather in the cytoplasmic area or processes. The cells were irregularly shaped and bore cytoplasmic processes which sometimes ended with thick growth cone-like structures. The Golgi complex seemed to be well developed, suggesting the synthesis of new storage vesicles. One month after transplantation, the vast majority of chromaffin cells showed the noradrenaline phenotype typical of noradrenaline-storing cells in the normal gland, irrespective of graft components used or implantation sites. Some cells, presumably corresponding to the adrenaline phenotype, had secretory vesicles (140–210 nm in diameter) with denser cores than in the adrenaline-storing cells of normal gland. In the subarachnoid space, both types of graft had mostly cuboid chromaffin cells which bore a few, short, blung cytoplasmic processes. In the intracerebral transplants, the chromaffin cells of cortex-free adrenal medullary grafts developed processes having the characteristics of neurites extending from the chromaffin cells, in contrast to their counterparts with attached adrenocortical tissue. Thin sections through both types of graft showed isolated nerve cells, morphologically similar to sympathetic neurons, in the neighbourhood of the chromaffin cells. Reinnervation of the chromaffin cells was frequently observed in cortex-free implants. The integration of these grafts in the host brain is strongly suggested.
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References
Aloe L, Levi-Montalcini R (1979) Nerve growth factor in-vivo induced transformation of immature chromaffin cells in sympathetic neurons: effect of antiserum to the nerve growth factor. Proc Natl Acad Sci USA 76: 1246–1250
Ayer-Le Lievre CS, Ebendal T, Olson L, Seiger A (1983) Localization of nerve growth factor-like immunoreactivity in rat nervous tissue. Med Biol 61: 269–304
Brade Y-A, Edgar D, Thoenen H (1982) Purification of a new neurotrophic factor from mammalian brain. EMBO J 1: 549–553
Bohn MC, Goldstein M, Black IB (1981) Role of glucocorticoids in expression of the adrenergic phenotype in the rat embryonic adrenal gland. Dev Biol 82: 1–10
Bunge MB (1973) Fine structure of nerve fibers and growth cones of isolated sympathetic neurons in culture. J Cell Biol 56: 713–736
Carruba M, Ceccarelli B, Clementi F, Mantegazza P (1974) Selectivity in the innervation of iris and adrenal medulla by superior cervical ganglion after transplantation under the kidney capsule. Brain Res 77: 39–53
Coupland RE (1965) EM observation on the structure of the rat adrenal medulla. Normal innervation. J Anat 99: 255–272
Coupland RE, Kobayashi S (1976) Recent studies on the fixation of adrenaline and noradrenaline, and on amine synthesis and storage in chromaffin cells. In: Coupland RE, Fujita T (eds) Chromaffin, enterochromaffin and related cells. Elsevier Scientific Publishing Company, Amsterdam New York, pp 59–81
Doupe AJ, Landis SC, Patterson PH (1985) Environmental influences in the development of neural crest derivatives: glucocorticoids growth factors, and chromaffin cell plasticity. J Neurosci 5: 2119–2142
Elfvin L-G (1967) The development of the secretory granules in the rat adrenal medulla. J Ultrastruct Res 17: 45–62
Freed WJ, Morihisa JM, Spoor E, Hoffer BJ, Olson L, Seiger A, Wyatt RJ (1981) Transplanted adrenal chromaffin cells in rat brain reduce lesion-induced rotational behaviour. Nature 292: 351–352
Goldstein M, Fuxe K, Hökfelt T, Joh TH (1971) Immunohistochemical studies on phenylethanolamine-N-methyltransferase, dopa-decarboxylase and dopamine-β-hydroxylase. Experienta 27: 951–952
Gorgas K, Böck P (1976) Morphology and histochemistry of the adrenal medulla. I. Various types of primary catecholaminestoring cells in the mouse adrenal medulla. Histochemistry 50: 17–31
Grynszpan-Winograd O (1974) Adrenaline and noradrenaline cell in the adrenal medulla of the hamster: a morphological study of their innervation. J Neurocytol 3: 341–361
Harper GP, Pearce FL, Vernon CA (1976) Production of nerve growth factor by the mouse adrenal medulla. Nature 261: 251–253
Hirano T (1982) Neuronal regulation of adrenal chromaffin cell function in the mouse-stress effect on the distribution of 3Hdopamine in denervated adrenal medulla. Brain Res 238: 45–54
Jousselin-Hosaja M (1988) Effects of transplantation on mouse adrenal chromaffin cells. J Endocr 116: 149–153
Kobayashi S, Coupland RE (1977) Two population of microvesicles in the SGC (small granule chromaffin) cells of the mouse adrenal medulla. Arch Histol Jpn 40: 251–259
Kondo H (1978) Reinnervation of the rat adrenal medulla transplanted in the anterior eye chamber. J Anat 127: 323–331
Kromer LF, Björklund A, Stenevi U (1980) Innervation of embryonic hippocampal implants by regenerating axons of cholinergic septal neurons in the adult rat. Brain Res 210: 153–171
LaGamma EF, Adler FJ, Black IB (1984) Impulse activity differentially regulates [Leu] enkephalin and catecholamine characters in the adrenal medulla. Science 224: 1102–1104
Livett BG, Day R, Elde RP, Howe PRC (1982) Co-storage of enkephalines and adrenaline in the bovine adrenal medulla. Neuroscience 7: 1323–1332
Manuelidis L, Manuelidis EM (1975) Synaptic boutons and neuron-like cells in isolated adrenal gland cultures. Brain Res 96: 181–186
Millar TJ, Unsicker K (1981) Catecholamine-storing cells in the adrenal medulla of the pre and postnatal rat. Cell Tissue Res 217: 155–170
Ogawa M, Ishikawa T, Irimajiri A (1984) Adrenal chromaffin cells form functional cholinergic synapses in culture. Nature (London) 307: 66–68
Olson L (1970) Fluorescence histochemical evidence for axonal growth and secretion from transplanted adrenal medullary tissue. Histochemie 22: 1–17
Olson L, Malmfors L (1970) Growth characteristics of adrenergic nerves in the adult rats. Acta Phys Scand (Supplem) 348: 84–87
Olson L, Seiger A, Freedman R, Hoffer B (1980) Chromaffine cells can innervate brain tissue: evidence from intraocular double grafts. Exp Neurol 70: 414–426
Olson L, Hamberger B, Hoffer B, Miller R, Seiger Å (1981) Nerve fiber formation by grafted adult adrenal medullary cells. In: Stjärne L, Hedqvist P, Lagercrantz Z, Wennmalm Å (eds) Chemical neurotransmission. Academic Press, London, pp 3–48
Piezzi RS, Cavicchia JC (1973) Explants of rat adrenal medulla: a light and electron microscopic study. Anat Rec 175: 77–86
Pelto-Huikko H, Salminen T, Hervonen A (1982) Enkephalinelike immunoreactivity is restricted to the adrenaline cells in the hamster adrenal medulla. Histochemistry 73: 493–497
Purves D (1975) Persistent innervation of mammalian sympathetic neurons by native and foreign fibers. Nature 256: 589–590
Sagen J, Pappas GD, Perlow MJ (1986) Adrenal medullary tissue transplants in the rat spinal cord reduced pain sensitivity. Brain Res 384: 189–194
Sagen J, Pappas GD, Perlow MJ (1987) Fine structure of adrenal medullary grafts in the pain modulatory regions of the rat periaqueductal gray. Exp Brain Res 67: 380–390
Schultzberg M, Lundberg JM, Hökfelt T, Terenius L, Brandt J, Elde RP, Goldstein M (1978) Enkephaline-like immunoreactivity in gland cells and nerve terminals of the adrenal medulla. Neuroscience 3: 1169–1186
Stenevi U, Björklund A, Svendgaard N-A (1976) Transplantation of central and peripheral monoamine neurons to the adult rat brain: techniques and condition for survival. Brain Res 114: 1–20
Strömberg I, Herrera-Marschitz M, Hultgren L, Ungerstead U, Olson L (1984) Adrenal medullary implants in the dopaminedenervated rat striatum. I. Acute catecholamine levels in grafts and host caudate as determined by HPLC-electrochemistry and fluorescence histochemical image analysis. Brain Res 297: 41–51
Strömberg I, Ebendal T, Seiger A, Olson L (1985a) Nerve fiber production by intraocular adrenal medullary grafts: stimulation by nerve growth factor or sympathetic denervation of the host iris. Cell Tissue Res 241: 241–249
Strömberg I, Herrera-Marschitz M, Ungerstedt U, Ebendal T, Olson L (1985b) Chronic implants of chromaffin tissue into the dopamine-denervated striatum: effects of NGF on grafts survival, fiber growth and rotational behaviour. Exp Brain Res 60: 335–349
Taxi J (1965) Contribution a l'étude des connexions des neurones moteurs du système nerveux autonome. Ann Sci Nat Zool Biol Anim 7: 413–674
Teitelman G, Joh TH, Park D, Brodsky M, New M, Reis DJ (1982) Expression of the adrenergic phenotype in cultured fetal adrenal medullary cells: role of intrinsic and extrinsic factors. Dev Biol 89: 450–459
Tischler AS, Green LA (1980) Phenotypic plasticity of pheochromocytome and normal adrenal medullary cells. In: Eränko O, Soinila S, Päivärinta H (eds) Histochemistry and cell biology of autonomic neurons, SIF cells and paraneurons. Raven Press, New York, pp 61–68
Tischler AS, Perlman RL, Numnemacher G, Morse GM, DeLellis RA, Wolfe HJ, Sheard BE (1982) Long-term effects of dexamethasone and nerve growth factor on adrenal medullary cells cultured from young adult rat. Cell Tissue Res 225: 525–542
Unsicker K, Zwarg U, Habura O (1977) Electron microscopic evidence for the formation of synapses and synaptoid contacts in adrenal medullary grafts. Brain Res 120: 533–539
Unsicker K, Tschechne B, Tschechne D (1978a) Formation of cholinergic synapses on adrenal chromaffin cells in anterior eye chamber transplants. Brain Res 152: 334–340
Unsicker K, Habura-Flüh O, Zwarg U (1978b) Different types of small granule-containing cells and neurons in the guinea-pig adrenal medulla. Cell Tissue Res 189: 109–130
Unsicker K, Griesser GH, Lindmar R, Löffelholz K, Wolf U (1980) Establishment, characterization and fibre outgrowth of isolated bovine adrenal medullary cells in long-term cultures. Neuroscience 5: 1445–1460
Unsicker K, Tschechne B, Tschechne D (1981) Differentiation and transdifferentiation of adrenal chromaffin cells of the guinea-pig. I. Transplants to the anterior chamber of the eye. Cell Tissue Res 215: 341–367
Unsicker K, Zwarg U, Habura-Flüh O (1983) Differentiation and transdifferentiation of adrenal chromaffin cells of the guineapig. III. Transplants under the kidney capsule. Cell Tissue Res 229: 299–308
Wurtman RJ, Axelrod J (1965) Adrenaline synthesis control by the pituitary gland and adrenal glucocorticoids. Science 150: 1464–1465
Ziegler W, Hoffman H-D, Unsicker K (1983) Rat adrenal non-chromaffin cells contain a neurite outgrowth-promoting factor immunologically different from nerve growth factor. Dev Brain Res 7: 353–357
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Jousselin-Hosaja, M. Ultrastructural evidence for the development of adrenal medullary grafts in the brain. Exp Brain Res 73, 637–647 (1988). https://doi.org/10.1007/BF00406623
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DOI: https://doi.org/10.1007/BF00406623