Abstract
Enteric glia share morphological, biochemical, and functional properties with astrocytes. Thus, like astrocytes, transplantation of enteric glia into the central nervous system (CNS) might facilitate the development of the characteristics of the blood brain barrier (BBB) in endothelial cells. This study explored this possibility by examining barrier formation after implantation into the spinal cord of rats. Phaseolus vulgaris leucoagglutin (PHAL)-treated enteric glia suspensions were injected into the spinal cord at the T11–T12 level of adult Wistar female rats. Control animals were injected with either 3T3 fibroblast, glioma C6 cells, or culture medium. Evan’s blue, a dye excluded by the BBB, was injected intravenously from 1 week to 2 months after implantation. Leakage of dye was determined macroscopically and the ultrastructure of the capillaries was examined. During the first week leakage of dye correlated ultrastructurally with predominantly non-overlapping endothelial cell junctions, even with clefts between adjacent cells. Tight junctions were fully formed by 2 months and no dye leaked. Electron microscopic analysis showed that enteric glia had end-feet in close contact with endothelial cells. In contrast, the injection sites in all control animals leaked dye until 2 months, and most of the tight junctions that did form were incomplete. Furthermore, most 3T3 or C6 control cells had died at 2 months and those that survived, unlike enteric glia, had no anatomical relationship to blood vessels. These data demonstrate that implantation of enteric glia accelerates the formation of the characteristics of the BBB in spinal cord capillaries.
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References
Abbott NJ (2002) Astrocyte-endothelial interactions and blood-brain barrier permeability. J Anat 200:629–638
Baluk P, Jessen KR, Saffrey MJ, Burnstock G (1983) The enteric nervous system in tissue culture. II. Ultrastructural studies of cell types and their relationships. Brain Res 262:37–47
Brightman M (1991) Implication of astroglia in the blood-brain barrier. Ann NY Acad Sci 633:343–347
Broussard DL, Bannerman PG, Tang CM, Hardy M, Pleasure D (1993) Electrophysiologic and molecular properties of cultured enteric glia. J Neurosci Res 34:24–31
Bush TG (2002) Enteric glial cells. An upstream target for induction of necrotizing enterocolitis and Crohn’s disease? Bioessays 24:130–140
Cook RD, Burnstock G (1976) The Ultrastructure of Auerbach’s plexus in the guinea-pig. Neuronal elements. J Neurocytol 5:171–194
Erde SM, Sherman D, Gershon MD (1985) Morphology and serotonergic innervation of physiologically identified cells of the guinea pig’s myenteric plexus. J Neurosci 5:617–633
Esteban I, Levanti B, Garcia-Suarez O, Germana G, Ciriaco E, Naves FJ, Vega JA (1998) A neuronal subpopulation in the mammalian enteric nervous system expresses TrkA and TrkC neurotrophin receptor-like proteins. Anat Res 251:360–370
Ferri GL, Probert L, Cocchia D, Michetti F, Marangos PJ, Polak JM (1982) Evidence for the presence of S-100 protein in the glial component of the human enteric nervous system. Nature 297:409–410
Focke PJ, Schiltz CA, Jones SE, Watters JJ, Epstein ML (2001) Enteric neuroblasts require the phosphatidylinositol 3-kinase pathway for GDNF-stimulated proliferation. J Neurobiol 47:306–317
Furness JB, Costa M (1980) Types of nerves in the enteric nervous system. Neuroscience 5:1–20
Gershon MD, Rothman TP (1991) Enteric glia. Glia 4:195–204
Gershon MD (1998) V. Genes, lineages, and tissue interactions in the development of the enteric nervous system. Am J Physiol 275:G869–G873
Hayashi Y, Nomura M, Yamagishi S, Harada S, Yamashita J, Yamamoto H (1997) Induction of various blood-brain barrier properties in non-neural endothelial cells by close apposition to co-cultured astrocytes. Glia 19:13–26
Isobe I, Watanabe T, Yotsuyanagi T, Hazemoto N, Yamagata K, Ueki T, Nakanishi K, Asai K, Kato T (1996) Astrocytic contributions to blood-brain barrier (BBB) formation by endothelial cells: a possible use of aortic endothelial cell for in vitro BBB model. Neurochem Int 28:523–533
Jaeger CB, Toombs JP, Borgens RB (1993) Grafting in acute spinal cord injury: morphological and immunological aspects of transplanted adult rat enteric ganglia. Neuroscience 52:333–346
Jessen KR, Mirsky R (1980) Glial cells in the enteric nervous system contain glial fibrillary acidic protein. Nature 286:736–737
Jiang S, Wang J, Khan MI, Middlemiss PJ, Salgado-Ceballos H, Werstiuk ES, Wickson R, Rathbone MP (2003a) Enteric glia promote regeneration of transected dorsal root axons into spinal cord of adult rats. Exp Neurol 181:79–83
Jiang S, Khan MI, Wang J, Middlemiss PJ, Werstiuk ES, Wickson ES, Rathbone MP (2003b) Enteric glia promote functional recovery of CTM reflex after dorsal root transection. NeuroReport 14:1301–1304
Komuro T, Baluk P, Burnstock G (1982) An ultrastructural study of neurons and non-neuronal cells in the myenteric plexus of the rabbit colon. Neuroscience 7:1797–1806
Lawrence JM, Raisman G, Mirsky R, Jessen KR (1991) Transplantation of postnatal rat enteric ganglia into denervated adult rat hippocampus. Neuroscience 44:371–379
Lucini C, Maruccio L, de Girolamo P, Vega JA, Castaldo L (2002) Localisation of neurotrophin—containing cells in higher vertebrate intestine. Anat Embryol 205:135–140
Lui VC, Samy ET, Sham MH, Mulligan LM, Tam PK (2002) Glial cell line-derived neurotrophic factor family receptors are abnormally expressed in aganglionic bowel of a subpopulation of patients with Hirschsprung’s disease. Lab Invest 82:703–712
Middlemiss PJ, Jiang S, Wang J, Rathbone MP (2002) A method for purifying enteric glia from rat myenteric plexus. In Vitro Cellular Dev Biol Animal 38:188–190
Montgomery DL (1994) Astrocytes: form, functions, and roles in disease. Vet Pathol 31:145–167
Raub TJ (1996) Signal transduction and glial cell modulation of cultured brain microvessel endothelial cell tight junctions. Am J Physiol 271:495–503
Rist RJ, Romero IA, Chan MW, Couraud PO, Roux F, Abbott NJ (1997) F-actin cytoskeleton and sucrose permeability of immortalised rat brain microvascular endothelial cell monolayers: effects of cyclic AMP and astrocytic factors. Brain Res 768:10–18
Rubin LL, Staddon JM (1999) The cell biology of the blood-brain barrier. Annu Rev Neurosci 22:11–28
Ruhl A, Franzke S, Collins SM, Stremmel W (2001) Interleukin-6 expression and regulation in rat enteric glial cells. Am J Physiol Gastrointest Liver Physiol 280:G1163–G1171
Saarma M, Sariola H (1999) Other neurotrophic factors: glial cell line-derived neurotrophic factor (GDNF). Microsc Res Tech 45:292–302
Sanchez MP, Silos-Santiago I, Frisen J, He B, Lira SA, Barbacid M (1996) Renal agenesis and the absence of enteric neurons in mice lacking GDNF. Nature 382:70–73
Shen L, Figurov A, Lu B (1997) Recent progress in studies of neurotrophic factors and their clinical implications. J Mol Med 75:637–644
Stewart PA, Hayakawa EM (1987) Interendothelial junctional changes underlie the developmental ‘tightening’ of the blood-brain barrier. Brain Res 429:271–281
Stewart PA, Wiley MJ (1981) Developing nervous tissue induces formation of blood-brain barrier characteristics in invading endothelial cells: a study using quail--chick transplantation chimeras. Dev Biol 84:183–192
Tator CH, Fehlings MG (1991) Review of the secondary injury theory of acute spinal cord trauma with emphasis on vascular mechanisms. J Neurosurg 75:15–26
Tew EM, Anderson PN, Burnstock G (1992) Implantation of the myenteric plexus into the corpus striatum of adult rats: survival of the neurons and glia and interactions with host brain. Restor Neurol Neurosci 4:311–321
Tew EM, Saffrey MJ, Anderson PN, Burnstock G (1993) Postnatal rat NADPH-diaphorase-containing myenteric neurons extend processes when transplanted into adult rat corpus striatum. Exp Neurol 124:265–273
Tew EM, Anderson PN, Saffrey MJ, Burnstock G (1994) Transplantation of the postnatal rat myenteric plexus into the adult rat corpus striatum: an electron microscopic study. Exp Neurol 129:120
Acknowledgements
Support: Neurological Technologies Inc. and Canadian Spinal Research Organization. We thank Drs Raelene Kinlough-Rathbone and Laurie Doering for their helpful suggestions and critical appraisal of the manuscript.
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Jiang, S., Khan, M.I., Lu, Y. et al. Acceleration of blood-brain barrier formation after transplantation of enteric glia into spinal cords of rats. Exp Brain Res 162, 56–62 (2005). https://doi.org/10.1007/s00221-004-2119-3
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DOI: https://doi.org/10.1007/s00221-004-2119-3