Abstract / Description of output
Original language | English |
---|---|
Pages (from-to) | 3412-3424 |
Number of pages | 13 |
Journal | Journal of Clinical Investigation |
Volume | 121 |
Issue number | 9 |
Early online date | 25 Aug 2011 |
DOIs | |
Publication status | Published - 1 Sept 2011 |
Keywords / Materials (for Non-textual outputs)
- transcription factor Sox10
- animal cell
- animal experiment
- animal tissue
- article
- cell lineage
- chemical injury
- controlled study
- embryo
- gene mapping
- glia cell
- in vivo study
- intestine innervation
- mouse
- myenteric plexus
- nervous system development
- neural crest cell
- nonhuman
- priority journal
- Animals
- Cell Lineage
- Cells, Cultured
- Embryo, Mammalian
- Enteric Nervous System
- Female
- Mice
- Mice, Transgenic
- Multipotent Stem Cells
- Neural Crest
- Neurogenesis
- Neuroglia
- Neurons
- Pregnancy
- Recombinant Fusion Proteins
- SOXE Transcription Factors
Fingerprint
Dive into the research topics of 'Glial cells in the mouse enteric nervous system can undergo neurogenesis in response to injury'. Together they form a unique fingerprint.Cite this
- APA
- Author
- BIBTEX
- Harvard
- Standard
- RIS
- Vancouver
}
In: Journal of Clinical Investigation, Vol. 121, No. 9, 01.09.2011, p. 3412-3424.
Research output: Contribution to journal › Article › peer-review
TY - JOUR
T1 - Glial cells in the mouse enteric nervous system can undergo neurogenesis in response to injury
AU - Laranjeira, C.
AU - Sandgren, K.
AU - Pachnis, V.
AU - Kessaris, N.
AU - Richardson, W.
AU - Potocnik, A.
AU - Vanden Berghe, P.
N1 - Cited By :57 Export Date: 11 March 2015 CODEN: JCINA Correspondence Address: Pachnis, V.; Division of Molecular Neurobiology, MRC, National Institute for Medical Research, Mill Hill, London NW7 1AA, United Kingdom; email: [email protected] Chemicals/CAS: Recombinant Fusion Proteins; SOXE Transcription Factors; Sox10 protein, mouse References: Temple, S., Alvarez-Buylla, A., Stem cells in the adult mammalian central nervous system (1999) Current Opinion in Neurobiology, 9 (1), pp. 135-141. , DOI 10.1016/S0959-4388(99)80017-8; Alvarez-Buylla, A., Garcia-Verdugo, J.M., Tramontin, A.D., A unified hypothesis on the lineage of neural stem cells (2001) Nature Reviews Neuroscience, 2 (4), pp. 287-293. , DOI 10.1038/35067582; Dupin, E., Calloni, G., Real, C., Goncalves-Trentin, A., Le, D.N.M., Neural crest progenitors and stem cells (2007) Comptes Rendus - Biologies, 330 (6-7), pp. 521-529. , DOI 10.1016/j.crvi.2007.04.004, PII S1631069107001606, Regenerative Cell Therapy; Pardal, R., Ortega-Saenz, P., Duran, R., Lopez-Barneo, J., Glia-like Stem Cells Sustain Physiologic Neurogenesis in the Adult Mammalian Carotid Body (2007) Cell, 131 (2), pp. 364-377. , DOI 10.1016/j.cell.2007.07.043, PII S0092867407010239; Kunze, W.A.A., Furness, J.B., The enteric nervous system and regulation of intestinal motility (1999) Annual Review of Physiology, 61, pp. 117-142. , DOI 10.1146/annurev.physiol.61.1.117; Laranjeira, C., Pachnis, V., Enteric nervous system development: Recent progress and future challenges (2009) Auton Neurosci, 151 (1), pp. 61-69; Paratore, C., Eichenberger, C., Suter, U., Sommer, L., Sox10 haploinsufficiency affects maintenance of progenitor cells in a mouse model of Hirschsprung disease (2002) Human Molecular Genetics, 11 (24), pp. 3075-3085; Bondurand, N., Natarajan, D., Thapar, N., Atkins, C., Pachnis, V., Neuron and glia generating progenitors of the mammalian enteric nervous system isolated from foetal and postnatal gut cultures (2003) Development, 130 (25), pp. 6387-6400. , DOI 10.1242/dev.00857; Anderson, R.B., Stewart, A.L., Young, H.M., Phenotypes of neural-crest-derived cells in vagal and sacral pathways (2006) Cell and Tissue Research, 323 (1), pp. 11-25. , DOI 10.1007/s00441-005-0047-6; Mollaaghababa, R., Pavan, W.J., The importance of having your SOX on: Role of SOX10 in the development of neural crest-derived melanocytes and glia (2003) Oncogene, 22 (20), pp. 3024-3034. , DOI 10.1038/sj.onc.1206442, Melanoma; Pham, T.D., Gershon, M.D., Rothman, T.P., Time of origin of neurons in the murine enteric nervous system: Sequence in relation to phenotype (1991) J Comp Neurol, 314 (4), pp. 789-798; Liu, M.T., Kuan, Y.H., Wang, J., Hen, R., Gershon, M.D., 5-HT4 receptor-mediated neuroprotection and neurogenesis in the enteric nervous system of adult mice (2009) J Neurosci, 29 (31), pp. 9683-9699; Kruger, G.M., Mosher, J.T., Bixby, S., Joseph, N., Iwashita, T., Morrison, S.J., Neural crest stem cells persist in the adult gut but undergo changes in self-renewal, neuronal subtype potential, and factor responsiveness (2002) Neuron, 35 (4), pp. 657-669. , DOI 10.1016/S0896-6273(02)00827-9; Suarez-Rodriguez, R., Belkind-Gerson, J., Cultured nestin-positive cells from postnatal mouse small bowel differentiate ex vivo into neurons, glia, and smooth muscle (2004) Stem Cells, 22 (7), pp. 1373-1385. , DOI 10.1634/stemcells.2003-0049; Filogamo, G., Cracco, C., Models of neuronal plasticity and repair in the enteric nervous system: A review (1995) Ital J Anat Embryol, 100 (SUPPL. 1), pp. 185-195; Geboes, K., Collins, S., Structural abnormalities of the nervous system in Crohn's disease and ulcerative colitis (1998) Neurogastroenterology and Motility, 10 (3), pp. 189-202. , DOI 10.1046/j.1365-2982.1998.00102.x; Matsuoka, T., Ahlberg, P.E., Kessaris, N., Iannarelli, R., Dennehy, U., Richardson, W.D., McMahon, A.P., Koentges, G., Neural crest origins of the neck and shoulder (2005) Nature, 436 (7049), pp. 347-355. , DOI 10.1038/nature03837; Srinivas, S., Cre reporter strains produced by targeted insertion of EYFP and ECFP into the ROSA26 locus (2001) BMC Dev Biol, 1, p. 4; Young, H.M., Bergner, A.J., Muller, T., Acquisition of neuronal and glial markers by neural crest-derived cells in the mouse intestine (2003) Journal of Comparative Neurology, 456 (1), pp. 1-11. , DOI 10.1002/cne.10448; Wakamatsu, Y., Weston, J.A., Sequential expression and role of Hu RNA-binding proteins during neurogenesis (1997) Development, 124 (17), pp. 3449-3460; Morrison, S.J., White, P.M., Zock, C., Anderson, D.J., Prospective identification, isolation by flow cytometry, and in vivo self-renewal of multipotent mammalian neural crest stem cells (1999) Cell, 96 (5), pp. 737-749; Claxton, S., Kostourou, V., Jadeja, S., Chambon, P., Hodivala-Dilke, K., Fruttiger, M., Efficient, inducible cre-recombinase activation in vascular endothelium (2008) Genesis, 46 (2), pp. 74-80. , DOI 10.1002/dvg.20367; Lee, E.C., A highly efficient Escherichia colibased chromosome engineering system adapted for recombinogenic targeting and subcloning of BAC DNA (2001) Genomics, 73 (1), pp. 56-65; Stemple, D.L., Anderson, D.J., Isolation of a stem cell for neurons and glia from the mammalian neural crest (1992) Cell, 71 (6), pp. 973-985; Young, H.M., Hearn, C.J., Ciampoli, D., Southwell, B.R., Brunet, J.-F., Newgreen, D.F., A single rostrocaudal colonization of the rodent intestine by enteric neuron precursors is revealed by the expression of Phox2b, Ret, and p75 and by explants grown under the kidney capsule or in organ culture (1998) Developmental Biology, 202 (1), pp. 67-84. , DOI 10.1006/dbio.1998.8987; Heanue, T.A., Pachnis, V., Prospective identification and isolation of enteric nervous system progenitors using SOX2 (2011) Stem Cells, 29 (1), pp. 128-140; Blaugrund, E., Pham, T.D., Tennyson, V.M., Lo, L., Sommer, L., Anderson, D.J., Gershon, M.D., Distinct subpopulations of enteric neuronal progenitors defined by time of development, sympathoadrenal lineage markers and Mash-1-dependence (1996) Development, 122 (1), pp. 309-320; Hao, M.M., Young, H.M., Development of enteric neuron diversity (2009) J Cell Mol Med, 13 (7), pp. 1193-1210; Ganat, Y.M., Silbereis, J., Cave, C., Ngu, H., Anderson, G.M., Ohkubo, Y., Ment, L.R., Vaccarino, F.M., Early postnatal astroglial cells produce multilineage precursors and neural stem cells In Vivo (2006) Journal of Neuroscience, 26 (33), pp. 8609-8621. , http://www.jneurosci.org/cgi/reprint/26/33/8609.pdf, DOI 10.1523/JNEUROSCI.2532-06.2006; Vanden, B.P., Missiaen, L., Janssens, J., Tack, J., Calcium signalling and removal mechanisms in myenteric neurones (2002) Neurogastroenterology and Motility, 14 (1), pp. 63-73. , DOI 10.1046/j.1365-2982.2002.00303.x; Shcherbo, D., Far-red fluorescent tags for protein imaging in living tissues (2009) Biochem J, 418 (3), pp. 567-574; Gomes, P., ATP-dependent paracrine communication between enteric neurons and glia in a primary cell culture derived from embryonic mice (2009) Neurogastroenterol Motil, 21 (8), pp. 870-e862; Vanden, B.P., Klingauf, J., Spatial organization and dynamic properties of neurotransmitter release sites in the enteric nervous system (2007) Neuroscience, 145 (1), pp. 88-99. , DOI 10.1016/j.neuroscience.2006.11.048, PII S0306452206016289; Vanden, B.P., Tack, J., Boesmans, W., Highlighting Synaptic Communication in the Enteric Nervous System (2008) Gastroenterology, 135 (1), pp. 20-23. , DOI 10.1053/j.gastro.2008.06.001, PII S001650850800958X; Fox, D.A., Epstein, M.L., Bass, P., Surfactants selectively ablate enteric neurons of the rat jejunum (1983) Journal of Pharmacology and Experimental Therapeutics, 227 (2), pp. 538-544; Hanani, M., Ledder, O., Yutkin, V., Abu-Dalu, R., Huang, T.-Y., Hartig, W., Vannucchi, M.-G., Faussone-Pellegrini, M.-S., Regeneration of myenteric plexus in the mouse colon after experimental denervation with benzalkonium chloride (2003) Journal of Comparative Neurology, 462 (3), pp. 315-327. , DOI 10.1002/cne.10721; Ramalho, F.S., Santos, G.C., Ramalho, L.N.Z., Kajiwara, J.K., Zucoloto, S., Myenteric neuron number after acute and chronic denervation of the proximal jejunum induced by benzalkonium chloride (1993) Neuroscience Letters, 163 (1), pp. 74-76. , DOI 10.1016/0304-3940(93)90232-A; Bixby, S., Kruger, G.M., Mosher, J.T., Joseph, N.M., Morrison, S.J., Cell-intrinsic differences between stem cells from different regions of the peripheral nervous system regulate the generation of neural diversity (2002) Neuron, 35 (4), pp. 643-656. , DOI 10.1016/S0896-6273(02)00825-5; Hoff, S., Quantitative assessment of glial cells in the human and guinea pig enteric nervous system with an anti-Sox8/9/10 antibody (2008) J Comp Neurol, 509 (4), pp. 356-371; Temple, S., The development of neural stem cells (2001) Nature, 414 (6859), pp. 112-117. , DOI 10.1038/35102174; Joseph, N.M., He, S., Quintana, E., Kim, Y.-G., Núñez, G., Morrison, S.J., Enteric glia are multipotent in culture but primarily form glia in the adult rodent gut J Clin Invest, , doi: 10.1172/JCI58186; Fellin, T., Communication between neurons and astrocytes: Relevance to the modulation of synaptic and network activity (2009) J Neurochem, 108 (3), pp. 533-544; Alvarez-Buylla, A., Seri, B., Doetsch, F., Identification of neural stem cells in the adult vertebrate brain (2002) Brain Research Bulletin, 57 (6), pp. 751-758. , DOI 10.1016/S0361-9230(01)00770-5, PII S0361923001007705; Ooto, S., Akagi, T., Kageyama, R., Akita, J., Mandai, M., Honda, Y., Takahashi, M., Potential for neural regeneration after neurotoxic injury in the adult mammalian retina (2004) Proceedings of the National Academy of Sciences of the United States of America, 101 (37), pp. 13654-13659. , DOI 10.1073/pnas.0402129101; Heinrich, C., Directing astroglia from the cerebral cortex into subtype specific functional neurons (2010) PLoS Biol, 8 (5), pp. e1000373; Wood, J.D., Neuropathy in the brain-in-the-gut (2000) European Journal of Gastroenterology and Hepatology, 12 (6), pp. 597-600; Steinhoff, M.M., Kodner, I.J., DeSchryver-Kecskemeti, K., Axonal degeneration/necrosis: A possible ultrastructural marker for Crohn's disease (1988) Mod Pathol, 1 (3), pp. 182-187; Indra, A.K., Warot, X., Brocard, J., Bornert, J.-M., Xiao, J.-H., Chambon, P., Metzger, D., Temporally-controlled site-specific mutagenesis in the basal layer of the epidermis: Comparison of the recombinase activity of the tamoxifen-inducible Cre-ER(T) and Cre-ER(T2) recombinases (1999) Nucleic Acids Research, 27 (22), pp. 4324-4327. , DOI 10.1093/nar/27.22.4324; Fogarty, M., Grist, M., Gelman, D., Marin, O., Pachnis, V., Kessaris, N., Spatial genetic patterning of the embryonic neuroepithelium generates GABAergic interneuron diversity in the adult cortex (2007) Journal of Neuroscience, 27 (41), pp. 10935-10946. , http://www.jneurosci.org/cgi/reprint/27/41/10935, DOI 10.1523/JNEUROSCI.1629-07.2007; Schaeren-Wiemers, N., Gerfin-Moser, A., A single protocol to detect transcripts of various types and expression levels in neural tissue and cultured cells: In situ hybridization using digoxigenin-labelled cRNA probes (1993) Histochemistry, 100 (6), pp. 431-440; Kessaris, N., Fogarty, M., Iannarelli, P., Grist, M., Wegner, M., Richardson, W.D., Competing waves of oligodendrocytes in the forebrain and postnatal elimination of an embryonic lineage (2006) Nature Neuroscience, 9 (2), pp. 173-179. , DOI 10.1038/nn1620, PII NN1620
PY - 2011/9/1
Y1 - 2011/9/1
N2 - The enteric nervous system (ENS) in mammals forms from neural crest cells during embryogenesis and early postnatal life. Nevertheless, multipotent progenitors of the ENS can be identified in the adult intestine using clonal cultures and in vivo transplantation assays. The identity of these neurogenic precursors in the adult gut and their relationship to the embryonic progenitors of the ENS are currently unknown. Using genetic fate mapping, we here demonstrate that mouse neural crest cells marked by SRY box-containing gene 10 (Sox10) generate the neuronal and glial lineages of enteric ganglia. Most neurons originated from progenitors residing in the gut during mid-gestation. Afterward, enteric neurogenesis was reduced, and it ceased between 1 and 3 months of postnatal life. Sox10-expressing cells present in the myenteric plexus of adult mice expressed glial markers, and we found no evidence that these cells participated in neurogenesis under steady-state conditions. However, they retained neurogenic potential, as they were capable of generating neurons with characteristics of enteric neurons in culture. Furthermore, enteric glia gave rise to neurons in vivo in response to chemical injury to the enteric ganglia. Our results indicate that despite the absence of constitutive neurogenesis in the adult gut, enteric glia maintain limited neurogenic potential, which can be activated by tissue dissociation or injury.
AB - The enteric nervous system (ENS) in mammals forms from neural crest cells during embryogenesis and early postnatal life. Nevertheless, multipotent progenitors of the ENS can be identified in the adult intestine using clonal cultures and in vivo transplantation assays. The identity of these neurogenic precursors in the adult gut and their relationship to the embryonic progenitors of the ENS are currently unknown. Using genetic fate mapping, we here demonstrate that mouse neural crest cells marked by SRY box-containing gene 10 (Sox10) generate the neuronal and glial lineages of enteric ganglia. Most neurons originated from progenitors residing in the gut during mid-gestation. Afterward, enteric neurogenesis was reduced, and it ceased between 1 and 3 months of postnatal life. Sox10-expressing cells present in the myenteric plexus of adult mice expressed glial markers, and we found no evidence that these cells participated in neurogenesis under steady-state conditions. However, they retained neurogenic potential, as they were capable of generating neurons with characteristics of enteric neurons in culture. Furthermore, enteric glia gave rise to neurons in vivo in response to chemical injury to the enteric ganglia. Our results indicate that despite the absence of constitutive neurogenesis in the adult gut, enteric glia maintain limited neurogenic potential, which can be activated by tissue dissociation or injury.
KW - transcription factor Sox10
KW - animal cell
KW - animal experiment
KW - animal tissue
KW - article
KW - cell lineage
KW - chemical injury
KW - controlled study
KW - embryo
KW - gene mapping
KW - glia cell
KW - in vivo study
KW - intestine innervation
KW - mouse
KW - myenteric plexus
KW - nervous system development
KW - neural crest cell
KW - nonhuman
KW - priority journal
KW - Animals
KW - Cell Lineage
KW - Cells, Cultured
KW - Embryo, Mammalian
KW - Enteric Nervous System
KW - Female
KW - Mice
KW - Mice, Transgenic
KW - Multipotent Stem Cells
KW - Neural Crest
KW - Neurogenesis
KW - Neuroglia
KW - Neurons
KW - Pregnancy
KW - Recombinant Fusion Proteins
KW - SOXE Transcription Factors
UR - http://www.scopus.com/inward/record.url?eid=2-s2.0-80052361701&partnerID=8YFLogxK
U2 - 10.1172/JCI58200
DO - 10.1172/JCI58200
M3 - Article
AN - SCOPUS:80052361701
SN - 0021-9738
VL - 121
SP - 3412
EP - 3424
JO - Journal of Clinical Investigation
JF - Journal of Clinical Investigation
IS - 9
ER -