Abstract
Enteric glial cells are vital for the autonomic control of gastrointestinal homeostasis by the enteric nervous system. Several different functions have been assigned to enteric glial cells but whether these are performed by specialized subtypes with a distinctive phenotype and function remains elusive. We used Mosaic Analysis with Double Markers and inducible lineage tracing to characterize the morphology and dynamic molecular marker expression of enteric GLIA in the myenteric plexus. Functional analysis in individually identified enteric glia was performed by Ca(2+) imaging. Our experiments have identified four morphologically distinct subpopulations of enteric glia in the gastrointestinal tract of adult mice. Marker expression analysis showed that the majority of glia in the myenteric plexus co-express glial fibrillary acidic protein (GFAP), S100β, and Sox10. However, a considerable fraction (up to 80%) of glia outside the myenteric ganglia, did not label for these markers. Lineage tracing experiments suggest that these alternative combinations of markers reflect dynamic gene regulation rather than lineage restrictions. At the functional level, the three myenteric glia subtypes can be distinguished by their differential response to adenosine triphosphate. Together, our studies reveal extensive heterogeneity and phenotypic plasticity of enteric glial cells and set a framework for further investigations aimed at deciphering their role in digestive function and disease.
Highlights
Glial cells are essential for the organization and function of the nervous system (Jessen, 2004)
High Resolution Labeling of Enteric glial cells (EGCs) Using Mosaic Analysis With Double Markers (MADM) Glia-specific molecular markers that are expressed widely in the central and peripheral nervous system have been used extensively for the identification and characterization of EGCs in mouse embryos and adult animals. Among such markers are the intermediate filament glial fibrillary acidic protein (GFAP) and the Ca21-binding protein S100b, which are expressed by committed EGC progenitors and differentiated EGCs (Ferri et al, 1982; Jessen and Mirsky, 1980; Young et al, 2003)
Introduction of the Sox10::Cre transgene, which drives expression of Cre recombinase in all neural crest cell lineages and peripheral glial cells (Laranjeira et al, 2011; Matsuoka et al, 2005), into Mosaic Analysis with Double Markers (MADM)-6GR/RG compound heterozygous mice, allowed us to mark with GFP or RFP-myc or both, isolated EGCs (Fig. 1a) and enteric neurons
Summary
Glial cells are essential for the organization and function of the nervous system (Jessen, 2004). In addition to their “traditional” roles in providing nourishment and support for neurons, glial cells regulate synaptic transmission, maintain the blood-brain barrier, mediate communication between the nervous and immune systems and monitor the nutritional state of organisms (Allaman et al, 2011; Giaume et al, 2010; Perea et al, 2009) Highlighting their critical role during embryogenesis and in postnatal life, several developmental, degenerative, and inflammatory disorders of the nervous system have been associated with deficits in glial cell function (Barres, 2008; Lee et al, 2000; Lemke, 2001). Enteric neurons and EGCs are derived from neural crest cells which emerge during embryogenesis from the vagal and sacral level of the neural tube and colonize
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