Müller Cell Molecular Heterogeneity: Facts and Predictions

The retina was historically considered as an "approachable part of the brain"; advantageous, for its simplicity, to use as a model organ for deciphering cellular and molecular mechanisms underlying physiology and pathology of the nervous system. However, the most relevant discoveries arise precisely from unveiling the complexity of the retina. A complexity that partially relies on the layered organization of an extended variety of specialized neuronal and glial cellular types and subtypes. Based on functional, morphological or transcriptome data, over 40 subtypes of retinal ganglion cells or 60 subtypes of retinal amacrine cells have been described. A high degree of specialization, that may lead to segregation into functionally diverse subtypes, is also conceivable for M & uuml;ller cells, a pleiotropic glial component of all vertebrate retinas. The essential role of M & uuml;ller glia in retinal homeostasis maintenance involves participation in structural, metabolic and intercellular communication processes. Additionally, they are the only retinal cells that possess regenerative potential in response to injury or disease, and thus may be considered as therapeutic tools. In the assumption that functional heterogeneity might be driven by molecular heterogeneity this review aims to compile emerging evidence that could broaden our understanding of M & uuml;ller cell biology and retinal physiology.Summary statementM & uuml;ller glial cells exert multiple essential functions in retinal physiology and retinopathies reflecting perhaps the existence of distinct M & uuml;ller cellular subpopulations. Harnessing M & uuml;ller cell heterogeneity may serve to enhance new therapeutic approaches for retinal disease.