<p>Astrocytes maintain extracellular ion and transmitter homeostasis, with the Na⁺ inward gradient playing a crucial role. Earlier studies suggested a rather low, uniform Na⁺ distribution in astrocytes, consistent with the view that these basic homeostatic properties are well-protected. Here, we employed multi-photon fluorescence lifetime imaging to quantitatively determine astrocytic [Na<sup>+</sup>] in mouse brain tissue slices and in vivo. Our data reveals a significant subcellular and cellular heterogeneity in astrocytic [Na<sup>+</sup>], accompanied by differences in the capacity for Na<sup>+</sup>/K<sup>+</sup>-ATPase (NKA)-mediated uptake of extracellular K<sup>+</sup>. RNAscope and immunohistochemistry indicate differential spatial expression patterns of NKA ß1 and ß2 subunits in astrocytes. Biophysical modeling of differential NKA expression together with varying strength of Na<sup>+</sup> influx replicate the experimentally observed heterogeneity in astrocytic [Na<sup>+</sup>]. Altogether, our results suggest the existence of functionally distinct astrocytes and astrocyte subdomains in which Na<sup>+</sup> homeostasis is locally adapted to the specific requirements of surrounding neural networks.</p>

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Cellular and subcellular heterogeneity of astrocytic Na⁺ homeostasis tuning astrocytes into functionally distinct subgroups in the mouse brain

  • Jan Meyer,
  • Viola Bornemann,
  • Alok Bhattarai,
  • Sara Eitelmann,
  • Petr Unichenko,
  • Simone Durry,
  • Karl W. Kafitz,
  • Nicholas Chalmers,
  • Jianfeng Fan,
  • Ruth Beckervordersandforth,
  • Christian Henneberger,
  • Ghanim Ullah,
  • Christine R. Rose

摘要

Astrocytes maintain extracellular ion and transmitter homeostasis, with the Na⁺ inward gradient playing a crucial role. Earlier studies suggested a rather low, uniform Na⁺ distribution in astrocytes, consistent with the view that these basic homeostatic properties are well-protected. Here, we employed multi-photon fluorescence lifetime imaging to quantitatively determine astrocytic [Na+] in mouse brain tissue slices and in vivo. Our data reveals a significant subcellular and cellular heterogeneity in astrocytic [Na+], accompanied by differences in the capacity for Na+/K+-ATPase (NKA)-mediated uptake of extracellular K+. RNAscope and immunohistochemistry indicate differential spatial expression patterns of NKA ß1 and ß2 subunits in astrocytes. Biophysical modeling of differential NKA expression together with varying strength of Na+ influx replicate the experimentally observed heterogeneity in astrocytic [Na+]. Altogether, our results suggest the existence of functionally distinct astrocytes and astrocyte subdomains in which Na+ homeostasis is locally adapted to the specific requirements of surrounding neural networks.