Live imaging of excitable axonal microdomains in ankyrin-G-GFP mice

Thome, Christian; Baum, Konrad; Schultz, Christian; Soyka, Stella J; Benoit, Chloé M; Stevens, Nikolas A; Ganea, Dan Alin; Lehmann, Nadja; Engelhardt, Maren; Acuna, Claudio; Gründemann, Jan; D'Este, Elisa; Bock, Michael; Jenkins, Paul; Hasegawa, Masashi; Janssen, Jan Maximilian; Karabulut, Seda; Bird, Kalynn M; Roos, Johannes; Bennett, Vann; Min, Lia Y

doi:10.7554/eLife.87078

Journal Article

DZNE-2025-00294

Live imaging of excitable axonal microdomains in ankyrin-G-GFP mice

Thome, C. ; Janssen, J. M. ; Karabulut, S. ; Acuna, C. ; D'Este, E. ; Soyka, S. J. ; Baum, K. ; Bock, M. ; Lehmann, N. ; Roos, J. ; Stevens, N. A. ; Hasegawa, M.DZNE* ; Ganea, D. A.Extern* ; Benoit, C. M.DZNE* ; Gründemann, J.DZNE* ; Min, L. Y. ; Bird, K. M. ; Schultz, C. ; Bennett, V. ; Jenkins, P. ; Engelhardt, M.

2025
eLife Sciences Publications Cambridge

eLife 12, RP87078 (2025) [10.7554/eLife.87078]

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Please use a persistent id in citations: doi:10.7554/eLife.87078

Abstract: The axon initial segment (AIS) constitutes not only the site of action potential initiation, but also a hub for activity-dependent modulation of output generation. Recent studies shedding light on AIS function used predominantly post-hoc approaches since no robust murine in vivo live reporters exist. Here, we introduce a reporter line in which the AIS is intrinsically labeled by an ankyrin-G-GFP fusion protein activated by Cre recombinase, tagging the native Ank3 gene. Using confocal, superresolution, and two-photon microscopy as well as whole-cell patch-clamp recordings in vitro, ex vivo, and in vivo, we confirm that the subcellular scaffold of the AIS and electrophysiological parameters of labeled cells remain unchanged. We further uncover rapid AIS remodeling following increased network activity in this model system, as well as highly reproducible in vivo labeling of AIS over weeks. This novel reporter line allows longitudinal studies of AIS modulation and plasticity in vivo in real-time and thus provides a unique approach to study subcellular plasticity in a broad range of applications.

Keyword(s): Animals (MeSH) ; Ankyrins: metabolism (MeSH) ; Ankyrins: genetics (MeSH) ; Mice (MeSH) ; Green Fluorescent Proteins: metabolism (MeSH) ; Green Fluorescent Proteins: genetics (MeSH) ; Axons: physiology (MeSH) ; Axons: metabolism (MeSH) ; Axon Initial Segment: metabolism (MeSH) ; Patch-Clamp Techniques (MeSH) ; Genes, Reporter (MeSH) ; Mice, Transgenic (MeSH) ; Action Potentials (MeSH) ; AIS plasticity ; ankryin-G ; axon initial segment ; live imaging ; mouse ; neuroscience ; node of Ranvier ; Ankyrins ; Green Fluorescent Proteins ; Ank3 protein, mouse

Classification:

ddc:600

Contributing Institute(s):

Neural Circuit Computations (AG Gründemann)

Research Program(s):

351 - Brain Function (POF4-351) (POF4-351)

Appears in the scientific report 2025

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Medline

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Document types > Articles > Journal Article
Institute Collections > BN DZNE > BN DZNE-AG Gründemann
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Record created 2025-02-04, last modified 2025-04-12

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