Impaired neuromuscular transmission and skeletal muscle fiber necrosis in mice lacking Na/Ca exchanger 3
Sophie Sokolow, … , Andre Herchuelz, Stéphane Schurmans
Sophie Sokolow, … , Andre Herchuelz, Stéphane Schurmans
Published January 15, 2004
Citation Information: J Clin Invest. 2004;113(2):265-273. https://doi.org/10.1172/JCI18688.
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Article Neuroscience

Impaired neuromuscular transmission and skeletal muscle fiber necrosis in mice lacking Na/Ca exchanger 3

Abstract

We produced and analyzed mice deficient for Na/Ca exchanger 3 (NCX3), a protein that mediates cellular Ca2+ efflux (forward mode) or Ca2+ influx (reverse mode) and thus controls intracellular Ca2+ concentration. NCX3-deficient mice (Ncx3–/–) present a skeletal muscle fiber necrosis and a defective neuromuscular transmission, reflecting the absence of NCX3 in the sarcolemma of the muscle fibers and at the neuromuscular junction. The defective neuromuscular transmission is characterized by the presence of electromyographic abnormalities, including low compound muscle action potential amplitude, a decremental response at low-frequency nerve stimulation, an incremental response, and a prominent postexercise facilitation at high-frequency nerve stimulation, as well as neuromuscular blocks. The analysis of quantal transmitter release in Ncx3–/– neuromuscular junctions revealed an important facilitation superimposed on the depression of synaptic responses and an elevated delayed release during high-frequency nerve stimulation. It is suggested that Ca2+ entering nerve terminals is cleared relatively slowly in the absence of NCX3, thereby enhancing residual Ca2+ and evoked and delayed quantal transmitter release during repetitive nerve stimulation. Our findings indicate that NCX3 plays an important role in vivo in the control of Ca2+ concentrations in the skeletal muscle fibers and at the neuromuscular junction.

Authors

Sophie Sokolow, Mario Manto, Philippe Gailly, Jordi Molgó, Clarisse Vandebrouck, Jean-Marie Vanderwinden, Andre Herchuelz, Stéphane Schurmans

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Figure 1

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Targeted disruption of the Ncx3 gene. (a) Structure of the WT and the ta...
Targeted disruption of the Ncx3 gene. (a) Structure of the WT and the targeted alleles. The second exon (shaded boxes), the neomycin resistance cassette (black box), the probes used in DNA and RNA hybridization analysis (black bars underneath the second exon), as well as the DNA fragments generated after digestion with KnpI + SpeI or KpnI alone are represented. K, KpnI; H, HindIII; S, SpeI; E, EcoRI; B, BamHI. (b and c) DNA hybridization analysis of KpnI + SpeI– (b) and KpnI- (c) digested genomic DNA isolated from ES clones using the depicted probe. (d) RNA hybridization analysis. Messenger RNA (0.5 μg/lane) was hybridized with Ncx3 or GAPDH RNA probes. (e) RT-PCR analysis. Ncx3 amplicon (∼600 bp) and housekeeping gene HPRT amplicon (∼250 bp) were simultaneously amplified from gastrocnemius muscle messenger RNA by one-step RT-PCR. (f, g, and h) Western blot analysis. (f) Membrane fractions (50 μg/lane) from gastrocnemius muscle were analyzed with anti-NCX3–specific antibody. (g) Immunodetection of membrane fractions from Ncx3+/+ (lanes 1–3) and Ncx3–/– (lanes 4–6) gastrocnemius muscle analyzed with anti-NCX1– and anti-PMCA1–specific antibodies. Amount of protein loaded: lanes 1 and 4, 50 μg; lanes 2 and 5, 15 μg; lanes 3 and 6, 5 μg. (h) Membrane fractions (20 μg/lane) from FDB muscle were analyzed with anti-NCX1–specific antibody. Protein loading in (fh) was determined by using a mouse anti-desmin monoclonal antibody.