The human channel gating–modifying A749G CACNA1D (Cav1.3) variant induces a neurodevelopmental syndrome–like phenotype in mice
Nadine J. Ortner, … , Jochen Roeper, Jörg Striessnig
Nadine J. Ortner, … , Jochen Roeper, Jörg Striessnig
Published September 12, 2023
Citation Information: JCI Insight. 2023;8(20):e162100. https://doi.org/10.1172/jci.insight.162100.
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Research Article Neuroscience

The human channel gating–modifying A749G CACNA1D (Cav1.3) variant induces a neurodevelopmental syndrome–like phenotype in mice

Abstract

Germline de novo missense variants of the CACNA1D gene, encoding the pore-forming α1 subunit of Cav1.3 L-type Ca2+ channels (LTCCs), have been found in patients with neurodevelopmental and endocrine dysfunction, but their disease-causing potential is unproven. These variants alter channel gating, enabling enhanced Cav1.3 activity, suggesting Cav1.3 inhibition as a potential therapeutic option. Here we provide proof of the disease-causing nature of such gating-modifying CACNA1D variants using mice (Cav1.3AG) containing the A749G variant reported de novo in a patient with autism spectrum disorder (ASD) and intellectual impairment. In heterozygous mutants, native LTCC currents in adrenal chromaffin cells exhibited gating changes as predicted from heterologous expression. The A749G mutation induced aberrant excitability of dorsomedial striatum–projecting substantia nigra dopamine neurons and medium spiny neurons in the dorsal striatum. The phenotype observed in heterozygous mutants reproduced many of the abnormalities described within the human disease spectrum, including developmental delay, social deficit, and pronounced hyperactivity without major changes in gross neuroanatomy. Despite an approximately 7-fold higher sensitivity of A749G-containing channels to the LTCC inhibitor isradipine, oral pretreatment over 2 days did not rescue the hyperlocomotion. Cav1.3AG mice confirm the pathogenicity of the A749G variant and point toward a pathogenetic role of altered signaling in the dopamine midbrain system.

Authors

Nadine J. Ortner, Anupam Sah, Enrica Paradiso, Josef Shin, Strahinja Stojanovic, Niklas Hammer, Maria Haritonova, Nadja T. Hofer, Andrea Marcantoni, Laura Guarina, Petronel Tuluc, Tamara Theiner, Florian Pitterl, Karl Ebner, Herbert Oberacher, Emilio Carbone, Nadia Stefanova, Francesco Ferraguti, Nicolas Singewald, Jochen Roeper, Jörg Striessnig

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Figure 3

Similar brain morphology in Cav1.3AG mutant mice.

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Similar brain morphology in Cav1.3AG mutant mice. Data are shown as mean...
Data are shown as mean ± SEM. (A) Representative pictures of Nissl-stained brain sections from adult (13–15 wk) male mice of the cerebellum (n = 3–7/genotype), hippocampus (n = 5–10/genotype), and olfactory bulb (n = 5–7/genotype). Scale bars: 1 mm (cerebellum; top), 500 μm (hippocampus, middle; olfactory bulb, bottom). (B) Brain weight and respective body weight of male and female animals for the indicated age and number of animals. KO, Cav1.3-KO animals. Statistical analyses were performed with 1-way ANOVA with Dunnett’s multiple-comparison post hoc test. Due to the limited availability of homozygous mutants and respective experiments, we have excluded homozygous animals of the 5 wk cohort from statistical analysis due to the low n. (C) Left: Representative pictures of Nissl-stained sagittal brain sections from male WT and HET mice (olfactory bulb was not captures at the same level). Right: Comparable volumes of individual brain regions (Cavalieri principle; unpaired Student’s t test). Scale bar: 2 mm. (DG) No statistically significant differences (1-way ANOVA) of the striatal volume (D, dorsal: caudate putamen [CPu]; E, ventral: nucleus accumbens [NAc]) or TH+ neuron number within the SN (F) and VTA (G) between adult male WT and mutant mice determined in serial TH-stained brain sections (Supplemental Figure 4, A and B). ***P < 0.001, **P < 0.01, *P < 0.05.