A dual-reporter mouse for therapeutic discovery in Angelman syndrome
Hanna Vihma, Lucas M. James, Hannah C. Nourie, Audrey L. Smith, Siyuan Liang, Carlee A. Friar, Tasmai Vulli, Lei Xing, Dale O. Cowley, Alain C. Burette, Benjamin D. Philpot
Hanna Vihma, Lucas M. James, Hannah C. Nourie, Audrey L. Smith, Siyuan Liang, Carlee A. Friar, Tasmai Vulli, Lei Xing, Dale O. Cowley, Alain C. Burette, Benjamin D. Philpot
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Research Article Genetics Neuroscience

A dual-reporter mouse for therapeutic discovery in Angelman syndrome

Abstract

Angelman syndrome is a neurodevelopmental disorder caused by loss of the maternal UBE3A allele, the sole source of UBE3A in mature neurons owing to epigenetic silencing of the paternal allele. Although emerging therapies are being developed to restore UBE3A expression by activating the dormant paternal UBE3A allele, existing mouse models for such preclinical studies have limited throughput and utility, creating bottlenecks for both in vitro therapeutic screening and in vivo characterization. To address this, we developed the Ube3a-INSG dual-reporter knockin mouse, in which an IRES-Nanoluciferase-T2A-Sun1-sfGFP (INSG) cassette was inserted downstream of the endogenous Ube3a stop codon. The INSG model preserves UBE3A protein levels and function while enabling 2 complementary allele-specific readouts: Sun1-sfGFP and Nanoluciferase. We show that Sun1-sfGFP, a nuclear envelope–localized reporter, enables single-cell fluorescence analysis, whole-brain light-sheet imaging, and nuclear quantification by flow cytometry. Further, Nanoluciferase supports high-throughput luminescence assays for sensitive pharmacological profiling in cultured neurons and noninvasive in vivo bioluminescence imaging for pharmacodynamic assessment. By combining scalable screening, cellular analysis, and real-time in vivo monitoring in a single model, the Ube3a-INSG dual-reporter mouse provides a powerful platform to accelerate therapeutic development centered on UBE3A.

Authors

Hanna Vihma, Lucas M. James, Hannah C. Nourie, Audrey L. Smith, Siyuan Liang, Carlee A. Friar, Tasmai Vulli, Lei Xing, Dale O. Cowley, Alain C. Burette, Benjamin D. Philpot

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Figure 9

Brain-wide imaging of the Sun1-sfGFP reporter using LSFM.

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Brain-wide imaging of the Sun1-sfGFP reporter using LSFM. (A and B) Maxi...
(A and B) Maximum-intensity projections of left hemispheres from P30 matINSG (A) and patINSG (B) brains labeled with GFP using iDISCO and visualized with 3D LSFM. The matINSG brain shows robust, widespread GFP expression, whereas patINSG shows lower overall expression, with the strongest labeling in the rostral migratory stream (arrowheads) and dentate gyrus (arrows). (C and D) Virtual 25 μm slices from A and B. (C) The matINSG brain shows a strong GFP signal across cortical layers and hippocampus, particularly in the pyramidal cell layer and dentate gyrus. (D) In contrast, the patINSG shows markedly reduced labeling, with prominent expression in the subventricular zone (arrowheads) and subgranular zone of the dentate gyrus (arrow). (E and F) Single light-sheet images in XY, XZ, and YZ planes from the neocortex of A and B, showing single-cell resolution. In both matINSG and patINSG brains, individual GFP-positive cells are identifiable, with resolution sufficient to show the nuclear localization of the Sun1-sfGFP reporter. The matINSG neocortex exhibits markedly higher GFP-positive cell density compared with patINSG, with the patINSG neocortex predominantly showing labeling of small nuclei, presumably of glia. Scale bars: 150 μm (C and D).