Impaired glycine neurotransmission causes adolescent idiopathic scoliosis
Xiaolu Wang, … , You-Qiang Song, Bo Gao
Xiaolu Wang, … , You-Qiang Song, Bo Gao
Published November 14, 2023
Citation Information: J Clin Invest. 2024;134(2):e168783. https://doi.org/10.1172/JCI168783.
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Research Article Bone biology Genetics

Impaired glycine neurotransmission causes adolescent idiopathic scoliosis

Abstract

Adolescent idiopathic scoliosis (AIS) is the most common form of spinal deformity, affecting millions of adolescents worldwide, but it lacks a defined theory of etiopathogenesis. Because of this, treatment of AIS is limited to bracing and/or invasive surgery after onset. Preonset diagnosis or preventive treatment remains unavailable. Here, we performed a genetic analysis of a large multicenter AIS cohort and identified disease-causing and predisposing variants of SLC6A9 in multigeneration families, trios, and sporadic patients. Variants of SLC6A9, which encodes glycine transporter 1 (GLYT1), reduced glycine-uptake activity in cells, leading to increased extracellular glycine levels and aberrant glycinergic neurotransmission. Slc6a9 mutant zebrafish exhibited discoordination of spinal neural activities and pronounced lateral spinal curvature, a phenotype resembling human patients. The penetrance and severity of curvature were sensitive to the dosage of functional glyt1. Administration of a glycine receptor antagonist or a clinically used glycine neutralizer (sodium benzoate) partially rescued the phenotype. Our results indicate a neuropathic origin for “idiopathic” scoliosis, involving the dysfunction of synaptic neurotransmission and central pattern generators (CPGs), potentially a common cause of AIS. Our work further suggests avenues for early diagnosis and intervention of AIS in preadolescents.

Authors

Xiaolu Wang, Ming Yue, Jason Pui Yin Cheung, Prudence Wing Hang Cheung, Yanhui Fan, Meicheng Wu, Xiaojun Wang, Sen Zhao, Anas M. Khanshour, Jonathan J. Rios, Zheyi Chen, Xiwei Wang, Wenwei Tu, Danny Chan, Qiuju Yuan, Dajiang Qin, Guixing Qiu, Zhihong Wu, Terry Jianguo Zhang, Shiro Ikegawa, Nan Wu, Carol A. Wise, Yong Hu, Keith Dip Kei Luk, You-Qiang Song, Bo Gao

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Figure 5

Body curvature caused by disturbance of CPG.

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Body curvature caused by disturbance of CPG. (A) Dorsal view fluorescent...
(A) Dorsal view fluorescent snapshots of the spinal cord of WT and slc6a9m/m zebrafish in a Tg(elavl3-H2B-GCaMP6s) background at 24 hpf. ROI is circled and numbered as 1–4. Lower panel shows quantification of fluorescence changes in the ROIs of WT and slc6a9m/m zebrafish. Each frame was taken with a 100 ms exposure and at 10 fps. GCaMP6s fluorescence intensity was defined as the ΔF/F, and ΔF/F changes within a 20-second recording time are shown. (B) Quantification of left and right alternation index in WT (n = 6) and slc6a9m/m (n = 6) zebrafish. This analysis was performed based on quantified intensities of total left- and right-side neural activities within a 1-minute recording time period. Unpaired Student’s t test. ****P < 0.0001. (C) Frequency of neural activities in WT (n = 6) and slc6a9m/m (n = 6) zebrafish. Frequency (Hz) was calculated based on left-side neural activity. Unpaired Student’s t test. ****P < 0.0001. (D) Spinal curvature of dmrt3a mutant zebrafish at 21 dpf. (E) Curvature phenotype and micro-CT images of dmrt3a mutant zebrafish at 120 dpf. Images are shown in either side or dorsal view. To detect the details of apices of curvatures, the 2 curvature regions (areas 1 and 2) of dmrt3am/m zebrafish are enlarged and oriented in different angles (right). Note that all highlighted adjacent vertebrae (arrows) are morphologically normal. Scale bars: 200 μm (A); 2 mm (D, E, right); 1 cm (E, left). Boxes show median and IQRs with all individual data points superimposed. Number of analyzed fish and the penetrance of curvature (θ ≥10°) are quantified and indicated for each genotype. Unpaired Student’s t test (B and C) or 1-way ANOVA test (D). ***P < 0.001; ****P < 0.0001.