Ma Ying, Qiu Shi-Wei, Wang Wei-Qian, Feng Hai-Feng, Zheng Lu, Wei Ge-Ge, Nie Hui-Yi, Yang Jin-Yuan, Chen Yi-Jin, Dai Pu, Gao Xue, Yuan Yong-Yi
Senior Department of Otolaryngology Head and Neck Surgery, The 6th Medical Center of Chinese PLA General Hospital, Chinese PLA Medical School, Beijing, China.
State Key Laboratory of Hearing and Balance Science, Beijing, China.
Front Genet. 2025 Sep 15;16:1634493. doi: 10.3389/fgene.2025.1634493. eCollection 2025.
The solute carriers (SLCs) are important membrane-bound transporters that regulate cellular nutrition, metabolism, homeostasis and survival. Emerging evidence highlights the critical involvement of SLCs in auditory physiology. To date, over ten SLC family members have been linked to hearing function. MFSD3 (also known as SLC33A2), is a putative plasma membrane-localized acetyl-CoA transporter regulating lipid metabolism and energy homeostasis. It has been found to be associated with the pathogenesis of neurodegenerative dementia and tumor progression. Nevertheless, its potential role in hearing remains unexplored. In this study, through qRT-PCR, we demonstrated that was predominantly expressed during early embryonic development in zebrafish. Morpholino-mediated knockdown in zebrafish induced inner ear malformations (hypoplastic otic vesicles, reduced otolith size) and hair cells loss in lateral line neuromasts. Additionally, Mfsd3 deficiency led to developmental defects (pericardial edema, body axis curvature) and impaired locomotor activity in zebrafish. The qRT-PCR analysis further revealed significant upregulation of key Wnt/β-catenin pathway components (, , , and ) in knockdown zebrafish. Our findings suggest as a potential participant in auditory function and embryogenesis, with implications for understanding hearing loss pathogenesis.
溶质载体(SLCs)是重要的膜结合转运蛋白,可调节细胞营养、代谢、内环境稳定和存活。新出现的证据突显了SLCs在听觉生理学中的关键作用。迄今为止,已有十多个SLC家族成员与听力功能相关。MFSD3(也称为SLC33A2)是一种假定的质膜定位的乙酰辅酶A转运蛋白,可调节脂质代谢和能量稳态。已发现它与神经退行性痴呆的发病机制和肿瘤进展有关。然而,其在听力方面的潜在作用仍未得到探索。在本研究中,通过定量逆转录聚合酶链反应(qRT-PCR),我们证明了其在斑马鱼胚胎发育早期主要表达。在斑马鱼中,吗啉代介导的MFSD3敲低诱导了内耳畸形(耳囊发育不全、耳石尺寸减小)和侧线神经丘中的毛细胞损失。此外,Mfsd3缺陷导致斑马鱼出现发育缺陷(心包水肿、身体轴弯曲)和运动活动受损。qRT-PCR分析进一步揭示了在MFSD3敲低的斑马鱼中关键Wnt/β-连环蛋白信号通路成分(、、、和)的显著上调。我们的研究结果表明MFSD3是听觉功能和胚胎发生的潜在参与者,对理解听力损失的发病机制具有重要意义。
