考虑基因治疗以预防x连锁耳聋DFNX2和相关神经发育障碍

Ibrain Pub Date : 2022-09-27 DOI:10.1002/ibra.12068
Jean Defourny
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引用次数: 0

摘要

编码POU3F4转录因子的基因或上游基因的突变和缺失导致人类x连锁进行性耳聋DFNX2和其他神经发育障碍。听力损失可以是纯感音神经性的,也可以是混合性的,即既有传导性成分,也有感音神经性成分。受影响的男性表现为内耳解剖异常,共同定义为不完全分区III型。目前改善DFNX2患者听力和语言技能的方法似乎并不完全有效。由于内耳畸形,人工耳蜗植入术难度大,易发生严重并发症。即使在安全植入的情况下,患者的听力和语言结果仍然存在很大差异。小鼠DFNX2型耳聋模型显示,耳蜗外侧壁螺旋韧带纤维细胞功能障碍可引起感音神经丧失,导致耳蜗内电位降低。高度阳性的耳蜗电位对感觉毛细胞机械传导和听力至关重要。在此背景下,我们提出了一种基于腺相关病毒(AAV)载体介导的耳蜗螺旋韧带纤维细胞基因转移的雄性Pou3f4−/y小鼠的治疗方法。在广泛的AAV载体中,发现AAV7对螺旋韧带表现出强烈的趋向性。因此,我们认为aav7介导的Pou3f4互补DNA在Pou3f4−/y小鼠螺旋韧带中的传递可能是一种有吸引力的策略,可以在听力损失发展为深度耳聋之前防止纤维细胞变性,恢复正常的耳蜗功能和特性,包括耳蜗内电位的阳性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Considering gene therapy to protect from X-linked deafness DFNX2 and associated neurodevelopmental disorders

Considering gene therapy to protect from X-linked deafness DFNX2 and associated neurodevelopmental disorders

Mutations and deletions in the gene or upstream of the gene encoding the POU3F4 transcription factor cause X-linked progressive deafness DFNX2 and additional neurodevelopmental disorders in humans. Hearing loss can be purely sensorineural or mixed, that is, with both conductive and sensorineural components. Affected males show anatomical abnormalities of the inner ear, which are jointly defined as incomplete partition type III. Current approaches to improve hearing and speech skills of DFNX2 patients do not seem to be fully effective. Owing to inner ear malformations, cochlear implantation is surgically difficult and may predispose towards severe complications. Even in cases where implantation is safely performed, hearing and speech outcomes remain highly variable among patients. Mouse models for DFNX2 deafness revealed that sensorineural loss could arise from a dysfunction of spiral ligament fibrocytes in the lateral wall of the cochlea, which leads to reduced endocochlear potential. Highly positive endocochlear potential is critical for sensory hair cell mechanotransduction and hearing. In this context, here, we propose to develop a therapeutic approach in male Pou3f4−/y mice based on an adeno-associated viral (AAV) vector-mediated gene transfer in cochlear spiral ligament fibrocytes. Among a broad range of AAV vectors, AAV7 was found to show a strong tropism for the spiral ligament. Thus, we suggest that an AAV7-mediated delivery of Pou3f4 complementary DNA in the spiral ligament of Pou3f4−/y mice could represent an attractive strategy to prevent fibrocyte degeneration and to restore normal cochlear functions and properties, including a positive endocochlear potential, before hearing loss progresses to profound deafness.

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