Vestibular compensation after unilateral labyrinthectomy: normal versus cerebellar dysfunctional mice.

The Journal of otolaryngology Pub Date : 2007-12-01

Mohammad Aleisa, Anthony G Zeitouni, Kathleen E Cullen

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Abstract

Introduction: Loss of vestibular information from one labyrinth produces marked asymmetries of postural and ocular motor control, which resolve over time. Recent developments in mouse genetic engineering, which allow the generation of transgenic and knockout mutant mice, provide a unique opportunity to bridge the gap between the molecular mechanisms that underlie compensation and behaviour.

Method: We compared compensation following unilateral labyrinthectomy in wild-type mice and a cerebellar-dysfunctional mouse (the Lurcher mutant). The Lurcher mutant is characterized by a point mutation in the ionotropic glutamate receptor delta 2 subunit gene that results in loss of all Purkinje cells. To further investigate this question, we characterized vestibular compensation in a strain of mutant mice that completely lack cerebellar Purkinje cells.

Results: Static signs resolved within 24 hours in wild-type mice but did not fully resolve in Lurcher mice. Dynamic signs were evaluated by the quantitative analysis of vestibulo-ocular (VOR) and vestibulocollic (VCR) reflexes. The VOR assessed at 0.5 Hz exhibited increasing gain from day 1 to day 5, reaching control levels by day 20 for the wild-type mice. In contrast, Lurcher mutant mice showed significantly less compensation over this same period. VOR compensation in the mutant mice was slightly more robust in response to high acceleration thrusts but again never reached control levels. Similarly, VCR gains showed limited compensation and remained subnormal in mutant mice.

Conclusion: Compensation for dynamic signs starts at day 5 after unilateral labyrinthectomy in normal mice. Cerebellar dysfunctional mutant mice do not compensate for static signs and show limited vestibular compensation for dynamic signs only. We conclude that other noncerebellar pathways for vestibular compensation exist, and our findings emphasize the need for these to be further explored.

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单侧迷路切除后的前庭代偿:正常小鼠与小脑功能障碍小鼠。

导读:迷宫症前庭信息的丢失会导致姿势和眼运动控制的明显不对称，这种不对称会随着时间的推移而消退。小鼠基因工程的最新发展，允许转基因和基因敲除突变小鼠的产生，提供了一个独特的机会来弥合补偿和行为背后的分子机制之间的差距。方法:我们比较了野生型小鼠和小脑功能障碍小鼠(Lurcher突变体)单侧迷路切除术后的代偿。Lurcher突变的特点是在嗜离子性谷氨酸受体δ 2亚基基因中发生点突变，导致所有浦肯野细胞的丢失。为了进一步研究这个问题，我们在一株完全缺乏小脑浦肯野细胞的突变小鼠中表征了前庭代偿。结果:野生型小鼠的静态体征在24小时内消失，而Lurcher小鼠的静态体征未完全消失。通过前庭-眼(VOR)和前庭-结肠(VCR)反射的定量分析来评估动态体征。在0.5 Hz下评估的VOR从第1天到第5天增加，到第20天达到野生型小鼠的控制水平。相比之下，Lurcher突变小鼠在同一时期表现出明显更少的补偿。突变小鼠的VOR补偿对高加速度推力的反应略强，但再次没有达到控制水平。同样，变异小鼠的VCR增益表现出有限的补偿，并保持在亚正常水平。结论:正常小鼠单侧迷路切除术后第5天开始出现动态体征代偿。小脑功能失调突变小鼠不补偿静态信号，仅对动态信号表现出有限的前庭代偿。我们的结论是，存在其他非小脑的前庭代偿途径，我们的发现强调需要进一步探索这些途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Journal of otolaryngology

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