Rhyu Im Joo, Nahm Sang-Soep, Hwang Seung Jun, Kim Hyun, Suh Young-Suk, Oda Sen-Ich, Frank Tamy C, Abbott Louise C
Institute of Human Genetics and Department of Anatomy, Korea University College of Medicine, 126-1 Anam-Dong 5-Ga, Seongbuk-Ku, Seoul 136-705, South Korea.
Brain Res. 2003 Jul 11;977(2):129-40. doi: 10.1016/s0006-8993(03)02403-x.
Tottering, rolling Nagoya, and leaner mutant mice all exhibit cerebellar ataxia to varying degrees, from mild (tottering mice) to severe (leaner mice). Collectively, these mice are regarded as tottering locus mutants because each of these mutant mice expresses a different autosomal recessive mutation in the gene coding for the alpha(1A) calcium ion channel protein, which is the pore forming subunit for P/Q-type high voltage activated calcium ion channels. These mutant mice all exhibit varying degrees of cerebellar dysfunction and neuronal cell death. Nitric oxide (NO) is an important messenger molecule in the central nervous system, especially in the cerebellum, and it is produced via the enzyme, nitric oxide synthase (NOS). We investigated expression of neuronal-NOS (n-NOS) in the cerebella of all three mutant mice, as revealed by NADPH-diaphorase (NADPH-d) histochemical staining, quantitation of n-NOS protein using Western blotting and quantitation of n-NOS mRNA using in situ hybridization. The expression of n-NOS mRNA and protein as well as the NADPH-d histochemical reaction were elevated in tottering and rolling Nagoya cerebella. n-NOS mRNA and the NADPH-d histochemical reaction were decreased in the leaner cerebellum, but the leaner mouse n-NOS protein concentration was not significantly different compared to age- and gender-matched controls. These findings suggest that NO may act as an important mediator in the production of the neuropathology observed in these mutant mice.
蹒跚、滚动型名古屋小鼠和瘦型突变小鼠均表现出不同程度的小脑共济失调,从轻度(蹒跚小鼠)到重度(瘦型小鼠)。总体而言,这些小鼠被视为蹒跚基因座突变体,因为这些突变小鼠中的每一只都在编码α(1A)钙离子通道蛋白的基因中表达了不同的常染色体隐性突变,该蛋白是P/Q型高电压激活钙离子通道的孔形成亚基。这些突变小鼠均表现出不同程度的小脑功能障碍和神经元细胞死亡。一氧化氮(NO)是中枢神经系统尤其是小脑中的一种重要信使分子,它通过一氧化氮合酶(NOS)产生。我们通过NADPH-黄递酶(NADPH-d)组织化学染色、使用蛋白质印迹法定量n-NOS蛋白以及使用原位杂交法定量n-NOS mRNA,研究了所有三种突变小鼠小脑中神经元型NOS(n-NOS)的表达。在蹒跚和滚动型名古屋小鼠的小脑中,n-NOS mRNA和蛋白的表达以及NADPH-d组织化学反应均升高。在瘦型小鼠小脑中,n-NOS mRNA和NADPH-d组织化学反应降低,但与年龄和性别匹配的对照相比,瘦型小鼠的n-NOS蛋白浓度没有显著差异。这些发现表明,NO可能是这些突变小鼠中观察到的神经病理学产生的重要介质。
