Pearce D A, Ferea T, Nosel S A, Das B, Sherman F
Department of Biochemistry and Biophysics, University of Rochester School of Medicine and Dentistry, New York 14642, USA.
Nat Genet. 1999 May;22(1):55-8. doi: 10.1038/8861.
Neuronal ceroid-lipofuscinoses (NCL) are autosomal recessive disorders that form the most common group of progressive neurodegenerative diseases in children, with an incidence as high as 1 in 12,500 live births, and with approximately 440,000 carriers in the United States. Disease progression is characterized by a decline in mental abilities, increased severity of untreatable seizures, blindness, loss of motor skills and premature death. The CLN3 gene, which is responsible for Batten disease, has been positionally cloned. The yeast gene, denoted BTN1, encodes a non-essential protein that is 39% identical and 59% similar to human CLN3. Strains lacking Btn1p, btn1-delta, are resistant to D-(-)-threo-2-amino-1-[p-nitrophenyl]-1,3-propanediol (ANP) in a pH-dependent manner. This phenotype was complemented by expression of human CLN3, demonstrating that yeast Btn1p and human CLN3 share the same function. Here, we report that btn1-delta yeast strains have an abnormally acidic vacuolar pH in the early phases of growth. Furthermore, DNA microarray analysis of BTN1 and btn1-delta strains revealed differential expression of two genes, with at least one, HSP30, involved in pH control. Because Btn1p is located in the vacuole, we suggest that Batten disease is caused by a defect in vacuolar (lysosomal) pH control. Our findings draw parallels between fundamental biological processes in yeast and previously observed characteristics of neurodegeneration in humans.
神经元蜡样脂褐质沉积症(NCL)是常染色体隐性疾病,是儿童中最常见的一组进行性神经退行性疾病,活产发病率高达1/12500,在美国约有44万携带者。疾病进展的特征是智力下降、无法治疗的癫痫发作严重程度增加、失明、运动技能丧失和过早死亡。导致巴顿病的CLN3基因已被定位克隆。酵母基因BTN1编码一种非必需蛋白,与人类CLN3的同源性为39%,相似性为59%。缺乏Btn1p的菌株btn1-δ对D-(-)-苏式-2-氨基-1-(对硝基苯基)-1,3-丙二醇(ANP)具有pH依赖性抗性。这种表型通过人类CLN3的表达得到互补,表明酵母Btn1p和人类CLN3具有相同的功能。在此,我们报道btn1-δ酵母菌株在生长早期具有异常酸性的液泡pH值。此外,对BTN1和btn1-δ菌株的DNA微阵列分析揭示了两个基因的差异表达,其中至少有一个基因HSP30参与pH调控。由于Btn1p位于液泡中,我们认为巴顿病是由液泡(溶酶体)pH调控缺陷引起的。我们的发现揭示了酵母中基本生物学过程与人类先前观察到的神经退行性变特征之间的相似之处。
