DiDonato Christine J, Parks Robin J, Kothary Rashmi
Ottawa Health Research Institute, Molecular Medicine Program and University of Ottawa Center for Neuromuscular Disease, Ottawa, ON, K1N 8L6, Canada.
Hum Gene Ther. 2003 Jan 20;14(2):179-88. doi: 10.1089/104303403321070874.
Spinal muscular atrophy (SMA) is a motor neuron degeneration disorder, and manifests itself in patients as muscle weakness and paralysis that ultimately leads to death. Currently, there is no effective treatment for this disease. As a first step in developing a treatment for SMA, we are examining whether delivery of the gene encoding survival motor neuron (SMN) protein to primary fibroblast cell lines derived from SMA patients can lead to restoration of nuclear-staining foci, called gems, which are absent in patients with severe SMA. Using adenovirus-mediated gene delivery, we show that SMN can be efficiently expressed in patient fibroblasts, and leads to restoration of nuclear gems, which are thought to be important for the functional rescue of the SMA phenotype. The number of gems per cell is equal to or greater than those found in fibroblasts of normal individuals. Furthermore, ectopic expression of SMN also caused relocalization of Gemin2, an SMN-interacting protein, to gems. Overall, this work is the first demonstration of the feasibility of virus-based delivery of the SMN-coding gene to restore the normal SMN expression pattern in SMA patient-derived cells, and holds promise for gene therapy of SMA, as a potential long-term therapy for this devastating childhood disease.
脊髓性肌萎缩症(SMA)是一种运动神经元退行性疾病,在患者身上表现为肌肉无力和瘫痪,最终导致死亡。目前,这种疾病尚无有效治疗方法。作为开发SMA治疗方法的第一步,我们正在研究将编码存活运动神经元(SMN)蛋白的基因导入源自SMA患者的原代成纤维细胞系,是否能够使核染色灶(称为宝石样小体)恢复,而严重SMA患者体内不存在这种小体。通过腺病毒介导的基因传递,我们发现SMN能够在患者成纤维细胞中高效表达,并导致核宝石样小体恢复,而这些小体被认为对SMA表型的功能挽救很重要。每个细胞中的宝石样小体数量等于或大于正常个体成纤维细胞中的数量。此外,SMN的异位表达还导致与SMN相互作用的蛋白Gemin2重新定位到宝石样小体上。总体而言,这项工作首次证明了基于病毒传递SMN编码基因以恢复SMA患者来源细胞中正常SMN表达模式的可行性,并为SMA的基因治疗带来了希望,有望成为这种毁灭性儿童疾病的潜在长期治疗方法。
