Stem Cell and Neurotherapies, Division of Cell Matrix Biology and Regenerative Medicine, Faculty of Biology, Medicine and Health, The University of Manchester, Manchester, Manchester, United Kingdom.
Department of Infectious Diseases, School of Immunology and Microbial Sciences, King's College London, London, United Kingdom.
Hum Gene Ther. 2019 Sep;30(9):1052-1066. doi: 10.1089/hum.2018.189. Epub 2019 Jun 4.
Patients with the lysosomal storage disease mucopolysaccharidosis IIIA (MPSIIIA) lack the lysosomal enzyme N-sulfoglucosamine sulfohydrolase (SGSH), one of the many enzymes involved in degradation of heparan sulfate. Build-up of un-degraded heparan sulfate results in severe progressive neurodegeneration for which there is currently no treatment. Experimental gene therapies based on gene addition are currently being explored. Following preclinical evaluation in MPSIIIA mice, an adeno-associated virus vector of serotype rh10 designed to deliver SGSH and sulfatase modifying factor 1 (SAF301) was trialed in four MPSIIIA patients, showing good tolerance and absence of adverse events with some improvements in neurocognitive measures. This study aimed to improve SAF301 further by removing sulfatase modifying factor 1 (SUMF1) and assessing if expression of this gene is needed to increase the SGSH enzyme activity (SAF301b). Second, the murine phosphoglycerate kinase (PGK) promotor was exchanged with a chicken beta actin/CMV composite (CAG) promotor (SAF302) to see if SGSH expression levels could be boosted further. The three different vectors were administered to MPSIIIA mice via intracranial injection, and SGSH expression levels were compared 4 weeks post treatment. Removal of SUMF1 resulted in marginal reductions in enzyme activity. However, promotor exchange significantly increased the amount of SGSH expressed in the brain, leading to superior therapeutic correction with SAF302. Biodistribution of SAF302 was further assessed using green fluorescent protein (GFP), indicating that vector spread was limited to the area around the injection tract. Further modification of the injection strategy to a single depth with higher injection volume increased vector distribution, leading to more widespread GFP distribution and sustained expression, suggesting this approach should be adopted in future trials.
患有黏多糖贮积症 IIIA 型(MPSIIIA)的患者缺乏溶酶体酶 N-磺基葡萄糖胺硫酸酯酶(SGSH),这是参与硫酸乙酰肝素降解的许多酶之一。未降解的硫酸乙酰肝素的积累导致严重的进行性神经退行性变,目前尚无治疗方法。目前正在探索基于基因添加的实验性基因治疗。在 MPSIIIA 小鼠的临床前评估之后,设计用于递送 SGSH 和硫酸酯酶修饰因子 1(SAF301)的血清型 rh10 腺相关病毒载体在四名 MPSIIIA 患者中进行了试验,结果显示良好的耐受性和无不良反应,一些神经认知测量指标有所改善。本研究旨在通过去除硫酸酯酶修饰因子 1(SUMF1)并评估该基因的表达是否需要增加 SGSH 酶活性(SAF301b)来进一步改进 SAF301。其次,用鸡β肌动蛋白/CMV 复合物(CAG)启动子(SAF302)替换小鼠磷酸甘油酸激酶(PGK)启动子,以观察 SGSH 表达水平是否可以进一步提高。通过颅内注射将三种不同的载体递送至 MPSIIIA 小鼠,在治疗后 4 周比较 SGSH 表达水平。去除 SUMF1 导致酶活性略有降低。然而,启动子交换显著增加了大脑中表达的 SGSH 量,导致 SAF302 的治疗校正效果更好。使用绿色荧光蛋白(GFP)进一步评估了 SAF302 的生物分布,表明载体传播仅限于注射部位周围区域。通过增加注射体积将注射策略修改为单个深度,可以增加载体分布,从而导致更广泛的 GFP 分布和持续表达,表明在未来的试验中应采用这种方法。
