Shuai Li, Xiaoyan Wang, Kuan-Yu Nick Lai, Jonathan Wert, Li Zhi, Mohammed Shameem, Dingjiang Liu
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Thus, further characterization to improve the understanding of genome DNA leakage is necessary for mitigating the risks associated with genome DNA leakage during AAV product development. In this work, we developed an optimized size-exclusion chromatography (SEC) method for quantifying the leakage of genome DNA across multiple different AAV serotypes and demonstrated satisfactory assay performance in sensitivity, precision, and linearity. Furthermore, we showed that this method could also be applied to quantifying additional quality attributes of AAV, including the percentage of full capsids and quantification of AAV dimers. By using this optimized SEC method, we demonstrated that significantly increased free DNA was observed with increasing freeze/thaw cycles or at a temperature approaching the onset temperature for genome DNA ejection, which was effectively mitigated by the addition of 1.5% w/v sucrose in the AAV formulation. 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引用次数: 0
摘要
腺相关病毒(AAV)载体因其优越的安全性、相对较低的免疫原性和针对不同组织的能力,被广泛用于传递治疗性转基因。AAV 基因治疗产品通常配制成冷冻液体,储存温度低于零下 60 摄氏度,因此在生产和使用过程中会经历多次冷冻/解冻循环。最近的研究表明,冻融应激可诱发基因组 DNA 泄漏。据报道,AAV 病毒外壳的 DNA 泄漏可能会影响产品的稳定性、诱发免疫反应并损害产品功效。因此,为了降低 AAV 产品开发过程中与基因组 DNA 泄漏相关的风险,有必要进一步描述基因组 DNA 的特性,以加深对基因组 DNA 泄漏的了解。在这项工作中,我们开发了一种优化的尺寸排阻色谱(SEC)方法,用于量化多种不同 AAV 血清型的基因组 DNA 泄漏,并证明该方法在灵敏度、精确度和线性度方面都具有令人满意的检测性能。此外,我们还发现这种方法还可用于量化 AAV 的其他质量属性,包括完整包囊的百分比和 AAV 二聚体的量化。通过使用这种优化的 SEC 方法,我们发现随着冻/融周期的增加或在接近基因组 DNA 排出起始温度时,游离 DNA 会显著增加,而在 AAV 配方中添加 1.5% w/v 的蔗糖可有效缓解这种情况。因此,这种优化的 SEC 方法可以作为 AAV 配方、产品和工艺开发的宝贵工具,确保 AAV 基因治疗产品的质量和稳定性。
Development of an optimized SEC method for characterization of genome DNA leakage from adeno-associated virus products.
Adeno-associated virus (AAV) vectors are widely used to deliver therapeutic transgenes due to their superior safety, relatively low immunogenicity, and ability to target diverse tissues. AAV gene therapy products are typically formulated as frozen liquid and stored below - 60 °C, and therefore are subjected to multiple freeze/thaw cycles during manufacturing and administration. Recent studies have shown that genome DNA leakage could be induced by freeze/thaw stress. DNA leakage from AAV capsids has been reported to potentially impact product stability, induce immune responses, and compromise product efficacy. Thus, further characterization to improve the understanding of genome DNA leakage is necessary for mitigating the risks associated with genome DNA leakage during AAV product development. In this work, we developed an optimized size-exclusion chromatography (SEC) method for quantifying the leakage of genome DNA across multiple different AAV serotypes and demonstrated satisfactory assay performance in sensitivity, precision, and linearity. Furthermore, we showed that this method could also be applied to quantifying additional quality attributes of AAV, including the percentage of full capsids and quantification of AAV dimers. By using this optimized SEC method, we demonstrated that significantly increased free DNA was observed with increasing freeze/thaw cycles or at a temperature approaching the onset temperature for genome DNA ejection, which was effectively mitigated by the addition of 1.5% w/v sucrose in the AAV formulation. Thus, this optimized SEC method can serve as an invaluable tool for AAV formulation, product, and process development in ensuring the quality and stability of AAV gene therapy products.
期刊介绍:
Analytical and Bioanalytical Chemistry’s mission is the rapid publication of excellent and high-impact research articles on fundamental and applied topics of analytical and bioanalytical measurement science. Its scope is broad, and ranges from novel measurement platforms and their characterization to multidisciplinary approaches that effectively address important scientific problems. The Editors encourage submissions presenting innovative analytical research in concept, instrumentation, methods, and/or applications, including: mass spectrometry, spectroscopy, and electroanalysis; advanced separations; analytical strategies in “-omics” and imaging, bioanalysis, and sampling; miniaturized devices, medical diagnostics, sensors; analytical characterization of nano- and biomaterials; chemometrics and advanced data analysis.