Darin Abbadessa, Cameron A. Smurthwaite, Connor Reed, R. Wolkowicz
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引用次数: 1
摘要
尽管生物医学研究和药物发现取得了进步,但传染病仍影响着人类健康。其中,由于从动物到人类的突然转移、高突变率、对当前治疗的耐药性以及它们与宿主分子相互作用的复杂性,病毒尤其难以解决。作为这些相互作用的一个例子,我们描述了一种基于细胞的方法来监测由病毒编码的蛋白酶或病毒上的宿主蛋白执行的特定蛋白水解事件。然后,我们强调在自然发生裂解的亚细胞区室内检查蛋白质水解的重要性。我们展示了稳定表达的力量,强调了基于细胞的多路复用方法的有用性,我们已经适应了之前开发的两种独立检测,用于监测(a) hiv -1编码蛋白酶的活性或(b)宿主对hiv -1编码包膜蛋白的切割。通过混合每个携带不同检测的细胞或通过表达两种检测的工程细胞来实现多路复用。多路复用依赖于单个检测的稳健性和它们的明确区分,进一步增强了筛选能力,试图阻断病毒感染和传播所需的蛋白水解事件。
A Single-Cell Platform for Monitoring Viral Proteolytic Cleavage in Different Cellular Compartments
Infectious diseases affect human health despite advances in biomedical research and drug discovery. Among these, viruses are especially difficult to tackle due to the sudden transfer from animals to humans, high mutational rates, resistance to current treatments, and the intricacies of their molecular interactions with the host. As an example of these interactions, we describe a cell-based approach to monitor specific proteolytic events executed by either the viral-encoded protease or by host proteins on the virus. We then emphasize the significance of examining proteolysis within the subcellular compartment where cleavage occurs naturally. We show the power of stable expression, highlighting the usefulness of the cell-based multiplexed approach, which we have adapted to two independent assays previously developed to monitor (a) the activity of the HIV-1-encoded protease or (b) the cleavage of the HIV-1-encoded envelope protein by the host. Multiplexing was achieved by mixing cells each carrying a different assay or, alternatively, by engineering cells expressing two assays. Multiplexing relies on the robustness of the individual assays and their clear discrimination, further enhancing screening capabilities in an attempt to block proteolytic events required for viral infectivity and spread.