Adaptation of the intact proviral DNA assay to a nanowell-based digital PCR platform

IF 3.5 4区 医学 Q2 IMMUNOLOGY Journal of Virus Eradication Pub Date : 2023-06-01 DOI:10.1016/j.jve.2023.100335
Carolin Tumpach , Catherine R. Cochrane , Youry Kim , Jesslyn Ong , Ajantha Rhodes , Thomas A. Angelovich , Melissa J. Churchill , Sharon R. Lewin , Sushama Telwatte , Michael Roche
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引用次数: 2

Abstract

Quantification of intact proviruses is a critical measurement in HIV cure studies both in vitro and in vivo. The widely adopted ‘intact proviral DNA assay’ (IPDA), designed to discriminate and quantify genetically intact HIV proviruses based on detection of two HIV sequence-specific targets, was originally validated using Bio-Rad's droplet digital PCR technology (ddPCR). Despite its advantages, ddPCR is limited in multiplexing capability (two-channel) and is both labor- and time intensive. To overcome some of these limitations, we utilized a nanowell-based digital PCR platform (dPCR, QIAcuity from Qiagen) which is a fully automated system that partitions samples into nanowells rather than droplets. In this study we adapted the IPDA assay to the QIAcuity platform and assessed its performance relative to ddPCR. The dPCR could differentiate between intact, 5’ defective and 3’ defective proviruses and was sensitive to single HIV copy input. We found the intra-assay and inter-assay variability was within acceptable ranges (with coefficient of variation at or below 10%). When comparing the performance of the IPDA in ex vivo CD4+ T cells from people with HIV on antiretroviral therapy, there was a strong correlation in the quantification of intact (rs = 0.93; p < 0.001) and 3’ defective proviruses (rs = 0.96; p < 0.001) with a significant but less strong correlation for 5’ defective proviruses (rs = 0.7; p = 0.04). We demonstrate that the dPCR platform enables sensitive and accurate quantification of genetically intact and defective proviruses similar to the ddPCR system but with greater speed and efficiency. This flexible system can be further optimized in the future, to detect up to 5 targets, enabling a more precise detection of intact and potentially replication-competent proviruses.

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完整的原病毒DNA检测适应于基于纳米孔的数字PCR平台
在体外和体内HIV治疗研究中,对完整的前病毒进行定量是一项关键的测量。广泛采用的“完整前病毒DNA分析”(IPDA)旨在根据两个HIV序列特异性靶标的检测来区分和量化基因完整的HIV前病毒,最初是使用Bio-Rad的液滴数字PCR技术(ddPCR)进行验证的。尽管ddPCR具有优势,但其多路复用能力(双通道)有限,而且劳动和时间密集。为了克服其中的一些限制,我们使用了一个基于纳米阱的数字PCR平台(dPCR,Qiagen的QIAcity),这是一个完全自动化的系统,将样本划分为纳米阱而不是液滴。在这项研究中,我们将IPDA测定法应用于QIAcity平台,并评估了其相对于ddPCR的性能。dPCR可以区分完整的、5'缺陷的和3'缺陷的前病毒,并且对单个HIV拷贝输入敏感。我们发现批内和批间变异性在可接受的范围内(变异系数为或低于10%)。当比较IPDA在来自HIV患者的离体CD4+T细胞中对抗逆转录病毒治疗的性能时,完整的(rs=0.93;p<;0.001)和3'缺陷的前病毒的定量存在很强的相关性(rs=0.96;p&llt;0.001ddPCR系统,但具有更高的速度和效率。这种灵活的系统将来可以进一步优化,最多可以检测5个靶点,从而能够更精确地检测完整的和潜在的具有复制能力的前病毒。
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来源期刊
Journal of Virus Eradication
Journal of Virus Eradication Medicine-Public Health, Environmental and Occupational Health
CiteScore
6.10
自引率
1.80%
发文量
28
审稿时长
39 weeks
期刊介绍: The Journal of Virus Eradication aims to provide a specialist, open-access forum to publish work in the rapidly developing field of virus eradication. The Journal covers all human viruses, in the context of new therapeutic strategies, as well as societal eradication of viral infections with preventive interventions. The Journal is aimed at the international community involved in the prevention and management of viral infections. It provides an academic forum for the publication of original research into viral reservoirs, viral persistence and virus eradication and ultimately development of cures. The Journal not only publishes original research, but provides an opportunity for opinions, reviews, case studies and comments on the published literature. It focusses on evidence-based medicine as the major thrust in the successful management of viral infections.The Journal encompasses virological, immunological, epidemiological, modelling, pharmacological, pre-clinical and in vitro, as well as clinical, data including but not limited to drugs, immunotherapy and gene therapy. It is an important source of information on the development of vaccine programs and preventative measures aimed at virus eradication.
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