基于量子点微球和RPA技术的ASFV抗体-核酸快速现场联检方法的建立

doi:10.3864/j.issn.0578-1752.2024.24.013

中国农业科学 ›› 2024, Vol. 57 ›› Issue (24): 4990-5002.doi: 10.3864/j.issn.0578-1752.2024.24.013

• 畜牧·兽医 • 上一篇

基于量子点微球和RPA技术的ASFV抗体-核酸快速现场联检方法的建立

赵伊然¹(), 单衍可¹, 李嘉豪¹, 何昭群¹, 王欣艺¹, 温墩¹, 王米拉¹, 储蕊¹, 赵东明²(), 刘斐¹()

¹ 南京农业大学动物医学院单分子生物化学与生物医学实验室，南京 210095
² 兽医生物技术国家重点实验室/中国农业科学院哈尔滨兽医研究所，哈尔滨 150009

收稿日期:2024-06-18 接受日期:2024-11-06 出版日期:2024-12-16 发布日期:2024-12-23
通信作者:
刘斐，Tel：025-84395856；E-mail：feiliu24@njau.edu.cn。
赵东明，E-mail：zhaodongming@caas.cn
联系方式: 赵伊然，Tel：18864823232；E-mail：ZhaoYR1998@163.com。
基金资助:
国家重点研发计划(2023YFD1800502); 湖南省重点研发计划(2023NK2017)

Establishment of Rapid Field Co-Detection Method of ASFV Antibody and Nucleic Acid Based on Quantum Dot Microspheres and RPA Technology

ZHAO YiRan¹(), SHAN YanKe¹, LI JiaHao¹, HE ZhaoQun¹, WANG XinYi¹, WEN Dun¹, WANG MiLa¹, CHU Rui¹, ZHAO DongMing²(), LIU Fei¹()

¹ Single Molecule Biochemistry and Biomedical Laboratory, College of Veterinary Medicine, Nanjing Agricultural University, Nanjing 210095
² State Key Laboratory of Veterinary Biotechnology/Harbin Institute of Veterinary Medicine, Chinese Academy of Agricultural Sciences, Harbin 150009

Received:2024-06-18 Accepted:2024-11-06 Published:2024-12-16 Online:2024-12-23

摘要/Abstract

摘要：

【背景】非洲猪瘟（African swine fever，ASF）作为世界动物卫生组织（world organization for animal health，WOAH）规定必须通报的疫病之一，同时也是我国一类动物疫病，因缺乏有效疫苗和治疗方法，早期、有效、快速和敏感的检测对防控ASF至关重要。目前，非洲猪瘟病毒（African swine fever virus，ASFV）常用临床检测方法主要包括荧光定量PCR（quantitative real-time PCR，qPCR）、酶联免疫吸附测定试验（enzyme linked immunosorbent assay，ELISA）等，但这些技术均需要复杂的操作、昂贵的仪器以及较长的检测时间，不适用于现场快速检测。此外，ASFV感染后宿主体内的抗体和核酸含量在不同时间段有明显的差异，因此单独检测ASFV核酸或抗体可能会导致假阴性的存在。【目的】通过研发一种基于量子点微球和重组酶聚合酶扩增技术（recombinase polymerase amplification，RPA）的ASFV抗体-核酸联检试纸条，实现ASFV抗体和核酸的现场同时检测，以提高检测的灵敏度、特异性，降低检测成本，节约检测时间。【方法】通过结合量子点荧光免疫层析技术及RPA技术建立了同时检测ASFV抗体及核酸的侧向流层析试纸条，配套便携式荧光分析仪可实现ASFV抗体-核酸的快速现场联检。本研究优化了量子点偶联蛋白量及检测线包被浓度等条件。在此基础上，确定了该检测方法的cutoff值、敏感性、特异性及重复性，并将所建立的ASFV联检试纸条与市售ELISA试剂盒、qPCR检测试剂盒对临床样品进行检测，比较检测结果，验证该方法的符合率，评价该试纸条的实用性。【结果】联检试纸条使用方便、快速，整个检测过程可在30 min内完成。且与其他6种常见猪传染性病毒之间不存在交叉反应，特异性良好。核酸检测灵敏度可达10 copies/µL，抗体检测灵敏度可达1﹕3 200。抗体和核酸检测批内变异系数均小于10%，批间变异系数均小于15%，重复性良好。经市售ELISA试剂盒、qPCR试剂盒分别验证，符合率均为100%。除此之外，在临床样品检测中发现，有2份抗体检测阳性的样品其对应的猪只核酸检测为阴性，且这2头猪无明显临床症状，该结果进一步证明了通过抗体和核酸联检能够提高检测的准确性，减少假阴性的存在。【结论】核酸-抗体联检单次试验成本与病原核酸抗体分别检测总成本相比有所降低，节约了检测成本和时间，对于ASF急性发作、慢性感染检测均敏感，避免了仅检测单个核酸或单个抗体的局限性。此方法对操作环境要求低，使用的荧光分析仪便于携带，易于操作，整个操作过程无需过多昂贵的实验仪器和专业技术人员，降低了对检测设备的精密要求，适用在偏远地区以及基层中开展ASFV检测工作。因此，该方法有望成为未来猪场ASFV即时检测的可靠方法。

关键词: 非洲猪瘟, 核酸检测, 抗体检测, 侧向流免疫试纸条

Abstract:

【Background】African swine fever (ASF), recognized as a notifiable disease by the World Organization for Animal Health (WOAH) and categorized as a Class I animal disease in China, presents significant challenges due to the absence of effective vaccines and treatment options. Therefore, early, effective, rapid, and sensitive detection on ASF is crucial for controlling ASF. Current clinical diagnostic methods for African swine fever virus (ASFV) primarily include quantitative real-time PCR (qPCR) and enzyme-linked immunosorbent assay (ELISA). However, these techniques require complex procedures, expensive equipment, and extended detection times, rendering them unsuitable for rapid field testing. Moreover, the levels of antibodies and nucleic acids in the host exhibit significant variations over time following ASFV infection, which can result in false negatives if only ASFV nucleic acids or antibodies are tested in isolation. 【Objective】This study aimed to develop a test strip that allowed for the simultaneous detection of ASFV antibodies and nucleic acids based on quantum dot microspheres and recombinase polymerase amplification (RPA) technology. The objective was to enable on-site detection of both ASFV antibodies and nucleic acids, thereby enhancing the sensitivity and specificity of the tests, reducing detection costs, and saving time. 【Method】In this study, a lateral flow immunoassay strip for the simultaneous detection of ASFV antibodies and nucleic acids was developed by combining quantum dot fluorescence immunochromatography technology with recombinase polymerase amplification (RPA). The corresponding portable fluorescence analyzer enables rapid on-site dual detection of ASFV antibodies and nucleic acids. The study optimized key parameters, such as the quantum dot-protein conjugation amount and the coating concentration of the test line. Based on these optimizations, the cutoff value, sensitivity, specificity, and reproducibility of the detection method were determined. Furthermore, the developed ASFV dual detection strip was compared with commercially available ELISA and qPCR kits by testing clinical samples to assess detection consistency, validating the method's concordance, and evaluating the practical applicability of the test strip. 【Result】The dual detection strip was user-friendly and rapid, with the entire testing process completed within 30 minutes. It demonstrated no cross-reactivity with six other common porcine infectious viruses, confirming excellent specificity. The sensitivity for nucleic acid detection reached 10 copies/µL, while the sensitivity for antibody detection was up to 1﹕3 200. The intra-assay variability coefficients for both antibody and nucleic acid tests were less than 10%, and the inter-assay variability coefficients were less than 15%, indicating excellent reproducibility. Validation against commercial ELISA and qPCR kits yielded a conformity rate of 100%. Furthermore, in clinical sample testing, two samples tested positive for antibodies but negative for nucleic acids in the corresponding pigs, which exhibited no significant clinical symptoms. These findings further confirmed that the combined detection of antibodies and nucleic acids could enhance the accuracy of testing and reduce the incidence of false negatives. 【Conclusion】The cost per experiment for this nucleic acid-antibody dual detection method was lower compared with the total cost of separate nucleic acid and antibody testing, thus reducing both detection costs and time. It was sensitive to both acute outbreaks and chronic infections of ASF, addressing the limitations of detecting only nucleic acids or antibodies individually. The method had minimal requirements for operating conditions, and the portable fluorescence analyzer was easy to use, requiring neither expensive laboratory equipment nor highly specialized personnel. This reduced the precision demands on detection devices, making it suitable for ASFV testing in remote areas and at the grassroots level. Therefore, this method held great potential as a reliable tool for point-of-care ASFV detection in pig farms in the future.

Key words: African swine fever, nucleic acid detection, antibody detection, lateral flow immunochromatography test strip

赵伊然, 单衍可, 李嘉豪, 何昭群, 王欣艺, 温墩, 王米拉, 储蕊, 赵东明, 刘斐. 基于量子点微球和RPA技术的ASFV抗体-核酸快速现场联检方法的建立[J]. 中国农业科学, 2024, 57(24): 4990-5002.

ZHAO YiRan, SHAN YanKe, LI JiaHao, HE ZhaoQun, WANG XinYi, WEN Dun, WANG MiLa, CHU Rui, ZHAO DongMing, LIU Fei. Establishment of Rapid Field Co-Detection Method of ASFV Antibody and Nucleic Acid Based on Quantum Dot Microspheres and RPA Technology[J]. Scientia Agricultura Sinica, 2024, 57(24): 4990-5002.

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[34]	张冯禧, 肖琦, 朱家平, 尹力鸿, 赵霞玲, 严明帅, 徐晋花, 温立斌, 牛家强, 何孔旺. 非洲猪瘟病毒P30蛋白单克隆抗体制备、鉴定及阻断ELISA方法的建立. 中国农业科学, 2022, 55(16): 3256-3266. doi: 10.3864/j.issn.0578-1752.2022.16.015
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引物/探针 Primer/Probe	序列Sequence（5′-3′）
引物F Primer F	TGATAGACCCCACGTAATCCGCGTAATCCGTGTCCCAAC
生物素-引物R Biotin-Primer R	biotin-GTTTCCATCAAAGTTCTGCAGCTCTTACATA
FITC-探针 FITC-Probe	FITC-CTCCCGTGGCTTCAAAGCAAAGGTAATCAT-THF-ATCGCACCCGGATCATCG-C3-spacer

样品 Sample	批内 Intra-assay			批间 Inter-assay
样品 Sample	1:200	1:400	1:800	1:200	1:400	1:800
T/T+C	0.44772	0.39053	0.30973	0.396821	0.38822	0.33565
	0.41416	0.37078	0.33944	0.477115	0.32101	0.32191
	0.43146	0.37649	0.32818	0.452673	0.36206	0.31119
变异系数CV	3.89%	2.68%	4.60%	9.31%	9.49%	3.80%

样品 Sample	批内 Intra-assay			批间 Inter-assay
样品 Sample	10⁷	10⁵	10³	10⁷	10⁵	10³
T/T+C	0.96707	0.71001	0.35254	0.94447	0.71428	0.31767
	0.98511	0.69655	0.29571	0.86099	0.64785	0.38631
	0.96146	0.68993	0.35298	0.96672	0.63711	0.29283
变异系数CV	1.27%	1.46%	9.87%	6.03%	6.27%	14.57%

基于量子点微球和RPA技术的ASFV抗体-核酸快速现场联检方法的建立

Establishment of Rapid Field Co-Detection Method of ASFV Antibody and Nucleic Acid Based on Quantum Dot Microspheres and RPA Technology

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检测方法 Detection method	阳性样品数 Number of positive samples	阴性样品数 Number of negative samples	符合率 Concordance rate
试纸条 Test strip	21	52	100%
酶联免疫吸附试验 ELISA	21	52	100%

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