基于纳米孔测序的十种猪病原检测方法的建立

doi:10.11843/j.issn.0366-6964.2025.09.033

摘要/Abstract

摘要： 旨在研究一套用于纳米孔靶向测序(nanopore targeting sequencing, NTS)的同时检测10种猪病原的引物组，并以此探索后续在此平台上检测全部猪病原的可能性。用Primer Premier 6软件设计10种病原的引物；用PCR及琼脂糖凝胶电泳方法验证10种引物的特异性；用纳米孔测序技术探索多重PCR体系中的最优引物浓度，通过比对各浓度梯度下的病原检出数量确定最优引物浓度；用纳米孔测序技术验证多重PCR的敏感性，用最优引物浓度对不同浓度梯度的病原模板进行扩增，确定检测敏感性；最后用临床样本(n=201)用荧光定量PCR对NTS进行符合性测试。结果显示：10种猪病病原引物特异，对其他10种猪病原均未扩出条带；反应体系中的引物终浓度在3和5 μmol·L^-1时，能检测到模板中的10种病原；在加入5 μL浓度为9×10² copies·mL^-1的核酸模板时，可检出4组重复中的所有阳性样本；在临床样本的检测上，NTS检测出的病原阳性数量更多。经卡方检验，两者对5种病原的检测结果存在统计学差异(P<0.05)，另5种不存在统计学差异(P>0.05)；经卡帕值分析，6种病原检测的一致性极好，4种较好。结果显示，NTS检测方法可以同时检测出10种不同的猪病原，对于两种检测方法结果不符合样本需经第三方检测方法进一步验证。

关键词: 纳米孔靶向测序, PCR, 一致性, 猪病原

Abstract: This study was conducted to develop a primer set for Nanopore targeting sequencing (NTS) to simultaneously detect ten porcine pathogens and explore the potential for detecting all porcine pathogens on this platform. Primers for ten pathogens were designed using Primer Premier 6 software. The specificity of the ten primers was verified by PCR and agarose gel electrophoresis. The optimal primer concentration in the multiplex PCR system was explored using nanopore sequencing technology by comparing the detection numbers of pathogens at different concentration gradients. The sensitivity of multiplex PCR was verified using the optimal primer concentration obtained in the previous step. The detection sensitivity was determined by amplifying pathogen templates at different concentration gradients and analyzing the corresponding results. Finally, a conformity test between fluorescence quantitative PCR and NTS was performed using clinical samples (n=201). The agarose gel electrophoresis images for verifying primer specificity all showed a single, bright, and clear band, and no bands were amplified for the other ten porcine pathogens not selected in this study. All ten pathogens could be detected in the reaction system when the final concentration of primers was 3 and 5 μmol·L^-1, while all other tested concentrations failed to detect all ten pathogens. All positive samples in the four replicates could be detected when 5 μL of the nucleic acid template with a concentration of 9×10² copies·mL^-1 was added. In the detection of clinical samples, more pathogen-positive samples were detected by NTS. After the chi-square test, there were statistically significant differences in the detection results of five pathogens (P<0.05), while no statistically significant differences were found in the detection results of the other five pathogens (P>0.05). After kappa value analysis, excellent consistency was observed in the detection of six pathogens, and good consistency was observed in the detection of four pathogens. The results indicate that the NTS detection method can simultaneously detect ten different porcine pathogens. For samples with inconsistent detection results compared to the control method, further verification by a third-party detection method is required.

Key words: nanopore targeted sequencing, PCR, consistency, porcine pathogens

中图分类号:

S854.4

邱话龙传, 金芊芊, 许潇涵, 周静, 蔡承志, 李龙. 基于纳米孔测序的十种猪病原检测方法的建立[J]. 畜牧兽医学报, 2025, 56(9): 4546-4558.

QIU Hualongchuan, JIN Qianqian, XU Xiaohan, ZHOU Jing, CAI Chengzhi, LI Long. Establishment of Ten Swine Pathogens Detection Method based on Nanopore Sequencing[J]. Acta Veterinaria et Zootechnica Sinica, 2025, 56(9): 4546-4558.

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