文章摘要
徐媛媛,于永翔,王印庚,王春元,李永杰,刘定远,秦蕾,张正.5种主要海水养殖病原菌多重微流控荧光定量PCR快速检测技术的建立.渔业科学进展,2023,44(3):222-234
5种主要海水养殖病原菌多重微流控荧光定量PCR快速检测技术的建立
Establishment of multiple microfluidic fluorescence quantitative PCR detection technology for five main mariculture bacterial pathogens
投稿时间:2021-12-24  修订日期:2022-02-14
DOI:10.19663/j.issn2095-9869.20211224001
中文关键词: 哈维氏弧菌  副溶血弧菌  大菱鲆弧菌  鳗弧菌  美人鱼发光杆菌美人鱼亚种  微流控PCR  现场快速检测
英文关键词: Vibrio harveyi  Vibrio parahaemolyticus  Vibrio scophthalmi  Vibrio anguillarum  Photobacterium damselae subsp. damselae  Microfluidic fluorescence quantitative PCR  On-site rapid detection
基金项目:
作者单位
徐媛媛 江苏海洋大学 江苏 连云港 222005农业农村部海水养殖病害防治重点实验室 中国水产科学研究院黄海水产研究所 山东 青岛 266071 
于永翔 农业农村部海水养殖病害防治重点实验室 中国水产科学研究院黄海水产研究所 山东 青岛 266071 
王印庚 农业农村部海水养殖病害防治重点实验室 中国水产科学研究院黄海水产研究所 山东 青岛 266071 青岛海洋科学与技术试点国家实验室海洋渔业科学与食品产出过程功能实验室 山东 青岛 266071 
王春元 农业农村部海水养殖病害防治重点实验室 中国水产科学研究院黄海水产研究所 山东 青岛 266071 
李永杰 农业农村部海水养殖病害防治重点实验室 中国水产科学研究院黄海水产研究所 山东 青岛 266071 
刘定远 江苏海洋大学 江苏 连云港 222005农业农村部海水养殖病害防治重点实验室 中国水产科学研究院黄海水产研究所 山东 青岛 266071 
秦蕾 江苏海洋大学 江苏 连云港 222005 
张正 农业农村部海水养殖病害防治重点实验室 中国水产科学研究院黄海水产研究所 山东 青岛 266071 青岛海洋科学与技术试点国家实验室海洋渔业科学与食品产出过程功能实验室 山东 青岛 266071 
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中文摘要:
      在养殖现场开展多病原的快速检测是水产养殖产业健康发展的重要技术需求之一。本研究选取哈维氏弧菌(Vibrio harveyi)的vhhA基因、副溶血弧菌(Vibrio parahaemolyticus)的toxR基因、大菱鲆弧菌(Vibrio scophthalmi)的luxR基因、鳗弧菌(Vibrio anguillarum)的empA基因和美人鱼发光杆菌美人鱼亚种(Photobacterium damselae subsp. damselae)的Mcp基因作为靶基因,设计特异性引物,通过优化反应体系和条件,并在微流控芯片进行集成,建立了可同步检测这5种病原菌的多重微流控荧光定量PCR检测技术。结果显示,本研究所建立的检测技术最佳反应体系:2×Taq Pro Universal SYBR qPCR Master Mix 5 μL,Primer F/R各1 μL,DNA模板2 μL,ddH2O 1 μL。反应条件为95 ℃ 30 s,95 ℃ 5 s,61 ℃ 30 s,扩增30个循环。通过绘制标准曲线发现,在109~104 copies/μL浓度范围内均有良好的线性相关性。该方法对哈维氏弧菌、副溶血弧菌、大菱鲆弧菌、鳗弧菌和美人鱼发光杆菌美人鱼亚种特异性强,对5种病原菌的最低检测限分别为40、20、200、500和20 CFU/mL,显示出较高的灵敏度,且样品平均检测时间缩短至26 min左右。本研究结果为开发水产养殖多病原快速、精准的现场检测技术奠定了重要基础。
英文摘要:
      Vibrio harveyi, Vibrio parahaemolyticus, Vibrio scophthalmi, Vibrio anguillarum, and Photobacterium damselae subsp. damselae are important pathogenic bacteria frequently reported in mariculture animal diseases in recent years. These pathogens exhibit strong pathogenicity, wide epidemic area, and high mortality rates, which usually cause serious economic losses in aquaculture. Strengthening the research on rapid detection technology of these pathogens can help to effectively prevent and control their transmission and infection, and reduce economic losses of the aquaculture industry. Therefore, rapid detection of multiple pathogens in this field can promote the disease control technology development of the aquaculture industry. In this study, the vhhA gene of V. harveyi, toxR gene of V. parahaemolyticus, luxR gene of V. scophthalmi, empA gene of V. anguillarum, and Mcp gene of P. damselae subsp. damselae were selected as the target genes. Specific primers were designed using Primer Premier 5.0 software. V. harveyi, V. parahaemolyticus, V. scophthalmi, V. anguillarum, and P. damselae subsp. damselae were used as the target bacteria, V. campbelii and 10 other bacterial species were used as the control group, and sterile water was used as the blank control. The specificity of the primers was verified by the laboratorial conventional real-time quantitative PCR. Thereafter, V. harveyi, V. parahaemolyticus, V. scophthalmi, V. anguillarum, and P. damselae subsp. damselae were amplified using the UF-150 microfluidic fluorescence quantitative PCR instrument to verify the feasibility and specificity of the designed primers on microfluidic fluorescence quantitative PCR. The PCR products were digested and recycled, then ligated to PMD-19T vector and transformed into DH-5α competent cells to construct the standard reference material. The extracted plasmid DNA was used as a template for fluorescence quantitative PCR amplification after 10-fold gradient dilution, and a standard curve was drawn. The DNA of V. harveyi, V. parahaemolyticus, V. scophthalmi, V. anguillarum, and P. damselae subsp. damselae were used to optimize the annealing temperatures for single microfluidics quantitative PCR. The annealing temperatures were set at 58 ℃, 59 ℃, 60 ℃, 61 ℃, 62 ℃, and 63 ℃, respectively, and the optimal common annealing temperatures of the five strains were finally screened. Meanwhile, the number of reaction cycles was set at 25, 30, 35 and 40, respectively, to verify the optimal number of reaction cycles. The designed specific primers of V. harveyi, V. parahaemolyticus, V. scophthalmi, V. anguillarum, and P. damselae subsp. damselae were integrated into the microfluidic chip; multiple microfluidic fluorescence quantitative PCR was performed on the integrated chip with the DNA template of the five strains to verify the cross-reaction between the primers. Based on the reaction systems and conditions of single detection methods, the reaction systems and conditions of multiple microfluidic fluorescence quantitative PCR were optimized, and the microfluidic chip was integrated to establish a multiple microfluidic fluorescence quantitative PCR detection technology that could simultaneously detect these five pathogens: V. harveyi, V. parahaemolyticus, V. scophthalmi, V. anguillarum and P. damselae subsp. damselae. Scophthalmus maximus, Litopenaeus vannamei, and Apostichopus japonicus were selected as the experimental orgainsms. The five pathogens were mixed with the tissues of S. maximus (muscle, gill and liver), L. vannamei (muscle and gill), and A. japonicus (respiratory tree and intestine). The established multiple microfluidic fluorescence quantitative PCR method was used to detect these tissues which contained the five pathogens, and the conventional real-time fluorescence quantitative PCR was performed for comparison. The results showed that the optimal reaction system of the established detection method was as follows: 2×Taq Pro Universal SYBR qPCR Master Mix 5 μL, primer F/R 1 μL, DNA template 2 μL, and ddH2O 1 μL. The reaction conditions were as follows: 95 ℃ for 30 s, 95 ℃ for 5 s, 61 ℃ for 30 s, and 30 cycles of amplification. The standard curves of V. harveyi, V. parahaemolyticus, V. scophthalmi, V. anguillarum, and P. damselae subsp. damselae showed good linearity in the range of 104–109 copies/μL. The linear equations were as follows: y= ‒2.972x+6.73, R2= 0.999; y= ‒3.287x+7.48, R2=0.998; y= ‒3.549x+8.14, R2=0.998; y= ‒3.912x+7.83, R2=0.999; y= ‒3.969x+7.07, R2=0.992, respectively. The method showed strong specificity and high sensitivity to V. harveyi, V. parahaemolyticus, V. scophthalmi, V. anguillarum, and P. damselae subsp. damselae, and the minimum detection limits for these bacteria were 40, 200, 200, 500 and 20 CFU/mL, respectively. The established multiplex microfluidic fluorescence quantitative PCR method was used to detect these pathogens in animal samples and compare the results to those of conventional fluorescence quantitative PCR. The results showed that the accuracy of the established multi-microfluidic fluorescence quantitative PCR method was higher than 96.2% of the conventional real-time fluorescence quantitative PCR method. The average detection time of the samples was only 26 min, which was significantly shorter than that of the conventional real-time fluorescence quantitative PCR reaction time of 1 h 40 min. The multiplex microfluidic fluorescence quantitative PCR method established in this study for the detection of five kinds of mariculture pathogens has strong specificity, high sensitivity, low environmental condition requirements, outstanding portability, and detection accuracy (same as that of conventional real-time fluorescence quantitative PCR), which is suitable for the development of rapid detection technology for aquatic pathogens.
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