{"title":"Amplification and Identification of Vertebrate Host Cytochrome <i>c</i> Oxidase Subunit I (<i>COI</i>) DNA Barcoding Templates from Mosquito Blood Meals.","authors":"Lawrence E Reeves, Nathan D Burkett-Cadena","doi":"10.1101/pdb.prot108292","DOIUrl":null,"url":null,"abstract":"<p><p>Mosquitoes take blood meals from a diverse range of host animals and their host associations vary by species. Characterizing these associations is an important element of the transmission dynamics of mosquito-vectored pathogens. To characterize mosquito host associations, various molecular techniques have been developed, which are collectively referred to as blood meal analysis. DNA barcoding has diverse biological applications and is well-suited to mosquito blood meal analysis. The standard DNA barcoding marker for animals is a 5' fragment of the cytochrome <i>c</i> oxidase I (<i>COI</i>) gene. A major advantage of this marker is its taxonomic coverage in DNA sequence reference databases, making it feasible to identify a wider range of mosquito host species than with any other gene. However, the <i>COI</i> gene contains high sequence variation at potential priming sites between vertebrate orders. Coupled with the need for primer sequences to be mismatched with mosquito priming sites so that annealing to mosquito DNA is inhibited, it can be difficult to design primers suitable for blood meal analysis applications. Several primers are available that perform well in mosquito blood meal analysis, annealing to priming sites for most vertebrate host taxa, but not to those of mosquitoes. Because priming site sequence variation among vertebrate taxa can cause amplification to fail, a hierarchical approach to DNA barcoding-based blood meal analysis can be applied. In such an approach, no single primer set is expected to be effective for 100% of potential host species. If amplification fails in the initial reaction, a subsequent reaction is attempted with primers that anneal to different priming sites, and so on, until amplification is successful.</p>","PeriodicalId":10496,"journal":{"name":"Cold Spring Harbor protocols","volume":" ","pages":"pdb.prot108292"},"PeriodicalIF":0.0000,"publicationDate":"2024-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Cold Spring Harbor protocols","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1101/pdb.prot108292","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Mosquitoes take blood meals from a diverse range of host animals and their host associations vary by species. Characterizing these associations is an important element of the transmission dynamics of mosquito-vectored pathogens. To characterize mosquito host associations, various molecular techniques have been developed, which are collectively referred to as blood meal analysis. DNA barcoding has diverse biological applications and is well-suited to mosquito blood meal analysis. The standard DNA barcoding marker for animals is a 5' fragment of the cytochrome c oxidase I (COI) gene. A major advantage of this marker is its taxonomic coverage in DNA sequence reference databases, making it feasible to identify a wider range of mosquito host species than with any other gene. However, the COI gene contains high sequence variation at potential priming sites between vertebrate orders. Coupled with the need for primer sequences to be mismatched with mosquito priming sites so that annealing to mosquito DNA is inhibited, it can be difficult to design primers suitable for blood meal analysis applications. Several primers are available that perform well in mosquito blood meal analysis, annealing to priming sites for most vertebrate host taxa, but not to those of mosquitoes. Because priming site sequence variation among vertebrate taxa can cause amplification to fail, a hierarchical approach to DNA barcoding-based blood meal analysis can be applied. In such an approach, no single primer set is expected to be effective for 100% of potential host species. If amplification fails in the initial reaction, a subsequent reaction is attempted with primers that anneal to different priming sites, and so on, until amplification is successful.
蚊子从各种宿主动物身上吸血,它们与宿主的关系因物种而异。描述这些关系是研究蚊子传播病原体的传播动态的一个重要因素。为了描述蚊子与宿主的关系,人们开发了各种分子技术,统称为血餐分析。DNA 条形码具有多种生物学应用,非常适合蚊子血粉分析。动物的标准 DNA 条形码标记是细胞色素 c 氧化酶 I(COI)基因的 5' 片段。该标记的一大优势是其在 DNA 序列参考数据库中的分类覆盖范围,因此与其他基因相比,可以识别更广泛的蚊子宿主物种。然而,COI 基因在不同脊椎动物目之间的潜在引物位点上存在较高的序列变异。再加上引物序列需要与蚊子的引物位点不匹配,从而抑制与蚊子 DNA 的退火,因此很难设计出适合血粉分析应用的引物。有几种引物在蚊子血粉分析中表现良好,能退火到大多数脊椎动物宿主类群的引物位点,但不能退火到蚊子的引物位点。由于脊椎动物类群间引物位点序列的差异会导致扩增失败,因此可采用分层方法进行基于 DNA 条形码的血粉分析。在这种方法中,没有一组引物能对 100% 的潜在宿主物种有效。如果初始反应扩增失败,则可尝试使用退火至不同引物位点的引物进行后续反应,依此类推,直至扩增成功。
Cold Spring Harbor protocolsBiochemistry, Genetics and Molecular Biology-Biochemistry, Genetics and Molecular Biology (all)
CiteScore
3.00
自引率
0.00%
发文量
163
期刊介绍:
Cold Spring Harbor Laboratory is renowned for its teaching of biomedical research techniques. For decades, participants in its celebrated, hands-on courses and users of its laboratory manuals have gained access to the most authoritative and reliable methods in molecular and cellular biology. Now that access has moved online. Cold Spring Harbor Protocols is an interdisciplinary journal providing a definitive source of research methods in cell, developmental and molecular biology, genetics, bioinformatics, protein science, computational biology, immunology, neuroscience and imaging. Each monthly issue details multiple essential methods—a mix of cutting-edge and well-established techniques.