间日疟原虫微卫星基因分型自动化毛细管系统的评估

Assessment of an automated capillary system for Plasmodium vivax microsatellite genotyping.

作者信息

Manrique Paulo, Hoshi Mari, Fasabi Manuel, Nolasco Oscar, Yori Pablo, Calderón Martiza, Gilman Robert H, Kosek Margaret N, Vinetz Joseph M, Gamboa Dionicia

机构信息

Malaria Laboratory, Institute of Tropical Medicine Alexander von Humboldt, Universidad Peruana Cayetano Heredia, Lima, Peru.

Instituto Nacional de Salud, Lima, Peru.

出版信息

Malar J. 2015 Aug 21;14:326. doi: 10.1186/s12936-015-0842-9.

DOI:10.1186/s12936-015-0842-9

PMID:26293655

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4546211/

Abstract

BACKGROUND

Several platforms have been used to generate the primary data for microsatellite analysis of malaria parasite genotypes. Each has relative advantages but share a limitation of being time- and cost-intensive. A commercially available automated capillary gel cartridge system was assessed in the microsatellite analysis of Plasmodium vivax diversity in the Peruvian Amazon.

METHODS

The reproducibility and accuracy of a commercially-available automated capillary system, QIAxcel, was assessed using a sequenced PCR product of 227 base pairs. This product was measured 42 times, then 27 P. vivax samples from Peruvian Amazon subjects were analyzed with this instrument using five informative microsatellites. Results from the QIAxcel system were compared with a Sanger-type sequencing machine, the ABI PRISM(®) 3100 Genetic Analyzer.

RESULTS

Significant differences were seen between the sequenced amplicons and the results from the QIAxcel instrument. Different runs, plates and cartridges yielded significantly different results. Additionally, allele size decreased with each run by 0.045, or 1 bp, every three plates. QIAxcel and ABI PRISM systems differed in giving different values than those obtained by ABI PRISM, and too many (i.e. inaccurate) alleles per locus were also seen with the automated instrument.

CONCLUSIONS

While P. vivax diversity could generally be estimated using an automated capillary gel cartridge system, the data demonstrate that this system is not sufficiently precise for reliably identifying parasite strains via microsatellite analysis. This conclusion reached after systematic analysis was due both to inadequate precision and poor reproducibility in measuring PCR product size.

摘要

背景

已有多种平台用于生成疟原虫基因型微卫星分析的原始数据。每种平台都有其相对优势，但都存在时间和成本密集的局限性。在秘鲁亚马逊地区间日疟原虫多样性的微卫星分析中，对一种商用自动化毛细管凝胶盒系统进行了评估。

方法

使用227个碱基对的测序PCR产物评估商用自动化毛细管系统QIAxcel的重现性和准确性。该产物测量了42次，然后使用五个信息性微卫星，用该仪器分析了来自秘鲁亚马逊地区受试者的27份间日疟原虫样本。将QIAxcel系统的结果与桑格型测序仪ABI PRISM(®) 3100遗传分析仪的结果进行比较。

结果

测序扩增子与QIAxcel仪器的结果之间存在显著差异。不同的运行、板和盒产生了显著不同的结果。此外，每次运行时等位基因大小每三个板下降0.045，即1个碱基对。QIAxcel和ABI PRISM系统给出的值与ABI PRISM获得的值不同，并且在自动化仪器中每个位点也观察到过多（即不准确）的等位基因。

结论

虽然通常可以使用自动化毛细管凝胶盒系统估计间日疟原虫的多样性，但数据表明该系统在通过微卫星分析可靠鉴定寄生虫菌株方面不够精确。经过系统分析得出这一结论，这既是由于测量PCR产物大小的精度不足，也是由于重现性差。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1f28/4546211/7511db63239d/12936_2015_842_Fig1_HTML.jpg

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间日疟原虫微卫星基因分型自动化毛细管系统的评估

Assessment of an automated capillary system for Plasmodium vivax microsatellite genotyping.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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