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从固定复杂度随机序列肽微阵列中鉴定表位

Epitope identification from fixed-complexity random-sequence peptide microarrays.

作者信息

Richer Josh, Johnston Stephen Albert, Stafford Phillip

机构信息

From *Arizona State University, Tempe, Arizona 85287.

From *Arizona State University, Tempe, Arizona 85287

出版信息

Mol Cell Proteomics. 2015 Jan;14(1):136-47. doi: 10.1074/mcp.M114.043513. Epub 2014 Nov 3.

DOI:10.1074/mcp.M114.043513
PMID:25368412
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4288249/
Abstract

Antibodies play an important role in modern science and medicine. They are essential in many biological assays and have emerged as an important class of therapeutics. Unfortunately, current methods for mapping antibody epitopes require costly synthesis or enrichment steps, and no low-cost universal platform exists. In order to address this, we tested a random-sequence peptide microarray consisting of over 330,000 unique peptide sequences sampling 83% of all possible tetramers and 27% of pentamers. It is a single, unbiased platform that can be used in many different types of tests, it does not rely on informatic selection of peptides for a particular proteome, and it does not require iterative rounds of selection. In order to optimize the platform, we developed an algorithm that considers the significance of k-length peptide subsequences (k-mers) within selected peptides that come from the microarray. We tested eight monoclonal antibodies and seven infectious disease cohorts. The method correctly identified five of the eight monoclonal epitopes and identified both reported and unreported epitope candidates in the infectious disease cohorts. This algorithm could greatly enhance the utility of random-sequence peptide microarrays by enabling rapid epitope mapping and antigen identification.

摘要

抗体在现代科学和医学中发挥着重要作用。它们在许多生物学检测中不可或缺,并已成为一类重要的治疗药物。不幸的是,目前绘制抗体表位的方法需要昂贵的合成或富集步骤,而且不存在低成本的通用平台。为了解决这个问题,我们测试了一种随机序列肽微阵列,它由超过330,000个独特的肽序列组成,涵盖了所有可能四聚体的83%和五聚体的27%。这是一个单一的、无偏差的平台,可用于许多不同类型的测试,它不依赖于针对特定蛋白质组的肽的信息学选择,也不需要迭代的选择轮次。为了优化该平台,我们开发了一种算法,该算法考虑了来自微阵列的选定肽段内k长度肽子序列(k聚体)的重要性。我们测试了八种单克隆抗体和七个传染病队列。该方法正确识别了八种单克隆表位中的五种,并在传染病队列中识别出了已报道和未报道的表位候选物。该算法通过实现快速表位绘制和抗原鉴定,可大大提高随机序列肽微阵列的实用性。

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