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优化用于鉴定T细胞抗原的肽矩阵。

Optimizing peptide matrices for identifying T-cell antigens.

作者信息

Precopio Melissa L, Butterfield Tiffany R, Casazza Joseph P, Little Susan J, Richman Douglas D, Koup Richard A, Roederer Mario

机构信息

Immunology Laboratory, Vaccine Research Center, NIAID, National Institutes of Health, Bethesda, Maryland 20892, USA.

出版信息

Cytometry A. 2008 Nov;73(11):1071-8. doi: 10.1002/cyto.a.20646.

DOI:10.1002/cyto.a.20646
PMID:18781655
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2586828/
Abstract

Mapping T-cell epitopes for a pathogen or vaccine requires a complex method for screening hundreds to thousands of peptides with a limited amount of donor sample. We describe an optimized deconvolution process by which peptides are pooled in a matrix format to minimize the number of tests required to identify peptide epitopes. Four peptide pool matrices were constructed to deconvolute the HIV-specific T-cell response in three HIV-infected individuals. ELISpot assays were used to map peptide antigens. Many HIV peptides were mapped in all three individuals. However, there were several challenges and limitations associated with the deconvolution process. Peptides that induced low-frequency responses or were masked by peptide competition within a given pool were not identified, because they did not meet the threshold criteria for a positive response. Also, amino acid sequence variation limited the ability of this method to map autologous HIV peptides. Alternative analysis strategies and revisions to the original matrix optimizations are presented that address ways to increase peptide identification. This optimized deconvolution method allows for efficient mapping of T-cell peptide epitopes. It is rapid, powerful, efficient, and unrestricted by HLA type.

摘要

绘制病原体或疫苗的T细胞表位需要一种复杂的方法,以便在供体样本量有限的情况下筛选数百至数千种肽段。我们描述了一种优化的反卷积过程,通过该过程将肽段以矩阵形式汇集,以尽量减少鉴定肽表位所需的测试次数。构建了四种肽池矩阵,以解析三名HIV感染者的HIV特异性T细胞反应。采用ELISpot检测法来绘制肽抗原。在所有三名个体中都绘制了许多HIV肽段。然而,反卷积过程存在一些挑战和局限性。诱导低频反应或在给定肽池中被肽竞争掩盖的肽段未被鉴定出来,因为它们未达到阳性反应的阈值标准。此外,氨基酸序列变异限制了该方法绘制自体HIV肽段的能力。本文提出了替代分析策略和对原始矩阵优化的修订,以解决增加肽段鉴定的方法。这种优化的反卷积方法能够高效地绘制T细胞肽表位。它快速、强大、高效,且不受HLA类型的限制。

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