Khavrutskii Ilja V, Chaudhury Sidhartha, Stronsky Sabrina M, Lee Donald W, Benko Jacqueline G, Wallqvist Anders, Bavari Sina, Cooper Christopher L
Department of Defense Biotechnology High Performance Computing Software Applications Institute (BHSAI), Telemedicine and Advanced Technology Research Center, United States Army Medical Research and Materiel Command, Fort Detrick, MD, United States.
Molecular and Translational Sciences, United States Army Medical Research Institute of Infectious Diseases (USAMRIID), Fort Detrick, MD, United States.
Front Immunol. 2017 Aug 14;8:910. doi: 10.3389/fimmu.2017.00910. eCollection 2017.
Recent advances in the next-generation sequencing of B-cell receptors (BCRs) enable the characterization of humoral responses at a repertoire-wide scale and provide the capability for identifying unique features of immune repertoires in response to disease, vaccination, or infection. Immunosequencing now readily generates 10-10 sequences per sample; however, statistical analysis of these repertoires is challenging because of the high genetic diversity of BCRs and the elaborate clonal relationships among them. To date, most immunosequencing analyses have focused on reporting qualitative trends in immunoglobulin (Ig) properties, such as usage or somatic hypermutation (SHM) percentage of the Ig heavy chain variable (IGHV) gene segment family, and on reducing complex Ig property distributions to simple summary statistics. However, because Ig properties are typically not normally distributed, any approach that fails to assess the distribution as a whole may be inadequate in (1) properly assessing the statistical significance of repertoire differences, (2) identifying two repertoires differ, and (3) determining appropriate confidence intervals for assessing the size of the differences and their potential biological relevance. To address these issues, we have developed a technique that uses Wilcox' robust statistics toolbox to identify statistically significant vaccine-specific differences between Ig repertoire properties. The advantage of this technique is that it can determine not only but also the distributions differ, even when the Ig repertoire properties are non-normally distributed. We used this technique to characterize murine germinal center (GC) B-cell repertoires in response to a complex Ebola virus-like particle (eVLP) vaccine candidate with known protective efficacy. The eVLP-mediated GC B-cell responses were highly diverse, consisting of thousands of clonotypes. Despite this staggering diversity, we identified statistically significant differences between non-immunized, vaccine only, and vaccine-plus-adjuvant groups in terms of Ig properties, including IGHV-family usage, SHM percentage, and characteristics of the BCR complementarity-determining region. Most notably, our analyses identified a robust eVLP-specific feature-enhanced IGHV8-family usage in B-cell repertoires. These findings demonstrate the utility of our technique in identifying statistically significant BCR repertoire differences following vaccination. More generally, our approach is potentially applicable to a wide range of studies in infection, vaccination, auto-immunity, and cancer.
B细胞受体(BCR)的新一代测序技术的最新进展,使得在全库范围内对体液免疫反应进行表征成为可能,并为识别免疫库在应对疾病、疫苗接种或感染时的独特特征提供了能力。免疫测序现在每个样本很容易产生10-10个序列;然而,由于BCR的高遗传多样性及其之间复杂的克隆关系,对这些免疫库进行统计分析具有挑战性。迄今为止,大多数免疫测序分析都集中在报告免疫球蛋白(Ig)特性的定性趋势上,例如Ig重链可变区(IGHV)基因片段家族的使用情况或体细胞超突变(SHM)百分比,并将复杂的Ig特性分布简化为简单的汇总统计数据。然而,由于Ig特性通常不是正态分布的,任何未能整体评估分布的方法在(1)正确评估免疫库差异的统计显著性、(2)识别两个免疫库的差异以及(3)确定用于评估差异大小及其潜在生物学相关性的合适置信区间方面可能都不足够。为了解决这些问题,我们开发了一种技术,该技术使用威尔科克斯稳健统计工具箱来识别Ig库特性之间具有统计学显著性的疫苗特异性差异。该技术的优点是,即使Ig库特性是非正态分布的,它不仅可以确定差异的存在,还可以确定分布是否不同。我们使用这项技术来表征小鼠生发中心(GC)B细胞库对一种具有已知保护效力的复杂埃博拉病毒样颗粒(eVLP)候选疫苗的反应。eVLP介导的GC B细胞反应高度多样,由数千种克隆型组成。尽管存在这种惊人的多样性,但我们在Ig特性方面,包括IGHV家族使用情况、SHM百分比和BCR互补决定区的特征,在未免疫、仅接种疫苗和疫苗加佐剂组之间发现了具有统计学显著性的差异。最值得注意的是,我们的分析在B细胞库中发现了一个强大的eVLP特异性特征——增强的IGHV8家族使用情况。这些发现证明了我们的技术在识别疫苗接种后具有统计学显著性的BCR库差异方面的实用性。更普遍地说,我们的方法可能适用于感染、疫苗接种、自身免疫和癌症等广泛的研究。
