Computational identification of antibody-binding epitopes from mimotope datasets.

IF 2.8 Q2 MATHEMATICAL & COMPUTATIONAL BIOLOGY Frontiers in bioinformatics Pub Date : 2024-02-23 eCollection Date: 2024-01-01 DOI:10.3389/fbinf.2024.1295972
Rang Li, Sabrina Wilderotter, Madison Stoddard, Debra Van Egeren, Arijit Chakravarty, Diane Joseph-McCarthy
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Abstract

Introduction: A fundamental challenge in computational vaccinology is that most B-cell epitopes are conformational and therefore hard to predict from sequence alone. Another significant challenge is that a great deal of the amino acid sequence of a viral surface protein might not in fact be antigenic. Thus, identifying the regions of a protein that are most promising for vaccine design based on the degree of surface exposure may not lead to a clinically relevant immune response. Methods: Linear peptides selected by phage display experiments that have high affinity to the monoclonal antibody of interest ("mimotopes") usually have similar physicochemical properties to the antigen epitope corresponding to that antibody. The sequences of these linear peptides can be used to find possible epitopes on the surface of the antigen structure or a homology model of the antigen in the absence of an antigen-antibody complex structure. Results and Discussion: Herein we describe two novel methods for mapping mimotopes to epitopes. The first is a novel algorithm named MimoTree that allows for gaps in the mimotopes and epitopes on the antigen. More specifically, a mimotope may have a gap that does not match to the epitope to allow it to adopt a conformation relevant for binding to an antibody, and residues may similarly be discontinuous in conformational epitopes. MimoTree is a fully automated epitope detection algorithm suitable for the identification of conformational as well as linear epitopes. The second is an ensemble approach, which combines the prediction results from MimoTree and two existing methods.

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从拟态数据集计算识别抗体结合表位。
导言:计算疫苗学的一个基本挑战是,大多数 B 细胞表位都是构象性的,因此很难仅凭序列预测。另一个重大挑战是病毒表面蛋白的大量氨基酸序列实际上可能不具有抗原性。因此,根据表面暴露程度确定最有希望设计疫苗的蛋白质区域可能不会产生临床相关的免疫反应。方法:通过噬菌体展示实验选出的与相关单克隆抗体具有高亲和力的线性肽("拟态")通常与该抗体对应的抗原表位具有相似的理化性质。这些线性肽的序列可用于寻找抗原结构表面的可能表位,或在没有抗原-抗体复合物结构的情况下寻找抗原的同源模型。结果与讨论:在此,我们介绍了两种将拟态映射到表位的新方法。第一种方法是一种名为 MimoTree 的新算法,它允许抗原上的拟态和表位之间存在间隙。更具体地说,拟态位点可能存在与表位不匹配的间隙,使其无法采用与抗体结合相关的构象,而构象表位中的残基也可能存在类似的不连续性。MimoTree 是一种全自动表位检测算法,适用于识别构象表位和线性表位。第二种是集合方法,它结合了 MimoTree 和两种现有方法的预测结果。
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