Department of Mathematics, Faculty of Science, Stockholm University, Stockholm, Sweden.
Bioinformatics Group, Department of Computer Science, Leipzig University, Leipzig, Germany.
Methods Mol Biol. 2024;2802:1-32. doi: 10.1007/978-1-0716-3838-5_1.
Most genes are part of larger families of evolutionary-related genes. The history of gene families typically involves duplications and losses of genes as well as horizontal transfers into other organisms. The reconstruction of detailed gene family histories, i.e., the precise dating of evolutionary events relative to phylogenetic tree of the underlying species has remained a challenging topic despite their importance as a basis for detailed investigations into adaptation and functional evolution of individual members of the gene family. The identification of orthologs, moreover, is a particularly important subproblem of the more general setting considered here. In the last few years, an extensive body of mathematical results has appeared that tightly links orthology, a formal notion of best matches among genes, and horizontal gene transfer. The purpose of this chapter is to broadly outline some of the key mathematical insights and to discuss their implication for practical applications. In particular, we focus on tree-free methods, i.e., methods to infer orthology or horizontal gene transfer as well as gene trees, species trees, and reconciliations between them without using a priori knowledge of the underlying trees or statistical models for the inference of phylogenetic trees. Instead, the initial step aims to extract binary relations among genes.
大多数基因是进化相关基因的更大家族的一部分。基因家族的历史通常涉及基因的复制和丢失,以及水平基因转移到其他生物体中。尽管基因家族的详细历史重建(即相对于基础物种的系统发育树来精确确定进化事件的日期)对于详细研究基因家族成员的适应和功能进化非常重要,但它们仍然是一个具有挑战性的话题。此外,直系同源物的识别是这里更广泛考虑的一般设置中的一个特别重要的子问题。在过去的几年中,出现了大量的数学结果,这些结果将直系同源物紧密地联系起来,直系同源物是基因之间最佳匹配的形式概念,以及水平基因转移。本章的目的是广泛概述一些关键的数学见解,并讨论它们对实际应用的影响。特别是,我们专注于无树方法,即推断直系同源物或水平基因转移以及基因树、物种树和它们之间的调和而无需使用基础树的先验知识或用于推断系统发育树的统计模型。相反,初始步骤旨在提取基因之间的二进制关系。
