Since Darwin's time, elucidating the mechanism of adaptive evolution has been one of the most important scientific issues in evolutionary biology and ecology. Adaptive evolution usually means that species evolve special phenotypic traits to increase fitness under selective pressures. Phenotypic adaptation can be observed at different hierarchical levels of morphology, physiology, biochemistry, histology, and behavior. With the breakthroughs of molecular biology and next-generation sequencing technologies, mounting evidence has uncovered the genetic architecture driving adaptive complex phenotypes. Studying the molecular genetic mechanisms of evolutionary adaption will enable us to understand the forces shaping biodiversity and set up genotype-phenotype-environment interactions. Genetic bases of adaptive evolution have been explained by multiple hypotheses, including major-effect genes, supergenes, polygenicity, noncoding regions, repeated regions, and introgression. The strong selection pressure exerted by high-altitude extreme environments greatly promotes the occurrence of phenotypic and genetic adaptation in species. Studies on multi-omics data provide new insights into adaptive evolution. In this review, we systematically summarize the genetic mechanism of adaptive evolution, research progress in adaptation to high-altitude environmental conditions, and existing challenges and discuss the future perspectives, thereby providing guidance for researchers in this field.
自达尔文时代起,解析适应性演化的机制一直是进化生物学和生态学领域研究最重要的科学问题之一。适应性演化通常指在自然选择驱动下,物种为提高适合度而演化出特定的表型。表型的适应表现在形态、生理生化、组织学、行为学等多个层级。随着分子生物学和测序技术的发展,越来越多的研究揭示了适应性复杂性状的遗传基础。研究适应性演化的分子遗传机制有助于理解塑造生物多样性的进化驱动力以及阐明基因型、表型和环境之间的关联关系。目前已有主效基因、超基因、多基因遗传、非编码区调控、重复序列调控、基因渐渗等多种假说可以解释适应性演化的遗传机制。高海拔极端环境的强选择压力极大地促进了物种表型和遗传适应的发生,对多组学数据的剖析为物种适应性演化提供了新的见解。本文对适应性演化的遗传机制、高海拔极端环境适应研究进展以及目前面临的主要挑战进行了综述,并对未来的发展趋势进行了展望,以期为该领域的科研人员提供参考。.
Keywords: high altitudes; multi-omics; noncoding region; phenotype; regulation.