各类病原体在全世界范围内影响人类健康。对病原体准确识别并获取其进化、传播等信息，有助于尽早采取适宜的防治措施。DNA测序技术的发展突破了传统病原体检测方法的局限性，可获取更多的病原体信息，有助于深入了解病原体的性质。基因序列构建的系统进化树凭借高效而准确的进化关系呈现，已成为病原学研究的重要方法。本文介绍了基于距离矩阵、序列、多位点序列分型和单核苷酸多态性算法的进化树分析和构建方法，以及在细菌、病毒、真菌和非典型病原体研究中的应用。系统进化树作为一种直观反映微生物相互关系的工具，可在物种鉴定和分型、耐药性分析、流行病学研究、微生物起源和进化、疫苗研制、病原学体监测和预警等方面为临床病原学研究提供新思路，促进对病原微生物更深层次的认知。

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