KRAB型锌指蛋白（KZNF）家族起源晚、进化快、物种特异性强，是人类最大的转录调控因子家族（含400多KZNF基因）。KZNF在胚胎干细胞（ESC）中抑制反转录转座子，对于ESC的稳定至关重要；前期研究提示KZNF在ESC向各谱系分化中呈现分工调控趋势，但具体分工模式和关键分子尚未明晰。本研究将针对KZNF家族特征，基于多组学数据，建立KZNF基因表达调控网络分析方法，挖掘KZNF基因表达和受调控模式、KZNF的靶基因及其参与的信号通路；构建KZNF在ESC分化中“共同”和“谱系特异”的表达调控网络，探索人和小鼠ESC分化的分子水平差异；挖掘起重要调控作用的KZNF分子，并针对部分KZNF进行功能和机制验证；同时，构建KZNF家族进化与表达调控信息数据库和检索平台，为研究者提供重要信息。本项目利于全面认识KZNF这一大家族的功能和进化特征及ESC分化机制，具有重要理论意义和潜在应用价值。

KRAB-domain-containing zinc finger protein (KZNF) family originated lately during evolution, then expaned and divergenced quickly, and there are strong specificity across species. KZNF family is the largest family of transcription factors in human (There are more than 400 KZNF genes in human genome). It is known that KZNFs play important roles in the repression of retroelements in embryonic stem cells (ESCs). However, the regular regulation patterns of KZNFs in the definitive differentiation of ESCs are largely unkonwn. In this study, with the improved integrated method for the analysis of KZNF regulation network, we will comprehensively analyze the important evolutionary events of KZNFs and the clade-specific KZNFs will be further classified. The omic data of gene expression and regulation during mouse and human ESC differentiation will be collected, and the expression and regulation pattern of KZNFs will be investigated. The target genes of KZNFs and the related signal pathways will be mined and we can infer the common and lineage-specific regulation networks and modules, from which we can understand the divergence of the regulation pattern of ESC differentiation between mouse and human. What's more, the key KZNF genes contributing to the regulation of ESC differentiation will be selected for the deep experimental validation. Their regulating function and regulation mechanisms will be confirmed by various experiments. Meanwhile, the database and search platform specified for KZNF family will be developed. This study will substantially enrich the information of the regulating functions and evolutionary mechanisms of KZNFs and is of great significance for the understanding of the mechanisms of ESC differentiation, which are of great theoretical significance and potential application value.