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KRAB 结构域的 ZNF10 指导特定氨基酸的鉴定,这些氨基酸将人类 PRDM9 中存在的 KRAB-A 相关结构域的祖先转变为规范的现代 KRAB-A 结构域。

The KRAB Domain of ZNF10 Guides the Identification of Specific Amino Acids That Transform the Ancestral KRAB-A-Related Domain Present in Human PRDM9 into a Canonical Modern KRAB-A Domain.

机构信息

Rostock University Medical Center, Institute of Immunology, Schillingallee 70, 18057 Rostock, Germany.

Gesellschaft für Individualisierte Medizin (IndyMed) mbH, 17, 18055 Rostock, Germany.

出版信息

Int J Mol Sci. 2022 Jan 19;23(3):1072. doi: 10.3390/ijms23031072.

DOI:10.3390/ijms23031072
PMID:35162997
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8835667/
Abstract

Krüppel-associated box (KRAB) zinc finger proteins are a large class of tetrapod transcription factors that usually exert transcriptional repression through recruitment of TRIM28/KAP1. The evolutionary root of modern KRAB domains (mKRAB) can be traced back to an ancestral motif (aKRAB) that occurs even in invertebrates. Here, we first stratified three subgroups of aKRAB sequences from the animal kingdom (PRDM9, SSX and coelacanth KZNF families) and defined ancestral subdomains for KRAB-A and KRAB-B. Using human ZNF10 mKRAB-AB as blueprints for function, we then identified the necessary amino acid changes that transform the inactive aKRAB-A of human PRDM9 into an mKRAB domain capable of mediating silencing and complexing TRIM28/KAP1 in human cells when employed as a hybrid with ZNF10-B. Full gain of function required replacement of residues KR by the conserved motif MLE (positionsA32-A34), which inserted an additional residue, and exchange of A9/S for F, A20/M for L, and A27/R for V. AlphaFold2 modelling documented an evolutionary conserved L-shaped body of two α-helices in all KRAB domains. It is transformed into a characteristic spatial arrangement typical for mKRAB-AB upon the amino acid replacements and in conjunction with a third helix supplied by mKRAB-B. Side-chains pointing outward from the core KRAB 3D structure may reveal a protein-protein interaction code enabling graded binding of TRIM28 to different KRAB domains. Our data provide basic insights into structure-function relationships and emulate transitions of KRAB during evolution.

摘要

Krüppel 相关盒 (KRAB) 锌指蛋白是一类大型四足转录因子,通常通过招募 TRIM28/KAP1 发挥转录抑制作用。现代 KRAB 结构域 (mKRAB) 的进化根源可以追溯到甚至在无脊椎动物中存在的祖先基序 (aKRAB)。在这里,我们首先从动物王国中划分出 aKRAB 序列的三个亚组(PRDM9、SSX 和腔棘鱼 KZNF 家族),并定义了 KRAB-A 和 KRAB-B 的祖先亚结构域。使用人类 ZNF10 mKRAB-AB 作为功能蓝图,然后确定了必要的氨基酸变化,这些变化将人类 PRDM9 中无活性的 aKRAB-A 转化为能够介导沉默并与人类细胞中的 TRIM28/KAP1 复合的 mKRAB 结构域,当与 ZNF10-B 混合使用时。完全获得功能需要用保守基序 MLE(位置 A32-A34)替换 KR 残基,该基序插入一个额外的残基,并将 A9/S 替换为 F、A20/M 替换为 L 和 A27/R 替换为 V。AlphaFold2 建模记录了所有 KRAB 结构域中两个α-螺旋的进化保守 L 形结构。当氨基酸替换并与 mKRAB-B 提供的第三个螺旋结合时,它会转变为 mKRAB-AB 的特征空间排列。从核心 KRAB 3D 结构向外指向的侧链可能揭示了一种蛋白质-蛋白质相互作用的密码,使 TRIM28 能够与不同的 KRAB 结构域进行分级结合。我们的数据提供了结构-功能关系的基本见解,并模拟了 KRAB 在进化过程中的转变。

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