Dimerization of the deaminase domain and locking interactions with Cas9 boost base editing efficiency in ABE8e.

IF 16.6 2区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Nucleic Acids Research Pub Date : 2024-11-21 DOI:10.1093/nar/gkae1066

Pablo R Arantes, Xiaoyu Chen, Souvik Sinha, Aakash Saha, Amun C Patel, Matthew Sample, Łukasz Nierzwicki, Audrone Lapinaite, Giulia Palermo

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Abstract

CRISPR-based DNA adenine base editors (ABEs) hold remarkable promises to address human genetic diseases caused by point mutations. ABEs were developed by combining CRISPR-Cas9 with a transfer RNA (tRNA) adenosine deaminase enzyme and through directed evolution, conferring the ability to deaminate DNA. However, the molecular mechanisms driving the efficient DNA deamination in the evolved ABEs remain unresolved. Here, extensive molecular simulations and biochemical experiments reveal the biophysical basis behind the astonishing base editing efficiency of ABE8e, the most efficient ABE to date. We demonstrate that the ABE8e's DNA deaminase domain, TadA8e, forms remarkably stable dimers compared to its tRNA-deaminating progenitor and that the strength of TadA dimerization is crucial for DNA deamination. The TadA8e dimer forms robust interactions involving its R98 and R129 residues, the RuvC domain of Cas9 and the DNA. These locking interactions are exclusive to ABE8e, distinguishing it from its predecessor, ABE7.10, and are indispensable to boost DNA deamination. Additionally, we identify three critical residues that drive the evolution of ABE8e toward improved base editing by balancing the enzyme's activity and stability, reinforcing the TadA8e dimer and improving the ABE8e's functionality. These insights offer new directions to engineer superior ABEs, advancing the design of safer precision genome editing tools.

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脱氨酶结构域的二聚化以及与 Cas9 的锁定相互作用提高了 ABE8e 的碱基编辑效率。

基于CRISPR的DNA腺嘌呤碱基编辑器（ABEs）在解决由点突变引起的人类遗传疾病方面前景广阔。ABEs是通过将CRISPR-Cas9与转运核糖核酸（tRNA）腺苷脱氨酶结合，并通过定向进化，赋予DNA脱氨能力而开发出来的。然而，驱动进化ABEs高效脱氨基的分子机制仍未解决。在这里，大量的分子模拟和生化实验揭示了 ABE8e（迄今为止最高效的 ABE）惊人的碱基编辑效率背后的生物物理基础。我们证明了 ABE8e 的 DNA 脱氨酶结构域 TadA8e 与其 tRNA 脱氨祖先相比形成了非常稳定的二聚体，而且 TadA 二聚体的强度对 DNA 脱氨至关重要。TadA8e 二聚体与其 R98 和 R129 残基、Cas9 的 RuvC 结构域以及 DNA 形成了强有力的相互作用。这些锁定相互作用是 ABE8e 独有的，使其有别于其前身 ABE7.10，是促进 DNA 去氨基不可或缺的因素。此外，我们还发现了三个关键残基，它们通过平衡酶的活性和稳定性、强化 TadA8e 二聚体和改善 ABE8e 的功能，推动 ABE8e 向着改进碱基编辑的方向进化。这些见解为设计更优越的 ABE 提供了新的方向，推动了更安全的精准基因组编辑工具的设计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nucleic Acids Research 生物-生化与分子生物学

CiteScore

27.10

自引率

4.70%

发文量

1057

审稿时长

2 months

期刊介绍： Nucleic Acids Research (NAR) is a scientific journal that publishes research on various aspects of nucleic acids and proteins involved in nucleic acid metabolism and interactions. It covers areas such as chemistry and synthetic biology, computational biology, gene regulation, chromatin and epigenetics, genome integrity, repair and replication, genomics, molecular biology, nucleic acid enzymes, RNA, and structural biology. The journal also includes a Survey and Summary section for brief reviews. Additionally, each year, the first issue is dedicated to biological databases, and an issue in July focuses on web-based software resources for the biological community. Nucleic Acids Research is indexed by several services including Abstracts on Hygiene and Communicable Diseases, Animal Breeding Abstracts, Agricultural Engineering Abstracts, Agbiotech News and Information, BIOSIS Previews, CAB Abstracts, and EMBASE.