转座子编码蛋白 TnpB 将自身 mRNA 加工成 ωRNA 以发挥引导核酸酶活性。

The Transposon-Encoded Protein TnpB Processes Its Own mRNA into ωRNA for Guided Nuclease Activity.

机构信息

Howard Hughes Medical Institute, Cambridge, Massachusetts, USA.

Broad Institute of MIT and Harvard, Cambridge, Massachusetts, USA.

出版信息

CRISPR J. 2023 Jun;6(3):232-242. doi: 10.1089/crispr.2023.0015.

DOI:10.1089/crispr.2023.0015

PMID:37272862

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10278001/

Abstract

TnpB is a member of the Obligate Mobile Element Guided Activity (OMEGA) RNA-guided nuclease family, is harbored in transposons, and likely functions to maintain the transposon in genomes. Previously, it was shown that TnpB cleaves double- and single-stranded DNA substrates in an RNA-guided manner, but the biogenesis of the TnpB ribonucleoprotein (RNP) complex is unknown. Using purified apo TnpB, we demonstrate the ability of TnpB to generate guide omegaRNA (ωRNA) from its own mRNA through 5' processing. We also uncover a potential -regulatory mechanism whereby a region of the TnpB mRNA inhibits DNA cleavage by the RNP complex. We further expand the characterization of TnpB by examining ωRNA processing and RNA-guided nuclease activity in 59 orthologs spanning the natural diversity of the TnpB family. This work reveals a new functionality, ωRNA biogenesis, of TnpB, and characterizes additional members of this biotechnologically useful family of programmable enzymes.

摘要

TnpB 是必需移动元件引导活性（OMEGA）RNA 引导核酸酶家族的成员，位于转座子中，可能具有维持基因组中转座子的功能。先前的研究表明，TnpB 以 RNA 指导的方式切割双链和单链 DNA 底物，但 TnpB 核糖核蛋白（RNP）复合物的生物发生尚不清楚。使用纯化的脱辅基 TnpB，我们证明了 TnpB 能够通过 5' 加工从自身 mRNA 产生引导 omegaRNA（ωRNA）。我们还揭示了一种潜在的调控机制，即 TnpB mRNA 的一个区域抑制 RNP 复合物的 DNA 切割。我们通过检查跨越 TnpB 家族自然多样性的 59 个直系同源物中的 ωRNA 加工和 RNA 引导核酸酶活性，进一步扩展了对 TnpB 的表征。这项工作揭示了 TnpB 的新功能，即 ωRNA 生物发生，并描述了这种具有生物技术用途的可编程酶家族的其他成员。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/850d/10278001/6002f7ffe7f8/crispr.2023.0015_figure1.jpg

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转座子编码蛋白 TnpB 将自身 mRNA 加工成 ωRNA 以发挥引导核酸酶活性。

The Transposon-Encoded Protein TnpB Processes Its Own mRNA into ωRNA for Guided Nuclease Activity.

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