Ylenia Jabalera, Igor Tascón, Sara Samperio, Jorge P. López-Alonso, Monika Gonzalez-Lopez, Ana M. Aransay, Guillermo Abascal-Palacios, Chase L. Beisel, Iban Ubarretxena-Belandia, Raul Perez-Jimenez
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引用次数: 0
摘要
Cas12a 核酸酶的特性限制了其靶标及其应用范围。在这项研究中,我们对一组来自水生细菌的 Cas12a 同源物进行了祖先序列重建(ASR),重建了一个共同的祖先 ReChb,其特点是近乎无 PAM 靶向以及识别多种核酸激活剂和附属底物。ReChb 与最接近的 Cas12a 直向同源物有 53% 的序列相同性,但不再需要富含 T 的 PAM,而且可以在天然 FnCas12a 或工程化的、具有 PAM 灵活性的 enAsCas12a 无法进入的位点对人类细胞进行基因组编辑。此外,ReChb 不仅能被双链 DNA 触发,还能被单链 RNA 和 DNA 靶标触发,从而以相似的效率对所有三种核酸底物进行非特异性附带切割。最后,通过低温电子显微镜获得的 ReChb 三级和四级结构揭示了其扩展生物物理活性的分子细节。总之,ReChb拓展了Cas12a核酸酶的应用空间,并强调了ASR在增强CRISPR技术方面的潜力。
A resurrected ancestor of Cas12a expands target access and substrate recognition for nucleic acid editing and detection
The properties of Cas12a nucleases constrict the range of accessible targets and their applications. In this study, we applied ancestral sequence reconstruction (ASR) to a set of Cas12a orthologs from hydrobacteria to reconstruct a common ancestor, ReChb, characterized by near-PAMless targeting and the recognition of diverse nucleic acid activators and collateral substrates. ReChb shares 53% sequence identity with the closest Cas12a ortholog but no longer requires a T-rich PAM and can achieve genome editing in human cells at sites inaccessible to the natural FnCas12a or the engineered and PAM-flexible enAsCas12a. Furthermore, ReChb can be triggered not only by double-stranded DNA but also by single-stranded RNA and DNA targets, leading to non-specific collateral cleavage of all three nucleic acid substrates with similar efficiencies. Finally, tertiary and quaternary structures of ReChb obtained by cryogenic electron microscopy reveal the molecular details underlying its expanded biophysical activities. Overall, ReChb expands the application space of Cas12a nucleases and underscores the potential of ASR for enhancing CRISPR technologies.
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