Thomson Hallmark scite author profile

Cas12a2 is a CRISPR-associated nuclease that performs RNA-guided, sequence-nonspecific degradation of single-stranded RNA, single-stranded DNA and double-stranded DNA following recognition of a complementary RNA target, culminating in abortive infection1. Here we report structures of Cas12a2 in binary, ternary and quaternary complexes to reveal a complete activation pathway. Our structures reveal that Cas12a2 is autoinhibited until binding a cognate RNA target, which exposes the RuvC active site within a large, positively charged cleft. Double-stranded DNA substrates are captured through duplex distortion and local melting, stabilized by pairs of ‘aromatic clamp’ residues that are crucial for double-stranded DNA degradation and in vivo immune system function. Our work provides a structural basis for this mechanism of abortive infection to achieve population-level immunity, which can be leveraged to create rational mutants that degrade a spectrum of collateral substrates.

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Cas12a2 elicits abortive infection through RNA-triggered destruction of dsDNA

Dmytrenko

Neumann

Hallmark

et al. 2023

Nature

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Bacterial abortive-infection systems limit the spread of foreign invaders by shutting down or killing infected cells before the invaders can replicate1,2. Several RNA-targeting CRISPR–Cas systems (that is, types III and VI) cause abortive-infection phenotypes by activating indiscriminate nucleases3–5. However, a CRISPR-mediated abortive mechanism that leverages indiscriminate DNase activity of an RNA-guided single-effector nuclease has yet to be observed. Here we report that RNA targeting by the type V single-effector nuclease Cas12a2 drives abortive infection through non-specific cleavage of double-stranded DNA (dsDNA). After recognizing an RNA target with an activating protospacer-flanking sequence, Cas12a2 efficiently degrades single-stranded RNA (ssRNA), single-stranded DNA (ssDNA) and dsDNA. Within cells, the activation of Cas12a2 induces an SOS DNA-damage response and impairs growth, preventing the dissemination of the invader. Finally, we harnessed the collateral activity of Cas12a2 for direct RNA detection, demonstrating that Cas12a2 can be repurposed as an RNA-guided RNA-targeting tool. These findings expand the known defensive abilities of CRISPR–Cas systems and create additional opportunities for CRISPR technologies.

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Positioning Diverse Type IV Structures and Functions Within Class 1 CRISPR-Cas Systems

et al. 2021

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Type IV CRISPR systems encode CRISPR associated (Cas)-like proteins that combine with small RNAs to form multi-subunit ribonucleoprotein complexes. However, the lack of Cas nucleases, integrases, and other genetic features commonly observed in most CRISPR systems has made it difficult to predict type IV mechanisms of action and biological function. Here we summarize recent bioinformatic and experimental advancements that collectively provide the first glimpses into the function of specific type IV subtypes. We also provide a bioinformatic and structural analysis of type IV-specific proteins within the context of multi-subunit (class 1) CRISPR systems, informing future studies aimed at elucidating the function of these cryptic systems.

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Cas12a2 elicits abortive infection via RNA-triggered destruction of double-stranded DNA

Dmytrenko

Neumann

Hallmark

et al. 2022

Preprint

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Bacterial abortive infection systems limit the spread of foreign invaders by shutting down or killing infected cells before the invaders can replicate. Several RNA-targeting CRISPR-Cas systems (e.g., types III and VI) cause Abi phenotypes by activating indiscriminate RNases. However, a CRISPR-mediated abortive mechanism that relies on indiscriminate DNase activity has yet to be observed. Here we report that RNA targeting by the type V Cas12a2 nuclease drives abortive infection through non-specific cleavage of double-stranded (ds)DNA. Upon recognition of an RNA target with an activating protospacer-flanking sequence, Cas12a2 efficiently degrades single–stranded (ss)RNA, ssDNA, and dsDNA. Within cells, the dsDNase activity induces an SOS response and impairs growth, stemming the infection. Finally, we harnessed the collateral activity of Cas12a2 for direct RNA detection, demonstrating that Cas12a2 can be repurposed as an RNA-guided, RNA-targeting tool. These findings expand the known defensive capabilities of CRISPR-Cas systems and create additional opportunities for CRISPR technologies.

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