Changkon Park scite author profile

Bacteria and archaea use the CRISPR-Cas system to fend off invasions of bacteriophages and foreign plasmids. In response, bacteriophages encode anti-CRISPR (Acr) proteins that potently inhibit host Cas proteins to suppress CRISPR-mediated immunity. AcrIE4-F7, which was isolated from Pseudomonas citronellolis, is a fused form of AcrIE4 and AcrIF7 that inhibits both type I-E and type I-F CRISPR-Cas systems. Here, we determined the structure of AcrIE4-F7 and identified its Cas target proteins. The N-terminal AcrIE4 domain adopts a novel α-helical fold that targets the PAM interaction site of the type I-E Cas8e subunit. The C-terminal AcrIF7 domain exhibits an αβ fold like native AcrIF7, which disables target DNA recognition by the PAM interaction site in the type I-F Cas8f subunit. The two Acr domains are connected by a flexible linker that allows prompt docking onto their cognate Cas8 targets. Conserved negative charges in each Acr domain are required for interaction with their Cas8 targets. Our results illustrate a common mechanism by which AcrIE4-F7 inhibits divergent CRISPR-Cas types.

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Structural Investigation of Self-Assembly and Target Binding of Anti-CRISPR AcrIIC2

Kim

Lee

Park

et al. 2021

The CRISPR Journal

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Anti-CRISPR (Acr) proteins are phage-borne inhibitors of the CRISPR-Cas immune system in archaea and bacteria. AcrIIC2 from prophages of Neisseria meningitidis disables the nuclease activity of type II-C Cas9, such that dimeric AcrIIC2 associates with the bridge helix (BH) region of Cas9 to compete with guide RNA loading. AcrIIC2 in solution readily assembles into oligomers of variable lengths, but the oligomeric states are not clearly understood. In this study, we investigated the dynamic assembly of AcrIIC2 oligomers, and identified key interactions underlying the self-association. We report that AcrIIC2 dimers associate into heterogeneous high-order oligomers with the equilibrium dissociation constant K D *8 lM. Oligomerization is driven by electrostatic interactions between charged residues, and rational mutagenesis produces a stable AcrIIC2 dimer with intact Cas9 binding. Remarkably, the BH peptide of Cas9 is unstructured in solution, and undergoes a coil-to-helix transition upon AcrIIC2 binding, revealing a unique folding-upon-binding mechanism for Acr recognition.

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Changkon Park

Determinants of PB1 Domain Interactions in Auxin Response Factor ARF5 and Repressor IAA17

The structure of AcrIE4-F7 reveals a common strategy for dual CRISPR inhibition by targeting PAM recognition sites

Structural Investigation of Self-Assembly and Target Binding of Anti-CRISPR AcrIIC2

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