Sam P. B. van Beljouw scite author profile

CRISPR and Caspase meet Many prokaryotes use CRISPR RNA–bound proteins to sense viral RNA instead of DNA to set an immune response in motion that protects from virus infection. Although these ribonucleoproteins are typically composed of many protein subunits, van Beljouw et al . discovered that CRISPR-Cas type III-E systems are formed by a large, single-component effector protein capable of double RNA cleavage. Distinct from other systems, this effector forms a complex with a peptidase from the caspase family, raising the intriguing possibility that viral RNA activates a protease activity to prevent virus propagation by host suicide. —DJ

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Visualisation of dCas9 target search in vivo using an open-microscopy framework

Martens

et al. 2019

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CRISPR-Cas9 is widely used in genomic editing, but the kinetics of target search and its relation to the cellular concentration of Cas9 have remained elusive. Effective target search requires constant screening of the protospacer adjacent motif (PAM) and a 30 ms upper limit for screening was recently found. To further quantify the rapid switching between DNA-bound and freely-diffusing states of dCas9, we developed an open-microscopy framework, the miCube, and introduce Monte-Carlo diffusion distribution analysis (MC-DDA). Our analysis reveals that dCas9 is screening PAMs 40% of the time in Gram-positive Lactoccous lactis , averaging 17 ± 4 ms per binding event. Using heterogeneous dCas9 expression, we determine the number of cellular target-containing plasmids and derive the copy number dependent Cas9 cleavage. Furthermore, we show that dCas9 is not irreversibly bound to target sites but can still interfere with plasmid replication. Taken together, our quantitative data facilitates further optimization of the CRISPR-Cas toolbox.

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Craspase is a CRISPR RNA-guided, RNA-activated protease

Beljouw

Nam

et al. 2022

Science

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The Type III-E RNA-targeting effector complex (gRAMP/Cas7-11) is associated with a caspase-like protein (TPR-CHAT/Csx29) to form Craspase (CRISPR-guided caspase). Here we use cryo-electron microscopy snapshots of Craspase to explain its target RNA cleavage and protease activation mechanisms. Target-guide pairing extending into the 5′ region of the guide RNA displaces a gating loop in gRAMP, which triggers an extensive conformational relay that allosterically aligns the protease catalytic dyad and opens an amino acid sidechain-binding pocket. We further define Csx30 as the endogenous protein substrate that is site-specifically proteolyzed by RNA-activated Craspase. This protease activity is switched off by target RNA cleavage by gRAMP, and is not activated by RNA targets containing a matching protospacer flanking sequence. We thus conclude that Craspase is a target RNA-activated protease with self-regulatory capacity.

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Approaches for bacteriophage genome engineering

Mahler

Costa

Beljouw

et al. 2023

Trends in Biotechnology

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RNA-targeting CRISPR–Cas systems

et al. 2022

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