CRISPR-Cas12a is a genome-editing system, recently also harnessed for nucleic acid
detection, which is promising for the diagnosis of the SARS-CoV-2 coronavirus through
the DETECTR technology. Here, a collective ensemble of multimicrosecond molecular
dynamics characterizes the key dynamic determinants allowing nucleic acid processing in
CRISPR-Cas12a. We show that DNA binding induces a switch in the conformational dynamics
of Cas12a, which results in the activation of the peripheral REC2 and Nuc domains to
enable cleavage of nucleic acids. The simulations reveal that large-amplitude motions of
the Nuc domain could favor the conformational activation of the system toward DNA
cleavages. In this process, the REC lobe plays a critical role. Accordingly, the joint
dynamics of REC and Nuc shows the tendency to prime the conformational transition of the
DNA target strand toward the catalytic site. Most notably, the highly coupled dynamics
of the REC2 region and Nuc domain suggests that REC2 could act as a regulator of the Nuc
function, similar to what was observed previously for the HNH domain in the
CRISPR-associated nuclease Cas9. These mutual domain dynamics could be critical for the
nonspecific binding of DNA and thereby for the underlying mechanistic functioning of the
DETECTR technology. Considering that REC is a key determinant in the system’s
specificity, our findings provide a rational basis for future biophysical studies aimed
at characterizing its function in CRISPR-Cas12a. Overall, our outcomes advance our
mechanistic understanding of CRISPR-Cas12a and provide grounds for novel engineering
efforts to improve genome editing and viral detection.
Allostery is a fundamental property of proteins, which regulates biochemical information transfer between spatially distant sites. Here, we report on the critical role of molecular dynamics (MD) simulations in discovering the mechanism of allosteric communication within CRISPR‐Cas9, a leading genome editing machinery with enormous promises for medicine and biotechnology. MD revealed how allostery intervenes during at least three steps of the CRISPR‐Cas9 function: affecting DNA recognition, mediating the cleavage and interfering with the off‐target activity. An allosteric communication that activates concerted DNA cleavages was found to led through the L1/L2 loops, which connect the HNH and RuvC catalytic domains. The identification of these “allosteric transducers” inspired the development of novel variants of the Cas9 protein with improved specificity, opening a new avenue for controlling the CRISPR‐Cas9 activity. Discussed studies also highlight the critical role of the recognition lobe in the conformational activation of the catalytic HNH domain. Specifically, the REC3 region was found to modulate the dynamics of HNH by sensing the formation of the RNA:DNA hybrid. The role of REC3 was revealed to be particularly relevant in the presence of DNA mismatches. Indeed, interference of REC3 with the RNA:DNA hybrid containing mismatched pairs at specific positions resulted in locking HNH in an inactive “conformational checkpoint” conformation, thereby hampering off‐target cleavages. Overall, MD simulations established the fundamental mechanisms underlying the allosterism of CRISPR‐Cas9, aiding engineering strategies to develop new CRISPR‐Cas9 variants for improved genome editing.
This article is categorized under:
Structure and Mechanism > Computational Biochemistry and Biophysics
The RNA programmed non-specific (trans) nuclease activity of CRISPR-Cas Type V and VI systems has opened a new era in the field of nucleic acid-based detection. Here, we report on the enhancement of trans-cleavage activity of Cas12a enzymes using hairpin DNA sequences as FRET-based reporters. We discover faster rate of trans-cleavage activity of Cas12a due to its improved affinity (Km) for hairpin DNA structures, and provide mechanistic insights of our findings through Molecular Dynamics simulations. Using hairpin DNA probes we significantly enhance FRET-based signal transduction compared to the widely used linear single stranded DNA reporters. Our signal transduction enables faster detection of clinically relevant double stranded DNA targets with improved sensitivity and specificity either in the presence or in the absence of an upstream pre-amplification step.
CRISPR-Cas12a is a powerful RNA-guided genome-editing system, also emerging as a robust diagnostic tool that cleaves double-stranded DNA using only the RuvC domain. This opens an overarching question on how the spatially distant DNA target strand (TS) traverses toward the RuvC catalytic core. Here, continuous tens of microsecond-long molecular dynamics and free- energy simulations reveal that an ⍺-helical lid, located within the RuvC domain, plays a pivotal role in the traversal of the TS by anchoring the crRNA:TS hybrid and elegantly guiding the TS toward the RuvC core, as also corroborated by DNA cleavage experiments. In this mechanism, the REC2 domain pushes the crRNA:TS hybrid toward the core of the enzyme, while the Nuc domain aids the bending and accommodation of the TS within the RuvC core by bending inward. Understanding of this cardinal process in the functioning of Cas12a will enrich fundamental knowledge and facilitate further engineering strategies for genome-editing.
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