Crystal structure of the CRISPR RNA–guided surveillance complex from
            <i>Escherichia coli</i>

Jackson, Ryan N.; Golden, Sarah; Erp, Paul B. G. van; Carter, Joshua; Westra, Edze R.; Brouns, Stan J. J.; Oost, John van der; Terwilliger, Thomas C.; Read, Randy J.; Wiedenheft, Blake

doi:10.1126/science.1256328

Cited by 239 publications

(370 citation statements)

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“…Our results also invite comparisons to the mechanisms of RNP assembly and DNA targeting in other CRISPR-Cas systems, particularly the type I-E Cascade interference complex. Although Cascade is composed of 11 distinct subunits, none of which possesses nuclease activity, the guide RNA (crRNA) plays a similarly critical role in scaffolding the assembly of distinct domains into a structure that is primed to engage DNA targets (19)(20)(21). Similar principles are likely to govern the assembly and activity of other CRISPR RNA-guided DNA-targeting complexes (2).…”

Section: Discussionmentioning

confidence: 99%

Rational design of a split-Cas9 enzyme complex

Wright

Sternberg²,

Taylor

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

273

207

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Cas9, an RNA-guided DNA endonuclease found in clustered regularly interspaced short palindromic repeats (CRISPR) bacterial immune systems, is a versatile tool for genome editing, transcriptional regulation, and cellular imaging applications. Structures of Streptococcus pyogenes Cas9 alone or bound to single-guide RNA (sgRNA) and target DNA revealed a bilobed protein architecture that undergoes major conformational changes upon guide RNA and DNA binding. To investigate the molecular determinants and relevance of the interlobe rearrangement for target recognition and cleavage, we designed a split-Cas9 enzyme in which the nuclease lobe and α-helical lobe are expressed as separate polypeptides. Although the lobes do not interact on their own, the sgRNA recruits them into a ternary complex that recapitulates the activity of full-length Cas9 and catalyzes site-specific DNA cleavage. The use of a modified sgRNA abrogates split-Cas9 activity by preventing dimerization, allowing for the development of an inducible dimerization system. We propose that split-Cas9 can act as a highly regulatable platform for genome-engineering applications.CRISPR-Cas9 | genome engineering | split enzyme B acteria use RNA-guided adaptive immune systems encoded by clustered regularly interspaced short palindromic repeats (CRISPR)-CRISPR-associated (Cas) genomic loci to defend against invasive DNA (1, 2). In type II CRISPR-Cas systems, a single enzyme called Cas9 is responsible for targeting and cleavage of foreign DNA (3). The ability to program Cas9 for DNA cleavage at sites defined by engineered single-guide RNAs (sgRNAs) (4) has led to its adoption as a robust and versatile platform for genome engineering (for recent reviews, see refs. 5-7).Cas9 contains two nuclease active sites that function together to generate DNA double-strand breaks (DSBs) at sites complementary to the 20-nt guide RNA sequence and adjacent to a protospacer adjacent motif (PAM). Structural studies of the Streptococcus pyogenes Cas9 showed that the protein exhibits a bilobed architecture comprising the catalytic nuclease lobe and the α-helical lobe of the enzyme (8). Electron microscopy (EM) studies and comparisons with X-ray crystal structures with and without a bound guide RNA and target DNA revealed a largescale conformational rearrangement of the two lobes relative to each other upon nucleic acid binding (8, 9). Strikingly, RNA binding induces the nuclease lobe to rotate ∼100°relative to the α-helical lobe, generating a nucleic-acid binding cleft that can accommodate DNA, and interactions between the two lobes seem to be mediated primarily through contacts with the bound nucleic acid rather than direct protein-protein contacts (8, 9). These observations suggested that the two structural lobes of Cas9 might be separable into independent polypeptides that retain the ability to assemble into an active enzyme complex. Such a system would enable analysis of the functionally distinct properties of each Cas9 structural region and might offer a unique mechanism for control...

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Section: Discussionmentioning

confidence: 99%

Rational design of a split-Cas9 enzyme complex

Wright

Sternberg²,

Taylor

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

273

207

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“…For both the Cas9 and the class 1 Cascade complex, a remarkable feature of the transition from the pre-target-bound binary state to the target-bound ternary state involves the formation of a preordered A-form crR-NA, either only within the seed region (Cas9) [14] or throughout the entire guide region (Cascade complex) [31][32][33]. This strategy is also employed by the eukaryotic Agronaute complexes during the transition from guide-RNA bound form to target transcript recognition [28][29][30], representing a convergent evolution of this mechanism [14].…”

Section: Disordered Seed Sequence In Pre-target-bound Binary Cpf1 Commentioning

confidence: 99%

Type V CRISPR-Cas Cpf1 endonuclease employs a unique mechanism for crRNA-mediated target DNA recognition

et al. 2016

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CRISPR-Cas9 and CRISPR-Cpf1 systems have been successfully harnessed for genome editing. In the CRIS-PR-Cas9 system, the preordered A-form RNA seed sequence and preformed protein PAM-interacting cleft are essential for Cas9 to form a DNA recognition-competent structure. Whether the CRISPR-Cpf1 system employs a similar mechanism for target DNA recognition remains unclear. Here, we have determined the crystal structure of Acidaminococcus sp. Cpf1 (AsCpf1) in complex with crRNA and target DNA. Structural comparison between the AsCpf1-crRNA-DNA ternary complex and the recently reported Lachnospiraceae bacterium Cpf1 (LbCpf1)-crRNA binary complex identifies a unique mechanism employed by Cpf1 for target recognition. The seed sequence required for initial DNA interrogation is disordered in the Cpf1-cRNA binary complex, but becomes ordered upon ternary complex formation. Further, the PAM interacting cleft of Cpf1 undergoes an "open-to-closed" conformational change upon target DNA binding, which in turn induces structural changes within Cpf1 to accommodate the ordered A-form seed RNA segment. This unique mechanism of target recognition by Cpf1 is distinct from that reported previously for Cas9.

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“…In vivo, several copies of Cas7 proteins are wrapped around crRNA in a sequence-unspecific helical fashion [5,30,50,51]. Crystal structures from single and complex-bound Cas7 proteins show two composite RNA-binding surfaces: a central cleft and a structurally variable insertion domain [5,23,24,52]. In all Cas7 proteins characterized to date both these domains are defined by insertions within the secondary structure elements of the central RRM domain (insertion domain 1 is b1-a1, b2-b3, a2-b4, and insertion domain 2 is a1-b2).…”

Section: Mapping the Rna Binding Interface In Cas7 Proteinsmentioning

confidence: 99%

“…We compared our results with the crRNA-binding surface of Type I-E Escherichia coli Cas7, which was crystallized in context of the fully assembled crRNP complex from E. coli [5]. For this, the crystal structure of T. pendens Cas7 and the homology models (T. tenax Cas7 and T. thermophilus Csm3) were superposed onto two copies of E. coli Cas7 (PDB ID: 1VY8) using secondary-structure matching (SSM) superposition in COOT [54].…”

Section: Cross-link Sites On the Structural Model Of Cas7 Proteinsmentioning

confidence: 99%

“…The ''gold standard'' for characterizing molecular interactions of RBDs with their cognate RNA molecules by structure determination is co-crystallization [4,5]; others include NMR of the complex [6], or high-resolution EM of entire RNPs, as performed for the ribosome [7]. Although the number of co-structures of RBPs has been steadily increasing with more than 200 co-structures of protein-RNA complexes available in the PDB, most RBPs are still crystallized without RNA.…”

Section: Introductionmentioning

confidence: 99%

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Analysis of protein–RNA interactions in CRISPR proteins and effector complexes by UV-induced cross-linking and mass spectrometry

Sharma

Hrle

Kramer

et al. 2015

Methods

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a b s t r a c tRibonucleoprotein (RNP) complexes play important roles in the cell by mediating basic cellular processes, including gene expression and its regulation. Understanding the molecular details of these processes requires the identification and characterization of protein-RNA interactions. Over the years various approaches have been used to investigate these interactions, including computational analyses to look for RNA binding domains, gel-shift mobility assays on recombinant and mutant proteins as well as co-crystallization and NMR studies for structure elucidation. Here we report a more specialized and direct approach using UV-induced cross-linking coupled with mass spectrometry. This approach permits the identification of cross-linked peptides and RNA moieties and can also pin-point exact RNA contact sites within the protein. The power of this method is illustrated by the application to different singleand multi-subunit RNP complexes belonging to the prokaryotic adaptive immune system, CRISPR-Cas (CRISPR: clustered regularly interspaced short palindromic repeats; Cas: CRISPR associated). In particular, we identified the RNA-binding sites within three Cas7 protein homologs and mapped the cross-linking results to reveal structurally conserved Cas7 -RNA binding interfaces. These results demonstrate the strong potential of UV-induced cross-linking coupled with mass spectrometry analysis to identify RNA interaction sites on the RNA binding proteins.

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Crystal structure of the CRISPR RNA–guided surveillance complex from Escherichia coli

Cited by 239 publications

References 50 publications

Rational design of a split-Cas9 enzyme complex

Rational design of a split-Cas9 enzyme complex

Type V CRISPR-Cas Cpf1 endonuclease employs a unique mechanism for crRNA-mediated target DNA recognition

Analysis of protein–RNA interactions in CRISPR proteins and effector complexes by UV-induced cross-linking and mass spectrometry

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