Ailong Ke scite author profile

Ribozymes enhance chemical reaction rates using many of the same catalytic strategies as protein enzymes. In the hepatitis delta virus (HDV) ribozyme, site-specific self-cleavage of the viral RNA phosphodiester backbone requires both divalent cations and a cytidine nucleotide. General acid-base catalysis, substrate destabilization and global and local conformational changes have all been proposed to contribute to the ribozyme catalytic mechanism. Here we report ten crystal structures of the HDV ribozyme in its pre-cleaved state, showing that cytidine is positioned to activate the 2'-OH nucleophile in the precursor structure. This observation supports its proposed role as a general base in the reaction mechanism. Comparison of crystal structures of the ribozyme in the pre- and post-cleavage states reveals a significant conformational change in the RNA after cleavage and that a catalytically critical divalent metal ion from the active site is ejected. The HDV ribozyme has remarkable chemical similarity to protein ribonucleases and to zymogens for which conformational dynamics are integral to biological activity. This finding implies that RNA structural rearrangements control the reactivity of ribozymes and ribonucleoprotein enzymes.

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Structural basis for promiscuous PAM recognition in type I–E Cascade from E. coli

Hayes

Xiao

Ding

et al. 2016

Nature

168

297

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Clusters of regularly interspaced short palindromic repeats (CRISPRs) and cas (CRISPR-associated) operon form an RNA-based adaptive immune system against foreign genetic elements in prokaryotes1. Type I account for 95% of CRISPR systems, and have been utilized to control gene expression and cell fate2,3. During CRISPR RNA (crRNA)-guided interference, Cascade (CRISPR-associated complex for antiviral defense) facilitates crRNA-guided invasion of double-stranded DNA (dsDNA) for complementary base-pairing with the target DNA strand, while displacing the non-target strand, forming an R-loop4,5. Cas3 nuclease/helicase is recruited subsequently to degrade two DNA strands4,6,7. Protospacer adjacent motif (PAM) flanking target DNA is crucial for self vs. foreign discrimination4,8–16. Here we present a 2.45 Å crystal structure of E. coli Cascade bound to a foreign dsDNA target. The 5′-ATG PAM is recognized in double-stranded form, from the minor groove side, by three structural features in Cse1. The promiscuity inherent to minor groove DNA recognition rationalizes the puzzling observation that a single Cascade can respond to several distinct PAM sequences. Optimal PAM recognition coincides with a wedge insertion, initiating the directional target DNA strand unwinding for segmented base-pairing with crRNA. The non-target strand is guided along a parallel path 25 Å apart, and the R-loop structure is further stabilized by locking this strand behind Cse2 dimer. These observations provide the structure basis for understanding the PAM-dependent directional R-loop formation process17,18.

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Structure Basis for Directional R-loop Formation and Substrate Handover Mechanisms in Type I CRISPR-Cas System

Xiao

Luo

Hayes

et al. 2017

Cell

183

261

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Summary Type I CRISPR systems feature a sequential dsDNA target searching and degradation process, by crRNA-displaying Cascade and nuclease-helicase fusion enzyme Cas3, respectively. Here we present two cryo-EM snapshots of the Thermobifida fusca Type I-E Cascade: 1) unwinding 11-bp of dsDNA at the seed-sequence region to scout for sequence complementarity, and 2) further unwinding of the entire protospacer to form a full R-loop. These structures provide the much-needed temporal and spatial resolution to resolve key mechanistic steps leading to Cas3 recruitment. In the early steps, PAM recognition causes severe DNA bending, leading to spontaneous DNA unwinding to form a seed-bubble. The full R-loop formation triggers conformational changes in Cascade, licensing Cas3 to bind. The same process also generates a bulge in the non-target DNA strand, enabling its handover to Cas3 for cleavage. The combination of both negative and positive checkpoints ensures stringent yet efficient target degradation in Type I CRISPR-Cas systems.

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Cas5d Protein Processes Pre-crRNA and Assembles into a Cascade-like Interference Complex in Subtype I-C/Dvulg CRISPR-Cas System

et al. 2012

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SUMMARY Clustered regularly interspaced short palindromic repeats (CRISPRs), together with an operon of CRISPR-associated (Cas) proteins, form an RNA-based prokaryotic immune system against exogenous genetic elements. Cas5 family proteins are found in several Type I CRISPR-Cas systems. Here we report the molecular function of Subtype I-C/Dvulg Cas5d from B. halodurans. We show that Cas5d cleaves pre-crRNA into unit length by recognizing both the hairpin structure and the 3′ single stranded sequence in the CRISPR repeat region. Cas5d structure reveals a ferredoxin domain-based architecture and a catalytic triad formed by Y46, K116 and H117 residues. We further show that after pre-crRNA processing, Cas5d assembles with crRNA, Csd1, and Csd2 proteins to form a multi-subunit interference complex similar to E. coli Cascade (CRISPR-associated complex for antiviral defense) in architecture. Our results suggest that formation of a crRNA-presenting Cascade-like complex is likely a common theme among Type I CRISPR subtypes.

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Crystal structures of the SAM-III/SMK riboswitch reveal the SAM-dependent translation inhibition mechanism

Smith

Fuchs

et al. 2008

Nat Struct Mol Biol

150

233

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Three distinct classes of S-adenosyl-l-methionine (SAM)-responsive riboswitches have been identified that regulate bacterial gene expression at the levels of transcription attenuation or translation inhibition. The SMK box (SAM-III) translational riboswitch has been identified in the SAM synthetase gene in members of the Lactobacillales. Here we report the 2.2-Å crystal structure of the Enterococcus faecalis SMK box riboswitch. The Y-shaped riboswitch organizes its conserved nucleotides around a three-way junction for SAM recognition. The Shine-Dalgarno sequence, which is sequestered by base-pairing with the anti–Shine-Dalgarno sequence in response to SAM binding, also directly participates in SAM recognition. The riboswitch makes extensive interactions with the adenosine and sulfonium moieties of SAM but does not appear to recognize the tail of the methionine moiety. We captured a structural snapshot of the SMK box riboswitch sampling the near-cognate ligand S-adenosyl-l-homocysteine (SAH) in which SAH was found to adopt an alternative conformation and fails to make several key interactions.

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Ailong Ke

A conformational switch controls hepatitis delta virus ribozyme catalysis

Structural basis for promiscuous PAM recognition in type I–E Cascade from E. coli

Structure Basis for Directional R-loop Formation and Substrate Handover Mechanisms in Type I CRISPR-Cas System

Cas5d Protein Processes Pre-crRNA and Assembles into a Cascade-like Interference Complex in Subtype I-C/Dvulg CRISPR-Cas System

Crystal structures of the SAM-III/SMK riboswitch reveal the SAM-dependent translation inhibition mechanism

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